Ophthalmology Update - Cleveland Clinic

Cleveland Clinic Cole Eye Institute | Ophthalmology Update Special Edition 2006
Cole Eye Institute
Ophthalmology
Update Special
Edition 2006

I n t h I s I s s u e :
02 Investigations
34 Innovation
38 staff
46 education and training
59 Research
Cleveland Clinic’s campus includes the Cole Eye Institute, lower left.

i n v e s t i g a t i O n s
Dear Colleagues
Welcome to an expanded special edition of Ophthalmology Update. We hope you find
the information on our ongoing clinical and basic science investigations to be interest-
ing and helpful in your everyday practice.
in addition, we have included a special addendum that provides an overview of the
exciting and cutting-edge capabilities and programs that are available here at the cole
eye institute. the sections in it are:
• innovation: What makes us different
• staff: Who we are
• education and training: Our commitment to professional development
• research: Our relentless pursuit of answers
We are very excited about the work that is being done by our clinicians and researchers
and remain committed to forging partnerships between the two groups. We have found
this to expedite the process of turning an idea into the highest quality clinical practice.
this issue also describes our 2006-2007 programs in Ophthalmic education, one of the
largest hospital-based continuing medical education programs in the country, and our
distinguished lecture series, featuring some of the biggest names in eye research. We
hope you will be able to join us at one or more of these events this year.
please do not hesitate to contact us with questions about our events or for more information
on how we can help you as you care for your patients.
hilel lewis, m.d.
Director, Cole Eye Institute
Chairman, Division of Ophthalmology
andrew p. schachat, m.d.
Vice Chair of Clinical Affairs
// c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i Oc . pOh rt g h/ ea yl e m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6 //

i n v e s t i g a t i O n s
i n t h i s s e c t i O n :
03 retina
13 cornea
22 glaucoma
23 pediatrics
27 Oncology
28 refractive surgery
30 Uveitis
32 Oculoplastics
Investigations
When the lines between research and patient care blur, doors
open and excellence flourishes.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Cole Eye Researchers Aiming to Elucidate
Physiological and Pathological Roles of TIMP3
Identification of the role of vascular endothelial
growth factor (VEGF) in the development
of choroidal neovascularization (CNV) has led
to exciting advances in treatment for exudative
age-related macular degeneration (AMD).
However, understanding of the pathogenesis
and regulation of ocular neovascularization is
still very limited.
at the cole eye institute, Bela anand-apte, m.B.B.s.,
ph.d., has been conducting research aiming to characterize
the physiological role of tissue inhibitor of
metalloproteinase-3 (timp3) and to elucidate the
mechanisms by which it might regulate angiogenesis in
eyes with amd and sorsby’s fundus dystrophy (sFd).
starting off with the basic knowledge that proteolytic
degradation of capillary basement membrane by
matrix metalloproteinases (mmps) is an initiating
event in the development of new blood vessel growth,
dr. anand-apte and colleagues focused their attention
on the timps that inhibit mmp function. their
interest was directed to timp3 because in contrast
to other members of the timp family, timp3 uniquely
binds to extracellular matrix. While these studies
were under way, independent researchers linked
mutations in the timp3 gene to sFd.
“although timp3 is ubiquitous throughout the body,
patients with sFd have only ocular symptoms.
therefore, it made sense that as a bound protein,
timp3 would have a localized effect,” dr. anandapte
explains.
experiments conducted so far in a mouse model of
laser-induced cnv show that timp3 is a potent inhibitor
of angiogenesis. additional studies indicate
that its mechanism appears to involve inhibition
of vegF action by preventing vegF from binding to
its receptors. Ongoing studies are examining what
effect timp3 might have on the progenitor cells that
are known to be involved in the development of cnv
in the mouse model.
the researchers are also aiming to understand the
role of the mutated timp3 in sFd with the hope that
information generated will provide clues to its
participation in amd-related cnv pathogenesis.
preliminary results from functional studies show that
the mutated protein does not inhibit angiogenesis
like the wild-type timp3, reports dr. anand-apte.
experiments are also under way to investigate whether
timp3 could be used therapeutically to prevent cnv.
“Knowing that timp3 inhibits vegF, we are interested
in determining if it has efficacy in regulating
vegF-mediated pathological angiogenesis,” dr.
anand-apte says.
initial studies are being performed with intravitreal
delivery of timp-3, but in the future, other modes of
administration will be examined, including subcutaneous
and scleral injections as well as intravitreal
delivery using a controlled-release system.
i n v e s t i g a t i O n s
For more information, contact
Bela Anand-Apte, M.B.B.S.,
Ph.D., at anandab@ccf.org.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n v e s t i g a t i O n s
Biomarker Discovery Research Aims to
Develop Tools for Predicting AMD Susceptibility,
Therapeutic Monitoring
Age-related macular degeneration (AMD)
continues to be the leading cause of
blindness among older people in Western
countries. Current estimates indicate that
more than 9 million people in the United
States are affected by some form of AMD,
with about one out of every five of those
patients having advanced AMD and being
legally blind.
at the cole eye institute, John W. crabb, ph.d., and
colleagues have been working to identify biomarkers
that could be used to predict who is at risk for
amd prior to the appearance of clinically evident
disease. such biomarkers could also be useful for
monitoring therapeutic efficacy in early intervention
or prophylaxis. they are hoping that measurement of
disease-related peptides in plasma might provide
useful tools for predicting amd susceptibility.
“plasma contains about 5,000 peptides that are
derived as proteolytic degradation products from
tissues throughout the body. We are using mass
spectrometry and peptidomic profiling in my laboratory
to sort through these plasma peptides as an
approach to monitoring the health of the retina,”
dr. crabb explains.
Based on findings from a series of previous studies,
the research for defining amd biomarkers has focused
on oxidative protein modifications known as
carboxyethylpyrrole (cep) adducts. Originally, dr.
crabb and colleagues discovered cep adducts in
drusen and found elevated levels in other ocular tissues
such as Bruch’s membrane from patients with
amd compared with normal controls. they then
found that patients with amd (areds categories 2, 3
and 4) also had higher plasma levels of cep adducts
and cep autoantibodies relative to age-matched normal
subjects.
cep protein adducts are uniquely derived from
oxidative fragmentation of docosahexaenoate-containing
lipids, which are abundant in the retina.
animal studies in rats and mice have shown that
intense light induces cep adducts in retina and that
cep adducts can stimulate new blood vessel growth.
this suggests that cep adducts may play a role in
choroidal neovascularization in advanced amd.
Other collaborative studies have shown that cep
proangiogenic activity can be inhibited with monoclonal
antibody to cep, raising the possibility that
cep antibodies may offer another avenue to amd
therapeutics. several laboratories elsewhere have
recently shown an association between genetic
variants of complement components and susceptibility
to amd, implicating inflammatory processes
in amd pathogenesis. dr. crabb thinks cep adducts
and autoantibodies may play a role in the inflammatory
processes relevant to amd.
“taken together, these findings led us to hypothesize
that the cep adducts serve as a primary catalyst in
amd pathology and are causally involved in drusen
formation, Bruch’s membrane thickening, choroidal
neovascularization and activation of the immune
response,” dr. crabb says.
as a proteomic approach to amd biomarker discovery,
the researchers used anti-cep monoclonal
antibodies attached to magnetic beads to fractionate
plasma for recovery of cep adducted peptides.
the recovered peptides were analyzed by maldi tOF
mass spectrometry followed by bioinformatic
methods to determine which peptides were statistically
significantly different between patients with
amd and controls. these peptides were then grouped
together in patterns or clusters based on the mass
analyses. remarkably, the resulting patterns also
reflected with significant accuracy whether the
plasma was from a patient with amd or a normal
control donor. For example, from 170 plasma
samples, including 90 from amd donors (areds categories
2, 3 and 4) and 80 from unaffected control
donors, correct identification as either amd or normal
was obtained for 94% of the 170 plasma samples
based on the mass analysis.
current work is focused on characterizing the structure
of key peptides in the patterns that distinguish
amd from normal plasma. such sequence information
is expected to provide the identity of (1) peptide
antigens for producing new antibodies that could be
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

useful prognostic tools and (2) the parent protein,
which could lead to new insights into mechanisms of
amd pathology.
immunological measurement of plasma cep adducts
and cep autoantibody titer may also offer a
method for therapeutic monitoring. For example, in
a preclinical study evaluating an experimental drug
that protects rats from retinal light damage, cep
parameters in plasma were measured by elisa and
found to be decreased relative to those in control
animals without drug treatment.
“We believe that a combination of these techniques
may eventually provide methods for early identification
of amd-susceptible individuals and for
monitoring the efficacy of amd therapeutics. however,
clinical validation of these methods requires
more time and research,” dr. crabb concludes.
i n v e s t i g a t i O n s
For more information,
contact John W. Crabb, Ph.D.
at crabbj@ccf.org.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n v e s t i g a t i O n s
For more information, contact
Stephanie A. Hagstrom, Ph.D.,
at hagstrs@ccf.org.
Mutational Screening Efforts Empowered
by State-of-the-Art Technology
and Proteomics-Guided Searches
Elucidation of the molecular genetics underlying
inherited diseases holds promise for a
number of important clinical applications
relating to screening, diagnosis, counseling
and treatment. In her research laboratory at
the Cole Eye Institute, geneticist Stephanie
A. Hagstrom, Ph.D., has been focusing on
using a candidate gene approach to screen
for mutations associated with inherited retinal
degenerations, including retinitis pigmentosa,
Leber congenital amaurosis and juvenile and
age-related forms of macular degeneration.
in addition, she has been collaborating with colleague
John W. crabb, ph.d., in performing genomics
studies that are directed by findings in dr.
crabb’s proteomics research to identify biomarkers
for age-related macular degeneration (amd) and
glaucoma.
“Our hope is that the combined efforts of genomics
and proteomics will yield biomarkers that can be
detected in those at risk for these diseases prior to
vision loss,” says dr. hagstrom.
all of the physicians on staff at the cole eye institute
alert the coordinator of the center for genetic eye
diseases if they see a patient with a known inherited
ocular disorder or who has a disease that is thought
may have a genetic component, such as a child with
syndromic congenital malformations including eyerelated
findings. the coordinator tries to recruit
those patients into the genetic screening program,
and after obtaining consent, performs a complete
medical history and blood draw.
in dr. hagstrom’s lab, the dna from the specimens
is submitted to direct sequence analysis using highthroughput,
semi-automated screening to identify
the presence of any differences compared with a
control sample.
“Our lab is equipped with cutting-edge molecular biology
technology that allows us to screen specimens
from hundreds of patients each day and puts us on
par with much larger laboratories in the country,”
she says.
the screening efforts may be focused on particular
candidate genes based on existing reports of genetic
associations. however, dr. hagstrom is also taking a
more targeted approach to the mutation screening
guided by the findings of dr. crabb’s proteomics
research.
For example, based on dr. crabb’s studies characterizing
the proteins in drusen and the findings of
peptidomic profiling of plasma in patients with
amd, mutation screening has been undertaken
focusing on pathways of genes that are involved in
the regulation of oxidative damage and immunemediated
processes that have been implicated in
amd pathogenesis. in addition, proteomics studies
conducted by dr. crabb revealing the presence of
cochlin (cOch) deposits in the trabecular meshwork
of both patients with open-angle glaucoma
and glaucomatous dBa/2J mice have focused mutational
screening on the cOch gene, as well as other
genes, in patients with glaucoma.
those studies are still in progress, but have led to the
identification of several genetic sequence changes in
both patients with amd and glaucoma that are being
studied further to identify their functional consequences
and determine whether they represent
a pathogenic link.
“We believe this joint approach involving our two
laboratories is somewhat unique in the genetic
research field, and we believe it offers a synergy that
will enable the discovery of underlying genetic
causes of these common sight-threatening diseases,”
dr. hagstrom says.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Studies on Redox-Sensitive Retinal Proteins
Aim to Provide Clues for Strategies to Counter
Oxidative Stress
Although the pathophysiology of age-related
macular degeneration (AMD) remains
unclear, available evidence points to a role of
oxidative stress. Consistent with that concept,
results from the Age-Related Eye
Disease Study (AREDS) indicated a positive
effect of antioxidant therapy with high doses
of vitamins and minerals for reducing disease
progression in patients with advanced AMD.
research being conducted by george hoppe, m.d.,
ph.d., and Jonathan sears, m.d., at the cole eye institute
is aiming to gain insight into the endogenous
antioxidant protective mechanisms in the retina with
the hope that information may ultimately be used to
design more effective antioxidant interventions.
“Understanding of the molecular basis for the antioxidant
mechanisms in the retina could allow us
to develop more targeted therapies that could induce
or facilitate their function. in current clinical use,
antioxidant treatment involves administration of
high doses and yields only a modest benefit. We
believe that therapeutic efficiency could be enhanced
by more precise elucidation of the molecular basis
for antioxidant mechanisms,” says dr. hoppe.
his research is focusing on characterizing redoxsensitive
proteins and the changes they undergo in
response to oxidative stress, and in particular determining
proteins that undergo redox-dependent
interactions with glutathione, a ubiquitous peptide
anti-oxidant.
“Oxidative modifications of cysteine residues on proteins
is a potent way of regulating protein function,
and when there is a redox shift toward oxidative
potential, glutathione tends to bond covalently with
the sulfhydryl moieties on proteins and this in turn
results in changes in protein conformation and
activity,” he explains.
so far, drs. hoppe and sears have identified two proteins
that appear to mediate retinal adaptation to a
high oxidative environment. the chaperone heat
shock cognate protein 70 (hsc70) is one of those
FIGURE 1
FIGURE 2
proteins, and their studies show that as a result of
interactions with glutathione during oxidation,
hsc70 increases its chaperone activity and becomes
more protective.
“another interesting finding is that this increase
in hsc70 chaperone activity occurs as an atp-independent
process. that suggests this protein can
adapt to conditions of high oxidative stress where
atp concentration is reduced by forming disulfide
bonds with glutathione,” dr. sears says.
the nuclear transcription factor high mobility group
protein B1 (hmgB1) is a second protein that they
have identified as being redox-sensitive. hmgB1,
which also has dna chaperone-like properties, has
been shown to be modified by glutathione with
resultant changes in its chaperone activity. most
Continued on page 8
i n v e s t i g a t i O n s
Figure 1: Expression of HmgB1
in the retina is seen in green
and red.
Figure 2: A three-dimensional
model of HmgB1 molecule
interacting with DNA.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n v e s t i g a t i O n s
For more information, contact
George Hoppe, M.D., Ph.D.,
at hoppeg@ccf.org.
Studies on Redox-Sensitive Retinal Proteins
Continued from page 7
recently, in a rodent study, drs. hoppe and sears
found that the expression of hmgB1 in retinal photoreceptor
cells is under circadian regulation.
“Our studies show that the expression of this protein
peaks during the middle of the day and is lowest at
night, even in animals that are kept in the dark.
hmgB1 is also found in other cells, but its expression
and activity in those cells is constant rather than
cyclical,” dr. hoppe says.
Based on those findings, drs. hoppe and sears are
postulating that hmgB1 is essential for transcription
activity in the photoreceptors during daylight
hours and that it regulates or facilitates expression
of genes that are important for photoreceptor
function during the light phase.
References
chai y-c, hoppe g, and sears Je. reversal of protein
s-glutathiolation by glutaredoxin in the retinal pigment
epithelium. exp eye res 76:155-159, 2003.
hoppe g, chai y-c, and sears Je. endogenous Oxidoreductase
expression is induced by aminoglycosides.
arch Biochem Biophys 414:19-23, 2003.
Other studies with hmgB1 have led to the identification
of the function of each of its three cysteine
residues. two have been found to participate in the
formation of the intermolecular disulfide bridge that
results in altered molecular conformation and the
third is involved in mediating hmgB1 transfer in
and out of the nucleus. Upon obliteration of that
third cysteine, nucleocytoplasmic shuttling of
hmgB1 no longer occurs.
“Understanding of the regulation of transcription in
retinal photoreceptors is of interest as it may suggest
strategies for regenerating photoreceptors that are
being lost as a result of age or disease. Our finding
that the expression of hmgB1 is under circadian
control may suggest new concepts on its function,”
dr. sears says.
epithelium converts heat shock protein 70 to an
active chaperone. exp eye res 78:1085-1092, 2004.
yokoyama t, yamane K, minamoto a, mishima hK,
yamashita h, hoppe g, and sears J. protein expression
patterns of cultured human rpe cells Under
hyperglycaemic condition investigated by proteome
analysis. (in press)
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Diverse Spectrum of New and Investigational
AMD Therapies Target VEGF
Identification of the activity of vascular endothelial
growth factor (VEGF) as a regulator of
angiogenesis and vascular permeability and
evidence of its role in the pathogenesis of
exudative age-related macular degeneration
(AMD) has led to the development of a number
of pharmacologic approaches targeting
VEGF as a new strategy to treat AMD.
in december 2004, pegaptanib sodium (macugen)
became the first anti-vegF agent approved by the
Fda for the treatment of wet amd. an aptamer that
acts to bind and inactivate vegF, pegaptanib sodium
was an exciting new modality because it received
an indication for use in eyes with any subfoveal choroidal
neovascular lesion, regardless of size, location
or composition. research with that compound is
continuing, and an ongoing study is evaluating its
role in combination therapy with verteporfin photodynamic
therapy (pdt).
now, Fda approval of a second anti-vegF agent,
ranibizumab (lucentis), is here. ranibizumab is an
antibody fragment that binds vegF, and in phase iii
trials of patients with exudative amd, it demonstrated
impressive potential to improve vision rather than
simply slowing its progressive loss.
meanwhile, a host of other pharmacologic agents
that act through diverse mechanisms of action to
inhibit the activity of vegF are in various stages
of clinical investigation for the treatment of amdrelated
choroidal neovascularization.
“there has been little to offer in the way of therapeutic
intervention for patients who are losing their sight
from amd, and so it is very exhilarating to see this
proliferation of clinical research focusing on amd
treatment. considering the number of compounds
now in clinical trials, their innovative mechanisms,
their favorable safety profiles even with repeated
treatments and the exciting responses that have been
achieved with ranibizumab, this is certainly a hopeful
and exciting time for patients affected with amd
and the physicians who treat them,” said peter K.
Kaiser, m.d., of cleveland clinic cole eye institute.
in January 2006, dr. Kaiser had the honor of being
the first to present publicly the results from the phase
iii anti-vegF antibody for the treatment of predominantly
classic chOroidal neovascularization
in amd (anchOr) study that demonstrated ranibizumab
had activity for improving vision. after 1 year
in that study, about 95% of patients treated with ranibizumab
0.3 mg or 0.5 mg had stable or improved
vision (lost less than 15 etdrs letters), and similar
results were achieved after 1 year in the phase iii
minimally classic/occult trial of the anti-vegF antibody
ranibizumab in the treatment of neovasuclar
amd (marina) study. in anchOr, patients in the
ranibizumab 0.3 mg and 0.5 mg groups had average
vision gains of 8.5 letters and 11 letters, respectively,
and almost 40% had a clinically significant improvement
in vision (gain of 15 letters or more). controls
in anchOr received pdt. they experienced an
average vision loss and only about 6% had a clinically
significant improvement.
“the benefits achieved in this study using ranibizumab
also occurred regardless of lesion subtype and translate
into important effects on patient function and
quality of life,” dr. Kaiser says.
the cole eye institute is also distinguished as the
site of the first human treatment using a novel antivegF
approach based on synthetic small interfering
rna (sirna) therapeutics. the compound being
studied, sirna-027 (sirna), prevents expression
of vegF receptor-1 (vegFr-1) by silencing the gene
coding for that protein.
“the vegFr-1 is stimulated by both vegF and placental
growth factor (plgF), which may also play a
role in angiogenesis and potentiate the activity of
vegF. By interfering with the action of all agonists
for vegFr-1, sirna-027 may offer a more powerful
treatment modality than those approaches targeting
only vegF,” notes dr. Kaiser.
another sirna (cand5, acuity pharmaceuticals) is
also under investigation at other centers. that agent
blocks the formation of vegF altogether, rather than
acting to inhibit the activity of protein that has
Continued on page 10
i n v e s t i g a t i O n s
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n v e s t i g a t i O n s
For more information, contact
Peter K. Kaiser, M.D., at
kaiserp@ccf.org.
Diverse Spectrum of New and Investigational AMD Therapies
Continued from page 9
already been produced, and is showing promise in
initial trials, dr. Kaiser says. the digital Oct reading
center of the cole eye institute serves as the
reading center for the cand5 clinical studies.
cole eye institute is also participating in a phase ii
study of intravitreal vegF trap (regeneron) therapy.
vegF trap is a fusion protein of key domains of
vegFr-1 and vegFr-2 that acts as a receptor decoy
for vegF, “trapping” it with extremely high affinity
to prevent its binding to the endogenous vegF
receptor.
“the mechanism of the vegF trap is somewhat analogous
to ranibizumab, but the vegF trap may have
the benefit of a longer duration of action due to its
higher binding affinity. that potential is being tested
in the ongoing trial,” dr. Kaiser says.
several companies are also developing small-molecule
receptor tyrosine kinase inhibitors targeting vegF
receptors as a new approach to the treatment of
exudative amd.
although no formal studies are under way, dr. Kaiser
and colleagues at the cole eye institute are evaluating
their experience with bevacizumab (avastin) as a
last-resort treatment for patients whose exudative
amd is refractory to other interventions. currently
available on the market as an intravenously administered
agent with approval for the treatment of
metastatic colorectal cancer, bevacizumab is being
used in off-label fashion as an intravitreal injection
in the treatment of exudative amd.
0 // O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

