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Journal of Clinical Microbiology, October 1998, p. 3020-3027, Vol. 36, No. 10
Department of Human Genetics, Roche Molecular
Systems, Inc., Alameda, California 945011
and
Department of Molecular Genetics and Microbiology,
University of New Mexico School of Medicine, Albuquerque, New
Mexico 871312
Received 5 March 1998/Returned for modification 6 May 1998/Accepted 12 June 1998
Amplification of human papillomavirus (HPV) DNA by L1 consensus
primer systems (e.g., MY09/11 or GP5+/6+) can
detect as few as 10 to 100 molecules of HPV targets from a genital
sample. However, genotype determination by dot blot hybridization is
laborious and requires at least 27 separate hybridizations for
substantive HPV-type discrimination. A reverse blot method was
developed which employs a biotin-labeled PCR product hybridized to an
array of immobilized oligonucleotide probes. By the reverse blot strip
analysis, genotype discrimination of multiple HPV types can be
accomplished in a single hybridization and wash cycle. Twenty-seven HPV
probe mixes, two control probe concentrations, and a single reference
line were immobilized to 75- by 6-mm nylon strips. Each individual
probe line contained a mixture of two bovine serum albumin-conjugated
oligonucleotide probes specific to a unique HPV genotype. The genotype
spectrum discriminated on this strip includes the high-risk, or
cancer-associated, HPV genotypes 16, 18, 26, 31, 33, 35, 39, 45, 51, 52, 55, 56, 58, 59, 68 (ME180), MM4 (W13B), MM7 (P291), and MM9 (P238A)
and the low-risk, or non-cancer-associated, genotypes 6, 11, 40, 42, 53, 54, 57, 66, and MM8 (P155). In addition, two concentrations of Epidemiologic evidence identifying
human papillomavirus (HPV) as the sexually transmitted, primary cause
of cervical cancer is strong (12). It is clear from several
large case-control and cohort studies that HPV infection is the main
risk factor for the development of cervical intraepithelial neoplasia
and that risk is significantly increased by persistent infection with high-risk, or cancer-associated, HPV genotypes (2, 3, 14, 15,
23). PCR technology, particularly with consensus, or general, primer systems such as MY09/11 (1) and
GP5+/6+ (13), has been instrumental
to these studies by elaborating the natural history of HPV infections.
The recognition of HPV infection as a factor that is necessary, but not
sufficient, for the development of cervical cancer has resulted in the
initiation of several longitudinal studies and randomized clinical
trials designed to examine the predictive value of HPV DNA testing
(5, 6, 12, 17, 18, 24). Preliminary findings from these studies support the potential utility of HPV testing for the effective triage of Pap smears of atypical squamous cells of undetermined significance and atypical glandular cells of undetermined significance and suggest a potential role in primary screening of populations in
which Pap smears have not been sufficiently effective. A rapid PCR-based test for HPV DNA is also important to accurately investigate the natural history of HPV infections. Furthermore, because of the high
sensitivity and type specificity afforded only by amplified DNA
detection methods, specific PCR-based HPV DNA typing may have a unique
utility in the clinical management of cervical lesions.
We report a method that uses a sensitive and broad-spectrum
amplification system (1), followed by a single hybridization with a reverse line blot detection method for complete HPV genotype discrimination (see Fig. 1). This method, like other PCR-based assays,
avoids false negatives below the limit of detection of nonamplified
methods and can readily detect a broad spectrum of HPV genotypes.
Furthermore, HPV type-specific disease associations can be precisely
defined, since genotypes are individually discriminated.
Sample acquisition and preparation.
Cervical specimens were
collected in 1.0 ml of specimen transport medium (Digene Diagnostics,
Silver Spring, Md.) as part of an ongoing natural history study of HPV
infection conducted at the University of New Mexico Health Sciences
Center. The samples were processed by adding 30 µl of digestion
solution to achieve a final concentration of 200 µg of proteinase K
per ml and 0.1% Laureth-12. Digestion was conducted at 56°C for
1 h. A 300-µl aliquot of the digested material was added to 1.0 ml of absolute ethanol containing ammonium acetate and precipitated
overnight at PCR and dot blot-based HPV-testing methods.
