Advanced Techniques in Diagnostic Microbiology

More documents

Recommendations

Info

204 M.L. Pendrak and S.S. Yan of human immunodeficiency virus type 1 isolates from groups M,N, and O. J Clin Microbiol, 39, 1378–84. Dean, F.B., Nelson, J.R., Giesler, T.L., & Lasken, R.S. (2001). Rapid amplification of plasmid and phage DNA using Phi 29 DNA polymerase and multiply-primed rolling circle amplification. Genome Res, 11, 1095–9. Dean, F.B., Hosono, S., Fang, L., Wu, X., & Faruqi, A.F., et al. (2002). Comprehensive human genome amplification using multiple displacement amplification. Proc Natl Acad SciUSA, 99, 5261–6. Deiman, B., van Aarle, P., & Sillekens, P. (2002). Characteristics and applications of nucleic acid sequence-based amplification (NASBA). Mol Biotechnol, 20, 163–79. del Solar, G., Giraldo, R., Ruiz-Echevarria, M.J., Espinosa, M., & Diaz-Orejas, R. (1998). Replication and control of circular bacterial plasmids. Microbiol Mol Biol Rev, 62, 434– 64. Detter, J.C., Jett, J.M., Lucas, S.M., Dalin, E., & Arellano, A.R., et al. (2002). Isothermal strand-displacement amplification applications for high-throughput genomics. Genomics, 80, 691–8. Diener, T.O. (1991). Subviral pathogens of plants: viroids and viroidlike satellite RNAs. FASEB J, 5, 2808–13. Doermann, A.H. (1973). T4 and the rolling circle model of replication. Annu Rev Genet, 7, 325–41. Dunn, J.J., & Studier, F.W. (1983). Complete nucleotide sequence of bacteriophage T7 DNA and the locations of T7 genetic elements. J Mol Biol, 166, 477–535. Fahy, E., Kwoh, D.Y., & Gingeras, T.R. (1991). Self-sustained sequence replication (3SR): an isothermal transcription-based amplification system alternative to PCR. PCR Methods Appl, 1, 25–33. Fahy, E., Biery, M., Goulden, M., Ghosh, S.S., & Gingeras, T.R. (1994). Issues of variability, carryover contamination, and detection in 3SR-based assays. PCR Methods Appl, 3, S83– 94. Faruqi, A.F., Hosono, S., Driscoll, M.D., Dean, F.B., & Alsmadi, O., et al. (2001). Highthroughput genotyping of single nucleotide polymorphisms with rolling circle amplification. BMC Genomics, 2, 4. Fire, A., & Xu, S.Q. (1995). Rolling replication of short DNA circles. Proc Natl Acad Sci USA, 92, 4641–5. Gaydos, C.A., Theodore, M., Dalesio, N., Wood, B.J., & Quinn, T.C. (2004). Comparison of three nucleic acid amplification tests for detection of Chlamydia trachomatis in urine specimens. J Clin Microbiol, 42, 3041–5. Gebinoga, M. (1996). Comparison of self-sustained sequence-replication reaction systems. Eur J Biochem, 235, 256–61. Goossens, V.J., Christiaans, M.H., Blok, M.J., Terporten, P.H., & Sillekens, P., et al. (2004). Onset and duration of cytomegalovirus immediate early 1 mRNA expression in the blood of renal transplant recipients. J Med Virol, 72, 94–101. Greijer, A.E., Adriaanse, H.M., Kahl, M., Tacken, N.M., & Oldenburg, N., et al. (2001). Quantitative competitive NASBA for measuring mRNA expression levels of the immediate early 1, late pp67, and immune evasion genes US3, US6 and US11 in cells infected with human cytomegalovirus. J Virol Methods, 96, 133–47. Guatelli, J.C., Whitfield, K.M., Kwoh, D.Y., Barringer, K.J., Richman, D.D., & Gingeras, T.R. (1990). Isothermal, in vitro amplification of nucleic acids by a multienzyme reaction modeled after retroviral replication. Proc Natl Acad SciUSA, 87, 1874– 8.
