Advanced Techniques in Diagnostic Microbiology

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4. Advanced Antibody Detection 59 Andreotti, P.E., Ludwig, G.V., Peruski, A.H., Tuite, J.J., Morse, S.S., & Peruski Jr., L.F. (2003). Immunoassay of infectious agents. BioTechniques, 35, 850–859. Bellisario, R., Colinas, R.J., & Pass, K.A. (2001). Simultaneous measurement of antibodies to three HIV-1 antigens in newborn dried blood-spot specimens using a multiplexed microsphere-based immunoassay. Early Hum Dev, 64, 21–25. Berthold, F. (1990). Instrumentation for chemiluminescence immunoassays, In: Van Dyke, K., & Van Dyke, R., eds. Luminescence Immunoassay and Molecular Applications. CRC Press, Boca Raton, pp. 11–25. Biagini, R.E., Sammons, D.L., Smith, J.P., MacKenzie, B.A., Striley, C.A.F., Semenova, V., Steward-Clark, E., Stamey, K., Freeman, A.E., Quinn, C.P., & Snawder, J.E. (2004). Comparison of a multiplexed fluorescent covalent microsphere immunoassay and an enzyme-linked immunosorbent assay for measurement of human immunoglobulin G antibodies to anthrax toxins. Clin Diagn Lab Immunol, 11, 50–55. Biagini, R.E., Schlottmann, S.A., Sammons, D.L., Smith, J.P., Snawder, J.C., Striley, C.A., MacKenzie, B.A., & Weissman, D.N. (2003). Method for simultaneous measurement of antibodies to 23 pneumoncoccal capsular polysaccharides. Clin Diagn Lab Immunol, 10, 744–750. Blackburn, G.F., Shah, H.P., Kenten, J.H., Leland, J., Kamin, R.A., Link, J., Peterman, J., Powell, M.J., Shah, A., Talley, D.B., Tyagi, S.K., Wilkens, E., Wu, T., & Massey, R.J. (1991). Electrochemiluminescence detection for development of immunoassays and DNA probe assays for clinical diagnosis. Clin Chem, 37, 1534–1539. Campbell, A.K. ed. (1988). Detection and quantification of chemiluminescence. In: Chemiluminescence Principles and Applications in Biology and Medicine. Horwood VCH, Chichester, 68–126. Carson, R.T., & Vignali, D.A. (1999). Simultaneous quantitation of 15 cytokines using a multiplexed flow cytometric assay. J Immunol Methods, 227, 41–52. Davis, B. S., Chang, G-J.J., Cropp, B., Roehrig, J.T., Martin, D.A., Mitchell, C.J., Bowen, R., & Bunning, M.L. (2001). West Nile virus recombinant DNA vaccine protects mouse and horse from virus challenge and expresses in vitro a noninfectious recombinant antigen that can be used in enzyme-linked immunosorbent assays. J Virol, 75, 4040– 4047. de Jager, W., Velthuis, H., Prakken, B.J., Kuis, W., & Rijkers, G.T. (2003). Simultaneous detection of 15 human cytokines in a single sample of stimulated peripheral blood mononuclear cells. Clin Diagn Lab Immunol, 10, 133–139. Engvall, E., & Perlmann, P. (1971). Enzyme-linked immunosorbent assay (ELISA). Quantitative assay of immunoglobulin G. Immunochemistry, 8, 871–874. Engvall, E., & Perlmann, P. (1972). Enzyme-linked immunosorbent assay, ELISA: quantitation of specific antibodies by enzyme-labeled anti–immunoglobulin in antigen-coated tubes. J Immunol, 109, 129–135. Faucher, S., Martel, A., Sherring, A., Ding, T., Malloch, L., Kim, J.E., Bergeron, M., Sandstrom, P., & Mandy, F.F. (2004). Protein bead array for the detection of HIV-1 antibodies from fresh plasma and dried-blood-spot specimens. Clin Chem, 50, 1250– 1253. Fiore, M., Mitchell, J., Doan, T., Nelson, R., Winter, G., Grandome, C., Zeng, K., Haraden, R., Smith, J., & Harris, K. (1988). The Abbott IMx automated benchtop immunochemistry analyzer system. Clin Chem, 34, 1726–1732. Fulton, R.J., McDade, R.L., Smith, P.L., Kienker, L.J., & Kettman, J.R. (1997). Advanced multiplexed analysis with the FlowMetrix system. Clin Chem, 43, 1749–1756. Haukanes, B.L., & Kyam, C. (1993). Application of magnetic beads in bioassays. Bio/Technology, 11, 60–63.
