2009-2010 Bulletin â PDF - SEAS Bulletin - Columbia University
2009-2010 Bulletin â PDF - SEAS Bulletin - Columbia University
2009-2010 Bulletin â PDF - SEAS Bulletin - Columbia University
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the equivalent. Design, fabrication, and application<br />
of micro- and nano-structured systems for<br />
cell engineering. Recognition and response of<br />
cells to spatial aspects of their extracellular environment.<br />
Focus on neural, cardiac, co-culture,<br />
and stem cell systems. Molecular complexes at<br />
the nanoscale.<br />
BMEN E4560y Dynamics of biological<br />
membranes<br />
Lect: 3. 3 pts. Not given in <strong>2009</strong>–<strong>2010</strong>.<br />
Prerequisite: Undergraduate cell biology or BMEN<br />
E4001. The structure and dynamics of biological<br />
(cellular) membranes are discussed, with an<br />
emphasis on biophysical properties. Topics will<br />
include membrane composition, fluidity, lipid<br />
asymmetry, lipid-protein interactions, membrane<br />
turnover, membrane fusion, transport, lipid phase<br />
behavior. In the second half of the semester, students<br />
will lead discussions of recent journal articles.<br />
BMEN E4570x Science and engineering of<br />
body fluids<br />
Lect: 3. 3 pts. Professor Matsuoka.<br />
Prerequisites: General chemistry, organic chemistry,<br />
and basic calculus. Body fluids as a dilute<br />
solution of polyelectrolyte molecules in water.<br />
Study of physical behavior as affected by the<br />
presence of ions in surrounding environments.<br />
The physics of covalent, ionic, and hydrogen<br />
bonds are reviewed, in relation to the structure/<br />
properties of the body fluid. Selected physiological<br />
processes are examined in physical-chemical<br />
terms for polymers.<br />
BMEN E4590x BioMems: cellular and molecular<br />
applications<br />
Lect: 3. 3 pts. Not given in <strong>2009</strong>–<strong>2010</strong>.<br />
Prerequisites: CHEM C3443 or CHEN C3545 or the<br />
equivalent and MATH V1201. Corequisites: BIOL<br />
W2005 or the equivalent. Topics include biomicroelectromechanical,<br />
microfluidic, and lab-on-a-chip<br />
systems in biomedical engineering, with a focus on<br />
cellular and molecular applications. Microfabrication<br />
techniques, biocompatibility, miniaturization of analytical<br />
and diagnostic devices, high-throughput cellular<br />
studies, microfabrication for tissue engineering,<br />
and in vivo devices.<br />
BMEN E4601y Cellular electricity<br />
Lect: 2 Lab: 3. 3 pts. Not given in <strong>2009</strong>–<strong>2010</strong>.<br />
Bioelectricity of the cell membrane. Basis of cell<br />
resting voltage, voltage changes that lead to the<br />
action potential and electrical oscillations used<br />
in sensing systems. Laboratory includes building<br />
electronic circuits to measure capacitance of artificial<br />
membranes and ion pumping in frog skin.<br />
APBM E4650x Anatomy for physicists and<br />
engineers<br />
Lect: 3. 3 pts. Instructor to be announced.<br />
Prerequisite: Engineering or physics background.<br />
A systemic approach to the study of the human<br />
body from a medical imaging point of view: skeletal,<br />
respiratory, cardiovascular, digestive, and urinary<br />
systems; breast and women’s issues; head<br />
and neck; and central nervous system. Lectures<br />
are reinforced by examples from clinical two- and<br />
three-dimensional and functional imaging (CT,<br />
MRI, PET, SPECT, U/S, etc.).<br />
BIOL G4700y Seminar in stem cell biology<br />
Lect: 3. 3 pts. Professors Bulinsk, Kalderon, Hung,<br />
Vunjak-Novakovic.<br />
Alternating weeks of high-level research seminars<br />
with guest speakers and class discussions will<br />
cover selected topics at the forefront of stem cell<br />
biology research in a course designed for Ph.D.<br />
and advanced master’s students. Grading based<br />
on class participation, written assignments every<br />
other week, and a term paper with an original<br />
synthesis of ideas or a research proposal.<br />
BMME E4702x Advanced musculoskeletal<br />
biomechanics<br />
Lect: 2.5. Lab: 0.5. 3 pts. Not given in <strong>2009</strong>–<strong>2010</strong>.<br />
Advanced analysis and modeling of the musculoskeletal<br />
system. Topics include advanced concepts<br />
of 3-D segmental kinematics, musculoskeletal<br />
dynamics, experimental measurements of joint<br />
kinematics and anatomy, modeling of muscles<br />
and locomotion, multibody joint modeling, introduction<br />
to musculoskeletal surgicalsimulations.<br />
BMEN E4737x Computer control of medical<br />
instrumentation<br />