Page 2:
Advanced Techniques in Diagnostic M
Page 6:
Yi-Wei Tang Molecular Infectious Di
Page 10:
vi Contributors Wonder Drake Depart
Page 14:
viii Contributors Jacques Schrenzel
Page 18:
Preface Clinical microbiologists ar
Page 22:
Contents Part I Techniques 1 Automa
Page 26:
Contents xv 22 Review of Molecular
Page 30:
1 Automated Blood Cultures XIANG Y.
Page 34:
Interpretation of Significance 1. A
Page 38:
1. Automated Blood Cultures 7 conta
Page 42:
1. Automated Blood Cultures 9 Crump
Page 46:
2 Urea Breath Tests for Detection o
Page 50:
2. Urea Breath Tests 13 and point o
Page 54:
2. Urea Breath Tests 15 Other detec
Page 58:
TABLE 2.1. Comparison of 13 C-urea
Page 62:
2. Urea Breath Tests 19 Bazzoli, F.
Page 66:
2. Urea Breath Tests 21 Logan, R. (
Page 70:
3 Rapid Antigen Tests SHELDON CAMPB
Page 74:
3. Rapid Antigen Tests 25 antigen i
Page 78:
3. Rapid Antigen Tests 27 either on
Page 82:
3. Rapid Antigen Tests 29 and moves
Page 86:
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
Page 118:
4. Advanced Antibody Detection 47 c
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 142:
4. Advanced Antibody Detection 59 A
Page 146:
4. Advanced Antibody Detection 61 M
Page 150:
5 Phenotypic Testing of Bacterial A
Page 154:
5. Antimicrobial Susceptibility Tes
Page 158:
Page 162:
Page 166:
Susceptibility Tests for Fastidious
Page 170:
Page 174:
Page 178:
Page 182:
References 5. Antimicrobial Suscept
Page 186:
Page 190:
Page 194:
6. Biochemical Profile-Based Microb
Page 198:
Page 202:
Page 206:
Page 210:
Page 214:
Page 218:
Page 222:
Page 226:
Page 230:
Page 234:
Page 238:
Page 242:
Page 246:
Page 250:
Page 254:
Page 258:
7 Rapid Bacterial Characterization
Page 262:
7. MALDI-TOF MS 119 photons followe
Page 266:
7. MALDI-TOF MS 121 for analysis by
Page 270:
7. MALDI-TOF MS 123 Sample wells Ca
Page 274:
7. MALDI-TOF MS 125 also given. Thi
Page 278:
7. MALDI-TOF MS 127 characteristics
Page 282:
References 7. MALDI-TOF MS 129 Ande
Page 286:
7. MALDI-TOF MS 131 Hindre, T., Did
Page 290:
7. MALDI-TOF MS 133 von Wintzingero
Page 294:
8. Probe-Based Microbial Detection
Page 298:
Page 302:
Page 306:
Page 310:
9 Pulsed-Field Gel Electrophoresis
Page 314:
9. Pulsed-Field Gel Electrophoresis
Page 318:
Page 322:
PFGE Performance Characteristics 9.
Page 326:
Page 330:
Page 334:
Page 338:
Page 342:
TABLE 10.1. Nucleic acid amplificat
Page 346:
10. In Vitro Nucleic Acid Amplifica
Page 350:
Page 354:
Page 358:
11. PCR and Its Variations 167 Prin
Page 362:
11. PCR and Its Variations 169 Exte
Page 366:
11. PCR and Its Variations 171 targ
Page 370:
11. PCR and Its Variations 173 bind
Page 374:
11. PCR and Its Variations 175 Reve
Page 378:
11. PCR and Its Variations 177 ampl
Page 382: 11. PCR and Its Variations 179 pres
Page 386: 11. PCR and Its Variations 181 Soft
Page 390: 11. PCR and Its Variations 183 Saik
Page 394: 12. Non-PCR Amplification 185 1989;
Page 398: 12. Non-PCR Amplification 187 FIGUR
Page 402: 12. Non-PCR Amplification 189 This
Page 406: 12. Non-PCR Amplification 191 FIGUR
Page 410: 12. Non-PCR Amplification 193 and c
Page 414: 12. Non-PCR Amplification 195 used
Page 418: 12. Non-PCR Amplification 197 do no
Page 422: Application of the SDA Technique Re
Page 426: 12. Non-PCR Amplification 201 Ancho
Page 430: 12. Non-PCR Amplification 203 Baner
Page 436: 206 M.L. Pendrak and S.S. Yan Kwoh,