CSNB Mouse Models Provide Valuable Tool
for Understanding Disease Pathophysiology,
Developing Therapeutic Approaches
Congenital stationary night blindness (CSNB)
is a rare heritable disease that manifests in
various phenotypes, but all forms are characterized
by a profound loss of vision in darkness.
At Cleveland Clinic’s Cole Eye Institute, Neal
S. Peachey, Ph.D., and coworkers have made
significant advances in CSNB research based
on their identification and characterization of
naturally occurring mouse models for two
forms of the human disease.
“as these animals provide accurate models of clinical
csnB, we believe that the anatomical, biochemical and
functional observations made with them will have
direct relevance to humans and that they will provide
a valuable platform for future research aiming to
develop targeted gene therapy,” dr. peachey says.
the first murine model of csnB was discovered serendipitously
in animals being used in an unrelated
research project. results of electroretinography
(erg) studies revealed the mouse had a normal
a-wave but an absent b-wave, and thus it was named
the nob (no b-wave) mouse.
“the erg pattern in this animal is analogous to what
is seen in patients with complete csnB (csnB1) and
it indicates there is normal rod phototransduction
function but a communication defect such that
the photoreceptor cells are failing to activate the
depolarizing bipolar cells,” dr. peachey explains.
Other studies identified that these animals were
affected by the same X-linked inheritance pattern
seen in humans with csnB1, and work conducted in
collaboration with researchers from the University
of louisville led to the determination that they
also had a mutation in the nyx gene encoding for the
protein nyctalopin.
extensive histological studies have also been conducted
using general light and electron microscopy
to evaluate structures from the photoreceptors to
the bipolar cells, but have found no morphological
defects in the retina.
current research is focusing on identifying the
function of nyctalopin in the normal retina and in
developing gene therapy approaches. encouraging
success has been achieved in rescuing the erg
defect in the nob mice by introducing a correct copy
of the nyx gene. those studies involved crossing
nob mice with transgenically engineered mice
expressing and transmitting nyx.
“Our ability to achieve bipolar cell expression of
nyctalopin in offspring of nob mice and rescue their
erg function has huge implications for human
therapy. as we expect that the retina in patients
with csnB1 will be normal and that they too will
have null mutations, they are likely to be very good
candidates for gene therapy. in theory, therefore, if
we can insert a normal copy of the protein into
the retina, we should be able to restore night vision
in these individuals,” dr. peachey says.
he acknowledges that the research in the mouse
model has centered on turning the gene on during
development. Ongoing studies are investigating
whether it can be turned on after birth and at different
stages of life.
the second mouse model of csnB, known as the
nob2 mouse, has abnormal light- and dark-adapted
b-waves on erg and so is similar to patients with
incomplete csnB (csnB2). genetic studies in those
animals identified they had a cns-specific deletion
of the gene encoding for a subunit of the l-type
Continued on page 12
i n v e s t i g a t i O n s
ERGs recorded from three
mice in response to a bright
stimulus flash presented in
darkness. Note that the normal
response (black line) includes
a negative-polarity a-wave that
is followed by a positive-polarity
b-wave. In nob1 mice (blue
line), only the a-wave is seen,
indicating that rod photoreceptors
do not transmit information
to bipolar cells, the next neuron
in the visual pathway. In nob2
mice (red line), the b-wave is
reduced in amplitude but is
clearly present, indicating that
rod photoreceptors continue to
transmit information to
bipolar cells.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n v e s t i g a t i O n s
For more information, contact
Neal S. Peachey, Ph.D., at
peachen@ccf.org.
CSNB Mouse Models Provide Valuable Tool
Continued from page 11
calcium channel that normally regulates release of
glutamate at the photoreceptor terminal.
morphological studies undertaken by dr. peachey
and colleagues found extensive anatomic abnormalities
in the outer synaptic and outer plexiform layers
of the retina, and functional studies showed a
reduced dynamic range of On-center cells without
any defects in the response of OFF-center cells.
Further studies in this model are focusing on
defining the role of the l-type calcium channels in
ribbon synapse formation.
Because csnB is so rare, occurring in an estimated 1
in 500,000 people, and is likely underdiagnosed,
there is a lack of information about anatomic defects
in affected patients. to date, findings have been
published from a single postmortem specimen, but
the relevance of those observations is uncertain as
the patient had an undefined form of csnB and
comorbid glaucoma, notes dr. peachey.
“We are hoping now to use high-resolution Oct in
patients with these two forms of csnB to see if their
anatomical findings correlate with the observations
made in our animal models,” he concludes.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Study Conclusively Links Haze After PRK
to Stromal Surface Irregularity
Despite advances in laser technology, clinically
significant haze still develops in 2% to
4% of eyes undergoing PRK for the correction
of higher levels of myopia. Various
hypotheses have been put forth regarding
the pathogenesis for haze formation, but no
studies have produced definitive evidence to
support any one theory.
now, however, results of a study undertaken by steven
e. Wilson, m.d., and colleagues at the cole eye institute
are providing new understanding about the basic
mechanisms for the development of haze after prK.
in an elegantly designed experiment using a rabbit
model, the researchers demonstrated conclusively
that haze development after prK was related to
levels of stromal surface irregularity and anterior
stromal myofibroblast generation. in addition, they
showed haze formation could be mitigated by
performing phototherapeutic keratectomy (ptK)
smoothing after prK and provided evidence that
defective basement membrane regeneration in eyes
with surface irregularity likely plays a role in the
development of haze.
“it has always been suspected that haze develops after
prK because of the rough stromal surface that
remains after the ablation, and there has been some
indirect evidence to support that concept. the
results of our study demonstrate unequivocally that
it is critical to leave a smooth surface at the end of
any surface ablation procedure, and they also support
the use of ptK-smoothing to achieve that goal.
Based on another study we will be reporting that investigated
the long-term effects of mitomycin-c on
stromal cells, ptK-smoothing is certainly an option
to adjunctive mitomycin-c from a safety standpoint
as a method for minimizing haze when performing
prK for higher corrections,” says dr. Wilson.
the study divided rabbits into eight groups to receive
no treatment, –4.5 d prK, –4.5 d prK with a fine mesh
screen positioned in the path of the laser to create
surface irregularity by blocking 10%, 30% or 50% of
followed by ptK smoothing, –9.0 d prK or –9.0 d prK
with ptK smoothing. haze was graded at the slit lamp
after 4 weeks using a scale of 0 to 4.
consistent with previous studies, the results of those
evaluations showed haze was trace or absent in the
eyes treated with the –4.5 d ablation whereas severe
haze developed after the -9.0 d prK. in the groups
where the –4.5 d prK was performed with the mesh
screen in place for part of the procedure, the amount
of haze present increased proportionally as the
percentage of surface irregularity increased.
the effect of surface irregularity on haze development
was also demonstrated by the findings in eyes that
underwent ptK smoothing. in eyes that had a –4.5 d
ablation with 50% irregularity, use of the ptK smoothing
technique essentially mitigated haze development,
the terminal pulses, –4.5 d prK with 50% irregularity Continued on page 14
i n v e s t i g a t i O n s
Basement membrane defects and
myofibroblasts in corneas with
irregular surfaces after PRK.
Triple staining of the central
cornea for α-smooth muscle
actin-expressing myofibroblasts
(red) and integrin beta-4 (green),
along with DAPI (blue).
A) Note the more homogeneous
basement membrane regeneration
in a cornea without haze
after –4.5 D PRK.
B) Basement membrane with
obvious disruptions (arrows)
adjacent to an area with more
uniform basement membrane
(arrowheads) Red α-smooth
muscle actin-positive cells can
be noted below the defects in
the basement membrane.
Magnification is 400x.
Reprinted from Experimental Eye
Research; Vol 82; Marcelo V.
Netto, Rajiv R. Mohan, Sunilima
Sinha, Ajay Sharma, William
Dupps, Steven E. Wilson; Stromal
haze, myofibroblasts, and surface
irregularity after PRK; Pages 788
– 797; Copyright 2006, with
permission from Elsevier
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n v e s t i g a t i O n s
For more information, contact
Steven E. Wilson, M.D., at
wilsons4@ccf.org.
Study Conclusively Links Haze After PRK
Continued from page 13
while ptK smoothing after the –9.0 d prK treatment
significantly reduced haze development, but did not
eliminate it.
“the failure of ptK smoothing to prevent haze after
the higher correction indicates that there must be additional
factors besides stromal irregularity that contribute
to haze development,” dr. Wilson notes.
the rabbit study also confirmed that myofibroblast
density was a key factor in producing corneal haze.
Use of alpha-smooth muscle actin staining to identify
myofibroblasts showed the density of those cells
in the anterior stroma corresponded to the severity
of haze.
“the relationship between haze severity and myofibroblast
density makes sense since myofibroblasts
are less transparent than keratocytes and also produce
collagen and other stromal matrix components
that are disorganized compared with components in
normal stroma,” dr. Wilson says.
Using high-power confocal microscopy and immunohistochemical
staining techniques to examine
the corneas in vitro at 4 weeks after prK when the
epithelium had healed, the researchers also identified
residual ultrastructural defects in the basement
membrane in eyes with surface irregularity and
grade 1 or greater haze, along with localization of
the myofibroblasts beneath those breaks in the
basement membrane.
“the finding of imperfect regeneration of the basement
membrane is perhaps the most important finding of
this study because it can be used to explain why higher
prK corrections are associated with more haze. Our
study suggests that phenomenon occurs because the
higher correction produces more surface irregularity
that translates into structural and /or functional basement
membrane anomalies and greater potential for
transforming growth factor-beta, and perhaps other
cytokines, to penetrate into the stroma from the overlying
epithelium to stimulate myofibroblast generation
from stromal fibroblasts,” dr. Wilson says.
the study also provided evidence that late apoptosis
of the myofibroblast cells may be a key mechanism
for the disappearance of post-prK haze over time.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Corneal Biomechanical Clues Studied to Optimize
Results of Intrastromal Ring Segment Surgery
A number of studies demonstrate that insertion
of intrastromal ring segments (Intacs,
Addition Technology) can be a useful procedure
to reduce corneal irregularity, improve
vision and delay or avoid the need for corneal
transplantation in eyes with keratoconus and
other ectatic disorders. However, the mechanisms
mediating the effect of the intrastromal
ring segments on corneal curvature are not
fully understood, and topographic and visual
outcomes can be less predictable than desired.
Therefore, identification of prognostic
factors for determining the treatment response
would be a welcome advance for optimizing
surgical decision-making.
since placement of the ring segments presumably
works via a biomechanical effect, William J. dupps,
Jr, m.d., ph.d., and Bennie h. Jeng, m.d., at cleveland
clinic’s cole eye institute are studying whether there
is any correlation between preoperative corneal biomechanical
properties and surgical outcome. Based
on the hypothesis that stiffness of the cornea may
be an important variable affecting the response to
segment placement, they are using non-invasive
ultrasound elastometry (sonic eye, priavision) to
measure stiffness in various locations across the
cornea in normal donor eyes prior to and after
intacs placement surgery.
“We believe patients with keratoconus represent
a very heterogeneous group both biologically and
biomechanically. as a result, it is difficult to predict
with high confidence the response any given patient
will have topographically to segment insertion,”
says dr. dupps.
“identifying features that predict the flattening
response to intrastromal segments could help
surgeons to select candidates most likely to benefit
from the procedure and also provide a guide for
surgical dosing, which is a function of ring diameter,
channel diameter, segment thickness and channel
depth,” he continues.
the prototype elastometer they are using to investigate
corneal stiffness consists of a handheld probe
with a resonant element and receiver spaced 4.5 mm
apart. it measures the “time-of-flight” in velocity units
(meters per second) for propagation of a low-frequency
ultrasonic stimulus. Wave velocity is a marker for
corneal stiffness because the speed of a sound wave
increases with increasing rigidity of the medium. dr.
dupps and co-investigators at the cole eye institute
have a scientific manuscript in press describing the
technique and illustrating its potential utility in a
variety of clinically important situations.
“this technology is noninvasive and has the advantage
of being able to measure regional and directional
differences in stiffness,” says dr. dupps.
Using a template dr. dupps devised in early studies
with the device, measurements are acquired along 10
corneal vectors, including the horizontal and vertical
vectors at the center of the cornea, radial vectors in
all four peripheral quadrants and circumferential
vectors just anterior to the limbus of the same quadrants.
average velocities were calculated for the central,
radial and circumferential regions and analyzed for
correlations to the surgical curvature change measured
from intraoperative topography maps.
so far, an analysis of one ring segment size has been
performed in a small subset of three human globes
maintained at a physiological iOp of 15 mm hg and
with corneas that were restored to normal thickness
with hyperosmotic solution. measures of corneal
stiffness (surface wave velocity) and corneal curvature
(Keratron scout topography) were obtained
prior to surgery and after placement of two 0.45-mm
segments through a superior incision at 12 o’clock.
Both the incision and channels were created using
the standard intacs surgical kit.
the results showed a correlation between the surgical
change in simulated keratometry values and the preoperative
stiffness in the radial mid-peripheral vectors
such that the flattening effect was greater when preoperative
stiffness was higher. no relationships were
found between central and circumferential
Continued on page 16
i n v e s t i g a t i O n s
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n v e s t i g a t i O n s
For more information, contact
William J. Dupps, Jr., M.D.,
Ph.D., at duppsw@ccf.org.
Corneal Biomechanical Clues Studied to Optimize Results
Continued from page 15
stiffness measurements and curvature response to
intrastromal segment implantation.
“it is logical that the region of the cornea that was
found to be predictive of response directly straddles
the site of channel insertion. in other words, the
mechanical properties of the tissue closest to the
inserts seem to be most important in predicting
surgical response. these findings are very preliminary;
they are based on a small number of
non-keratoconic donor eyes and account only for
the acute biomechanical changes associated with
surgery. But continued experimentation in this vein
may provide us with predictive information
for planning surgery that we simply didn’t have
before,” dr. dupps says.
as a caveat, dr. dupps also notes that previous research
with the elastometer indicates that posterior
corneal properties may be relatively underrepresented
in the measurements it produces. Furthermore,
clinical measurement of corneal stiffness by this
technique involves additional challenges, including
a tendency toward much lower wave velocities
in the presence of a normal tear film.
“We are actively investigating technique and instrument
modifications to overcome these issues and
are fortunate to have the support of both addition
technology and priavision in this venture,” says
dr. dupps.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Autologous Serum Eyedrops May Offer Effective
Therapy for Patients with Intractable Ocular
Surface Disorders
Treatment of severe ocular surface disorders
remains a challenge, and in some patients,
the disorder is refractory to conventional interventions.
For them, Cole Eye Institute
ophthalmologist Bennie H. Jeng, M.D., has
found that the topical use of autologous
serum is a safe and often highly effective
modality for affording symptomatic relief
and/or promoting ocular surface healing.
relative to tears, autologous serum contains a similar
spectrum of growth factors, vitamins and immunoglobulins
that have positive epitheliotrophic
activity, and the concentrations of some of those
components in autologous serum exceeds that found
in tears. Over the past 2 years, dr. Jeng has used
autologous serum eyedrops to treat approximately
25 patients with a variety of ocular surface conditions
that were intractable to more conventional
therapies. the diagnoses in those patients included
persistent epithelial defects secondary to a variety
of etiologies as well as severe, chronic dry eye, often
associated with chronic graft-versus-host disease.
some patients with recurrent erosion syndrome
are also candidates for treatment with autologous
serum eyedrops.
Follow-up in those cases showed that improvement,
measured as a reduction in symptoms and/or as
epithelial repair, occurred fairly rapidly, within the
first few weeks of treatment, while complete healing
of epithelial defects was observed most of the time
within 4 weeks. Overall, the efficacy rate for autologous
tears has been 80% to 90%, reports dr. Jeng.
“While that still leaves us with a 10% to 20% failure rate,
considering that these are intractable cases of eyes
that have otherwise reached the end of the therapeutic
line, the outcomes achieved with autologous
tears are really quite impressive,” he says.
candidates for this experimental therapy are screened
to exclude people with hepatitis or hiv infection.
eligible patients have their blood drawn at cleveland
clinic. the sample is then spun down, and the sepa-
BEFORE
AFTER
rated serum is shipped to a pharmacy in california for
further processing and purification. the prepared autologous
serum eyedrops are shipped to the patients’
homes packaged in small containers that are kept frozen
until time for use.
in recent years, there has been an increase in reports
in the literature describing autologous serum eyedrops
as a treatment for ocular surface disorders. the
majority of those investigators have used autologous
serum that has been diluted to 20% with the addition
of normal saline. however, dr. Jeng has the pharmacy
prepare a 50% autologous serum formulation for
his patients.
“not only does this provide a higher concentration of
the epitheliotrophic factors, but it is also more viscous,
and that thicker consistency offers an additional
soothing effect when instilled into the eye,” he says.
Continued on page 18
i n v e s t i g a t i O n s
Figure 1: Eye prior to treatment
with autologus serum.
Figure 2: Same eye after
treatment.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n v e s t i g a t i O n s
For more information,
contact Bennie H. Jeng, M.D.,
at jengb@ccf.org.
Autologous Serum Eyedrops May Offer Effective Therapy
Continued from page 17
patients are usually instructed to begin treatment
with instillation every 2 hours, and then the frequency
of administration is titrated to response. Once there is
some onset of effect, dosing is reduced to four times
a day and it can be further reduced as healing occurs.
in patients who were being treated for persistent
epithelial defects, no recurrences have been observed
during follow-up of 6 to 12 months after treatment
discontinuation. patients using the autologous
serum for dry eye relief continue maintenance
therapy indefinitely.
treatment with the autologous serum eyedrops
has had an excellent safety profile. the drops are well
tolerated, and so far there have been no cases
of secondary infectious keratitis or any other
adverse events.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Switching from ECCE to Phacoemulsification in
Triple Procedures Can Yield Refractive Surprises
accurate iOl power prediction for eyes undergoing a
triple procedure with penetrating keratoplasty (pK),
cataract extraction and iOl implantation presents a
challenge because the preoperatively measured biometric
data used for power calculation can be significantly
altered by the surgery. nevertheless, the predictability
of refractive outcomes can be improved if
surgeons analyze their outcomes to determine average
postkeratoplasty keratometry values and personalized
a-constants for use in iOl power calculations.
Following that approach, cole eye institute surgeon
roger h. s. langston, m.d., was able to achieve good
refractive results when performing a triple procedure
with lens removal by extracapsular cataract extraction
(ecce). however, when he switched to phacoemulsification,
he encountered some surprises in
postoperative K values that were associated with a
poor refractive result.
now, dr. langston is further investigating his outcomes
after combined pK/phaco/iOl implantation to
try to identify factors and techniques that could improve
the accuracy of iOl power calculation. however,
his experience provides a cautionary note to
colleagues who may also be switching from ecce to
phacoemulsification.
“surgeons need to be aware that despite its advantages,
changing from ecce to small-incision cataract surgery
can alter the average corneal power after a triple
procedure. therefore, it is important to analyze one’s
outcomes carefully,” says dr. langston.
Weighing the risk of inaccurate iOl power calculation,
he suggests that it may also be worthwhile to consider
consecutive rather than simultaneous surgery, allowing
the cornea to heal after pK before going back to do
the cataract procedure and iOl implantation.
“Of course, the liability of the staged approach is that it
exposes the patient to the risks of a second procedure
and significantly delays visual rehabilitation since
one must wait until after the graft sutures are removed
to assure corneal curvature stability. however, the
pros and cons of both simultaneous and staged surgery
should probably be discussed with patients, who
can then make their own informed decision,”
dr. langston says.
he compared his outcomes of triple procedures
performed with ecce or phacoemulsification in a retrospective
study including eyes that underwent corneal
transplantation for Fuchs’ dystrophy. there were 22 cases
performed with ecce and 16 performed with phacoemulsification.
in the ecce eyes, the postoperative K
value averaged 47 d and ranged from 44.75 to 50.0 d.
mean astigmatism was 5 d with a range from 0 to 12 d.
in the phacoemulsification group, mean astigmatism
was 3.7 d with a range of 0 to 7.5 d. however, in analyzing
the K values, dr. langston found the corneas were
flatter overall (range 39.25 to 48.5 d) and on average
(mean K 45.4 d), and two eyes in particular had a
corneal power much lower than anticipated.
as a result, the refractive predictability was worse in
the eyes that underwent phacoemulsification. While
19 of the 22 eyes (86%) that had the triple procedure
with ecce were within 2 d of their intended se target,
only 9 of the 16 eyes (56%) undergoing phacoemulsification
had an achieved se within that range.
there are a number of factors that can influence the
corneal curvature outcome after a triple procedure. however,
recognizing that iOp affects tissue response during
trephination, dr. langston has hypothesized that his
experience may be explained by increased iOp variability
after phacoemulsification compared with ecce.
“Based on that concept, i started to measure iOp after
completing the phaco procedure and confirmed there
was significant variation,” dr. langston says.
currently, he is applying a honan balloon as he would
in eyes undergoing ecce in an effort to control iOp,
and will be analyzing his outcomes to see if that technique
is beneficial for limiting variation in corneal
curvature outcomes and improving refractive results.
i n v e s t i g a t i O n s
Postoperative view of eye
after combined PK/phaco/
IOL insertion.
For more information, contact
Roger H.S. Langston, M.D.,
at langstr@ccf.org.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n v e s t i g a t i O n s
Artificial Cornea Provides Hope for Sight in
Patients with No Alternatives
With advances in device design, surgical
technique and postoperative management,
keratoprosthesis implantation has become a
viable approach for attempting to restore
vision in eyes that are at high risk for corneal
transplantation.
Of the several types of keratoprostheses that are
commercially available, the Boston keratoprosthesis
developed by claes dohlman, m.d., ph.d., professor
emeritus of ophthalmology, harvard medical school,
is the most widely used in the United states. cole eye
institute corneal surgeon victor l. perez, m.d., completed
his fellowship training with dr. dohlman and
has been performing implantation of both the type i
and type ii Boston keratoprostheses at cole for 3
years. to date, he has treated six eyes, and the results
have been encouraging with respect to both safety
and visual rehabilitation.
“as my experience with these procedures increases,
so too has my level of comfort for using this approach
in appropriate candidates. now, the keratoprosthesis
has become an important part of my armamentarium
for trying to provide a clear window for vision in
patients with a history of multiple graft failures,”
dr. perez says.
One of the most satisfying cases undertaken so far
involved a russian radiologist who, while living in
that country, suffered corneal burns in both eyes as
a result of having lye thrown at his face. the patient
developed severe corneal melts and was treated
by a russian ophthalmologist with permanent
tarsorrhaphy.
he presented to dr. perez several years later, after
moving to the United states. an ultrasound study
revealed that the eyes were present in the orbit and
that the retinas were attached. therefore, dr. perez
proceeded to open the tarsorrhaphy in the right eye
for further evaluation, but was unable to find the
anterior segment.
“it was clear to me that the only intervention that
might help this man was to implant the type ii
Boston keratoprosthesis and attempt to provide
a tunnel for vision through the lid,” he says.
due to the excessive scar tissue present, the implantation
surgery was lengthy and challenging. however,
dr. perez was successful in implanting the type ii
keratoprosthesis and placed a glaucoma shunt as
well. he reports that the patient has done well postoperatively
and now has vision of 20/100.
“For the first time, this gentleman has been able to
see his grandchildren who were born after his accident,
and he is able to read again. so far so good as
far as safety is concerned as well, but we are proceeding
with very cautious optimism because these are
such complicated cases,” dr. perez says.
most of the Boston keratoprosthesis procedures performed
by dr. perez involved the type i device. in that
series of eyes, he has not encountered any significant
complications, such as corneal melt, device extrusion
or endophthalmitis. visual outcomes have been
limited by macular potential.
“these patients tend to have multiple ocular abnormalities
that limit their visual potential. at least,
however, the keratoprosthetic surgery provides
an opportunity to restore some functional vision,”
dr. perez says.
since retinal conditions are often present in patients
who come for keratoprosthesis surgery, a team
approach with an experienced retinal surgeon is also
important to optimize outcomes.
“We want to try to offer these patients the best
possible vision, and we are fortunate at the cole eye
institute to have talented retinal surgeons who can
collaborate in these procedures,” dr. perez says.
historically, success with keratoprosthetic surgery
has presented a difficult challenge. Biocompatibility
between the prosthetic device and the corneal tissue
and avoidance of device extrusion and corneal
melts have presented a major obstacle. however,
dr. dohlman made a significant contribution to
addressing those problems with his design of the
two-plate keratoprosthetic device that allows nutrients
from the anterior chamber to interface with the
cornea. recognizing that it was also important to
maintain a moist surface, dr. dohlman introduced
the idea of covering the eye with a bandage contact
0 // O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