Lect: 2. Lab: 1. 3 pts. Not given in <strong>2009</strong>–<strong>2010</strong>.<br />
Prerequisite: Basic knowledge of the C programming<br />
language. Acquisition and presentation of<br />
data for medical interpretation. Operating principles<br />
of medical devices: technology of medical<br />
sensors, algorithms for signal analysis, computer<br />
interfacing and programming, interface design.<br />
Laboratory assignments cover basic measurement<br />
technology, interfacing techniques, use of<br />
Labview software instrument interrogation and<br />
control, automated ECG analysis, ultrasonic<br />
measurements, image processing applied to<br />
x-ray images and CAT scans.<br />
BMEN E4738y Transduction and acquisition<br />
of biomedical data<br />
Lect: 2. Lab: 1. 3 pts. Not given in <strong>2009</strong>–<strong>2010</strong>.<br />
Data transduction and acquisition systems used<br />
in biomedicine. Assembly of bio-transducers and<br />
the analog/digital circuitry for acquiring electrocardiogram,<br />
electromyogram, and blood pressure<br />
signals. Each small group will develop and construct<br />
a working data acquisition board, which will<br />
be interfaced with a signal generator to elucidate<br />
the dynamics of timing constraints during retrieval<br />
of bio-data.<br />
BMEN E4750y Sound and hearing<br />
Lect: 3. 3 pts. Professor Olson.<br />
Prerequisites: General physics sequence and two<br />
semesters of calculus. Introductory acoustics,<br />
basics of waves and discrete mechanical systems.<br />
The mechanics of hearing—how sound is transmitted<br />
through the external and middle ear to the<br />
inner ear, and the mechanical processing of sound<br />
within the inner ear.<br />
CBMF W4761y Computational genomics<br />
Lect: 3. 3 pts. Professor Leslie.<br />
Prerequisites: Working knowledge of at least one<br />
programming language, and some background<br />
in probability and statistics. Computational techniques<br />
for analyzing and understanding genomic<br />
data, including DNA, RNA, protein, and gene<br />
expression data. Basic concepts in molecular<br />
biology relevant to these analyses. Emphasis on<br />
techniques from artificial intelligence and machine<br />
learning. String-matching algorithms, dynamic<br />
programming, hidden Markov models, expectation-maximization,<br />
neural networks, clustering<br />
algorithms, support vector machines. Students<br />
with life sciences backgrounds who satisfy the<br />
prerequisites are encouraged to enroll.<br />
BMEN E4810y Artificial organs<br />
Lect: 3. 3 pts. Professor Leonard.<br />
Analysis and design of replacements for the<br />
heart, kidneys, and lungs. Specification and realization<br />
of structures for artificial organ systems.<br />
BMEN E4894x Biomedical imaging<br />
Lect: 3. 3 pts. Professor Hielscher.<br />
This course covers image formation, methods of<br />
analysis, and representation of digital images.<br />
Measures of qualitative performance in the context<br />
of clinical imaging. Algorithms fundamental to the<br />
construction of medical images via methods of<br />
computed tomography, magnetic resonance,<br />
and ultrasound. Algorithms and methods for the<br />
enhancement and quantification of specific features<br />
of clinical importance in each of these modalities.<br />
BMEN E4898y Biophotonics<br />
Lect: 3. 3 pts. Professor Hielscher.<br />
Prerequisite: BMEN E4894, PHYS C1403, or the<br />
instructor’s permission. This course provides a<br />
broad-based introduction into the field of biophotonics.<br />
Fundamental concepts of optical, thermal,<br />
and chemical aspects of the light-tissue interactions<br />
are presented. The application of these concepts<br />
for medical therapy and diagnostics is discussed.<br />
The course includes theoretical modeling<br />
of light-tissue interactions as well as optical medical<br />
instrument design and methods of clinical<br />
data interpretation.<br />
BMEN E6003x: Computational modeling of<br />
physiological systems<br />
Lect: 3. 3pts. Professor Morrison.<br />
Prerequisites: BMEN E4001-E4002 and APMA<br />
E4200 or the equivalent. Advanced modeling and<br />
quantitative analysis of selected molecular, cellular,<br />
or organ systems. Four systems are analyzed,<br />
with emphasis on biologic systems. Systems may<br />
include muscle contraction, respiratory physiology,<br />
nerve transmission, pharmacokinetics, circulatory<br />
control, auditory signal processing, cell signaling,<br />
molecular transport, excitable membranes, and/or<br />
statistical data analysis.<br />
79<br />
<strong>SEAS</strong> <strong>2009</strong>–<strong>2010</strong>