Advanced Techniques in Diagnostic Microbiology

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274 Tao Hong Gürtler, V., & Barrie, H.D. (1995). Typing of Staphylococcus aureus strains by PCRamplification of variable-length 16S-23S rDNA spacer regions: characterization of spacer sequences. Microbiology 141, 1255–1265. Gürtler, V., & Stanisich, V.A. (1996). New approaches to typing and identification of bacteria using 16S-23S rDNA spacer region. Microbiology, 142, 3–16. Hance, A.J., Grandchamp, B., Le’vy-Fre’bault, V., Lecossier, D., Rauzier, J., Bocart, D., & Gicquel, B. (1989). Detection and identification of mycobacteria by amplification of mycobacterial DNA. Mol Microbiol, 3, 843–849. Hamid, Mohamed E., Andreas Roth, Olfert Landt, Reiner M. Kroppenstedt, Goodfellow, M., & Mauch, H. (2002). Differentiation between Mycobacterium farcinogenes and Mycobacterium senegalense strains based on 16S-23S ribosomal DNA internal transcribed spacer sequences. J Clin Microbiol, 40, 707–711. Jordan J.A., Butchko, A.R., Durso, M.B. (2005). Use of pyrosequencing of 16S rRNA fragments to differentiate between bacteria responsible for neonatal sepsis. J Mol Diagn, 7, 105–110. Kapur, V., Li, L.L., Hamrick, M.R., Plikaytis, B.B., Shinnick, T.M., Telenti, A., Jacobs, W.R., Banerjee, A., Cole, S., Yuen, K.Y., Clarridge, J.E., Kreiswirth, B.N., & Musser, J.M. (1995). Rapid Mycobacterium species assignment and unambiguous identification of mutations associated with antimicrobial resistance in Mycobacterium tuberculosis by automated DNA sequencing. Arch Pathol Lab Med, 119, 131–138. Lindström, A., Odeberg, J., & Albert, J. (2004). Pyrosequencing for detection of lamivudineresistant hepatitis B virus. J Clin Microbiol, 42, 4788–4795. Magnus U., Olce’n, P., Jonasson, J., & Fredlund, H. (2004). Molecular typing of Neisseria gonorrhoeae isolates by pyrosequencing of highly polymorphic segments of the porB gene. J Clin Microbiol, 42, 2926–2934. Maxam A.M., & Gilbert, W. (1977). A new method for sequencing DNA Proc Natl Acad Sci USA, 74, 560–564. McNabb A., Eisler, D., Adie, K., Amos, M., Rodrigues, M., Stephens, G., Black, W.A., & Isaac-Renton, J. (2004). Assessment of partial sequencing of the 65-kilodalton heat shock protein gene (hsp65) for routine identification of Mycobacterium species isolated from clinical sources J Clin Microbiol, 42, 3000–3011. O’meara, D., Wilbe, K., Leitner, T., Hejdeman, B., Albert, J., & Lundeberg, J. (2001). Monitoring resistance to human immunodeficiency virus type 1 protease inhibitors by pyrosequencing J Clin Microbiol, 39, 464–473. Plikaytis, B.B., Plikaytis, B.D., Yakrus, A., Butler, W.R., Woodley, C.L., Silcox, V.A., & Shinnick, T.M. (1992). Differentiation of slowly growing Mycobacterium species, including Mycobacterium tuberculosis, by gene amplification and restriction fragment length polymorphism analysis. J Clin Microbiol, 30, 1815–1822. Rogall, T., Wolters, J., Floher, T., & Böttger, E.C. (1990). Towards a phylogeny and definition of the species at the molecular level within the genus Mycobacterium. Int J Syst Bacteriol, 40, 323–330. Roth, A., Fischer, M., Hamid, H.E., Ludwig, W., Michalke, S., & Mauch, H. (1998). Differentiation of phylogenetically related slowly growing mycobacteria based on 16S- 23S rRNA gene internal transcribed spacer sequences. J Clin Microbiol, 36, 139– 147. Ruano, G., & Kidd, K.K. (1991). Coupled amplification and sequencing of genomic DNA Proc Natl Acad Sci USA, 88, 2815–2819. Sambrook, J., Fritsch, E.F., & Maniatis, T. (1989). Molecular Cloning: A laboratory Manual, 2nd ed. Cold Spring Harb. Laboratory Press, Cold Spring Harbor, New York.