lens. that technique has also been important in
reducing postoperative degradation of the cornea and
the prosthesis.
Based on dr. dohlman’s suggested postoperative
management scheme, patients who undergo keratoprosthesis
implantation at cole eye institute are
treated with routine topical antibiotics to prevent
infection.
“this strategy is somewhat controversial, but with its
use, the risk of endophthalmitis has been markedly
diminished,” dr. perez says.
comanagement of glaucoma is another important
consideration in these eyes. many patients have glaucoma
already or are at risk for developing it because
keratoprosthesis implantation changes the anatomy
of the angle. For that reason, an aggressive approach
to iOp control is taken with implantation of glaucoma
devices at the time of the keratoprosthesis procedure
in eyes with advanced existing glaucoma or those
considered to be at high risk.
i n v e s t i g a t i O n s
For more information,
contact Victor L. Perez, M.D.,
at perezv@ccf.org.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n v e s t i g a t i O n s
For more information, contact
Edward J. Rockwood, M.D.,
at rockwoe@ccf.org.
Simultaneous Penetrating Keratoplasty/Pars
Plana Vitrectomy/Glaucoma Implant Surgery
Yielding Encouraging Outcomes
Uncontrolled glaucoma is an occasional
comorbid finding in patients with corneal
disease who are candidates for penetrating
keratoplasty. Placement of a glaucoma drainage
implant has become a valuable option
for maintaining IOP in these challenging
cases. However, the presence of a glaucoma
implant tube in the anterior chamber has
also been associated with an increased risk
for graft failure.
at the cole eye institute, glaucoma specialist edward
J. rockwood, m.d., has been collaborating with
corneal transplant surgeon david m. meisler, m.d.,
and vitreoretinal specialists Jonathan e. sears, m.d.,
and peter K. Kaiser, m.d., to perform a simultaneous
procedure combining penetrating keratoplasty, pars
plana vitrectomy and placement of the glaucoma
implant tube through a pars plana sclerotomy. they
have accumulated eight eyes in their combined
procedure series so far with follow-up ranging from
a few months to up to 3 years.
“it is critical to achieve and maintain good iOp
control in eyes undergoing penetrating keratoplasty
because both elevated iOp and any need for additional
glaucoma surgery increase the risk of graft failure.
For some patients, a glaucoma implant has been the
best choice for achieving that goal, and our outcomes
with posterior implant tube placement in this small
series of cases have been very encouraging in terms
of successful iOp control with reduced need for glaucoma
medications and maintenance of graft clarity,”
says dr. rockwood.
in the combined procedure, dr. rockwood first
places the glaucoma implant but without inserting
the tube in the vitreous. then the retina specialist
performs the vitrectomy with scleral depression to
remove as much of the vitreous base as possible in
the planned quadrant of the implant tube insertion,
usually supero-temporal. next, the cornea surgeon
takes over to perform the transplant, and finally
dr. rockwood steps in again to insert the glaucoma
implant tube, place a preserved pericardial graft
over the tube and close the conjunctiva. the
glaucoma implant tube is passed through a 23-gauge
needle tract at a location about 3.5 mm posterior to
the limbus.
“in some patients with significant corneal edema that
precludes good surgical visualization, a keratoprosthesis
will be placed temporarily after insertion
of the glaucoma implant to enable vitrectomy. Once
that portion of the operation is completed, the
cornea surgeon removes the keratoprosthesis and
places the corneal graft tissue,” dr. rockwood says.
since undertaking the triple procedure a few years
ago and based on additional experience with combined
glaucoma implant surgery and pars plana
vitrectomy in other eyes, the surgeons have introduced
a number of modifications to their technique
that have proven useful for minimizing complications
postoperatively, and particularly serious
posterior segment events. For example, in order to
lessen the risk of hypotony and the associated potential
in these vitrectomized eyes for choroidal
effusion and suprachoroidal hemorrhage, dr.
rockwood now uses only a valve-style glaucoma
implant in the combined procedures.
the vitrectomy technique has also been refined to
ensure adequate removal of the vitreous near the
planned site of tube insertion to reduce the risk of
vitreous incarceration and tube obstruction. in addition,
it has been found best to leave the tube long (at
least 3-4 mm) in the vitreous. While too long a tube in
the anterior chamber can cause problems, it has not
been a problem in the vitreous and may reduce
the risk of vitreous obstructing the tube, notes
dr. rockwood.
“By reducing complications, these refinements have
also been important for eliminating the need for further
surgical intervention and its related morbidity,”
he adds.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

NEI-Sponsored Study Evaluating Role of Primary
IOL Implantation in Infants with Unilateral
Congenital Cataract
Primary IOL implantation has become generally
accepted as the standard of care for
achieving visual rehabilitation after cataract
surgery in older children. In infants, however,
although use of primary IOL implantation
has been increasing at some centers, the
procedure remains controversial, particularly
because of the paucity of data on long-term
risks. As such, contact lenses are still
considered the gold standard for visual rehabilitation
after cataract surgery in children
less than 1 year of age.
however, contact lens wear has its own limitations.
according to some available data, when it is used in
infants after removal of a unilateral congenital
cataract, a significant proportion of children
remain legally blind in their aphakic eye as a result
of competition from the sound eye and contact
lens compliance issues.
now, in order to define better the benefits and risks
of primary iOl implantation in infants with unilateral
congenital cataracts, the national eye institute
of the national institutes of health is sponsoring the
infant aphakia treatment study (iats), a multicenter,
randomized clinical trial comparing primary
iOl implantation with contact lens wear. cleveland
clinic’s cole eye institute is one of only 12 sites
nationwide participating in that study. pediatric
ophthalmologist elias i. traboulsi, m.d., is the
principal investigator at cole.
“iOl implantation is doable in these very small eyes,
but technically challenging, and a pilot study found
that secondary surgery was often needed to remove
proliferating lens material. however, by providing
immediate visual rehabilitation with an implant and
eliminating potential problems with contact lens
use, it is hoped primary iOl implantation can
provide better visual outcomes and reduce caregiver
stress. We are looking forward to the results of this
trial that will show us whether there are advantages
that offset the limitations,” dr. traboulsi says.
enrollment in the study began in early 2005 and is
planned to occur over a 4-year period. to be eligible,
infants must be 28 to 210 days of age with a visually
significant, monocular, congenital cataract. the
surgery in all patients involves lensectomy, posterior
capsulotomy and anterior vitrectomy. For children in
the implant group, the iOl will be placed in the
capsular bag and spectacles prescribed to correct
residual refractive error. protocols for patching
and follow-up after surgery are identical for the two
study groups, and all functional assessments and
safety evaluations are being performed by a traveling
vision examiner.
so far, the cole eye institute has been one of the
more active iats sites, enrolling five patients as of
may 2006. recruitment, however, is difficult because
unilateral congenital cataract is a relatively rare
condition, notes dr. traboulsi.
“since these patients are uncommonly encountered,
we are very dependent on referrals to enroll participants
in this trial. We are very grateful to the
physicians who have referred patients to us so far,
and we strongly encourage others to contact us if they
are caring for or aware of a child who might be a
candidate for this study,” he says.
dr. traboulsi has been performing primary iOl implantation
after cataract surgery in infants for several
years. a few years ago at an annual meeting of the association
for research in vision and Ophthalmology,
he reviewed that experience in a series of 34 eyes of 23
patients who underwent lens extraction prior to 2
years of age for unilateral or bilateral cataracts. twenty-five
(78%) of the procedures were performed when
the child was younger than 20 weeks. eighteen (56%)
of the eyes received an in-the-bag iOl at the time of
cataract extraction.
“there were no significant intraoperative complications
whether or not an iOl was implanted primarily.
notably, however, there were no cases of glaucoma
among the iOl recipients during follow-up extending
to 4 years, whereas glaucoma developed in three eyes
of two patients who did not have an iOl implanted.
Continued on page 24
i n v e s t i g a t i O n s
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n v e s t i g a t i O n s
For more information, contact
Elias I. Traboulsi, M.D., at
traboue@ccf.org.
NEI-Sponsored Study Evaluating Role of Primary IOL
Continued from page 23
that latter observation is consistent with previous
studies of infants who have undergone surgery for
congenital cataracts without iOl implantation,” dr.
traboulsi says. however, he notes the findings from
his review must be considered against the limitations
of the study, which was retrospective and
not randomized.
“the safety and benefits of primary iOl implantation
in infants need to be confirmed in the ongoing,
prospective iats study,” dr. traboulsi says.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Case Study: Five-Month-Old Boy Presents with
Incomitant Esotropia
By Evelyn Fu, M.D., and Elias I. Traboulsi, M.D.
a 5-month-old boy with no significant ocular history
presented to cleveland clinic cole eye institute with
esotropia of the right eye for 1 month. no other visual
symptoms were noted. his medical history revealed
a recent episode of otitis media treated with antibiotic
eardrops. he was born at full term via vaginal
delivery without perinatal complications. review
of systems is significant for episodic nonprojectile
vomiting with increasing frequency that began one
week prior to presentation. Family history is positive
for hypertension and aortic dissection in paternal
great-grandfather and grandfather.
On examination, the boy appears well nourished and
developed. he fixes and follows well with both eyes.
there is a moderate esotropia of the right eye in primary
gaze that increases on right gaze and decreases
on left gaze. the degree of esotropia is equal at
distance and near. there is severe limitation in
abduction of the right eye beyond midline. globe
retraction is not noted in adduction. the pupils are
equal, round and reactive to light without an afferent
defect. slit-lamp examination and dilated ophthalmoscopy
are normal in both eyes. the remaining
medical and neurological examination is normal.
Differential Diagnosis
incomitant esotropia describes an inward deviation
of the eye that varies in different fields of gaze. it results
from a variety of etiologies including sixth-nerve
palsy, type i duane syndrome, divergence insufficiency
and orbital blowout fracture with restriction of the
lateral rectus muscle. patients with type i duane syndrome
have poor abduction with globe retraction in
adduction. divergence insufficiency is characterized
by esotropia that is greater at distance than at near.
Further, the deviation does not change with vertical or
horizontal gaze. Our patient’s symptoms and signs
are most consistent with an isolated sixth-nerve palsy.
Diagnosis
the most common causes of sixth-nerve palsy in
children are trauma and intracranial lesions. 1, 2 in
the absence of trauma, a full neurological evaluation
including neuroimaging is recommended. On head
ct, a 2.6-cm hyperdense mass was noted in the right
middle fossa with remodeling of the adjacent
FIGURE 1
FIGURE 2
sphenoid body and greater wing (Figure 1). cta and
mri demonstrated characteristics of a giant thrombosed
aneurysm of the cavernous internal carotid
artery, without compression of the optic nerve or
chiasm (Figure 2). the diagnosis was a giant intracavernous
carotid artery aneurysm (iccaa).
Discussion
iccaas are extremely rare in the pediatric population.
3, 4 information regarding the natural history,
pathogenesis, radiographic features, treatment and
prognosis are derived from large case series of adult
patients. 5, 6, 7 symptoms from iccaa can be divided
Continued on page 26
i n v e s t i g a t i O n s
Figure 1: CT image of
a 5-month-old boy with
incomitant esotropia.
Figure 2: MR image of
a 5-month-old boy with
incomitant esotropia.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n v e s t i g a t i O n s
For more information, contact
Elias I. Traboulsi, M.D. at
traboue@ccf.org.
Case Study: Five-Month-Old Boy Presents with Incomitant Esotropia
Continued from page 25
into two categories: vascular and compressive. vascular
symptoms include subarachnoid hemorrhage, carotid-cavernous
fistula, epistaxis, subdural hematoma
and embolic or ischemic events. compressive symptoms
are caused by pressure of the aneurysm wall on
surrounding structures and depend on the initial
location, size and direction of growth.
Ophthalmically anterior and lateral extensions may
result in superior orbital fissure syndrome and cavernous
sinus syndrome, respectively. hahn et. al.
reported patients often complain of diplopia (89%),
retro-orbital pain (61%), headache (19%), blurred
vision (14%) and photophobia (4%). 8
common presenting signs include partial ophthalmoplegia
(77%), ptosis (51%), decreased visual acuity
(12%), complete ophthalmoplegia (16%), proptosis
(7%) and visual field defects (7%). isolated cranial
nerve palsies most frequently occur in the sixth nerve
(39%) because it is anatomically closest to the artery,
References
1. holmes Jm, mutyala s, maus tl, grill r, hodge
dO, gray dt. pediatric third, fourth, and sixth
nerve palsies: a population-based study. am J
Ophthalmol 1999;127:388-92.
2. Kodsi sr, younge Br. acquired oculomotor,
trochlear, and abducent cranial nerve palsies
in pediatric patients. am J Ophthalmol
1992;114:568-74.
3. allison JW, davis pc, sato y, et al. intracranial
aneurysms in infants and children. pediatr
radiol 1998;28:223-9.
4. huang J, mcgirt mJ, gailloud p, tamargo rJ.
intracranial aneurysms in the pediatric population:
case series and literature review. surg
neurol 2005;63:424-32; discussion 432-3.
5. Barrow dl, alleyne c. natural history of giant
intracranial aneurysms and indications for
intervention. clin neurosurg 1995;42:214-44.
follow by the third nerve (11%). 8 Fourth-nerve palsy
has not been reported. the mechanisms of cranial
nerve palsies are believed to result from direct compression
or acute ischemia secondary to occlusion of
the cavernous sinus arterial branches supplying the
cranial nerves.
spontaneous improvement and complete resolution
are often noted. nguyen et al. reported a case of 60year-old
woman with recurrent episodes of isolated
sixth-nerve palsy as a result of iccaa. 9 mortality of
iccaa is low and spontaneous rupture is rare. surgical
intervention is reserved for complications of
vascular rupture, progressive ophthalmoplegia,
visual loss and radiographic evidence of enlargement
and extension into the subarachnoid space.
Our patient is being followed closely with frequent
neuroimaging. his right eye is being patched 2 hours
per day to avoid amblyopia.
6. linskey me, sekhar ln, hirsch W, Jr., yonas h,
horton Ja. aneurysms of the intracavernous
carotid artery: clinical presentation, radiographic
features, and pathogenesis. neurosurgery
1990;26:71-9.
7. linskey me, sekhar ln, hirsch Wl, Jr., yonas h,
horton Ja. aneurysms of the intracavernous
carotid artery: natural history and indications for
treatment. neurosurgery 1990;26:933-7; discussion
937-8.
8. hahn cd, nicolle da, lownie sp, drake cg. giant
cavernous carotid aneurysms: clinical presentation
in fifty-seven cases. J neuroophthalmol
2000;20:253-8.
9. nguyen dQ, perera l, Kyle g. recurrent isolated
sixth nerve palsy secondary to an intracavernous
carotid artery aneurysm. eye 2006.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Study Investigates Risk Factors
for Choroidal Melanocytic Lesion Growth
Clinical distinction between a choroidal
nevus and small choroidal melanoma may
be difficult, and patients who are diagnosed
as having a choroidal melanocytic lesion
may become confused as they seek several
opinions and get conflicting information
about diagnosis and management.
the identification of parameters that could improve
the diagnosis and management of choroidal melanocytic
lesions represents a major research interest
of arun d. singh, m.d., director, department of
Ophthalmic Oncology, cole eye institute, cleveland
clinic. in a recently published paper [Ophthalmology,
June 2006], dr. singh reported the findings of
a study he undertook to characterize baseline
features of small choroidal melanocytic lesions
that were predictive of growth.
the study had a retrospective observational case
series design and included 240 patients, mean age 62
years, with a presumptive diagnosis of a small choroidal
melanocytic lesion who underwent observational
management. during a mean follow-up of 3.3 years,
tumor growth occurred in 11 (4.6%) patients, and most
of those events occurred within the first 33 months
after initial recognition. Univariate analyses identified
lesion thickness, location in relation to the foveola,
gender and presence of symptoms and orange
pigment as significant predictors of growth risk.
“the ability to differentiate choroidal nevi from small
choroidal melanoma is an important clinical issue.
currently, tumor growth over a short period is used to
make that distinction, and so frequent careful observation
is recommended to document changes in
lesion size. however, better information is needed
about the risk of tumor growth and prognostic factors
for that occurrence. Our study provides some insight
as to features of small choroidal melanocytic lesions
that are associated with a higher risk of growth.
however, a large multicenter, prospective study is
needed to provide definitive answers for improving
risk stratification,” says dr. singh.
the patients included in the study had lesions measuring
between 1.0 and 3.5 mm in height and/or
between 1 and 15 mm in largest basal diameter without
prior growth, chose observation for growth as
their management, and were followed for at least 12
months. tumor growth was defined as increase in
size of 0.3 mm or greater in any dimension based on
comparisons of fundus drawings, fundus photographs
and ultrasound a and B scans.
comparisons of the groups with and without tumor
growth showed the factors associated with the greatest
relative risk (rr) for growth were presence of
orange pigment (rr = 9.6), tumor height ≥2 mm
(rr = 8.2) and juxtapapillary location (

i n v e s t i g a t i O n s
For more information, contact
Ronald R. Krueger, M.D., M.S.E.,
at krueger@ccf.org.
Customized Re-treatment Can Provide a Solution
When 20/20 Is Not Good Enough
The development of wavefront-guided custom
corneal ablation has led to significant
improvements in the efficacy and predictability
of laser vision correction surgery.
However, wavefront-guided treatment is
also proving to be a feasible method for
enhancement in select patients who achieve
20/20 uncorrected visual acuity (UCVA)
after LASIK but are unhappy because of
quality-of-vision issues, says Ronald R.
Krueger, M.D., medical director of the
Department of Refractive Surgery at Cleveland
Clinic’s Cole Eye Institute.
“Ucva measured on a high-contrast snellen acuity
chart has been the standard measure for assessing
outcomes after refractive surgery, but the advent of
wavefront aberrometry has led us to appreciate that
it is not always an accurate gauge of quality of vision.
Using wavefront devices to measure the optical quality
of the eye, we now understand that 20/20 or even
20/15 Ucva is sometimes not good enough because
patients can be emmetropic and have excellent visual
acuity but still suffer debilitating visual symptoms
as a result of higher-order aberrations induced by
their surgery,” dr. Krueger explains.
“While historically we would avoid treating any eye
that is 20/20, using a wavefront-guided retreatment,
we can sometimes selectively address the higher-order
aberrations underlying a patient’s complaints to
provide those individuals with the quality of vision
they desire,” he continues.
in a study undertaken a few years ago in which more
than 100 postlasiK eyes were evaluated with the
ladarWave aberrometer (alcon), dr. Krueger and
colleagues found statistically significant correlations
between certain higher-order aberrations and
particular visual symptoms. For example, patients
who had high levels of horizontal coma suffered with
double vision while spherical aberration was associated
with complaints of halos, glare and starburst.
subsequently, dr. Krueger has used the customcornea
system (alcon) to perform an “upgrade treatment”
in about 30 eyes that were 20/20 after lasiK but
symptomatic. the primary treatment in most of
those eyes was done with a conventional lasiK
procedure, but there were some cases that had
wavefront-guided ablations, primarily. For the vast
majority of patients, the custom enhancement
procedure has resulted in a very good outcome. the
following is a description of an illustrative case.
a 37-year-old female pharmacist presented to the
cole eye institute with complaints of poor vision in
dim light, with the right eye being worse than the left,
along with bothersome glare and halos when driving
at night. she originally had a spherical error of about
–5.0 d in both eyes and had undergone lasiK 5 years
earlier at another refractive surgery center followed
by a bilateral enhancement about 1 year ago. at
presentation, her right eye was –0.25+0.25 × 88° and
20/20+1 Ucva. her left eye was plano with Ucva
of 20/15–2. a few dry spots were noted on her
cornea, but otherwise her ophthalmic exam was unremarkable
and showed normal pupils and corneal
thickness for postlasiK eyes. corneal topography
revealed slight irregularity and asymmetry in the
previously treated central area (Figure 1a), and
wavefront aberrometry showed higher levels of coma
and spherical aberration that were consistent with
her vision complaints (Figure 1b).
after a thorough discussion of the potential risks of
yet another re-treatment, the patient chose to undergo
the custom upgrade procedure in the right eye. On
the first postoperative day, the eye was 20/20 uncorrected
and the patient was extremely happy with her
vision. aberrometry revealed her refraction was close
to plano and showed significant improvement in the
higher-order aberrations. at day 7 postop, the vision
was –0.25 d by manifest refraction and 20/20. after
dilation, the eye measured +0.50 d and 20/15–1.
coma and spherical aberration had both decreased
by at least 50%. the exam findings at 1 month were
similar, and the patient was still very pleased with
her outcome.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

however, a few months later she returned, complaining
that she was still having difficulty with vision
at night in her left eye. dr. Krueger dissuaded
the patient from having a custom upgrade in that
eye with 20/15 Ucva, but she returned 2 months
later determined to have surgery. still reluctant, dr.
Krueger proceeded to do a preoperative work-up
that revealed abnormally high levels of coma and
spherical aberration. a carefully planned ablation
was performed with a good result. at 1 week and 6
weeks, aberrometry showed a refraction of –0.25 d
with the level of coma reduced by about one-third
and spherical aberration reduced by about 50%.
complaints of starburst and glare at night were
markedly improved, and the patient was very happy
with her vision in both eyes.
WR: +0.38–0.57x09
– Coma=0.76 µm
– Sph Ab=0.78 µm
– Other=0.26 µm
FIGURE 1a
Note of caution
although the outcome in this case and others has
been favorable, dr. Krueger warns that in eyes in
which there is minimal refractive error, the custom
re-treatment needs to be carefully planned to avoid a
spherical overcorrection that can leave the patient
even more unhappy.
“When correcting higher amounts of higher-order
aberrations, it is important to incorporate an offset
into the ablation that will compensate for the
relatively large amount of treatment that is delivered.
Unfortunately, we have seen several patients
treated elsewhere with a custom enhancement
whose vision has been massively overcorrected,”
dr. Krueger says.
FIGURE 1b
i n v e s t i g a t i O n s
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n v e s t i g a t i O n s
Second Intravitreal Implant Investigated
as Treatment for Uveitis
Corticosteroid treatment has long been a
mainstay of therapy for uveitis, and until recently,
most patients with vision-threatening
posterior, intermediate and panuveitis were
treated with systemic anti-inflammatory
therapy using corticosteroids and/or steroidsparing
immunosuppressive medications.
given the serious systemic side effects associated
with those modalities, the approval of the intravitreal
fluocinolone acetonide implant (retisert, Bausch
& lomb) for the treatment of chronic, noninfectious
posterior uveitis represented a significant advance
because it afforded long-lasting, effective disease
control without extraocular toxicity. nevertheless,
these benefits were not achieved without risks.
“in the premarketing clinical trials, nearly two-thirds
of patients who received the implant required
iOp-lowering treatment, about one-third had to
undergo glaucoma surgery and nearly all phakic
eyes developed cataracts that required removal,”
explains cole eye institute ophthalmologist careen
y. lowder, m.d., ph.d.
now, the cole eye institute is one of the clinical sites
participating in two recently launched multicenter
studies that are evaluating the efficacy and safety of a
dexamethasone posterior segment drug delivery
system (posurdex, allergan) for the treatment of
noninfectious anterior and intermediate uveitis.
dr. lowder and other investigators in those trials are
hopeful that this sustained-release corticosteroid
will also prove effective for reducing inflammation
while offering a better ocular safety profile than the
fluocinolone acetonide implant.
results of a phase ii trial investigating the dexamethasone
posterior segment drug delivery system
for the treatment of cystoid macular edema (cme)
provide evidence of its potential efficacy in the treatment
of uveitis, notes dr. lowder.
that study included 39 patients with cme associated
with uveitis. analyses of vision outcomes showed
that at 2 months after randomization, approximately
60% of patients who received the 350 or 700 µg dexamethasone
implant achieved a 10-letter-or-greater
improvement in best corrected visual acuity (Bcva)
compared with only about 21% of those in the
observation control arm. By 6 months after implantation,
42% of patients in the 350-µg implant group
and 46% of those in the 700-µg group maintained a
10-letter-or-greater improvement from baseline in
Bcva compared with only 21% of patients in the
observation group.
“in contrast to the fluocinolone device that released
corticosteroid for a period of almost 3 years, the bioerodable
dexamethasone implant was formulated
specifically for use in the eye and releases medication
for only about 3 months. We hope that duration
of treatment will be adequate to control the ocular
inflammation but be short enough that it will
be associated with lower risks of glaucoma and
cataractogenesis compared with the longer-lasting
fluocinolone implant,” dr. lowder says.
Both the anterior uveitis and intermediate uveitis
studies are masked, have a planned 26-week duration
and will randomly assign patients equally to
three arms to receive one of two doses of the dexamethasone
posterior segment drug delivery system
(350 µg and 700 µg) or sham treatment with a needleless
applicator system. the primary efficacy
assessment will be performed after 6 weeks in the
anterior uveitis study and after 8 weeks in the intermediate
uveitis study, and will be based on anterior
chamber cells (anterior uveitis) and vitreous
haze (intermediate uveitis) using standardized
grading scales.
0 // O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