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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
Page 90: Fungi Cryptococcus Agglutination, E
Page 94: Adenovirus, enteric types 40,41 EIA
Page 98: 3. Rapid Antigen Tests 37 Antigen t
Page 102: 3. Rapid Antigen Tests 39 retains a
Page 106: 3. Rapid Antigen Tests 41 Wilhelmi,
Page 110: 4. Advanced Antibody Detection 43 D
Page 114: TABLE 4.1. Types of antibody detect
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Page 122: 4. Advanced Antibody Detection 49 U
Page 126: 4. Advanced Antibody Detection 51 a
Page 130: 4. Advanced Antibody Detection 53 a
Page 134: 4. Advanced Antibody Detection 55 H
Page 138: 4. Advanced Antibody Detection 57 r
Page 144: 60 Y. F. Wang Hemmila, I., Dakubu,
Page 148: 62 Y. F. Wang (2002). Specific, sen
Page 152: 64 C. Qi, C. W. Stratton, and X. Zh
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6 Biochemical Profile-Based Microbi
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86 J. Aslanzadeh + beta hemolytic +
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88 J. Aslanzadeh Gram Negative Cocc
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90 J. Aslanzadeh Preliminary Identi
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92 J. Aslanzadeh tryptophane result
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94 J. Aslanzadeh β-naphthylamine p
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96 J. Aslanzadeh Reading the test b
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98 J. Aslanzadeh TABLE 6.1. Commonl
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100 J. Aslanzadeh Do not incubate t
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102 J. Aslanzadeh Using a sterile i
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104 J. Aslanzadeh Voges-Proskaure (
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106 J. Aslanzadeh The strip is exam
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108 J. Aslanzadeh ferrous sulfate i
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110 J. Aslanzadeh TABLE 6.2. Commer
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112 J. Aslanzadeh substrates. It is
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114 J. Aslanzadeh The reagents will
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116 J. Aslanzadeh Killian, M. (1974
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118 D. Dare Furthermore, the amount
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120 D. Dare be required. Currently,
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122 D. Dare TABLE 7.1. Comparison o
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124 D. Dare Search results Combined
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126 D. Dare (a) No. genera 4123 No.
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128 D. Dare that similarity of the
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130 D. Dare Dare, D., Sutton, H., K
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132 D. Dare McKenna, T., Lunt, M.,
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8 Probe-Based Microbial Detection a
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136 T. Hong Hybridization and Detec
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138 T. Hong Candida species can det
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140 T. Hong and 100%, respectively.
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142 T. Hong Wagner, M., Schmid, M.,
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144 F. Wu and P. Della-Latta migrat
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146 F. Wu and P. Della-Latta TABLE
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148 F. Wu and P. Della-Latta DNA d
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150 F. Wu and P. Della-Latta TABLE
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152 F. Wu and P. Della-Latta λ 1 2
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154 F. Wu and P. Della-Latta Summar
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156 F. Wu and P. Della-Latta pneumo
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10 In Vitro Nucleic Acid Amplificat
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160 H. Li and Y-W. Tang of these me
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162 H. Li and Y-W. Tang Currently,
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164 H. Li and Y-W. Tang La Rocco, M
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11 PCR and Its Variations MICHAEL L
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168 M. Loeffelholz and H. Deng to o
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170 M. Loeffelholz and H. Deng FIGU
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172 M. Loeffelholz and H. Deng be i
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174 M. Loeffelholz and H. Deng the
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176 M. Loeffelholz and H. Deng RT-P
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178 M. Loeffelholz and H. Deng Dete
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180 M. Loeffelholz and H. Deng buff
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182 M. Loeffelholz and H. Deng Grat
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12 Non-Polymerase Chain Reaction Me
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186 M.L. Pendrak and S.S. Yan TMA (
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188 M.L. Pendrak and S.S. Yan dsDNA
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190 M.L. Pendrak and S.S. Yan (van
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192 M.L. Pendrak and S.S. Yan ampli
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194 M.L. Pendrak and S.S. Yan FIGUR
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196 M.L. Pendrak and S.S. Yan RCA m
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202 M.L. Pendrak and S.S. Yan TABLE
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204 M.L. Pendrak and S.S. Yan of hu
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206 M.L. Pendrak and S.S. Yan Kwoh,
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208 M.L. Pendrak and S.S. Yan Smirn
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13 Recent Advances in Probe Amplifi
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212 D. Zhang et al. TABLE 13.1. Com
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214 D. Zhang et al. scanner after h
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216 D. Zhang et al. FIGURE 13.3. Sc
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218 D. Zhang et al. FIGURE 13.4. Sc
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220 D. Zhang et al. A. B. Invasive
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222 D. Zhang et al. FIGURE 13.6. Pr
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224 D. Zhang et al. The mecA probe
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226 D. Zhang et al. Landegren, U.,
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14 Signal Amplification Techniques:
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230 Y. F. Wang Virus (3)* (2) (4)*
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232 Y. F. Wang 1. Denaturation 2. H
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234 Y. F. Wang Application of the T
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236 Y. F. Wang specimen. A study (K
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238 Y. F. Wang amplification techno
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240 Y. F. Wang Cuzick, J., Szarewsk
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242 Y. F. Wang Qian, X., & Lloyd, R
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244 R. P. Podzorski, M. Loeffelholz
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16 Direct Nucleotide Sequencing for
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266 Tao Hong approximately 10 min (
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268 Tao Hong frequently caused prob
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270 Tao Hong for the use of the 16S
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272 Tao Hong of MRSA. The coagulase
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274 Tao Hong Gürtler, V., & Barrie
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17 Microarray-Based Microbial Ident
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278 T.J. Gentry and J. Zhou These a
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280 T.J. Gentry and J. Zhou the des
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282 T.J. Gentry and J. Zhou Communi
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284 T.J. Gentry and J. Zhou PCR-bas
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286 T.J. Gentry and J. Zhou Althoug
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288 T.J. Gentry and J. Zhou Korczak
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290 T.J. Gentry and J. Zhou Willse,
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292 X. Qin allow real-time monitori
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294 X. Qin which the observed fluor
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296 X. Qin that there would be no G
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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
Page 808:
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
Page 908:
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
Page 936:
458 S. R. Frye and M. Healy isolate
Page 940:
460 S. R. Frye and M. Healy molecul
Page 944:
462 S. R. Frye and M. Healy Boerlin
Page 948:
464 S. R. Frye and M. Healy Fey, P.
Page 952:
466 S. R. Frye and M. Healy Kwara,
Page 956:
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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