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Advanced Techniques in Diagnostic M
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Yi-Wei Tang Molecular Infectious Di
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vi Contributors Wonder Drake Depart
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viii Contributors Jacques Schrenzel
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Preface Clinical microbiologists ar
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Contents Part I Techniques 1 Automa
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Contents xv 22 Review of Molecular
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1 Automated Blood Cultures XIANG Y.
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Interpretation of Significance 1. A
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1. Automated Blood Cultures 7 conta
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1. Automated Blood Cultures 9 Crump
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2 Urea Breath Tests for Detection o
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2. Urea Breath Tests 13 and point o
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2. Urea Breath Tests 15 Other detec
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TABLE 2.1. Comparison of 13 C-urea
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2. Urea Breath Tests 19 Bazzoli, F.
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2. Urea Breath Tests 21 Logan, R. (
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3 Rapid Antigen Tests SHELDON CAMPB
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3. Rapid Antigen Tests 25 antigen i
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3. Rapid Antigen Tests 27 either on
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3. Rapid Antigen Tests 29 and moves
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3. Rapid Antigen Tests 31 Applicati
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Fungi Cryptococcus Agglutination, E
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Adenovirus, enteric types 40,41 EIA
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3. Rapid Antigen Tests 37 Antigen t
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3. Rapid Antigen Tests 39 retains a
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3. Rapid Antigen Tests 41 Wilhelmi,
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4. Advanced Antibody Detection 43 D
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TABLE 4.1. Types of antibody detect
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4. Advanced Antibody Detection 47 c
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4. Advanced Antibody Detection 49 U
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4. Advanced Antibody Detection 51 a
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4. Advanced Antibody Detection 53 a
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4. Advanced Antibody Detection 55 H
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4. Advanced Antibody Detection 57 r
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4. Advanced Antibody Detection 59 A
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4. Advanced Antibody Detection 61 M
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5 Phenotypic Testing of Bacterial A
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5. Antimicrobial Susceptibility Tes
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Susceptibility Tests for Fastidious
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References 5. Antimicrobial Suscept
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6. Biochemical Profile-Based Microb
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7 Rapid Bacterial Characterization
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7. MALDI-TOF MS 119 photons followe
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7. MALDI-TOF MS 121 for analysis by
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7. MALDI-TOF MS 123 Sample wells Ca
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7. MALDI-TOF MS 125 also given. Thi
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7. MALDI-TOF MS 127 characteristics
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References 7. MALDI-TOF MS 129 Ande
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7. MALDI-TOF MS 131 Hindre, T., Did
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7. MALDI-TOF MS 133 von Wintzingero
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8. Probe-Based Microbial Detection
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9 Pulsed-Field Gel Electrophoresis
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9. Pulsed-Field Gel Electrophoresis
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PFGE Performance Characteristics 9.