each trial will enroll 189 adult patients with a diagnosis
of non-infectious uveitis in at least one eye
based on criteria established in the standardization
of Uveitis nomenclature Working group classification
report. to be eligible, patients with intermediate
uveitis must have vitreous haze of at least +2 and a
snellen equivalent Bcva of 20/40 to 20/200 in the
study eye. patients with anterior uveitis must have
persistent inflammation for more than 3 months
and an anterior chamber cell score of at least +2.
patients taking stable regimens of topical steroids,
topical nsaids, systemic corticosteroids or systemic
immunosuppressants are eligible. patients with
ocular hypertension, glaucoma or a history of an iOpsteroid
response are excluded.
“We look forward to the results of the dexamethasone
posterior segment drug delivery system trials. treatment
of chronic non-infectious posterior and diffuse
uveitis continues to be a challenge because all
currently available treatment modalities have significant
side effects. We need to continue to search
for better options,” dr. lowder concludes.
i n v e s t i g a t i O n s
For more information, contact
Careen Y. Lowder, M.D., Ph.D.,
at lowderc@ccf.org.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n v e s t i g a t i O n s
Figure 1: Preoperative image of
patient with mild upper eyelid
ptosis.
Figure 2: Patient 1 week after
sutureless ptosis surgery using
a fibrin sealant. A review of 53
such procedures performed in
33 patients over a 2-year period
shows it is safe and predictably
effective with reduced morbidity.
Figure 3: Patient several
months after the surgery.
Sutureless Technique Reduces Morbidity,
Hastens Healing for Conjunctival Müllerectomy
Müller’s muscle-conjunctiva resection ptosis
repair is a highly effective technique for treating
mild upper eyelid ptosis. However, sutures
placed for wound closure can cause significant
postoperative discomfort and result
in complications that include keratopathy,
granuloma formation and infection.
For the past several years, oculoplastic surgeon
Julian d. perry, m.d., and colleagues at cleveland
clinic’s cole eye institute have been using fibrin
sealant (tisseel, Baxter ag industries) to perform
sutureless ptosis surgery. their review of outcomes
in a consecutive series of 53 procedures performed
FIGURE 1
FIGURE 2
FIGURE 3
in 33 patients over a 2-year period shows the sutureless
approach is safe, predictably effective and reduces
morbidity by both hastening postoperative
healing and avoiding suture-related complications.
as reported in a recently published paper [Ophthal
plast reconstr surg 2006;22(3):184-7], symmetry
results for the group were excellent and there were
no significant complications attributable to the
fibrin sealant.
“this tissue sealant has been used most widely as
a topical hemostatic agent in general surgery, and
several authors have described its use in various
external ophthalmic or corneal procedures. however,
we believe we are the first to report on sutureless
ptosis surgery using fibrin sealant,” says dr. perry.
“this product is nontoxic to the ocular surface and
mucous membranes, non-irritating to the cornea
because it is soft, and our experience indicates it is
a useful alternative to sutures for improving results
and patient satisfaction with ptosis surgery.”
dr. perry added that the fibrin sealant does have
some limitations to consider.
“it is more costly than suture material, and since it is
derived from human donor sources, patients need to
be informed there is a risk, albeit very low, of disease
transmission,” he explains.
the sutureless ptosis surgery is performed with the
same technique as is used when suture closure is
done, using an approach from the posterior aspect of
the eyelid and an algorithm published by dr. perry
and colleagues in 2002 to determine the amount of
tissue resection.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Briefly, after everting the eyelid, the tissue is grasped
within a putterman ptosis clamp and two locking
0.5 forceps are placed beneath the clamp to maintain
the relationship of the wound edges. then, half
of the tissue in the clamp is excised, cautery is used
to achieve hemostasis, the wound edges are held in
approximation and the tissue glue is placed onto the
dry field. then the same steps are repeated after the
remaining half of the tissue is excised.
the glue sets within several minutes, and the eyelid
retractor is removed after checking wound security.
the site is dressed with antibiotic ointment. total
time for the procedure is about eight minutes per
side, which represents a slight reduction in time
compared with when the procedure is performed
using suture closure.
“average surgical time for the standard procedure is
only about 11 minutes, and so increased efficiency is
not a major advantage of the sutureless procedure,”
notes dr. perry. Without question, however, there is
less bleeding intraoperatively when the fibrin
sealant is used, and as a result, ecchymoses and
swelling are reduced postoperatively and resolve
more quickly.
“When patients return for their postoperative visit
after 1 week, most have minimal bruising and swelling.
there is some evidence that the fibrin sealant
may accelerate healing by promoting fibroblast proliferation
and accumulation of vascular endothelial
growth factor, and it is likely that when a suture is
placed, fluid remains trapped in the eyelid until the
suture is removed,” notes dr. perry.
Occasionally, patients who undergo sutureless ptosis
surgery may experience a brief episode of conjunctival
bleeding 4 to 5 days postoperatively. the event is
painless and its onset appears consistent with the
timing of degradation of the fibrin sealant.
the fibrin sealant is derived in part from a human
plasma donor pool. manufacturing protocols incorporate
rigorous testing and vapor heat viral inactivation,
and to date there are no known reported cases
of viral or prion disease associated with use of the
product since the manufacturer introduced pcr
viral screening methodology. nevertheless, a risk of
infectious disease transmission cannot be excluded.
“this information is provided to patients and they are
given the option of sutureless or standard surgery.
however, because of its various benefits, we consider
use of the fibrin sealant the method of choice in
patients at increased risk for bleeding or suture
morbidity as well as for patients undergoing
cosmetic ptosis repair who would especially appreciate
a faster and more comfortable course of healing,”
dr. perry says.
i n v e s t i g a t i O n s
For more information, contact
Julian D. Perry, M.D., at
perryj1@ccf.org.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n n O v a t i O n
Innovation
We push the boundaries at every step of the way, refusing to be saddled
by conventional thinking or limitations.
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Who We Are
at the cole eye institute, the lines between research and patient
care blur. the belief that the two are interdependent and synergistic
is the foundation for everything we do. We believe that this
approach enhances diagnosis and advances treatment, to the
benefit of our patients today and tomorrow.
Our program ranks high in the U.S.News & World Report annual
survey, and is consistently the highest rated in Ohio. We have
some of the highest patient volumes in the United states,
handling more than 150,000 patient visits and more than 5,000
surgeries per year. We offer treatment of the full range of vision
disorders and conditions, as well as offering routine eye care for
all ages. Our internationally recognized staff of 26 ophthalmologists
is composed almost entirely of subspecialists, and eight
optometrists round out our comprehensive services.
Our state-of-the-art building demonstrates our dedication to
patients and to the tradition established by the founders of
cleveland clinic – a commitment to world-class care that always
puts the patient first as well as providing further education
for those who serve.
Our facilities are designed for maximum patient comfort, service
and quality. We offer one-stop eye care, with our diagnostic services
suite located just a quick elevator ride away from the clinical
suites, and our state-of-the-art operating rooms also are on premises.
all windows in the patient areas feature special light filters to
minimize the discomfort of patients whose eyes are dilated or
newly treated. Our waiting rooms are designed to be comfortable
and include a special area for children to play while they wait. We
also have a pearle vision on site and offer such amenities as valet
parking and an easy drive-up area for pick-up of postoperative
patients. Our regional eye care program provides services in five
suburban locations throughout the greater cleveland area,
including one ambulatory surgery center.
i n n O v a t i O n
Cleveland Clinic Cole Eye Institute is one of the few dedicated, comprehensive state-of-the-art eye institutes in
the world. We are here to serve the needs of patients and referring physicians by providing early, accurate
diagnosis and excellent, effective patient care. We strive daily to make this commitment to innovation a reality.
We are pioneering treatment protocols for complex vision-threatening
disorders, including age-related macular degeneration
and glaucoma, through our clinical trials program. Our aggressive
research program bridges the gap between laboratory and
patient care, and our team of dedicated researchers works in
some of the most well-equipped labs anywhere.
Other unique programs housed at Cole Eye Institute:
The Center for Genetic Eye Diseases: the center for genetic eye
diseases provides clinical diagnostic and therapeutic services
for patients with inherited eye conditions such as corneal and
retinal dystrophies and microphthalmia. patients with inherited
disorders that involve the eye, such as neurofibromatosis,
albinism, neurodegenerative disorders and marfan syndrome,
are referred to the center by physicians from around the country.
a monthly specialty clinic is dedicated to patients with retinal
dystrophies and their families.
A National Eye Donor Program: cole eye institute houses the
Foundation Fighting Blindness’ center for eyes donated by individuals
across the United states for blindness research. the center
shares tissue samples with researchers worldwide. Formally
known as the retinal degeneration pathophysiology Facility, the
collection center accepts eye donations after death from any person
of any age who has normal vision or any degree of vision loss
resulting from a retinal-degenerative disease. cole eye institute
staff prepares a detailed medical report about each donated eye
to help researchers track the effects of eye disease in different
types of people and environments. prior to moving to cleveland
clinic, the center was located in philadelphia.
For more information about our services or to refer a patient,
please call 216.444.2020 or 800.223.2273 ext 42020 or visit
clevelandclinic.org/eye.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

i n n O v a t i O n
Cole Eye Institute
Vision First Program
HElps KIds In ClEvElAnd pUBlIC sCHOOls
The Cleveland Clinic Cole Eye Institute reaches out to children in the Cleveland Municipal School District with
free vision screenings on its Vision Bus.
the bus, operated by the vision First project, began in the 2002-
2003 school year and travels to all elementary schools in the
district to test the vision of kindergarten and first-grade pupils,
as well as pre-kindergarten pupils in schools that offer that program.
the bus, the size of a recreational vehicle, is fully equipped
to perform complete eye examinations.
in the 2004-2005 school year, more than 6,000 children were
screened at 88 elementary schools. about 550 were found to need
glasses and more than 200 had a vision problem that required
further follow-up.
elias i. traboulsi, m.d., head of pediatric ophthalmology at
the cole eye institute, is the medical director for the program.
heather cimino, O.d., and rhonda Wilson, an ophthalmic technician,
staff the bus. they assess the need for glasses as well as depth
perception, ability to use both eyes fully, color perception and
eye muscle strength on each child whose parents return a signed
permission slip. children in whom problems are identified are
given a more comprehensive examination by dr. hasley that
includes dilating their pupils. if glasses or further medical attention
are warranted, the school nurse is given information to mail
home to parents. many families are eligible for no-cost follow-up
care from pediatric ophthalmologists who accept medicaid.
this program is so important because many childhood vision
problems such as amblyopia are treatable if caught early enough,
but can lead to permanent vision loss that hinders a child’s ability
to learn if they are not. also, the earlier students who need glasses
get them, the sooner they can start doing better in school.
In a typical school year,
more than 6,000 children are
screened at 88 elementary schools.
Because the program is designed for such young children,
the bus is equipped with a system that lets the staff use letters,
numbers and even pictures in the exams. video cartoons are
sometimes used also, and plenty of stickers are handed out as
rewards. school nurses play a vital role in making sure the students
bring back their signed permission slips and working with
families to be sure the children get any follow-up care they need.
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Refractive Surgery
FREEInG pATIEnTs FROm GlAssEs OR
COnTACT lEnsEs
We utilize the most advanced techniques to offer the complete
range of vision correction options. We recently were among the
first in the nation to get the newest alcon excimer laser, the
ladarvision 6000. We also have added the newest version of the
intralase device, the 60 Khz upgrade. Both lasers now deliver
quicker, more accurate treatments with less irritation and faster
recovery of excellent visual acuity. treatments for myopia, hyperopia
and astigmatism are offered. also, monovision/blended
vision treatments, in which one eye is corrected for near and
the other for mid-range, are a popular choice for many of our
patients over 40.
i n n O v a t i O n
The Cleveland Clinic Cole Eye Institute Refractive Center is a national leader in laser vision correction, and our
refractive surgeons are among the most experienced anywhere. The Cole Eye Institute laser vision correction
team is internationally respected for providing world-class eye care and for playing a prominent role in many
major ophthalmic clinical trials.
Our volumes have increased nearly 20 percent since 2002, and
we have achieved that growth by always remembering that
patients have a wide variety of choices available for laser vision
correction today. Our team proudly differentiates itself by consistently
putting patients first and delivering high quality results
and sensitive, thorough care before, during and after each procedure.
patients include many members of the local business,
cultural, law enforcement and athletic communities, and the
highest compliment they pay us is referring a family member
or friend.
every aspect of our refractive unit adheres to the highest
standards set by the cole eye institute for all patients.
Our team proudly differentiates itself by consistently putting patients first.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

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Staff
Our world-renowned experts have extensive experience treating the full
range of ophthalmic disorders with precision and compassion.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Cole Eye Institute Staff
Hilel Lewis, M.D.
Chairman, Division of Ophthalmology
Director, Cole Eye Institute
Specialty/Research Interests: Vitreoretinal surgery for
complicated retinal detachment and trauma, age-related
macular degeneration, diabetic retinopathy, retinal
photocoagulation, instrument development
Office Phone: 216.444.0430
Bela Anand-Apte, M.B.B.S., Ph.D.
Ophthalmic Research Department
Research Interest: Angiogenesis
Office Phone: 216.445.9739
John W. Crabb, Ph.D.
Ophthalmic Research Department
Research Interests: Age-related macular degeneration,
inherited retinal diseases
Office Phone: 216.445.0425
William J. Dupps, Jr., M.D., Ph.D. *
Cornea and External Disease Department
Specialty/Research Interests: Cornea, cataract and
refractive surgery
Office Phone: 216.444.8396
Marc A. Feldman, M.D.
Ophthalmic Anesthesia
Specialty Interests: Ophthalmic surgery anesthesia,
preoperative assessment, resident education
Office Phone: 216.444.9088
Bennie H. Jeng, M.D.
Cornea and External Disease Department
Specialty/Research Interests: Corneal transplantation,
ocular surface disease, limbal stem cell transplantation,
artificial corneas, eyebanking, cataracts
Office Phone: 216.445.9519
Richard E. Gans, M.D., F.A.C.S.
Comprehensive Ophthalmology Department
Specialty Interests: Cataract, glaucoma, diabetes
Office Phone: 216.831.0120
Philip N. Goldberg, M.D.
Comprehensive Ophthalmology Department
Specialty Interests: Cataract, glaucoma
Office Phone: 216.831.0120
Froncie A. Gutman, M.D.
Vitreoretinal Department
Specialty Interests: Retinal vascular diseases, laser
therapy, diabetic retinopathy
Office Phone: 216.444.5888
Stephanie A. Hagstrom, Ph.D.
Ophthalmic Research Department
Research Interests: Inherited forms of retinal degeneration,
including macular degeneration and retinitis pigmentosa
Office Phone: 216.445.4133
Joe G. Hollyfield, Ph.D.
Ophthalmic Research Department
Research Interests: Retinal degeneration, retinal diseases
Office Phone: 216.445.3252
Peter K. Kaiser, M.D.
Vitreoretinal Department
Specialty/Research Interests: Vitreoretinal diseases, agerelated
macular degeneration, retinal detachment, diabetic
retinopathy, endophthalmitis, posterior segment
complications of anterior segment surgery
Office Phone: 216.444.6702
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //
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Gregory S. Kosmorsky, D.O.
Neuro-Ophthalmology Department
Specialty Interests: Neuro-ophthalmology, cataract,
refractive surgery
Office Phone: 216.444.2855
Ronald R. Krueger, M.D., M.S.E.
Refractive Surgery Department
Specialty/Research Interests: Refractive surgery, lasers,
refractive corneal pathology, lamellar corneal transplants,
investigational clinical trials
Office Phone: 216.444.8158
Roger H.S. Langston, M.D.
Cornea and External Disease Department
Specialty Interests: Cornea and external disease,
corneal transplantation
Office Phone: 216.444.5898
Careen Y. Lowder, M.D., Ph.D.
Uveitis Department
Specialty/Research Interests: Uveitis, intraocular
inflammatory diseases, pathology
Office Phone: 216.444.3642
Andreas Marcotty, M.D.
Pediatric Ophthalmology and Strabismus Department
Specialty Interests: Pediatric ophthalmology,
adult strabismus
Office Phone: 216.831.0120
Shari Martyn, M.D.
Comprehensive Ophthalmology Department
Specialty Interests: Cataract, glaucoma, diabetes
Office Phone: 216.831.0120
David M. Meisler, M.D.
Cornea and External Disease Department
Specialty/Research Interests: Corneal and external disease,
inflammatory and infectious diseases of the cornea, corneal
transplantation, refractive surgery
Office Phone: 216.444.8102
Michael Millstein, M.D.
Comprehensive Ophthalmology Department
Specialty Interests: Cataract, glaucoma, refractive surgery
Office Phone: 216.831.0120
Neal S. Peachey, Ph.D.
Ophthalmic Research Department
Research Interests: Visual loss associated with hereditary
retinal degeneration
Office Phone: 216.445.1942
Victor L. Perez, M.D.
Cornea and External Disease Department
Specialty/Research Interests: Cornea and external
diseases, uveitis, medical and surgical treatment of
autoimmune inflammatory conditions of the cornea and
ocular surface
Office Phone: 216.445.2530
Julian D. Perry, M.D.
Oculoplastic and Orbital Surgery Department
Specialty/Research Interests: Aesthetic facial surgery/fat
transplantation and repositioning, acellular human dermal
graft matrix, new bovine hydroxyapatite orbital implant,
thyroid eye disease/rate of strabismus after decompression
surgery for dysthyroid orbitopathy
Office Phone: 216.444.3635
Edward J. Rockwood, M.D.
Glaucoma Department
Specialty/Research Interests: Glaucoma, glaucoma laser
surgery, combined cataract and glaucoma surgery,
glaucoma filtering surgery with antimetabolite therapy,
glaucomatous optic nerve damage, congenital glaucoma
Office Phone: 216.444.1995
0 // O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Allen S. Roth, M.D.
Comprehensive Ophthalmology Department
Specialty Interests: Corneal transplantation, refractive
surgery, cataract and implant surgery
Office Phone: 216.831.0120
Andrew P. Schachat, M.D. *
Vitreoretinal Department
Vice Chairman of Clinical Affairs
Specialty/Research Interests: Age-related macular
degeneration, diabetic retinopathy, medical retina
Office Phone: 216.444.7963
Jonathan E. Sears, M.D.
Vitreoretinal Department
Specialty/Research Interests: Pediatric and adult
vitreoretinal diseases, pediatric retinal detachment,
inherited vitreoretinal disorders, retinopathy of
prematurity, other acquired proliferative diseases
Office Phone: 216.444.8157
David B. Sholiton, M.D.
Comprehensive Ophthalmology Department
Specialty Interests: Cataract and implant surgery,
glaucoma, oculoplastics
Office Phone: 216.831.0120
Arun D. Singh, M.D.
Ophthalmic Oncology Department
Specialty/Research Interests: Adult and pediatric ocular
tumors, uveal melanoma, genetics of retinoblastoma,
retinal capillary hemangioma, von Hippel-Lindau disease.
Office Phone: 216.445.9479
Scott D. Smith, M.D., M.P.H.
Glaucoma Department
Specialty/Research Interests: Glaucoma, cataract,
prevention of eye disease, international ophthalmology,
congenital glaucoma
Office Phone: 216.444.4821
OpTOmETRIsTs
David Barnhart, O.D.
Anita Chitluri, O.D.*
Heather Cimino, O.D.
nEw sTAFF
* Denotes joined the Cole Eye Institute in 2006
Elias I. Traboulsi, M.D.
Pediatric Ophthalmology and Strabismus Department
Center for Genetic Eye Diseases
Specialty/Research Interests: Ocular diseases of children,
genetic eye diseases, strabismus, retinoblastoma,
congenital cataracts, childhood/congenital glaucoma
Office Phone: 216.444.4363
Steven E. Wilson, M.D.
Cornea and External Disease and
Refractive Surgery Departments
Specialty/Research Interests: Refractive surgery,
corneal healing
Office Phone: 216.444.5887
Ann Laurenzi, O.D.
Rosemary Perl, O.D.
William Sax, O.D. *
Mindy Toabe, O.D.
Diane Tucker, O.D.
William J. Dupps Jr., M.D., Ph.D.
William J. Dupps Jr., M.D., Ph.D., a refractive surgeon and corneal specialist who also has
a strong interest in ocular biomechanics, has joined the staff of Cleveland Clinic’s Cole
Eye Institute.
Dr. Dupps earned his master’s and doctoral degrees in biomedical engineering at The Ohio
State University in 1995 and 1998, respectively, followed by a medical degree in 2000 from
the same institution. After an internship in transitional medicine at Indiana University, he
completed a residency at the University of Iowa Department of Ophthalmology and Visual
Sciences in 2004. He is the first fellow to complete a two-year Cornea, External Disease
and Refractive Surgery Fellowship at the Cole Eye Institute, a program designed to
emphasize training of clinician-scientists.
He also completed a fellowship in ocular gene therapy at the National Eye Institute in 1996
and studied under a Medical Scientist Training Program Fellowship as a Presidential Fellow
at The Ohio State University from 1997 to 2000.
In addition to seeing patients in the refractive surgery and cornea clinics, Dr. Dupps,
with the help of a National Institutes of Health career development grant, will conduct
multi-disciplinary research emphasizing application of engineering tools to the diagnosis
and management of biomechanical disorders such as keratoconus and glaucoma. His work
also focuses on developing diagnostic tools for optimizing corneal and refractive surgery.
Nadia K. Waheed, M.D.
Nadia K. Waheed, M.D., a retina specialist, has joined Cleveland Clinic Cole Eye
Institute’s staff.
Dr. Waheed is a graduate of Aga Khan Medical School in Karachi, Pakistan, and earned a
masters degree in public health from the Harvard School of Public Health. She completed
her residency and her fellowship training at the Massachusetts Eye and Ear Infirmary at
Harvard Medical School.
She will specialize in treating medical and surgical diseases of the retina.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //
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Leadership Roles
Our physicians are committed to being involved in the ophthalmic world and serve in leadership positions with
numerous journals, organizations and conferences. Here are selected highlights of that service.
Roles in Publishing
American Journal of Ophthalmology
Executive Editor
Elias I. Traboulsi, M.D.
Editorial Board
Peter K. Kaiser, M.D.
Reviewers/Referees
Bennie H. Jeng, M.D.
Peter K. Kaiser, M.D.
Ronald R. Krueger, M.D.
Hilel Lewis, M.D.
Careen Y. Lowder, M.D., Ph.D.
Neal S. Peachey, Ph.D.
Julian D. Perry, M.D.
Steven E. Wilson, M.D.
Archives of Facial plastic surgery
Reviewer/Referee
Julian D. Perry, M.D.
Archives of Ophthalmology
Reviewers/Referees
Bennie H. Jeng, M.D.
Peter K. Kaiser, M.D.
Ronald R. Krueger, M.D.
Hilel Lewis, M.D.
Careen Y. Lowder, M.D., Ph.D.
Julian D. Perry, M.D.
Andrew P. Schachat, M.D.
Biomed Central (BmC) Ophthalmology
Reviewer/Referee
Bennie H. Jeng, M.D.
British Journal of Ophthalmology
Reviewers/Referees
Bennie H. Jeng, M.D.
Peter K. Kaiser, M.D.
Careen Y. Lowder, M.D., Ph.D.
Clinical Ophthalmic Oncology
Section Editor
Julian D. Perry, M.D.
Comprehensive Ophthalmology Update
Reviewer/Referee
Peter K. Kaiser, M.D.
Contemporary Ophthalmology
Editorial Board Member
Elias I. Traboulsi, M.D.
Cornea
Editorial Board
Steven E. Wilson, M.D.
Reviewers/Referees
Bennie H. Jeng, M.D.
Ronald R. Krueger, M.D.
David M. Meisler, M.D.
Current Eye Research
Reviewers/Referees
Peter K. Kaiser, M.D.
Ronald R. Krueger, M.D.
Hilel Lewis, M.D.
digital Journal of Ophthalmology
Founder and Senior Executive Editor
Peter K. Kaiser, M.D.
documenta Ophthalmologica
Reviewer/Referee
Neal S. Peachey, Ph.D.
Experimental Eye Research
Executive Editor
John W. Crabb, Ph.D.
Section Editor
Steven E. Wilson, M.D.
Reviewers/Referees
William J. Dupps, M.D., Ph.D.
Neal S. Peachey, Ph.D.
Eye
Section Editor
Bennie H. Jeng, M.D.
Reviewers/Referees
William J. Dupps, M.D., Ph.D.
Peter K. Kaiser, M.D.
Eyenet
Editorial Advisory Board Members
Andrew P. Schachat, M.D.
Steven E. Wilson, M.D.
Genome Biology
Reviewer/Referee
John W. Crabb, Ph.D.
German Journal of Ophthalmology
Reviewer/Referee
Hilel Lewis, M.D.
Graefe’s Archive for Clinical and
Experimental Ophthalmology
Reviewer/Referee
Hilel Lewis, M.D.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