Page 440: 208 M.L. Pendrak and S.S. Yan Smirn
Page 444: 13 Recent Advances in Probe Amplifi
Page 448: 212 D. Zhang et al. TABLE 13.1. Com
Page 452: 214 D. Zhang et al. scanner after h
Page 456: 216 D. Zhang et al. FIGURE 13.3. Sc
Page 460: 218 D. Zhang et al. FIGURE 13.4. Sc
Page 464: 220 D. Zhang et al. A. B. Invasive
Page 468: 222 D. Zhang et al. FIGURE 13.6. Pr
Page 472: 224 D. Zhang et al. The mecA probe
Page 476: 226 D. Zhang et al. Landegren, U.,
Page 480: 14 Signal Amplification Techniques:
Page 484:
230 Y. F. Wang Virus (3)* (2) (4)*
Page 488:
232 Y. F. Wang 1. Denaturation 2. H
Page 492:
234 Y. F. Wang Application of the T
Page 496:
236 Y. F. Wang specimen. A study (K
Page 500:
238 Y. F. Wang amplification techno
Page 504:
240 Y. F. Wang Cuzick, J., Szarewsk
Page 508:
242 Y. F. Wang Qian, X., & Lloyd, R
Page 512:
244 R. P. Podzorski, M. Loeffelholz
Page 516:
Page 520:
Page 524:
Page 528:
Page 532:
Page 536:
Page 540:
Page 544:
Page 548:
Page 552:
16 Direct Nucleotide Sequencing for
Page 556:
266 Tao Hong approximately 10 min (
Page 560:
268 Tao Hong frequently caused prob
Page 564:
270 Tao Hong for the use of the 16S
Page 568:
272 Tao Hong of MRSA. The coagulase
Page 572:
274 Tao Hong Gürtler, V., & Barrie
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
Page 624:
300 X. Qin Cattoli, G., Drago, A.,
Page 628:
302 X. Qin Kostrikis, L.G., Touloum
Page 632:
304 X. Qin Ririe, K.M., Rasmussen,
Page 636:
19 Amplification Product Inactivati
Page 640:
308 S. Sefers and Y-W. Tang Most de
Page 644:
310 S. Sefers and Y-W. Tang UNG Pro
Page 648:
312 S. Sefers and Y-W. Tang 4' Psor
Page 652:
314 S. Sefers and Y-W. Tang Isopsor
Page 656:
316 S. Sefers and Y-W. Tang used is
Page 660:
318 S. Sefers and Y-W. Tang Conclus
Page 664:
Part II Applications
Page 668:
324 X.Y. Han TABLE 20.1. The number
Page 672:
326 X.Y. Han Homology Search and Re
Page 676:
328 X.Y. Han TABLE 20.2. Examples o
Page 680:
330 X.Y. Han Conclusion In summary,
Page 684:
332 X.Y. Han Shimizu, T., Ohtani, K
Page 688:
TABLE 21.1. Licensed / Approved Cli
Page 692:
TABLE 21.1. (Continued) Tradename(s
Page 696:
TABLE 21.1. (Continued) Tradename(s
Page 700:
340 Y. Hu and I. Hirshfield gel ele
Page 704:
342 Y. Hu and I. Hirshfield Since 1
Page 708:
344 Y. Hu and I. Hirshfield they ar
Page 712:
346 Y. Hu and I. Hirshfield Antibod
Page 716:
348 Y. Hu and I. Hirshfield all ove
Page 720:
350 Y. Hu and I. Hirshfield chances
Page 724:
352 Y. Hu and I. Hirshfield Tang, Y
Page 728:
354 A. C. T. Lo and K. M. Kam in tu
Page 732:
356 A. C. T. Lo and K. M. Kam is no
Page 736:
358 A. C. T. Lo and K. M. Kam stabl
Page 740:
360 A. C. T. Lo and K. M. Kam Stran
Page 744:
362 A. C. T. Lo and K. M. Kam organ
Page 748:
364 A. C. T. Lo and K. M. Kam probe
Page 752:
366 A. C. T. Lo and K. M. Kam major
Page 756:
368 A. C. T. Lo and K. M. Kam Molec
Page 760:
370 A. C. T. Lo and K. M. Kam a sec
Page 764:
372 A. C. T. Lo and K. M. Kam cervi
Page 768:
374 A. C. T. Lo and K. M. Kam E6 an
Page 772:
376 A. C. T. Lo and K. M. Kam M. (2
Page 776:
378 A. C. T. Lo and K. M. Kam Hippe
Page 780:
380 A. C. T. Lo and K. M. Kam Larse
Page 784:
382 A. C. T. Lo and K. M. Kam Nobbe
Page 788:
384 A. C. T. Lo and K. M. Kam chlam
Page 792:
386 A. C. T. Lo and K. M. Kam ureal
Page 796:
388 A. Kilic and W. Drake Lipids wi
Page 800:
390 A. Kilic and W. Drake America,
Page 804:
392 A. Kilic and W. Drake MTB from
Page 808:
394 A. Kilic and W. Drake with anti
Page 812:
396 A. Kilic and W. Drake Molecular
Page 816:
398 A. Kilic and W. Drake and monit
Page 820:
400 A. Kilic and W. Drake system; t
Page 824:
402 A. Kilic and W. Drake transillu
Page 828:
404 A. Kilic and W. Drake Real-Time
Page 832:
406 A. Kilic and W. Drake Caws, M.,
Page 836:
408 A. Kilic and W. Drake Marttila,
Page 840:
410 A. Kilic and W. Drake Torres, M
Page 844:
412 P. Francois and J. Schrenzel an
Page 848:
414 P. Francois and J. Schrenzel th
Page 852:
416 P. Francois and J. Schrenzel A
Page 856:
418 P. Francois and J. Schrenzel St
Page 860:
420 P. Francois and J. Schrenzel Ac
Page 864:
422 P. Francois and J. Schrenzel or
Page 868:
424 P. Francois and J. Schrenzel Lo
Page 872:
426 P. Francois and J. Schrenzel Va
Page 876:
428 D. Ernst et al. several microme
Page 880:
430 D. Ernst et al. reanalysis to d
Page 884:
432 D. Ernst et al. Neisseria menin
Page 888:
434 D. Ernst et al. A. B. SEB-beads
Page 892:
436 D. Ernst et al. IL-6, IL-8, and
Page 896:
pg/ml 120 100 80 60 40 20 0 120 100
Page 900:
440 D. Ernst et al. Although interf
Page 904:
442 D. Ernst et al. Lal, G., Balmer
Page 908:
26 Molecular Strain Typing Using Re
Page 912:
446 S. R. Frye and M. Healy FIGURE
Page 916:
448 S. R. Frye and M. Healy Automat
Page 920:
450 S. R. Frye and M. Healy TABLE 2
Page 924:
452 S. R. Frye and M. Healy Noncomm
Page 928:
454 S. R. Frye and M. Healy 2001).
Page 932:
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
Page 960:
470 S. R. Frye and M. Healy Tang, Y
Page 964:
27 Molecular Differential Diagnoses
Page 968:
474 J. Han The technology advanceme
Page 972:
476 J. Han Targets Optimal Conditio
Page 976:
478 J. Han TABLE 27.1. Comparison o
Page 980:
480 J. Han TABLE 27.3. Comparison o
Page 984:
482 J. Han suspension hybridization
Page 988:
484 J. Han fluorescent dye is remov
Page 992:
486 J. Han TABLE 27.5. List of path
Page 996:
TABLE 27.8. Detection results of th
Page 1000:
490 J. Han common in HAI. In additi
Page 1004:
492 J. Han TABLE 27.12. Detection r
Page 1008:
494 J. Han TABLE 27.14. List of pat
Page 1012:
496 J. Han TABLE 27.18. Detectable
Page 1016:
TABLE 27.20. List of gene targets i
Page 1020:
500 J. Han Benefits and Impact: Del
Page 1024:
502 J. Han significantly increasing
Page 1028:
504 J. Han Hindiyeh, M., Hillyard D
Page 1032:
506 E. M. Marlowe and D. M. Wolk Al
Page 1036:
TABLE 28.1. Automated specimen proc
Page 1040:
510 E. M. Marlowe and D. M. Wolk Au
Page 1044:
512 E. M. Marlowe and D. M. Wolk La
Page 1048:
514 E. M. Marlowe and D. M. Wolk me
Page 1052:
516 E. M. Marlowe and D. M. Wolk mo
Page 1056:
518 E. M. Marlowe and D. M. Wolk Mo
Page 1060:
520 E. M. Marlowe and D. M. Wolk Ha
Page 1064:
522 E. M. Marlowe and D. M. Wolk Sa
Page 1068:
Index A acetate utilization, 100 Ac
Page 1072:
Index 527 rapid antigen tests, 27-2
Page 1076:
Index 529 flow cytometric immunoass
Page 1080:
Index 531 Human T-Lymphotropic Viru
Page 1084:
Index 533 MLEE. See multilocus enzy
Page 1088:
Index 535 PNA. See peptide-nucleic
Page 1092:
Index 537 Roseomonas, 328-329 rotav
Page 1096:
Index 539 T TaqMan probes, 293-296
show all

Advanced Techniques in Diagnostic Microbiology

You also want an ePaper? Increase the reach of your titles

Delete template?

Save as template?