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TABLE 10.1. Nucleic acid amplificat
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10. In Vitro Nucleic Acid Amplifica
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11. PCR and Its Variations 167 Prin
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11. PCR and Its Variations 169 Exte
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11. PCR and Its Variations 171 targ
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11. PCR and Its Variations 173 bind
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11. PCR and Its Variations 175 Reve
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11. PCR and Its Variations 177 ampl
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11. PCR and Its Variations 179 pres
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11. PCR and Its Variations 181 Soft
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11. PCR and Its Variations 183 Saik
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12. Non-PCR Amplification 185 1989;
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12. Non-PCR Amplification 187 FIGUR
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12. Non-PCR Amplification 189 This
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12. Non-PCR Amplification 191 FIGUR
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12. Non-PCR Amplification 193 and c
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12. Non-PCR Amplification 195 used
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12. Non-PCR Amplification 197 do no
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Application of the SDA Technique Re
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12. Non-PCR Amplification 201 Ancho
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12. Non-PCR Amplification 203 Baner
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12. Non-PCR Amplification 205 Guilf
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12. Non-PCR Amplification 207 Nilss
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12. Non-PCR Amplification 209 Wang,
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13. Recent Advances in Probe Amplif
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14. Signal Amplification Techniques
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TABLE 14.1. Comparison of bDNA and
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References 14. Signal Amplification
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15 Detection and Characterization o
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15. Agarose Gel Electrophoresis, So
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15. Agarose Gel Electrophoresis, So
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Page 554: 16. Direct Nucleotide Sequencing 26
Page 576: 17 Microarray-Based Microbial Ident
Page 580: 278 T.J. Gentry and J. Zhou These a
Page 584: 280 T.J. Gentry and J. Zhou the des
Page 588: 282 T.J. Gentry and J. Zhou Communi
Page 592: 284 T.J. Gentry and J. Zhou PCR-bas
Page 596: 286 T.J. Gentry and J. Zhou Althoug
Page 600: 288 T.J. Gentry and J. Zhou Korczak
Page 604: 290 T.J. Gentry and J. Zhou Willse,
Page 608: 292 X. Qin allow real-time monitori
Page 612: 294 X. Qin which the observed fluor
Page 616: 296 X. Qin that there would be no G
Page 620: 298 X. Qin 2005). Furthermore, the
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300 X. Qin Cattoli, G., Drago, A.,
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302 X. Qin Kostrikis, L.G., Touloum
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304 X. Qin Ririe, K.M., Rasmussen,
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19 Amplification Product Inactivati
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308 S. Sefers and Y-W. Tang Most de
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310 S. Sefers and Y-W. Tang UNG Pro
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312 S. Sefers and Y-W. Tang 4' Psor
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314 S. Sefers and Y-W. Tang Isopsor
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316 S. Sefers and Y-W. Tang used is
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318 S. Sefers and Y-W. Tang Conclus
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Part II Applications
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324 X.Y. Han TABLE 20.1. The number
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326 X.Y. Han Homology Search and Re
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328 X.Y. Han TABLE 20.2. Examples o
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330 X.Y. Han Conclusion In summary,
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332 X.Y. Han Shimizu, T., Ohtani, K
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TABLE 21.1. Licensed / Approved Cli
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TABLE 21.1. (Continued) Tradename(s
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TABLE 21.1. (Continued) Tradename(s
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340 Y. Hu and I. Hirshfield gel ele
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342 Y. Hu and I. Hirshfield Since 1
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344 Y. Hu and I. Hirshfield they ar
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346 Y. Hu and I. Hirshfield Antibod
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348 Y. Hu and I. Hirshfield all ove
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350 Y. Hu and I. Hirshfield chances
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352 Y. Hu and I. Hirshfield Tang, Y
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354 A. C. T. Lo and K. M. Kam in tu
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356 A. C. T. Lo and K. M. Kam is no
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358 A. C. T. Lo and K. M. Kam stabl
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360 A. C. T. Lo and K. M. Kam Stran
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362 A. C. T. Lo and K. M. Kam organ
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364 A. C. T. Lo and K. M. Kam probe
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366 A. C. T. Lo and K. M. Kam major
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368 A. C. T. Lo and K. M. Kam Molec
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370 A. C. T. Lo and K. M. Kam a sec
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372 A. C. T. Lo and K. M. Kam cervi
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374 A. C. T. Lo and K. M. Kam E6 an
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376 A. C. T. Lo and K. M. Kam M. (2
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378 A. C. T. Lo and K. M. Kam Hippe
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380 A. C. T. Lo and K. M. Kam Larse
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382 A. C. T. Lo and K. M. Kam Nobbe