International Ophthalmology
Reviewer/Referee
Hilel Lewis, M.D.
Investigative Ophthalmology and
visual science
Reviewers/Referees
John W. Crabb, Ph.D.
Peter K. Kaiser, M.D.
Hilel Lewis, M.D.
Andrew P. Schachat, M.D.
Steven E. Wilson, M.D.
Journal of Biological Chemistry
Reviewer/Referee
John W. Crabb, Ph.D.
Journal of Biomedical Optics
Reviewer/Referee
William J. Dupps, M.D., Ph.D.
Journal of Cataract and Refractive surgery
Reviewers/Referees
William J. Dupps, M.D., Ph.D.
Bennie H. Jeng, M.D.
Ronald R. Krueger, M.D.
Journal of neuro-Ophthalmology
Reviewers/Referees
Gregory S. Kosmorsky, D.O.
Julian D. Perry, M.D.
Journal of Refractive surgery
Associate Editor
Ronald R. Krueger, M.D.
Editorial Board
Steven E. Wilson, M.D.
Reviewers/Referees
William J. Dupps, M.D., Ph.D.
Ronald R. Krueger, M.D.
Journal of the American medical
Association
Reviewers/Referees
Hilel Lewis, M.D.
Andrew P. Schachat, M.D.
middle East Journal of Ophthalmology
Editorial Board Member
Elias I. Traboulsi, M.D.
molecular & Cellular proteomics
Reviewer/Referee
John W. Crabb, Ph.D.
molecular vision
Reviewer/Referee
John W. Crabb, Ph.D.
Ocular Infection and Immunity
Reviewer/Referee
Careen Y. Lowder, M.D., Ph.D.
Ocular surgery news
Editorial Board
Peter K. Kaiser, M.D.
Julian D. Perry, M.D.
Ophthalmic Genetics
Editor-in-Chief
Elias I. Traboulsi, M.D.
Reviewers/Referees
John W. Crabb, Ph.D.
Peter K. Kaiser, M.D.
Ophthalmic plastic and
Reconstructive surgery
Editorial Board
Julian D. Perry, M.D.
Ophthalmic surgery, lasers & Imaging
Reviewers/Referees
William J. Dupps, M.D., Ph.D.
David M. Meisler, M.D.
Julian D. Perry, M.D.
Ophthalmology
Editor-in-Chief
Andrew P. Schachat, M.D.
Reviewers/Referees
William J. Dupps, M.D., Ph.D.
Bennie H. Jeng, M.D.
Peter K. Kaiser, M.D.
Gregory S. Kosmorsky, D.O.
Ronald R. Krueger, M.D.
Hilel Lewis, M.D.
Careen Y. Lowder, M.D., Ph.D.
Julian D. Perry, M.D.
Steven E. Wilson, M.D.
pediatric perspectives
Editorial Board Member
Elias I. Traboulsi, M.D.
proceedings of the national Academy
of sciences
Reviewer/Referee
John W. Crabb, Ph.D.
Retina
Reviewers/Referees
Peter K. Kaiser, M.D.
Hilel Lewis, M.D.
Careen Y. Lowder, M.D., Ph.D.
Andrew P. Schachat, M.D.
Retinal physician
Editorial Board
Peter K. Kaiser, M.D.
Review of Refractive surgery
Editorial Board
Ronald R. Krueger, M.D.
survey of Ophthalmology
Reviewers/Referees
Bennie H. Jeng, M.D.
Ronald R. Krueger, M.D.
Roles at Conferences
Alicante Refractiva Internacional
Invited Lecture
Ronald R. Krueger, M.D.
American Academy of Ophthalmology
Organizer
Steven E. Wilson, M.D.
Invited Lectures
Ronald R. Krueger, M.D.
Julian D. Perry, M.D.
Elias I. Traboulsi, M.D.
American Association for pediatric
Ophthalmology and strabismus
Invited Lecture
Elias I. Traboulsi, M.D.
American Osteopathic Boards of
Ophthalmology and Otolaryngology
Invited Lecture
Ronald R. Krueger, M.D.
American society of Cataract and
Refractive surgery
Invited Lectures
Peter K. Kaiser, M.D.
Ronald R. Krueger, M.D.
American Uveitis society
Invited Lecture
Victor L. Perez, M.D.
Continued on page 44
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Argentina Ophthalmological society
Invited Lecture
Andrew P. Schachat, M.D.
Association for Research in vision
and Ophthalmology
Symposium Organizer
John W. Crabb, Ph.D.
Program Committee
Neal S. Peachey, Ph.D.
Moderators
David M. Meisler, M.D
Victor L. Perez, M.D.
Chinese Retina and vitreous society
Invited Lecture
Peter K. Kaiser, M.D.
Cleveland Ophthalmological society
Invited Lecture
Michael Millstein, M.D.
European society of Cataract and
Refractive surgeons
Invited Lecture
Ronald R. Krueger, M.D.
International Congress of EpilAsIK lAsEK
and Advanced surface Ablation
Planner
Ronald R. Krueger, M.D.
International Congress of Eye Research
Session Chair
Steven E. Wilson, M.D.
International Congress on
wavefront sensing
Organizer
Ronald R. Krueger, M.D.
Israeli Corneal society Annual meeting
Invited Lecture
Ronald R. Krueger, M.D.
Joint Commission for Allied Health
personnel in Ophthalmology
Invited Lecture
Elias I. Traboulsi, M.D.
pan-American Congress of Ophthalmology
Invited Lecture
Peter K. Kaiser, M.D.
Careen Y. Lowder, M.D., Ph.D.
Refractive on-line
Invited Lecture
Steven E. Wilson, M.D.
Royal Hawaiian Eye meeting
Invited Lectures
Peter K. Kaiser, M.D.
Ronald R. Krueger, M.D.
Andrew P. Schachat, M.D.
sociedad panamericana de Enfermedades
Inflamatorias Oculares
Invited Lecture
Careen Y. Lowder, M.D., Ph.D.
sociedad puertorriqueña de Oftalmología
Invited Lecture
Peter K. Kaiser, M.D.
wilmer Eye Institute Current Concepts
in Ophthalmology
Invited Lecture
Ronald R. Krueger, M.D.
world Ophthalmology Congress
Coordinator
David M. Meisler, M.D.
Session Chair
Careen Y. Lowder, M.D., Ph.D.
Plenary Lecturer
Steven E. Wilson, M.D.
Invited Lecture
Ronald R. Krueger, M.D.
Roles in Professional Societies
American Academy of Ophthalmology
Board of Trustees
Andrew P. Schachat, M.D.
Chairperson, Self-Assessment Committee
Bennie H. Jeng, M.D.
Senior Contributor
Bennie H. Jeng, M.D.
Basic and Clinical Science
Course Committee
Peter K. Kaiser, M.D.
Careen Y. Lowder, M.D., Ph.D.
Certification Committee
Careen Y. Lowder, M.D., Ph.D.
Distribution Advisory Subcommittee
Elias I. Traboulsi, M.D.
Ophthalmic Knowledge Base Panel
Careen Y. Lowder, M.D., Ph.D.
Program Director
Steven E. Wilson, M.D.
American Board of Ophthalmology
Associate Examiners
Careen Y. Lowder, M.D., Ph.D.
David M. Meisler, M.D.
Andrew P. Schachat, M.D.
Association for Research in vision
and Ophthalmology
Trustee
Steven E. Wilson, M.D.
Program Chair
Neal S. Peachey, Ph.D.
Atlanta vA Rehabilitation Center
of Excellence
Board Member
Neal S. Peachey, Ph.D.
Cleveland Eye Bank
Assistant Medical Director
Allen S. Roth, M.D.
Cleveland Ophthalmological society
President
Allen S. Roth, M.D.
Education Program Committee
Elias I. Traboulsi, M.D.
Cleveland sight Center
Advisory Board Member
Elias I. Traboulsi, M.D.
Cleveland vA medical Center,
Research service
Associate Chief of Staff
Neal S. Peachey, Ph.D.
Club Jules Gonin
Member
Hilel Lewis, M.D.
Gaining A new sight for Unsighted
In China (GAnsU, Inc.)
President, Board of Directors
Ronald R. Krueger, M.D.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Heed Ophthalmic Foundation
Executive Secretary
Froncie A. Gutman, M.D.
International society for Genetic Eye
disease and Retinoblastoma
Secretary/Treasurer
Elias I. Traboulsi, M.D.
International society of Refractive surgery
Education Committee Chair
Ronald R. Krueger, M.D.
Joint Commission on Allied Health
personnel in Ophthalmology
Annual Continuing Education Program
Elias I. Traboulsi, M.D.
molecular pathogenesis of Infectious
and Inflammatory Eye Research
Scientific Advisory Board
Victor L. Perez, M.D.
panamerican Association of Ophthalmology
President
Careen Y. Lowder, M.D., Ph.D.
society of Heed Fellows
Trustee
Froncie A. Gutman, M.D.
The diabetes Association of
Greater Cleveland
Chairman
Philip N. Goldberg, M.D.
Recognition
American Academy of Ophthalmology
Lans Distinguished Lecturer Award
Steven E. Wilson, M.D.
Senior Achievement Award
Careen Y. Lowder, M.D., Ph.D.
Senior Honor Award
Elias I. Traboulsi, M.D.
American society for Clinical Investigation
Travel Award
Victor L. Perez, M.D.
American society of Cataract and
Refractive surgery
Best Paper of Session Award
William J. Dupps, M.D., Ph.D.
Appointment to U.s. physician’s
Advisory Board
Ronald R. Krueger, M.D.
Best doctors in America
Careen Y. Lowder, M.D., Ph.D.
David M. Meisler, M.D.
Julian D. Perry, M.D.
Brazilian Ophthalmological society
Visiting Professor
Steven E. Wilson, M.D.
Castle Connolly America’s Top doctors
Ronald R. Krueger, M.D.
Cleveland Browns,
national Football league
Team Ophthalmologist
Peter K. Kaiser, M.D.
Cleveland Cavaliers,
national Basketball Association
Team Ophthalmologist
Peter K. Kaiser, M.D.
Cleveland Clinic
Innovator Award
William J. Dupps, M.D., Ph.D.
Gregory S. Kosmorsky, D.O.
Cleveland Clinic IRB member
Bennie H. Jeng, M.D.
Columbia University College of
physicians & surgeons
Annual Ulrich Ollendorff Lecturer
Hilel Lewis, M.D.
Henry Ford Hospital
Visiting Professor
Ronald R. Krueger, M.D.
International Biographical Centre
Top 100 Health Professionals
Julian D. Perry, M.D.
marquis’ who’s who in medicine
& Healthcare
William J. Dupps, M.D., Ph.D.
national leadership Award
Recipient
Ronald R. Krueger, M.D.
singapore Eye Research Institute
Visiting Professor
Steven E. Wilson, M.D.
strathmore’s who’s who of professionals
Ronald R. Krueger, M.D.
steinbach Award
John W. Crabb, Ph.D.
The Edward s. Harkness Eye Institute
Ollendorff Lectureship
Elias I. Traboulsi, M.D.
Top Fifty Opinion leaders (by readers
of Cataract & Refractive surgery Today)
Ronald R. Krueger, M.D.
University of Rochester Eye Institute
50th Annual Ophthalmology Conference
Snell Memorial Lecturer
Hilel Lewis, M.D.
washington University in st. louis
Visiting Professor
Victor L. Perez, M.D.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //
s t a F F

e d U c a t i O n a n d t r a i n i n g
Education
Education is crucial to our mission, from residency and fellowship
programs to continuing medical education, because we know it is
the path to the future.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Training the Leaders
of Tomorrow
e d U c a t i O n a n d t r a i n i n g
The Cole Eye Institute is committed to offering one of the best residency and fellowship programs in
the United States. These programs are highly competitive and produce superbly trained clinical and
academic ophthalmologists.
Residency Program
the cole eye institute residency training program’s mission
is to prepare participants to become leaders in patient care,
teaching and vision research. the program meets all the requirements
of the american Board of Ophthalmology and the accreditation
council for graduate medical education (acgme).
Four residents are accepted into the program each year.
residents rotate among the institute’s nine departments and
a resident-run clinic at metro-health medical center, while
completing their board requirements. they work under the
direct supervision of the staff during each rotation. the
departments are:
• cornea and external disease
• glaucoma
• neuro-ophthalmology
• Ophthalmic pathology
• Ophthalmic plastic, reconstructive and orbital surgery
• pediatric ophthalmology and adult strabismus
• refractive surgery
• retina and vitreous
• Uveitis, ocular inflammatory disease and immunology
this curriculum provides a balanced exposure to all subspecialty
areas of ophthalmology, ensuring graduates the ability to
perform general ophthalmology with skill, knowledge and confidence.
each resident works in a one-on-one relationship with a
staff physician to provide the best opportunity to study disease
processes and their medical and surgical management. this
arrangement also provides excellent supervision and optimal
continuity of patient care in the outpatient and hospital settings.
residents are also expected to participate in clinical and basic
research activities utilizing the staff's expertise. residents
complete independent clinical research projects that involve reviewing
the literature, developing a hypothesis and designing
and executing the study. research activities are carefully
supervised by an experienced clinical investigator. residents are
expected to submit and present their research at national meetings
and to write several papers for publication based on their
research activities. each June, ophthalmology residents, fellows
and staff participate in the annual research, resident and
alumni meeting, a scientific forum for the presentation of
research projects.
For more information about the cole eye institute residency
training program, contact elias i. traboulsi, m.d., at
216.444.4363.
Fellowship Program
cleveland clinic cole eye institute also offers high-quality
fellowship training opportunities in a variety of subspecialties.
these fellowships train the next generation of academic leaders
in the respective fields by combining an excellent academic
environment with mentorship support in a state-of-the-art eye
care facility.
Our fellowships include a two-year vitreoretinal program
(3 slots), a two-year cornea, external disease and refractive
surgery program (2 slots), a one-year glaucoma fellowship (1 slot)
and a one- or two-year pediatric-ophthalmology fellowship
(1 slot). in 2008, we will be adding a one-year oculoplastic
surgery fellowship (1 slot).
For more information about cole eye institute fellowship
programs, contact Jane sardelle at 216.444.2010.
Continued on page 48
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e d U c a t i O n a n d t r a i n i n g
Training the leaders of tomorrow
Continued from page 47
Our Recent Graduates
here is where our recent residency and fellowship graduates
have gone after completing their cole eye institute training.
Residency Class of 2005
susie chang, m.d.
vitreoretinal Fellow
massachusetts eye and ear infirmary
harvard Univerity
Boston, ma
sai chavala, m.d.
vitreoretinal research Fellow
Weill medical school
cornell University
new york, ny
albert dal canto, m.d., ph.d.
Oculoplastics surgery staff
West virginia University hospitals
morgantown, Wv
alex melamud, m.d., m.a. (chief resident 2005)
vitreoretinal Fellowship
duke University
durham, nc
Residency Class of 2006
pawan Bhatnagar, m.d.
vitreoretinal Fellowship
columbia University
new york, ny
anat galor, m.d. (chief resident 2006)
Uveitis Fellowship
Wilmer institute
Johns hopkins University
Baltimore, md
pankaj gupta, m.d.
cornea Fellowship
massachusetts eye & ear
harvard University
Boston, ma
sunita radhakrishnan, m.d.
glaucoma Fellowship
Wilmer institute
Johns hopkins University
Baltimore, md
Fellows Finishing in 2006
William J. dupps, m.d., ph.d. (was cornea,
external disease & refractive surgery fellow)
staff, cole eye institute
cleveland, Oh
rafael Ufret-vincenty, m.d. (was vitreoretinal fellow)
staff, vitreo-retinal department
University of texas southwestern medical center
dallas, tX
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Continuing Medical
Education
e d U c a t i O n a n d t r a i n i n g
Physicians are invited to join their colleagues from around the country in attending the following ophthalmic
continuing medical education courses at The Cleveland Clinic Cole Eye Institute. All courses will be held
in the James P. Storer Conference Center on the first floor of the Eye Institute, except the Innovations in
Ophthalmology course in March, which will be held in Los Cabos, Mexico.
For more information, contact Jane Sardelle, program coordinator, at 216.444.2010 or 800.223.2273,
ext. 42010, or sardelj@ccf.org.
Innovations in pediatric Ophthalmology
and strabismus
Strabismus Surgical Techniques, Instruments and
Outcomes, Vision Screening and Telemedicine in
Pediatric Ophthalmology
Saturday, September 16, 2006
8:00 a.m. to 2:00 p.m.
Course directors:
Elias I. Traboulsi, M.D.
Head, Pediatric Ophthalmology and
Adult Strabismus Department
Cleveland Clinic Cole Eye Institute
Andreas Marcotty, M.D.
Pediatric Ophthalmology and
Adult Strabismus Department
Cleveland Clinic Cole Eye Institute
Guest Faculty:
David L. Guyton, M.D.
Chairman, Department of Ophthalmology
Director, Krieger Children’s Eye Center
Krieger Professor of Pediatric Ophthalmology
Wilmer Institute, Johns Hopkins Hospital
Baltimore, MD
David G. Hunter, M.D., Ph.D.
Ophthalmologist-in-Chief
Children’s Hospital of Boston
Associate Professor of Ophthalmology
Harvard Medical School
Children’s Hospital Boston
Boston, MA
M. Edward Wilson, Jr., M.D.
Director, Albert Florens Storm Eye Institute
Chairman, Department of Ophthalmology
The Medical University of South Carolina
Pierre Gautier Jenkins Endowed Chair
Charleston, SC
description/Objectives: This course will focus on the mechanisms
of amblyopia and eye movement disorders associated with infantile
esotropia as well as on how insights into these mechanisms affect
clinical management of patients with these conditions.
At the end of the symposium, participants should be able to:
1. Identify the cortical mechanisms that underlie amblyopia in
humans.
2. List the types of conditions that lead to amblyopia and differentiate
them from structural causes of reduced vision in infants
and children.
3. Interpret the indications for different modalities of treatment
of amblyopia.
4. Dissect the complex eye movement abnormalities in the infantile
esotropia complex and understand their mechanisms.
5. Review information and decide on the timing of surgery for
infantile esotropia.
Continued on page 50
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e d U c a t i O n a n d t r a i n i n g
Continuing Medical Education
Continued from page 49
Innovations in Inflammatory Ocular Diseases
Saturday, October 14, 2006
7:30 a.m. to 4:00 p.m.
Course director:
Careen Y. Lowder, M.D., Ph.D.
Uveitis Department
Cleveland Clinic Cole Eye Institute
Cole Eye Institute Faculty:
Peter K. Kaiser, M.D.
Vitreoretinal Surgery Department
Cleveland Clinic Cole Eye Institute
Victor L. Perez, M.D.
Cornea and Uveitis Departments
Cleveland Clinic Cole Eye Institute
Guest Faculty:
Glenn Jaffe, M.D.
Professor, Department of Ophthalmology
Duke University
Durham, NC
Eric Suhler, M.D.
Assistant Professor, Casey Eye Institute
Oregon Health & Science University
Eugene, OR
Howard Tessler, M.D.
Professor, Illinois Eye and Ear Infirmary
Chicago, IL
Scott Whitcup, M.D.
Vice President
Allergan
Irvine, CA
description/Objectives: This course will review the latest treatment
modalities in uveitis including the intravitreal delivery systems for
long-acting and short-acting steroids and the various anti-tumor
necrosis factor alpha. We will compare these new treatments to the
currently accepted systemic immunosuppresssion regimens with
steroids and nonsteroidal immunosuppessive therapy. Cole Eye
Institute experience will be discussed.
At the conclusion of this course, participants should be able to:
1. Describe the use of nonspecific drugs, including immunosuppressive
therapy.
2. Describe current clinical trials in ocular inflammatory diseases.
3. Identify newer therapies for noninfectious posterior
uveitis syndromes.
4. Evaluate and determine which patients will benefit from the
various treatment modalities.
Innovations in Glaucoma
Saturday, December 9, 2006
7:30 a.m. to 4:00 p.m.
Course directors:
Scott D. Smith, M.D., M.P.H.
Edward J. Rockwood, M.D.
Glaucoma Department
Cleveland Clinic Cole Eye Institute
Guest Faculty:
George Baerveldt, MBCHB
Chairman and Professor
Department of Ophthalmology
University of California Irvine Medical Center
Irvine, CA
Reay H. Brown, M.D.
Northside Hospital
Atlanta, GA
description/Objectives: This is an update of diagnostic and surgical
innovations and a new look at old techniques for the management of
glaucoma. There will be didactic lectures, case presentations and
question-and-answer sessions.
At the conclusion of this course, participants should be able to:
1. Identify the role of optic disc imaging in the management of
ocular hypertension and glaucoma.
2. Review a comparison of ultrasound biomicroscopy and OCT
anterior segment imaging for the diagnosis and management of
narrow angles and angle-closure glaucoma.
3. Discuss surgical variations and why glaucoma surgery can be
difficult to simplify and improve.
4. Evaluate outcomes analyses and how they can lead to improved
surgical outcomes in glaucoma.
5. Identify the possible future role of the Eyepass glaucoma device.
6. Identify the role of cataract extraction in the management of
angle-closure glaucoma.
7. Understand the role of the trabectome in the surgical management
of glaucoma.
8. Identify the latest glaucoma implant innovations.
0 // O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Innovations in Ophthalmology
los Cabos, mexico
Sunday-Friday, March 25-30, 2007
7:00 a.m.-1:00 p.m., except first day 1:00-6:00 p.m.
Course director:
Hilel Lewis, M.D.
Chairman, Division of Ophthalmology
Director, Cleveland Clinic Cole Eye Institute
Cole Eye Institute Faculty:
William J. Dupps, M.D., Ph.D.
Cornea, External Disease and
Refractive Surgery Department
Ronald R. Krueger, M.D.
Refractive Surgery Department
David M. Meisler, M.D.
Cornea and External Disease Department
Michael Millstein, M.D.
Comprehensive Ophthalmology Department
Victor L. Perez, M.D.
Cornea and External Disease Department
Julian D. Perry, M.D.
Oculoplastic and Orbital Surgery Department
Andrew P. Schachat, M.D.
Vice Chairman for Clinical Affairs
Scott D. Smith, M.D., M.P.H.
Glaucoma Department
Nadia K. Waheed, M.D.
Vitreoretinal Department
Steven E. Wilson, M.D.
Cornea and External Disease and
Refractive Surgery Department
Guest Faculty:
Iqbal K. Ahmed, M.D.
Clinical Instructor
Department of Ophthalmology
University of Toronto
Toronto, Canada
Sterling S. Baker, M.D.
Assistant Clinical Professor
University of Oklahoma
Oklahoma City, OK
Perry S. Binder, M.D.
Preceptor
University of California, San Diego
San Diego, CA
Mark S. Blumenkranz, M.D.
Professor and Chairman
Stanford University School of Medicine
Stanford, CA
Robert J. Cionni, M.D.
Cincinnati Eye Institute
Cincinnati, OH
Roger A. Dailey, M.D.
Associate Professor of Ophthalmology
Lester T. Jones Chair, Ophthalmic Facial Plastic Surgery
Casey Eye Institute
Portland, OR
Thomas R. Friberg, M.D.
Professor, University of Pittsburgh
Pittsburgh Eye and Ear Institute
Pittsburgh, PA
Stephen D. Klyce, Ph.D.
Professor of Ophthalmology and Cell Biology/Anatomy
Adjunct Professor of Biomedical Engineering,
Tulane University
Louisiana State University Eye Center
New Orleans, LA
Stephen S. Lane, M.D.
Clinical Professor of Ophthalmology
University of Minnesota
Saint Paul, MN
Bradley N. Lemke, M.D.
Clinical Professor
University of Wisconsin-Madison School of Medicine
Lemke Facial Surgery
Madison, WI
Richard J. Mackool, M.D.
Assistant Clinical Professor
New York Medical College
New York Eye and Ear Infirmary
Astoria, NY
e d U c a t i O n a n d t r a i n i n g
Continued on page 52
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e d U c a t i O n a n d t r a i n i n g
Continuing Medical Education
Continued from page 51
Marguerite B. McDonald, M.D.
Clinical Professor of Ophthalmology
Tulane University School of Medicine
Southern Vision Institute
New Orleans, LA
Peter A. Netland, M.D., Ph.D.
Professor and Director of Glaucoma
University of Tennessee
Hamilton Eye Institute
Memphis, TN
Terrence P. O’Brien, M.D.
Professor of Ophthalmology
Bascom Palmer Eye Institute
University of Miami School of Medicine,
Miami, FL
Richard K. Parrish, M.D.
Professor
Associate Dean for Graduate Medical Education
Bascom Palmer Eye Institute
University of Miami School of Medicine
Miami, FL
Stephen C. Pflugfelder, M.D.
Professor, Department of Ophthalmology
Baylor College of Medicine
Houston, TX
Yaron S. Rabinowitz, M.D.
Director, Ophthalmology Research
Cedars Sinai Medical Center
Clinical Professor of Ophthalmology
UCLA School of Medicine
Los Angeles, CA
description/Objectives: The course will provide a comprehensive
review of new developments in clinical practice and will highlight
state-of-the-art management, problem-solving, case presentations
and evaluation of new innovations, interventions and technologies.
There will be ample time for questions and answers and the course
faculty will be available throughout the course for informal discussion
and consultation.
At the conclusion of the course, participants should be able to:
1. Describe the pathogenesis of various ocular disorders.
2. Evaluate and utilize new diagnostic and surgical techniques.
3. Develop effective management strategies.
Innovations in Refractive surgery & Cornea
Saturday, March 17, 2007
7:30 a.m. to 5:00 p.m.
Course director:
Steven E. Wilson, M.D.
Director, Corneal Research
Cleveland Clinic Cole Eye Institute
Cole Eye Institute Faculty:
Ronald R. Krueger, M.D.
Refractive Surgery Department
David M. Meisler, M.D.
Cornea Department
Victor L. Perez, M.D.
Cornea and Uveitis Departments
Guest Faculty:
Perry S. Binder, M.D.
Associate Clinical Professor
University of California-San Diego
Co-Medical Director
IntraLase Corporation
San Diego, CA
Eric Donnenfeld, M.D.
Founding Partner
Ophthalmic Consultants of Long Island
Associate Professor of Ophthalmology
New York University
New York, NY
David T.C. Lin, M.D.
Medical Director
Pacific-Laser Eye Centre
Clinical Assistant Professor of Ophthalmology
The University of British Columbia
Vancouver, BC
Yaron S. Rabinowitz, M.D.
Director, Ophthalmology Research
Cedars-Sinai Medical Center
Clinical Professor of Ophthalmology
UCLA School of Medicine
Los Angeles, CA
George O. Waring, III, M.D., F.A.C.S., FRCOphth
Private Practice/Multispecialty
Professor, Emory University
Atlanta, GA
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

description/Objectives: This course will highlight important
information related to innovations that are critical to refractive
surgeons, cornea specialists and comprehensive ophthalmologists
regarding refractive surgery procedures, complications in refractive
surgery and corneal diseases, such as chronic dry eye, keratoconus
and corneal transplant rejection.
At the conclusion of the course, participants should be able to:
1. Identify factors predisposing eyes to corneal ectasia following
refractive surgery.
2. Obtain a better understanding of procedures such as corneal
endothelial replacement surgery, femtosecond laser procedures
and the use of multifocal intraocular lenses.
3. Achieve a better understanding of the treatment of complications
of refractive surgery.
6th Retina summit: Innovations in vitreoretinal
diseases and surgery
Thursday and Friday, May 3-4, 2007
8:00 a.m. to 5:00 p.m.
Course director:
Hilel Lewis, M.D.
Chairman, Division of Ophthalmology
Director, Cleveland Clinic Cole Eye Institute
Cole Eye Institute Faculty:
Bela Anand-Apte, M.B.B.S., Ph.D.
Ophthalmic Research Department
John W. Crabb, Ph.D.
Ophthalmic Research Department
Joe G. Hollyfield, Ph.D.
Ophthalmic Research Department
Peter K. Kaiser, M.D.
Vitreoretinal Department
Andrew P. Schachat, M.D.
Vice Chairman for Clinical Affairs
Jonathan E. Sears, M.D.
Vitreoretinal Department
Guest Faculty:
Mark Blumenkranz, M.D.
Stanford University School of Medicine
Department of Ophthalmology
Stanford, CA
Stanley Chang, M.D.
Professor & Chairman
Department of Ophthalmology
Edward Harkness Eye Institute
Columbia University
New York, NY
Eugene de Juan, Jr, M.D.
Assistant Clinical Professor
Department of Ophthalmology
Beckman Vision Center
University of California, San Francisco
San Francisco, CA
Martin Friedlander, M.D.
Professor, Department of Cell Biology
Scripps Research Institute
La Jolla, CA
José Garcia-Arumi, M.D.
Professor of Ophthalmology
Universitat Autonoma de Barcelona
Institut de Microcirurgia Ocular
Barcelona, Spain
Mark S. Humayun, M.D., Ph.D.
Retina Institute
Doheny Eye Institute
Los Angeles, CA
Glenn J. Jaffe, M.D.
Professor of Ophthalmology
Vitreoretinal Diseases and Surgery
Duke University Eye Center
Durham, NC
e d U c a t i O n a n d t r a i n i n g
Henry J. Kaplan, M.D.
Evans Professor of Ophthalmology
Chair, Department of Ophthalmology and Visual Sciences
Director, Kentucky Lions Eye Center
Louisville, KY
Continued on page 54
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e d U c a t i O n a n d t r a i n i n g
Continuing Medical Education
Continued from page 53
Philip J. Rosenfeld, M.D., Ph.D.
Associate Professor
Department of Ophthalmology
Bascom Palmer Eye Institute
Miami, FL
Yasuo Tano, M.D.
Professor and Chairman
Ophthalmology Department
Osaka University Medical School
Suita, Japan
description/Objectives: This 6th Retina Summit is intended to
provide ophthalmologists and vitreoretinal specialists with information
about issues relating to diagnosing and treating patients with
vitreoretinal diseases, utilizing the full spectrum of medical and
surgical therapies currently available. Live surgery and live laser
sessions are part of the summit format. We will examine interesting
case presentations, in which experts will advise on specific
treatments for patients with vitreoretinal diseases. This summit
offers a great opportunity for audience participation.
At the conclusion of the summit, participants should be able to:
1. Discuss the pathophysiology and diagnosis of several
vitreoretinal diseases.
2. Review a variety of new treatments for age-related macular
degeneration, diabetic retinopathy, complicated retinal
detachment and other macular and retinal diseases.
3. Examine new technology, including state-of-the-art and
experimental imaging systems, drug-delivery systems and
new instrumentation.
4. Analyze cost-effective therapeutic protocols.
5. Review publicized findings, ongoing clinical trials and
the assessment of new data and discoveries.
6. Demonstrate live surgical procedures.
7. Examine interesting case presentations.
Annual Research, Residents & Alumni meeting
Thursday and Friday, June 21-22, 2007
5:00 p.m. to 7:30 p.m. (Thursday);
7:30 a.m. to 6:00 p.m. (Friday)
Course directors:
Hilel Lewis, M.D.
Chairman, Division of Ophthalmology
Director, Cleveland Clinic Cole Eye Institute
Careen Y. Lowder, M.D., Ph.D.
Director, Uveitis Department
Cleveland Clinic Cole Eye Institute
Keynote speaker:
Paul A. Sieving, M.D., Ph.D.
Director, National Eye Institute, National Institutes of Health
Bethesda, MD
description/Objectives: This program provides a scientific forum
to present original, thought-provoking clinical research papers and
basic science research of the Cole Eye Institute residents, fellows,
staff, alumni and invited ophthalmologists. In addition to the
educational aspects of the program and learning about new and
ongoing investigations, this event offers an excellent opportunity
to meet current residents, fellows, new faculty and invited ophthalmologists,
and to make and renew friendships.
At the conclusion of the meeting, participants should be able to:
1. Recognize the most up-to-date concepts and treatments in
research and clinical ophthalmology.
2. Identify current basic science research in age-related macular
degeneration.
3. Review the rationale and status of the most current treatments
for uveitic and diabetic macular edema.
4. Discuss outcomes of complicated glaucoma and cataract surgery.
5. Describe the latest techniques in refractive surgery.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

e d U c a t i O n a n d t r a i n i n g
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

e d U c a t i O n a n d t r a i n i n g
Grand Rounds
cole eye institute hosts grand rounds every monday morning
from 7 to 8 a.m. during the academic year (except holidays and
major meeting times). For the academic year 2006–2007, they
will begin sept. 18, 2006, and run through late June. the meetings
are designed for residents, fellows and staff physicians of
the cole eye institute, as well as other comprehensive and subspecialty
ophthalmologists. We are pleased to offer category 1
continuing education credits for each meeting. evaluations are
offered online following each meeting and attendance certificates
can be printed or saved for your record-keeping purposes.
the grand rounds’ forum consists of two clinical cases
presented by cole eye institute residents, followed by extensive
discussion. cases selected for presentation represent outstanding
teaching examples and are either difficult-to-manage cases,
unusual presentations of common disorders, rare conditions or
cases that highlight state-of-the-art diagnosis or management.
in addition, approximately every six weeks, m&m cases
are presented and discussed by third-year residents with
follow-up discussion.
the meetings are held the James p. storer conference room
on the first floor of the cole eye institute and registration is not
required to attend. park in the patient/visitor lot at e. 102nd
street (facing the front of the cole eye institute), or the patient/
visitors garage at e. 100th street and carnegie avenue. parking
tickets will be validated.
For questions, please call Jane sardelle at 216.444.2010 (sardelj@
ccf.org) or see careen y. lowder, m.d., ph.d., at the meetings.
// O p t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Distinguished
Lecture Series
e d U c a t i O n a n d t r a i n i n g
The Cole Eye Institute Distinguished Lecture Series provides a forum for renowned researchers in the visual
sciences to present their latest findings. This series of lectures features advances in many areas of ophthalmic
research presented by noted basic and clinical scientists from throughout the world. Ample opportunity for
questions and answers is provided.
All lectures are held on Thursdays from 7 to 8 a.m. in the James P. Storer Conference Room on the first floor of
The Cleveland Clinic Cole Eye Institute. Registration is not required. For questions, please call 216.444.5832.
pathogenic mechanisms in Uveoretinitis
September 14, 2006
John V. Forrester, M.D.
Cockburn Professor and Head
Department of Ophthalmology
University of Aberdeen
Institute of Medical Sciences
Foresthill
Aberdeen, Scotland
Circadian Clocks and neuromodulators in the Retina
October 19, 2006
P. Michael Iuvone, Ph.D.
Professor
Department of Pharmacology
Emory University
Atlanta, GA
making sense of neuronal diversity:
A Bottom-Up view of the Retina
November 16, 2006
Richard H. Masland, Ph.D.
Charles A. Pappas Professor of Neuroscience
Harvard Medical School
Investigator, Howard Hughes Medical Institute
Boston, MA
new Advances in syndromic Retinal degeneration
January 18, 2007
Elise Heon, M.D., F.R.C.S.C.
Ophthalmologist-in-Chief
Associate Surgeon-in-Chief for Research
Associate Scientist, Genetics and Genomic Biology
Research Institute, The Hospital for Sick Children
Professor of Ophthalmology
The University of Toronto
Toronto, Ontario
Using Experimental Genetics to Understand
mechanisms of Glaucoma
February 15, 2007
Simon W. M. John, Ph.D.
Associate Investigator
Howard Hughes Medical Institute
Jackson Laboratory
Bar Harbor, Maine
Continued on page 58
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

e d U c a t i O n a n d t r a i n i n g
Distinguished Lecture Series
Continued from page 57
design of a pediatric Clinical Trial for Treatment
of Congenital Blindness
March 15, 2007
Jean Bennett, M.D., Ph.D.
Professor
F.M. Kirby Center for Molecular Ophthalmology
Scheie Eye Institute
Institute of Neurological Sciences
University of Pennsylvania
Philadelphia, PA
The Bizarro world of Angiogenesis
April 19, 2007
Jayakrishna Ambati, M.D.
Department of Ophthalmology and Visual Sciences
University of Kentucky
Lexington, KY
Defining a Retinal Stem Cell Niche
May 17, 2007
Pamela Raymond, Ph.D.
Professor
Department of Molecular, Cellular and Developmental Biology
University of Michigan
Ann Arbor, MI
RnA Tools for Retinal diseases
June 21, 2007
Alfred S. Lewin, Ph.D.
Shaler-Richardson Professor
Department of Molecular Genetics & Microbiology
University of Florida
Gainesville, FL
pathogenesis of dry Amd:
Role of smoking and RpE Injury
July 19, 2007
Scott W. Cousins, M.D.
Professor of Ophthalmology
Duke Center for Macular Disease
Duke University Eye Center
Durham, NC
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Research
We will never stop pursuing answers to the most challenging problems
in ophthalmology.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

e s e a r c h
Grants
cleveland clinic cole eye institute had an aggregate annual
grant level of $19,965,008 in 2006*, with $13,305,405 coming
from federal and state sources. cole eye institute and its partners
received $6 million for age-related macular degeneration
(amd) research under Ohio’s Biomedical research and
technology transfer (Brtt) partnership program, which
supports biomedical and biotechnology research leading to
commercialization and long-term improvements to the health of
Ohio’s residents.
*Year-to-date through July 2006.
Title source sponsor Id# principal Investigator
A Multi-Center Study To Map Genes for Fuchs’ Dystrophy Federal NIH EY016482 William J. Dupps, M.D., Ph.D.
Advanced Imaging for Glaucoma Federal NIH EY013516 Scott D. Smith, M.D., M.P.H.
Amblyopia Treatment Study: Pediatric Federal NIH EY011751 Diane Tucker, O.D., F.A.A.O., F.C.O.V.D.
Amblyopia Treatment Study: Pediatric Federal NIH EY011751 Elias I. Traboulsi, M.D.
Corneal Donor Study Federal NIH EY012358 David M. Meisler, M.D.
Corneal Epithelial Growth Factors and Receptors Federal NIH EY010056 Steven E. Wilson, M.D.
Drusen and AMD: Sub-type Isolation and Characterization Federal NIH EY014240 Joe G. Hollyfield, Ph.D.
Expression and Regulation of Retinal Angiotensin II Federal NIH EY013752 Preenie deS Senanayake, Ph.D.
Infant Aphakia Treatment Study Federal NIH EY013272 Elias I. Traboulsi, M.D.
Inhibition of VEGF Mediated Angiogenesis by TIMP-3 Federal NIH CA106415 Bela Anand-Apte, M.B.B.S., Ph.D.
Mouse Models for Vision Research Federal NIH EY016501 Neal S. Peachey, Ph.D.
Proteomic Analyses of Human Trabecular Meshwork Federal NIH EY015266 Sanjoy Bhattacharya, Ph.D.
Proteomic Studies of Age Related Macular Degeneration Federal NIH EY014239 John W. Crabb, Ph.D.
Regulation of Corneal Inflammation by Fas Ligand Federal NIH EY014912 Victor L. Perez, M.D.
Role of TIMP-3 in Ocular Neovascularization Federal NIH EY016490 Bela Anand-Apte, M.B.B.S., Ph.D.
Role of TULP1 in Photoreceptor Cells Federal NIH EY016072 Stephanie Hagstrom, Ph.D.
Studies of Visual Cycle Proteins Federal NIH EY006603 John W. Crabb, Ph.D.
The dc-Electroretinogram Federal NIH EY014465 Neal S. Peachey, Ph.D.
The Intravitreal Corticosteroid for Macular Edema Study Federal NIH EY014351 Peter K. Kaiser, M.D.
Vascular Remodeling and Effects of Angiogenic Inhibition Federal NIH EY017528 Peter K. Kaiser, M.D.
Vision Research Infrastructure Development Grant Federal NIH EY015638 Joe G. Hollyfield, Ph.D.
Research into Age-related Macular Degeneration State State of Ohio BRTT 05-29 Hilel Lewis, M.D.
0 // O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

AMD Initiative for
Prevention and Cure
The Cole Eye Institute AMD Initiative for Prevention
and Cure was established through a grant from the
State of Ohio, corporate sponsors, investors and
leading academic institutions to develop and commercialize
new comprehensive technologies for early
diagnosis, prevention and treatment of age-related
macular degeneration.
spECIFIC InITIATIvEs OF THE pROGRAm InClUdE:
r e s e a r c h
• the commercialization of a blood test for amd based on
biomarkers that can track therapeutic efficacy and identify
high-risk patients prior to vision loss.
• the prevention of neovascular amd-related blood vessel
growth and leaking with novel cell-signaling inhibitors.
• identification and analysis of therapeutic agents that prevent
retinal protein oxidative damage and subsequent development
of amd.
• characterization of oxidative changes in the retina associated
with amd that will aid in the identification of drug targets to
prevent this disorder.
• isolation of genetic factors involved in amd and development
of new animal models that will result in more efficient screening,
faster optimization and better efficacy of new therapies
for amd.
• characterization of inflammatory and immunological signals
involved in the progression of disease that may lead to the
development of an amd vaccine.
• investigation of retinal stem cell-mediated vision restoration
in amd.
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

e s e a r c h
Clinical Trials
The following studies are currently enrolling. All studies have been approved by the Institutional Review Board.
RETInAl dIsE AsEs
protocol B7A-mC-mBdl Reduction in the Occurrence of
Center-Threatening diabetic macular Edema
Objective: The primary objective of this study is to test the hypothesis
that oral administration of 32 mg per day of Ruboxistaurin for
approximately 36 months will reduce, relative to placebo, the
occurrence of center-threatening diabetic macular edema as assessed
by fundus photography in patients with non-clinically significant
macular edema and nonproliferative diabetic retinopathy at baseline.
Contact: P. Kaiser, M.D., at 216.444.6702 or L. Schaaf, R.N.,
at 216.445.4086
protocol B7A-mC-mBCU The Effect of Ruboxistaurin
on Clinically Significant Macular Edema in Patients
with diabetes mellitus, as assessed by Optical
Coherence Tomography
Objective: The primary objective of this study is to test the hypothesis
that oral administration of 32 mg per day of ruboxistaurin for 18
months will reduce the baseline to endpoint changes in central
macular thickness, as measured by OCT in patients with CSME.
Contact: P. Kaiser, M.D., at 216.444.6702 or L. Schaaf, R.N.,
at 216.445.4086
The standard Care versus Corticosteroid for Retinal
vein Occlusion study
Objective: To evaluate the effectiveness of triamcinolone acetonide
injections for treatment of macular edema versus standard treatment.
Patients will have 11 to 13 visits over a period of up to
three years.
Contact: P. Kaiser, M.D., at 216.444.6702 or L. Holody, C.O.A.,
at 216.445.3762
A six-month phase 3, multicenter, masked, Randomized,
sham-Controlled Trial (with six-month Open-label
Extension) to Assess the Safety and Efficacy of 700 μg
and 350 μg Dexamethasone Posterior Segment Drug
delivery system
Objective: To evaluate the safety and efficacy of the 700 μg DEX PS
DDS Applicator System and 350 μg DEX PS DDS Applicator System
compared with a Sham DEX PS DDS Applicator System (needle-less
applicator) for six months in patients with macular edema following
branch retinal vein occlusion or central retinal vein occlusion.
The safety of the 700 μg DEX PS DDS Applicator System will
be assessed for an additional 6 months in patients who qualify
for treatment in an open-label safety extension.
Contact: P. Kaiser, M.D., at 216.444.6702 or L. Schaaf, R.N.,
at 216.445.4086
A Randomized Trial Comparing Intravitreal Triamcinolone
Acetonide and laser photocoagulation for diabetic
macular Edema
Objective: To determine whether intravitreal triamcinolone acetonide
injections at doses of 1 mg or 4 mg produce greater benefit, with an
acceptable safety profile, than macular laser photocoagulation in the
treatment of diabetic macular edema.
Contact: P. Kaiser, M.D., at 216.444.6702 or L. Holody, C.O.A.,
at 216.445.3762
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