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384 A. C. T. Lo and K. M. Kam chlam
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386 A. C. T. Lo and K. M. Kam ureal
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388 A. Kilic and W. Drake Lipids wi
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390 A. Kilic and W. Drake America,
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392 A. Kilic and W. Drake MTB from
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394 A. Kilic and W. Drake with anti
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396 A. Kilic and W. Drake Molecular
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398 A. Kilic and W. Drake and monit
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400 A. Kilic and W. Drake system; t
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402 A. Kilic and W. Drake transillu
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404 A. Kilic and W. Drake Real-Time
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406 A. Kilic and W. Drake Caws, M.,
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408 A. Kilic and W. Drake Marttila,
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410 A. Kilic and W. Drake Torres, M
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412 P. Francois and J. Schrenzel an
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414 P. Francois and J. Schrenzel th
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416 P. Francois and J. Schrenzel A
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418 P. Francois and J. Schrenzel St
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420 P. Francois and J. Schrenzel Ac
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422 P. Francois and J. Schrenzel or
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424 P. Francois and J. Schrenzel Lo
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426 P. Francois and J. Schrenzel Va
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428 D. Ernst et al. several microme
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430 D. Ernst et al. reanalysis to d
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432 D. Ernst et al. Neisseria menin
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434 D. Ernst et al. A. B. SEB-beads
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436 D. Ernst et al. IL-6, IL-8, and
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pg/ml 120 100 80 60 40 20 0 120 100
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440 D. Ernst et al. Although interf
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442 D. Ernst et al. Lal, G., Balmer
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26 Molecular Strain Typing Using Re
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446 S. R. Frye and M. Healy FIGURE
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448 S. R. Frye and M. Healy Automat
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450 S. R. Frye and M. Healy TABLE 2
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452 S. R. Frye and M. Healy Noncomm
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454 S. R. Frye and M. Healy 2001).
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456 S. R. Frye and M. Healy (Stempe
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458 S. R. Frye and M. Healy isolate
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460 S. R. Frye and M. Healy molecul
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462 S. R. Frye and M. Healy Boerlin
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464 S. R. Frye and M. Healy Fey, P.
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466 S. R. Frye and M. Healy Kwara,
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468 S. R. Frye and M. Healy Pfaller
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470 S. R. Frye and M. Healy Tang, Y
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27 Molecular Differential Diagnoses
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474 J. Han The technology advanceme
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476 J. Han Targets Optimal Conditio
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478 J. Han TABLE 27.1. Comparison o
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480 J. Han TABLE 27.3. Comparison o
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482 J. Han suspension hybridization
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484 J. Han fluorescent dye is remov
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486 J. Han TABLE 27.5. List of path
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TABLE 27.8. Detection results of th
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490 J. Han common in HAI. In additi
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492 J. Han TABLE 27.12. Detection r
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494 J. Han TABLE 27.14. List of pat
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496 J. Han TABLE 27.18. Detectable
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TABLE 27.20. List of gene targets i
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500 J. Han Benefits and Impact: Del
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502 J. Han significantly increasing
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504 J. Han Hindiyeh, M., Hillyard D
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506 E. M. Marlowe and D. M. Wolk Al
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TABLE 28.1. Automated specimen proc
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510 E. M. Marlowe and D. M. Wolk Au
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512 E. M. Marlowe and D. M. Wolk La
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514 E. M. Marlowe and D. M. Wolk me
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516 E. M. Marlowe and D. M. Wolk mo
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518 E. M. Marlowe and D. M. Wolk Mo
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520 E. M. Marlowe and D. M. Wolk Ha
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522 E. M. Marlowe and D. M. Wolk Sa
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Index A acetate utilization, 100 Ac
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Index 527 rapid antigen tests, 27-2
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Index 529 flow cytometric immunoass
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Index 531 Human T-Lymphotropic Viru
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Index 533 MLEE. See multilocus enzy
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Index 535 PNA. See peptide-nucleic
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Index 537 Roseomonas, 328-329 rotav
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Index 539 T TaqMan probes, 293-296
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