A 3-Year, phase 3, multicenter, masked, Randomized,
sham-Controlled Trial to Assess the Safety and Efficacy
of 700 μg and 350 μg Dexamethasone Posterior
segment drug delivery system (dEX ps dds) Applicator
system in the Treatment of patients with diabetic
macular Edema
Objective: To evaluate the safety and efficacy of the 700 μg DEX PS
DDS Applicator System and 350 μg DEX PS DDS Applicator System
compared with a Sham DEX PS DDS Applicator System (needle-less
applicator) in patients with diabetic macular edema.
Contact: P. Kaiser, M.D., at 216.444.6702 or L. Schaaf, R.N.,
at 216.445.4086
A phase IIIb, multicenter study To Evaluate the safety
and Tolerability of Ranibizumab in naïve and previously
Treated subjects with Choroidal neovascularization
secondary to Age-Related macular degeneration
Objective: To estimate the incidence of ocular and non-ocular
serious adverse events in subjects treated for 12 months with
0.3 mg or 0.5 mg intravitreal ranibizumab.
Contact: P. Kaiser, M.D., at 216.444.6702 or L. Bartko, R.N.,
at 216.444.7137
Gl AUCOmA
Advanced Imaging for Glaucoma
Objective: Advanced Imaging for Glaucoma (AIG) is a multi-center
bioengineering partnership sponsored by the National Eye Institute
to develop advanced imaging technologies to improve the detection
and management of glaucoma. The advanced imaging technologies
include optical coherence tomography, scanning laser polarimetry
and scanning laser tomography. The technologies will be evaluated
in a longitudinal five-year clinical trial composed of glaucoma
suspects, glaucoma patients and normal subjects.
Contact: S. Smith, M.D., M.P.H., at 216.444.4821
or L. Holody, C.O.A., at 216.445.3762
GEnETICs
studies of the molecular Genetics of Eye diseases
Objective: To map the genes for inherited eye diseases. To screen
candidate genes for mutations in a variety of genetic ocular
disorders, including ocular malformations, congenital cataracts
and retinal dystrophies.
Contact: E. Traboulsi, M.D., at 216.444.4363 or S. Crowe, C.O.T.,
at 216.445.3840
The Genetics of strabismus
r e s e a r c h
Objective: To discover the genes that cause some strabismus
syndromes, including those for accommodative esotropia, congenital
esotropia, congenital ocular fibrosis syndrome, intermittent exotropia,
Brown syndrome and Duane syndrome.
Contact: E. Traboulsi, M.D., at 216.444.4363 or S. Crowe, C.O.T.,
at 216.445.3840
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

e s e a r c h
Selected Recent
Publications
pEER-REvIEwEd JOURnAls
Advances in Experimental medicine and Biology
Bonilha VL, Rayborn ME, Bhattacharya SK, Gu X, Crabb JS, Crabb
JW, Hollyfield JG. The retinal pigment epithelium apical microvilli
and retinal function. Advances in Experimental Medicine and
Biology 2006;572:519-524.
Rayborn ME, Sakaguchi H, Shadrach KG, Crabb JW, Hollyfield JG.
Annexins in Bruch’s membrane and drusen. Advances in Experimental
Medicine and Biology 2006;572:75-78.
Wu Z, Bhattacharya SK, Jin Z, Bonilha VL, Liu T, Nawrot M, Teller
D, Saari JC, Crabb JW. CRALBP ligand and protein interactions.
Advances in Experimental Medicine and Biology
2006;572:477-483.
American Family physician
Melamud A, Palekar R, Singh A. Retinoblastoma. American Family
Physician 2006 Mar 15;73(6):1039-1044.
American Journal of medical Genetics. part A
Hagstrom SA, Pauer GJ, Reid J, Simpson E, Crowe S, Maumenee
IH, Traboulsi EI. SOX2 mutation causes anophthalmia, hearing loss,
and brain anomalies. American Journal of Medical Genetics Part A
2005 Sep 6;138A(2):95-98.
Li C, Kosmorsky G, Zhang K, Katz BJ, Ge J, Traboulsi EI. Optic
atrophy and sensorineural hearing loss in a family caused by an
R445H OPA1 mutation. American Journal of Medical Genetics
Part A 2005 Oct 15;138(3):208-211.
American Journal of Ophthalmology
Do DV, Nguyen QD, Bressler NM, Schachat AP, Solomon SD,
Melia M, Bressler SB. Hemoglobin A1c awareness among patients
receiving eye care at a tertiary ophthalmic center. American
Journal of Ophthalmology 2006 May;141(5):951-953.
Netto MV, Dupps W, Jr., Wilson SE. Wavefront-guided ablation:
evidence for efficacy compared to traditional ablation. American
Journal of Ophthalmology 2006 Feb;141(2):360-368.
Singh RP, Sears JE. Retinal pigment epithelial tears after
pegaptanib injection for exudative age-related macular degeneration.
American Journal of Ophthalmology 2006 Jul;142(1):160-162.
Bakri SJ, Kaiser PK. Reply. American Journal of Ophthalmology
2005 Nov;140(5):958-959.
Bakri SJ, Kaiser PK. Posterior subtenon triamcinolone acetonide
for refractory diabetic macular edema. American Journal of
Ophthalmology 2005 Feb;139(2):290-294.
Chalita MR, Li Y, Smith S, Patil C, Westphal V, Rollins AM, Izatt JA,
Huang D. High-speed optical coherence tomography of laser
iridotomy. American Journal of Ophthalmology 2005
Dec;140(6):1133-1136.
Kaiser PK. Steroids for branch retinal vein occlusion. American
Journal of Ophthalmology 2005 Jun;139(6):1095-1096.
Kaiser PK. Steroids for choroidal neovascularization. American
Journal of Ophthalmology 2005 Mar;139(3):533-535.
Liesegang TJ, Schachat AP, Albert DM. The Open Access initiative
in scientific and biomedical publishing: fourth in the series on
editorship. American Journal of Ophthalmology 2005
Jan;139(1):156-167.
Liesegang TJ, Schachat AP, Albert DM. Maintaining public trust in
medical journals. American Journal of Ophthalmology 2005
Apr;139(4):707-709.
Lowder CY, Davros WJ, Kaiser PK, Sanislo SR, Kosmorsky GS,
Meziane MA, Rice TW, Meisler DM. Author reply [Risks of computerized
tomography in the evaluation of chronic uveitis]. American
Journal of Ophthalmology 2005 May;139(5):952.
Meisler DM, Perez VL, Proudfit J. A device to facilitate limbal stem
cell procurement from eye bank donor tissue for keratolimbal
allograft procedures. American Journal of Ophthalmology 2005
Jan;139(1):212-214.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Traboulsi EI. The challenges and surprises of studying the genetics
of age-related macular degeneration. American Journal of Ophthalmology
2005 May;139(5):908-911.
Annals of plastic surgery
Perry JD. Re: surgery without skin resection for eyelid entropion.
Annals of Plastic Surgery 2005 Jan;54(1):114.
Archives of Ophthalmology
Leske MC, Wu SY, Hennis A, Nemesure B, Schachat AP,
Hyman L, Yang L. Nine-year incidence of diabetic retinopathy
in the Barbados Eye Studies. Archives of Ophthalmology 2006
Feb;124(2):250-255.
Ou JI, Moshfeghi DM, Tawansy K, Sears JE. Macular hole in
the shaken baby syndrome. Archives of Ophthalmology 2006
Jun;124(6):913-915.
Albert DM, Liesegang TJ, Schachat AP. Meeting our ethical
obligations in medical publishing: responsibilities of editors,
authors, and readers of peer-reviewed journals. Archives of
Ophthalmology 2005 May;123(5):684-686.
Apte RS, Dibernardo C, Pearlman JR, Patel S, Schachat AP,
Green WR, Gehlbach P. Retinal metastasis presenting as a retinal
hemorrhage in a patient with adenocarcinoma of the cecum.
Archives of Ophthalmology 2005 Jun;123(6):850-853.
Apte RS, Schachat AP, Dibernardo C, Handa JT. Retinal vascular
occlusion with overlying vitreous hemorrhage masquerading as a
tumor. Archives of Ophthalmology 2005 Feb;123(2):272-274.
Apte RS, Al-Abdulla NA, Green WR, Schachat AP, DeJong MR,
Dibernardo C, Handa JT. Systemic non-Hodgkin B-cell lymphoma
encountered as a vanishing choroidal mass. Archives of Ophthalmology
2005 Jan;123(1):105-109.
Bressler NM, Bressler SB, Haynes LA, Hao Y, Kaiser PK, Miller JW,
Naor J, Potter MJ, Pournaras CJ, Reaves A, Rosenfeld PJ, Schmidt-
Erfurth U, Slakter JS, Strong A, Vannier S. Verteporfin therapy for
subfoveal choroidal neovascularization in age-related macular
degeneration: four-year results of an open-label extension of 2
randomized clinical trials: TAP Report No. 7. Archives of
Ophthalmology 2005 Sep;123(9):1283-1285.
Levin LA, Gottlieb JL, Beck RW, Albert DM, Liesegang TJ, Hoyt CS,
Dick A, Bhisitkul R, Schachat AP. Registration of clinical trials.
Archives of Ophthalmology 2005 Sep;123(9):1263-1264.
Radhakrishnan S, Goldsmith J, Huang D, Westphal V, Dueker DK,
Rollins AM, Izatt JA, Smith SD. Comparison of optical coherence
tomography and ultrasound biomicroscopy for detection of narrow
anterior chamber angles. Archives of Ophthalmology 2005
Aug;123(8):1053-1059.
Singh AD, Mudhar HS, Bhola R, Rundle PA, Rennie IG. Sebaceous
adenoma of the eyelid in Muir-Torre syndrome. Archives of
Ophthalmology 2005 Apr;123(4):562-565.
Wilson SE, Netto MV. Refractive surgery and cornea: the neverending
spiral of technology. Archives of Ophthalmology 2005
Feb;123(2):265-266.
Arquivos Brasileiros de Oftalmologia
Netto MV, Ambrosio R, Jr., Chalita MR, Krueger RR, Wilson SE.
Resposta cicatricial corneana em diferentes modalidades de
cirurgia refrativa [Corneal wound healing response following
different modalities of refractive surgical procedures] [Portuguese].
Arquivos Brasileiros de Oftalmologia 2005 Jan;68(1):140-149.
Biochemistry
Maeda A, Crabb JW, Palczewski K. Microsomal glutathione
S-transferase 1 in the retinal pigment rpithelium: protection
against oxidative stress and a potential role in aging. Biochemistry
2005 Jan 18;44(2):480-489.
British Journal of Ophthalmology
Singh RP, Patel C, Sears JE. Management of subretinal macular
haemorrhage by direct administration of tissue plasminogen
activator. British Journal of Ophthalmology 2006 Apr;90(4):
429-431.
r e s e a r c h
Chavala SH, Sari A, Lewis H, Pauer GJT, Simpson E, Hagstrom SA,
Traboulsi EI. An Arg311Gln NR2E3 mutation in a family with classic
Goldmann-Favre syndrome. British Journal of Ophthalmology 2005
Aug;89(8):1065-1066.
Parsons MA, Rennie IG, Rundle PA, Dhingra S, Mudhar H, Singh
AD. Congenital hypertrophy of retinal pigment epithelium: a clinicopathological
case report. British Journal of Ophthalmology 2005
Jul;89(7):920-921.
Sabti K, Hajj BA, Hwang JM, Traboulsi EI, Reid J. Congenital third
nerve palsy, moyamoya disease and optic nerve head staphyloma.
British Journal of Ophthalmology 2005 Jun;89(6):778-779.
Cancer Research
Datta J, Majumder S, Bai S, Ghoshal K, Kutay H, Smith DS, Crabb
JW, Jacob ST. Physical and functional interaction of DNA methyltransferase
3A with Mbd3 and Brg1 in mouse lymphosarcoma
cells. Cancer Research 2005 Dec 1;65(23):10891-10900.
Continued on page 66
c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

e s e a r c h
Selected Recent Publications
Continued from page 65
Chemical Research in Toxicology
Gugiu BG, Mesaros CA, Sun M, Gu X, Crabb JW, Salomon RG.
Identification of oxidatively truncated ethanolamine phospholipids
in retina and their generation from polyunsaturated phosphatidylethanolamines.
Chemical Research in Toxicology 2006
Feb;19(2):262-271.
Cleveland Clinic Journal of medicine
Hajj-Ali RA, Lowder C, Mandell BF. Uveitis in the internist’s office:
are a patient’s eye symptoms serious? Cleveland Clinic Journal
of Medicine 2005 Apr;72(4):329-339.
Cornea
Netto MV, Mohan RR, Ambrosio R, Jr., Hutcheon AE, Zieske JD,
Wilson SE. Wound healing in the cornea: a review of refractive
surgery complications and new prospects for therapy. Cornea
2005 Jul;24(5):509-522.
Current medical Research & Opinion
Kaiser PK. Verteporfin therapy in combination with triamcinolone:
published studies investigating a potential synergistic effect.
Current Medical Research & Opinion 2005 May;21(5):705-713.
emedicine Journal [electronic resource]
Clark WL, Kaiser PK, Trattler W. Endophthalmitis, postoperative.
eMedicine Journal [electronic resource] 2005 Jun 16.
Parwar B, Tong J, Perry JD. Nasolacrimal system anatomy.
eMedicine Journal [electronic resource] 2005 May 27.
European Journal of Internal medicine
Chavala SH, Kosmorsky GS, Lee MK, Lee MS. Optic neuropathy in
vitamin B(12) deficiency. European Journal of Internal Medicine
2005 Oct;16(6):447-448.
Evidence-Based Ophthalmology
Singh AD. Macular retinoblastoma managed with chemoreduction
analysis of tumor control with or without adjuvant thermotherapy
in 68 tumors. Evidence-Based Ophthalmology 2005 Oct;6(4):
211-212.
Experimental Eye Research
Bonilha VL, Rayborn ME, Shadrach K, Lundwall A, Malm J,
Bhattacharya SK, Crabb JW, Hollyfield JG. Characterization
of semenogelin proteins in the human retina. Experimental Eye
Research 2006 Jul;83(1):120-127.
Bonilha VL, Rayborn ME, Saotome I, McClatchey AI, Hollyfield JG.
Microvilli defects in retinas of ezrin knockout mice. Experimental
Eye Research 2006 Apr;82(4):720-729.
Netto MV, Mohan RR, Sinha S, Sharma A, Dupps W, Wilson SE.
Stromal haze, myofibroblasts, and surface irregularity after PRK.
Experimental Eye Research 2006 May;82(5):788-797.
Senanayake PD, Calabro A, Hu JG, Bonilha VL, Darr A, Bok D,
Hollyfield JG. Glucose utilization by the retinal pigment epithelium:
Evidence for rapid uptake and storage in glycogen, followed by
glycogen utilization. Experimental Eye Research 2006
Aug;83(2):235-246.
Vaughan DK, Peachey NS, Richards MJ, Buchan B, Fliesler SJ.
Light-induced exacerbation of retinal degeneration in a rat model of
Smith-Lemli-Opitz syndrome. Experimental Eye Research 2006
Mar;82(3):496-504.
Wu J, Marmorstein AD, Peachey NS. Functional abnormalities in
the retinal pigment epithelium of CFTR mutant mice. Experimental
Eye Research 2006 Aug;83(2):424-428.
Xi Q, Pauer GJT, Traboulsi EI, Hagstrom SA. Mutation screen
of the TUB gene in patients with retinitis pigmentosa and Leber
congenital amaurosis. Experimental Eye Research 2006
Sep;83(3):569-573.
Yokoyama T, Yamane K, Minamoto A, Tsukamoto H, Yamashita H,
Izumi S, Hoppe G, Sears JE, Mishima HK. High glucose concentration
induces elevated expression of anti-oxidant and proteolytic
enzymes in cultured human retinal pigment epithelial cells.
Experimental Eye Research 2006 Sep;83(3):602-609.
Bhattacharya SK, Annangudi SP, Salomon RG, Kuchtey RW,
Peachey NS, Crabb JW. Cochlin deposits in the trabecular
meshwork of the glaucomatous DBA/2J mouse. Experimental Eye
Research 2005 May;80(5):741-744.
Hollyfield JG. Announcement from the Editor-in-Chief. Experimental
Eye Research 2005 Apr;80(4):451.
Jeng BH, Shadrach KG, Meisler DM, Hollyfield JG, Connor JT,
Koeck T, Aulak KS, Stuehr DJ. Immunohistochemical detection and
Western blot analysis of nitrated protein in stored human corneal
epithelium. Experimental Eye Research 2005 Apr;80(4):509-514.
// O p h t h a l m O l O g y U p d a t e s p e c i a l e d i t i O n 2 0 0 6

Nakata K, Crabb JW, Hollyfield JG. Crystallin distribution in Bruch’s
membrane-choroid complex from AMD and age-matched donor
eyes. Experimental Eye Research 2005 Jun;80(6):821-826.
Ouchi M, West K, Crabb JW, Kinoshita S, Kamei M. Proteomic
analysis of vitreous from diabetic macular edema. Experimental
Eye Research 2005 Aug;81(2):176-182.
Saari JC, Crabb JW. Focus on molecules: Cellular retinaldehydebinding
protein (CRALBP). Experimental Eye Research 2005
Sep;81(3):245-246.
Experimental neurology
Papathanasiou ES, Peachey NS, Goto Y, Neafsey EJ, Castro AJ,
Kartje GL. Visual cortical plasticity following unilateral sensorimotor
cortical lesions in the neonatal rat. Experimental Neurology 2006
May;199(1):122-129.
Expert Opinion on Investigational drugs
Bakri SJ, Kaiser PK. Anecortave acetate. Expert Opinion on
Investigational Drugs 2006 Feb;15(2):163-169.
Eye
Singh AD, Rundle PA, Longstaff S, Jacques R, Rennie IG. Iris
pigment epithelial adenoma: resection and repair. Eye 2006
Mar;20(3):385-386.
Singh AD, Jacques R, Rundle PA, Mudhar HS, Rennie IG. Combined
enucleation and orbitotomy for choroidal melanoma with orbital
extension. Eye 2006 May;20(5):615-617.
Dinakaran S, Singh AD, Rennie IG. Orbital amyloidosis presenting
as ptosis. Eye 2005 Jan;19(1):110-112.
Giles J, Singh AD, Rundle PA, Noe KP, Rennie IG. Retinal astrocytic
hamartoma with exudation. Eye 2005 Jun;19(6):724-725.
Gupta M, Singh AD, Stavrou P, Rundle PA, Rennie IG. Spontaneous
resolution of a choroidal mass. Eye 2005 May;19(5):601-603.
Mansour AM, Bitar F, Traboulsi E, Kassak K, Obeid M, Megarbane
A, Salti H. Reply to Bianca et al [Reply to ocular pathology in
congenital heart disease]. Eye 2005 Dec;19(12):1341.
Mansour AM, Bitar FF, Traboulsi EI, Kassak KM, Obeid MY,
Megarbane A, Salti HI. Ocular pathology in congenital heart
disease. Eye 2005 Jan;19(1):29-34.
r e s e a r c h
Singh AD, Rundle PA, Vardy SJ, Rennie IG. Photodynamic therapy
of choroidal haemangioma associated with sturge-weber syndrome.
Eye 2005 Mar;19(3):365-367.
Singh AD, Talbot JF, Rundle PA, Rennie IG. Choroidal neovascularization
secondary to choroidal osteoma: successful treatment with
photodynamic therapy. Eye 2005 Apr;19(4):482-484.
Singh AD, McCloskey L, Parsons MA, Slater DN. Eccrine hidrocystoma
of the eyelid. Eye 2005 Jan;19(1):77-79.
Eye & Contact lens
Jeng BH, Millstein ME. Reduction of hyperopia and astigmatism
after superficial keratectomy of peripheral hypertrophic subepithelial
corneal degeneration. Eye & Contact Lens 2006 May;32(3):153-156.
FAsEB Journal
Rosenthal R, Bakall B, Kinnick T, Peachey N, Wimmers S, Wadelius
C, Marmorstein A, Strauss O. Expression of bestrophin-1, the
product of the VMD2 gene, modulates voltage-dependent Ca2+
channels in retinal pigment epithelial cells. FASEB Journal 2006
Jan;20(1):178-180.
Kim KS, Ren J, Jiang Y, Ebrahem Q, Tipps R, Cristina K, Xiao YJ,
Qiao J, Taylor KL, Lum H, Anand-Apte B, Xu Y. GPR4 plays a
critical role in endothelial cell function and mediates the effects
of sphingosylphosphorylcholine. FASEB Journal 2005 May;
19(7):819-821.
Human molecular Genetics
Shu X, Fry AM, Tulloch B, Manson FDC, Crabb JW, Khanna H,
Faragher AJ, Lennon A, He S, Trojan P, Giessl A, Wolfrum U,
Vervoort R, Swaroop A, Wright AF. RPGR ORF15 isoform co-localizes
with RPGRIP1 at centrioles and basal bodies and interacts with
nucleophosmin. Human Molecular Genetics 2005 May
1;14(9):1183-1197.
International Journal of pediatric Otorhinolaryngology
Cannady SB, Kahn TA, Traboulsi EI, Koltai PJ. PHACE syndrome:
report of a case with a glioma of the anterior skull base and
ocular malformations. International Journal of Pediatric
Otorhinolaryngology 2006 Mar;70(3):561-564.
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Selected Recent Publications
Continued from page 67
International Journal of sTd and AIds
Holkar S, Mudhar HS, Jain A, Gupta M, Rogstad KE, Parsons MA,
Singh AD, Rennie IG. Regression of invasive conjunctival squamous
carcinoma in an HIV-positive patient on antiretroviral therapy.
International Journal of STD and AIDS 2005 Dec;16(12):782-783.
International Ophthalmology Clinics
Bakri SJ, Sculley L, Singh AD. Imaging techniques for uveal
melanoma. International Ophthalmology Clinics 2006;46(1):1-13.
Foster JA, Proffer PL, Proffer LH, Wulc AE, Perry JD. Modifying
brow position with botulinum toxin. International Ophthalmology
Clinics 2005 Summer;45(3):123-131.
Investigative Ophthalmology & visual science
Bhattacharya SK, Crabb JS, Bonilha VL, Gu X, Takahara H, Crabb
JW. Proteomics implicates peptidyl arginine deiminase 2 and optic
nerve citrullination in glaucoma pathogenesis. Investigative
Ophthalmology & Visual Science 2006 Jun;47(6):2508-2514.
Bidinost C, Matsumoto M, Chung D, Salem N, Zhang K, Stockton
DW, Khoury A, Megarbane A, Bejjani BA, Traboulsi EI. Heterozygous
and homozygous mutations in PITX3 in a large Lebanese
family with posterior polar cataracts and neurodevelopmental
abnormalities. Investigative Ophthalmology & Visual Science
2006 Apr;47(4):1274-1280.
Carlson EC, Drazba J, Yang X, Perez VL. Visualization and characterization
of inflammatory cell recruitment and migration through
the corneal stroma in endotoxin-induced keratitis. Investigative
Ophthalmology & Visual Science 2006 Jan;47(1):241-248.
Sears JE, Hoppe G. Triamcinolone acetonide destabilizes VEGF
mRNA in Muller cells under continuous cobalt stimulation.
Investigative Ophthalmology & Visual Science 2005
Nov;46(11):4336-4341.
Sokal I, Dupps WJ, Grassi MA, Brown J, Jr., Affatigato LM,
Roychowdhury N, Yang L, Filipek S, Palczewski K, Stone EM, Baehr
W. A novel GCAP1 missense mutation (L151F) in a large family
with autosomal dominant cone-rod dystrophy (adCORD). Investigative
Ophthalmology & Visual Science 2005 Apr;46(4):1124-1132.
Xi Q, Pauer GJT, Marmorstein AD, Crabb JW, Hagstrom SA. Tubbylike
Protein 1 (TULP1) interacts with F-actin in photoreceptor cells.
Investigative Ophthalmology & Visual Science 2005
Dec;46(12):4754-4761.
Journal of Biological Chemistry
Bhattacharya SK, Rockwood EJ, Smith SD, Bonilha VL, Crabb JS,
Kuchtey RW, Robertson NG, Peachey NS, Morton CC, Crabb JW.
Proteomics reveal cochlin deposits associated with glaucomatous
trabecular meshwork. Journal of Biological Chemistry 2005 Feb
18;280(7):6080-6084.
Journal of Cataract and Refractive surgery
Melamud A, Chalita MR, Krueger RR, Lee MS. Comatic aberration
as a cause of monocular diplopia. Journal of Cataract and
Refractive Surgery 2006 Mar;32(3):529-532.
Krueger RR, Kuszak J, Lubatschowski H, Myers RI, Ripken T,
Heisterkamp A. First safety study of femtosecond laser photodisruption
in animal lenses: Tissue morphology and cataractogenesis.
Journal of Cataract and Refractive Surgery 2005 Dec;31(12):
2386-2394.
Journal of General physiology
Marmorstein LY, Wu J, McLaughlin P, Yocom J, Karl MO, Neussert
R, Wimmers S, Stanton JB, Gregg RG, Strauss O, Peachey NS,
Marmorstein AD. The light peak of the electroretinogram is
dependent on voltage-gated calcium channels and antagonized by
bestrophin (best-1). Journal of General Physiology 2006
May;127(5):577-589.
Journal of Glaucoma
Mansberger SL, Johnson CA, Cioffi GA, Choi D, Krishnadas SR,
Srinivasan M, Balamurugan V, Kim U, Smith SD, Wilkins JH, Gritz
DC. Predictive value of frequency doubling technology perimetry for
detecting glaucoma in a developing country. Journal of Glaucoma
2005 Apr;14(2):128-134.
Journal of medical Genetics
Chan WM, Traboulsi EI, Arthur B, Friedman N, Andrews C, Engle
EC. Horizontal gaze palsy with progressive scoliosis can result from
compound heterozygous mutations in ROBO3. Journal of Medical
Genetics 2006 Mar;43(3):e11.
Melamud A, Shen GQ, Chung D, Xi Q, Simpson E, Li L, Peachey
NS, Zegarra H, Hagstrom SA, Wang QK, Traboulsi EI. Mapping a
new genetic locus for X linked retinitis pigmentosa to Xq28.
Journal of Medical Genetics 2006 Jun;43(6):e27.
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Journal of neuroscience
Bjartmar L, Huberman AD, Ullian EM, Renteria RC, Liu X, Xu W,
Prezioso J, Susman MW, Stellwagen D, Stokes CC, Cho R, Worley P,
Malenka RC, Ball S, Peachey NS, Copenhagen D, Chapman B,
Nakamoto M, Barres BA, Perin MS. Neuronal pentraxins mediate
synaptic refinement in the developing visual system. Journal of
Neuroscience 2006 Jun 7;26(23):6269-6281.
Yi X, Schubert M, Peachey NS, Suzuma K, Burks DJ, Kushner JA,
Suzuma I, Cahill C, Flint CL, Dow MA, Leshan RL, King GL, White
MF. Insulin receptor substrate 2 Is essential for maturation and
survival of photoreceptor cells. Journal of Neuroscience 2005 Feb
2;25(5):1240-1248.
Journal of pediatric Ophthalmology and strabismus
Simon J, Sood S, Yoon MK, Kaw P, Zobal-Ratner J, Archer S,
Gardiner JA, Hutchinson A, Marcotty A, Noel LP, Olsen TW,
Tawansy K, Wallace D. Vitrectomy for dense vitreous hemorrhage
in infancy. Journal of Pediatric Ophthalmology and Strabismus
2005 Jan;42(1):18-22.
Journal of Refractive surgery
Krueger RR. Corneal topography vs ocular wavefront sensing in
the retreatment of highly aberrated post surgical eyes. Journal of
Refractive Surgery 2006 Apr;22(4):328-330.
Netto MV, Mohan RR, Sinha S, Sharma A, Gupta PC, Wilson SE.
Effect of prophylactic and therapeutic mitomycin C on corneal
apoptosis, cellular proliferation, haze, and long-term keratocyte
density in rabbits. Journal of Refractive Surgery 2006
Jun;22(6):562-574.
Applegate RA, Krueger RR, Pesudovs K, Chalita MR. Introduction
to the proceedings of the 6th International Congress on Wavefront
Sensing and Optimized Refractive Corrections. Journal of Refractive
Surgery 2005;21(5):S506-S507.
Dupps WJ, Jr. Biomechanical modeling of corneal ectasia. Journal
of Refractive Surgery 2005 Mar;21(2):186-190.
Krueger RR. Technological improvements with the Alcon LADAR
6000 excimer laser platform. Journal of Refractive Surgery 2005
Nov;21(6):S775-S780.
Krueger RR. Introduction to commercially approved wavefrontguided
customization: third year in review. Journal of Refractive
Surgery 2005 Nov;21(6):S767-S768.
r e s e a r c h
Netto MV, Wilson SE. Indications for excimer laser surface ablation.
Journal of Refractive Surgery 2005 Nov;21(6):734-741.
Netto MV, Ambrosio R, Jr., Shen TT, Wilson SE. Wavefront analysis
in normal refractive surgery candidates. Journal of Refractive
Surgery 2005 Jul;21(4):332-338.
Waheed S, Chalita MR, Xu M, Krueger RR. Flap-induced and laserinduced
ocular aberrations in a two-step LASIK procedure. Journal
of Refractive Surgery 2005 Jul;21(4):346-352.
molecular and Cellular neurosciences
Lee Y, Kameya S, Cox GA, Hsu J, Hicks W, Maddatu TP, Smith RS,
Naggert JK, Peachey NS, Nishina PM. Ocular abnormalities in
Large(myd) and Large(vls) mice, spontaneous models for muscle,
eye, and brain diseases. Molecular and Cellular Neurosciences
2005 Oct;30(2):160-172.
Ocular Immunology and Inflammation
Taban M, Dupps WJ, Mandell B, Perez VL. Etanercept (enbrel)associated
inflammatory eye disease: case report and review of
the literature. Ocular Immunology and Inflammation 2006
Jun;14(3):145-150.
Ophthalmic Epidemiology
Gritz DC, Srinivasan M, Smith SD, Kim U, Lietman TM, Wilkins JH,
Priyadharshini B, Aravind S, Prajna NV, Smolin G, Thulasiraj RD,
Selvaraj S, Whitcher JP. Antioxidants in prevention of cataracts in
South India: methodology and baseline data. Ophthalmic Epidemiology
2006 Apr;13(2):97-107.
Ophthalmic Genetics
Bonilha VL, Hollyfield JG, Grover S, Fishman GA. Abnormal
distribution of red/green cone opsins in a patient with an autosomal
dominant cone dystrophy. Ophthalmic Genetics 2005 Jun;26(2):
69-76.
Pauer GJT, Xi Q, Zhang K, Traboulsi EI, Hagstrom SA. Mutation
screen of the membrane-type frizzled-related protein (MFRP) gene
in patients with inherited retinal degenerations. Ophthalmic
Genetics 2005 Dec;26(4):157-161.
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Selected Recent Publications
Continued from page 69
Ophthalmic plastic and Reconstructive surgery
Foster JA, Holck DE, Perry JD, Wulc AE, Burns JA, Cahill KV,
Morgenstern KE. Fibrin sealant for Muller muscle-conjunctiva
resection ptosis repair. Ophthalmic Plastic and Reconstructive
Surgery 2006 May;22(3):184-187.
Ophthalmic surgery, lasers & Imaging
Moshfeghi DM, Kaiser PK, Bakri SJ, Kaiser RS, Maturi RK, Sears
JE, Scott IU, Belmont J, Beer PM, Quiroz-Mercado H, Mieler WF.
Presumed sterile endophthalmitis following intravitreal triamcinolone
acetonide injection. Ophthalmic Surgery, Lasers & Imaging 2005
Jan;36(1):24-29.
Ophthalmology
Ambrosio R, Jr., Netto MV, Wilson SE. Surgery in patients with
Fuchs’. Ophthalmology 2006 Mar;113(3):503.
Dal Canto A, Perry JD. Author reply [Posterior sub–Tenon’s capsule
triamcinolone]. Ophthalmology 2006 Mar;113(3):504-505.
Leske MC, Wu SY, Hennis A, Nemesure B, Yang L, Hyman L,
Schachat AP. Nine-year incidence of age-related macular degeneration
in the Barbados Eye Studies. Ophthalmology 2006
Jan;113(1):29-35.
Singh AD, Bena JF, Mokashi AA, Jacques R, Rundle PA, Rennie IG.
Growth of small tumors. Ophthalmology 2006 Jun;113(6):
1061-1064.
Singh AD, Mokashi AA, Bena JF, Jacques R, Rundle PA, Rennie IG.
Small choroidal melanocytic lesions: features predictive of growth.
Ophthalmology 2006 Jun;113(6):1032-1039.
Dal Canto AJ, Downs-Kelly E, Perry JD. Ptosis and orbital fat
prolapse after posterior sub-Tenon’s capsule triamcinolone
injection. Ophthalmology 2005 Jun;112(6):1092-1097.
Estafanous MFG, Lowder CY, Kaiser PK. Patterns of macular edema
in uveitis patients. Ophthalmology 2005 Feb;112(2):360-361.
Leske MC, Wu SY, Hennis A, Hyman L, Nemesure B, Yang L,
Schachat AP. Hyperglycemia, blood pressure, and the 9-year
incidence of diabetic retinopathy: the Barbados Eye Studies.
Ophthalmology 2005 May;112(5):799-805.
Liesegang TJ, Schachat AP, Albert DA. Pharmaceutical companies
and ophthalmic research. Ophthalmology 2005 Mar;112(3):
363-365.
Schachat AP. New treatments for age-related macular degeneration.
Ophthalmology 2005 Apr;112(4):531-532.
Singh AD, Kalyani P, Topham A. Estimating the risk of malignant
transformation of a choroidal nevus. Ophthalmology 2005
Oct;112(10):1784-1789.
Ophthalmology Clinics of north America
Cox CA, Krueger RR. Monovision with laser vision correction.
Ophthalmology Clinics of North America 2006 Mar;19(1):71-75.
Honavar SG, Singh AD. Management of advanced retinoblastoma.
Ophthalmology Clinics of North America 2005 Mar;18(1):65-73.
Journee-de Korver HG, Midena E, Singh AD. Infrared thermotherapy:
from laboratory to clinic. Ophthalmology Clinics of North
America 2005 Mar;18(1):99-110.
Kuchtey RW, Lowder CY, Smith SD. Glaucoma in patients with
ocular inflammatory disease. Ophthalmology Clinics of North
America 2005 Sep;18(3):421-430.
Radhakrishnan S, Huang D, Smith SD. Optical coherence tomography
imaging of the anterior chamber angle. Ophthalmology Clinics
of North America 2005 Sep;18(3):375-381.
Singh AD, Borden EC. Metastatic uveal melanoma. Ophthalmology
Clinics of North America 2005 Mar;18(1):143-150.
Singh AD, Lewis H, Schachat AP. Primary lymphoma of the central
nervous system. Ophthalmology Clinics of North America 2005
Mar;18(1):199-207.
Singh AD, Bergman L, Seregard S. Uveal melanoma: epidemiologic
aspects. Ophthalmology Clinics of North America 2005
Mar;18(1):75-84.
Singh AD, Kivela T. The collaborative ocular melanoma study.
Ophthalmology Clinics of North America 2005 Mar;18(1):129-142.
Singh AD, Rundle PA, Rennie I. Retinal vascular tumors. Ophthalmology
Clinics of North America 2005 Mar;18(1):167-176.
Singh AD, Damato B, Howard P, Harbour JW. Uveal melanoma:
genetic aspects. Ophthalmology Clinics of North America 2005
Mar;18(1):85-97.
Singh AD, Kaiser PK, Sears JE. Choroidal hemangioma. Ophthalmology
Clinics of North America 2005 Mar;18(1):151-161.
Singh AD. Ophthalmic oncology. Philadelphia: Elsevier; 2005
(Ophthalmology Clinics of North America 18(1):1-213.)
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Singh AD. Ophthalmic oncology – preface. Ophthalmology Clinics
of North America 2005 Mar;18(1):xiii.
Smith SD. Glaucoma. Ophthalmology Clinics of North America
2005 Sep;18(3):ix.
Traboulsi EI. Ocular manifestations of familial adenomatous
polyposis (gardner syndrome). Ophthalmology Clinics of North
America 2005 Mar;18(1):163-166.
proceedings of the national Academy of sciences of the
United states of America
Jacobson SG, Aleman TS, Cideciyan AV, Sumaroka A, Schwartz SB,
Windsor EAM, Traboulsi EI, Heon E, Pittler SJ, Milam AH, Maguire
AM, Palczewski K, Stone EM, Bennett J. Identifying photoreceptors
in blind eyes caused by RPE65 mutations: Prerequisite for human
gene therapy success. Proceedings of the National Academy of
Sciences of the United States of America 2005 Apr
26;102(17):6177-6182.
Sundin OH, Leppert GS, Silva ED, Yang JM, Dharmaraj S, Maumenee
IH, Santos LC, Parsa CF, Traboulsi EI, Broman KW, Dibernardo
C, Sunness JS, Toy J, Weinberg EM. Extreme hyperopia is the result
of null mutations in MFRP, which encodes a Frizzled-related
protein. Proceedings of the National Academy of Sciences of the
United States of America 2005 Jul 5;102(27):9553-9558.
progress in Retinal and Eye Research
Mohan RR, Sharma A, Netto MV, Sinha S, Wilson SE. Gene therapy
in the cornea. Progress in Retinal and Eye Research 2005
Sep;24(5):537-559.
Retina
Bakri SJ, Sears JE, Singh AD. Transient closure of a retinal capillary
hemangioma with verteporfin photodynamic therapy. Retina 2005
Dec;25(8):1103-1104.
Goldstein M, Loewenstein A, Barak A, Pollack A, Bukelman A, Katz
H, Springer A, Schachat AP, Bressler NM, Bressler SB, Cooney
MJ, Alster Y, Rafaeli O, Malach R. Results of a multicenter clinical
trial to evaluate the preferential hyperacuity perimeter for detection
of age-related macular degeneration. Retina 2005
Apr;25(3):296-303.
Singerman LJ, Brucker AJ, Jampol LM, Lim JI, Rosenfeld P,
Schachat AP, Spaide RF. Neovascular age-related macular degeneration:
roundtable. Retina 2005 Oct;25(7 Suppl):S1-S22.
surgical neurology
r e s e a r c h
Lee JH, Tobias S, Kwon JT, Sade B, Kosmorsky G. Wilbrand’s knee:
does it exist? Surgical Neurology 2006 Jul;66(1):11-17.
survey of Ophthalmology
Saavedra E, Singh AD, Sears JE, Ratliff NB. Plexiform pigmented
schwannoma of the uvea. Survey of Ophthalmology 2006
Mar;51(2):162-168.
Transactions of the American Ophthalmological society
Traboulsi EI, Chung D, Koors JM, Bronwyn Bateman J, Raab EL,
Edward Wilson M, Spaeth GL. Polychromasia capsulare (multicolored
capsule): Report of three families. Transactions of the American
Ophthalmological Society 2005;103:93-97.
visual neuroscience
Chang B, Heckenlively JR, Bayley PR, Brecha NC, Davisson MT,
Hawes NL, Hirano AA, Hurd RE, Ikeda A, Johnson BA, McCall MA,
Morgans CW, Nusinowitz S, Peachey NS, Rice DS, Vessey KA,
Gregg RG. The nob2 mouse, a null mutation in Cacna1f: anatomical
and functional abnormalities in the outer retina and their consequences
on ganglion cell visual responses. Visual Neuroscience
2006 Jan;23(1):11-24.
Bhattacharya SK, Peachey NS, Crabb JW. Cochlin and glaucoma:
A mini-review. Visual Neuroscience 2005 Sep;22(5):605-613.
Sharma S, Ball SL, Peachey NS. Pharmacological studies of the
mouse cone electroretinogram. Visual Neuroscience 2005
Sep;22(5):631-636.
BOOK CHApTERs
Chalita MR, Krueger RR. Refractive surgery. In: Agarwal A, ed.
Handbook of ophthalmology. Thorofare, NJ: Slack, 2006.
Chapter 21. p. 617-640.
Krueger RR, Yeh PC, Azar DT. Wavefront analysis, principles, and
LASEK application. In: Azar DT, Camellin M, Yee RW, eds. LASEK,
PRK, and excimer laser stromal surface ablation. New York: Marcel
Dekker, 2005. Chapter 20. p. 205-223.(Refractive Surgery).
Bakri SJ, Kaiser PK. Diabetic retinopathy. In: Huang D, Kaiser PK,
Lowder CY, Traboulsi EI, eds. Retinal imaging. Philadelphia: Mosby
Elsevier, 2006. Chapter 21. p. 233-240.
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Selected Recent Publications
Continued from page 71
Chavala SH, Traboulsi EI. Hereditary/congenital vitreoretinal
disorders. In: Huang D, Kaiser PK, Lowder CY, Traboulsi EI, eds.
Retinal imaging. Philadelphia: Mosby Elsevier, 2006. Chapter 53.
p. 456-460.
Galor A, Perez VL, Kaiser PK. Ocular histoplasmosis. In: Huang D,
Kaiser PK, Lowder CY, Traboulsi EI, eds. Retinal imaging.
Philadelphia: Mosby Elsevier, 2006. Chapter 40. p. 359-365.
Kosobucki BR, Lowder CY, Freeman WR. Cytomegalovirus retinitis.
In: Huang D, Kaiser PK, Lowder CY, Traboulsi EI, eds. Retinal
imaging. Philadelphia: Mosby Elsevier, 2006. Chapter 48.
p. 413-417.
Lowder CY. Sarcoidosis. In: Huang D, Kaiser PK, Lowder CY,
Traboulsi EI, eds. Retinal imaging. Philadelphia: Mosby Elsevier,
2006. Chapter 33. p. 310-313.
Melamud A, Kaiser PK. Hypertensive retinopathy. In: Huang D,
Kaiser PK, Lowder CY, Traboulsi EI, eds. Retinal imaging.
Philadelphia: Mosby Elsevier, 2006. Chapter 28. p. 283-288.
Melamud A, Traboulsi EI, Sears J. Coats’ disease. In: Huang D,
Kaiser PK, Lowder CY, Traboulsi EI, eds. Retinal imaging. Philadelphia:
Mosby Elsevier, 2006. Chapter 25. p. 267-270.
Melamud A, Wang Q, Traboulsi EI. Retinitis pigmentosa and allied
disorders. In: Huang D, Kaiser PK, Lowder CY, Traboulsi EI, eds.
Retinal imaging. Philadelphia: Mosby Elsevier, 2006. Chapter 54.
p. 461-467.
Sears J. Retinopathy of prematurity. In: Huang D, Kaiser PK, Lowder
CY, Traboulsi EI, eds. Retinal imaging. Philadelphia: Mosby Elsevier,
2006. Chapter 26. p. 271-275.
Singh AD. Tuberous sclerosis complex. In: Huang D, Kaiser PK,
Lowder CY, Traboulsi EI, eds. Retinal imaging. Philadelphia: Mosby
Elsevier, 2006. Chapter 61. p. 509-512.
Singh AD. Congenital hypertrophy of the retinal pigment epithelium
and other pigmented lesions. In: Huang D, Kaiser PK, Lowder CY,
Traboulsi EI, eds. Retinal imaging. Philadelphia: Mosby Elsevier,
2006. Chapter 63. p. 519-523.
Singh AD, Traboulsi EI. Cavernous hemangioma of the retina. In:
Huang D, Kaiser PK, Lowder CY, Traboulsi EI, eds. Retinal imaging.
Philadelphia: Mosby Elsevier, 2006. Chapter 58. p. 496-498.
Singh AD, Kaiser PK. Choroidal hemangioma. In: Huang D, Kaiser
PK, Lowder CY, Traboulsi EI, eds. Retinal imaging. Philadelphia:
Mosby Elsevier, 2006. Chapter 60. p. 505-508.
Singh AD. Melanocytoma of the optic disc. In: Huang D, Kaiser PK,
Lowder CY, Traboulsi EI, eds. Retinal imaging. Philadelphia: Mosby
Elsevier, 2006. Chapter 69. p. 556-558.
Traboulsi EI. Macular dystrophies. In: Huang D, Kaiser PK, Lowder
CY, Traboulsi EI, eds. Retinal imaging. Philadelphia: Mosby Elsevier,
2006. Chapter 17. p. 198-205.
Traboulsi EI. Optic pits. In: Huang D, Kaiser PK, Lowder CY,
Traboulsi EI, eds. Retinal imaging. Philadelphia: Mosby Elsevier,
2006. Chapter 67. p. 545-547.
Traboulsi EI. Other optic nerve malformations. In: Huang D, Kaiser
PK, Lowder CY, Traboulsi EI, eds. Retinal imaging. Philadelphia:
Mosby Elsevier, 2006. Chapter 72. p. 591-595.
Ufret-Vincenty RL, Lerner LE, Kaiser PK. Non-neovascular agerelated
macular degeneration. In: Huang D, Kaiser PK, Lowder CY,
Traboulsi EI, eds. Retinal imaging. Philadelphia: Mosby Elsevier,
2006. Chapter 11. p. 145-151.
Jeng BH, Lowder CY, Holland GN, Meisler DM. Corneal and external
ocular infections in acquired immunodeficiency syndrome (AIDS).
In: Krachmer JH, Mannis MJ, Holland EJ, eds. Cornea. 2nd ed. St.
Louis; London: Elsevier Mosby, 2005. Volume 1. Chapter 72.
p. 869-877.
Jeng BH, Oxford KW, Abbott RL. Infections after penetrating
keratoplasty. In: Krachmer JH, Mannis MJ, Holland EJ, eds. Cornea.
2nd ed. St. Louis; London: Elsevier Mosby, 2005. Volume 2.
Chapter 129. p. 1551-1563.
Baylin EB, Traboulsi EI. Skeletal and connective tissue disorders.
In: Krachmer JH, Mannis MJ, Holland EJ, eds. Cornea. 2nd ed.
St. Louis; London: Elsevier Mosby, 2005. Volume 1. Chapter 65.
p. 777-796.
Chern KC, Meisler DM. Less common viral corneal infections. In:
Krachmer JH, Mannis MJ, Holland EJ, eds. Cornea. 2nd ed. St.
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c O l e e y e i n s t i t U t e c l e v e l a n d c l i n i c . O r g / e y e //

Ophthalmology Update // Special Edition 2006
Ophthalmology Update, a publication of The Cleveland Clinic
Cole Eye Institute, provides information for ophthalmologists
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