Prior to
amplification, the crude digests were allowed to reach room temperature
and centrifuged briefly. Six microliters of each specimen was amplified
with the MY09-MY11-HMB01 L1 consensus primer system (1) and
AmpliTaq polymerase (Perkin-Elmer, Foster City, Calif.). To
determine specimen adequacy, the GH20/PC04 human
0095-1137/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Genotyping of 27 Human Papillomavirus Types by
Using L1 Consensus PCR Products by a Single-Hybridization, Reverse
Line Blot Detection Method
ABSTRACT
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Abstract
Introduction
Materials & Methods
Results
Discussion
References
-globin probes allowed for assessment of individual specimen adequacy following amplification. We have evaluated the performance of
the strip method relative to that of a previously reported dot blot
format (H. M. Bauer et al., p. 132-152, in C. S. Herrington and J. O. D. McGee (ed.), Diagnostic Molecular
Pathology: a Practical Approach, (1992), by testing 328 cervical
swab samples collected in Digene specimen transport medium (Digene
Diagnostics, Silver Spring, Md.). We show excellent agreement between
the two detection formats, with 92% concordance for HPV positivity
(kappa = 0.78, P < 0.001). Nearly all of the
discrepant HPV-positive samples resulted from weak signals and can be
attributed to sampling error from specimens with low concentrations
(<1 copy/µl) of HPV DNA. The primary advantage of the strip-based
detection system is the ability to rapidly genotype HPVs present in
genital samples with high sensitivity and specificity, minimizing the
likelihood of misclassification.
INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
MATERIALS AND METHODS
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Abstract
Introduction
Materials & Methods
Results
Discussion
References
20°C. The precipitated DNA was centrifuged for 30 min
at 13,000 × g. The supernatant was immediately removed
and discarded with a plugged Pasteur pipette. The crude DNA pellet was
dried overnight at room temperature. The pellet was then resuspended in
150 µl of TE (10 mM Tris, 1 mM EDTA) and incubated for 15 min at
95°C to inactivate the proteinase K. The crude DNA extracts were then stored at 20°C until amplification.
-globin target was
coamplified with the HPV consensus primers. The PCRs were amplified in
a Perkin-Elmer GeneAmp PCR System 9600 for 40 cycles. The following
ultrasensitive, or long, amplification profile was used: 95°C
denaturation for 1 min, 55°C annealing for 1 min, and 72°C
extension for 1 min for 40 cycles; followed by a 5-min terminal
extension at 72°C. A subset of 56 specimens were amplified with an
alternate amplification profile (rapid amplification) as follows:
95°C denaturation for 20 s, 55°C annealing for 20 s, and
72°C terminal extension for 30 s for 40 cycles; followed by a
5-min extension at 72°C.
-globin
probe was used to assess specimen adequacy. Following hybridization,
membranes were washed at 56 to 57°C to remove nonspecifically bound
probe. The wash buffer was 56 to 57°C so that the wash stringency would be increased, given the salt and detergent concentrations and the
selected oligonucleotide probes. This ensures efficient removal of the
nonspecifically bound probe and optimal specific hybridization. The
bound probes were detected with streptavidin-horseradish peroxidase
(Vector, Burlingame, Calif.) and enhanced chemiluminescent substrate
(ECL; Amersham, Arlington Heights, Ill.). Blots were exposed to Kodak
X-OMAT AR 5 film initially for 10 min, followed by a second 2-h or
overnight exposure. HPV positivity by dot blot was determined by
establishment of a negative cutoff, and signals above the cutoff were
scored based on four graded levels of intensity with visual standard
references. In addition, these autoradiograms were read by two blinded
independent observers. The discrepant results were resolved
independently by a third observer.
PCR and line blot-based detection methods. HPV DNA was amplified by the L1 consensus primer system previously described for dot blot detection, except each primer was labeled with a 5' biotin molecule (denoted in the primer name by the inclusion of a capital B as follows: MYB09, MYB11, HMBB01, B GH20, B PC04). In brief, each amplification contained 10 mM Tris-HCl (pH 8.5), 50 mM KCl, 6 mM MgCl2, 200 µM (each) dCTP, dGTP, and dATP, 600 µM dUTP, 7 to 10 U of AmpliTaq Gold, 50 pmol of MYB09, 50 pmol of MYB11, 5 pmol of HMBB01, 5 pmol of B PC04, 5 pmol of B GH20, and 5 to 10 µl of sample (the MgCl2, dUTP, and AmpliTaq Gold were modifications from dot blot protocol). Modifications to the published L1 consensus amplification were made to obtain optimal sensitivity and to standardize the format to other RMS PCR assays. For eventual inclusion of uracil-N-glycosylase to prevent product carryover, dTTP was replaced with dUTP. It was empirically determined that the dUTP concentration must be increased threefold relative to the other dNTPs for efficient strand incorporation by a DNA polymerase. The MgCl2 was subsequently reoptimized to 6 mM to compensate for the increase in dNTP concentration. Reactions were amplified in a Perkin-Elmer TC9600 thermal cycler with the following ultrasensitive thermal profile: 9-min AmpliTaq Gold activation at 95°C, 40 cycles of 1-min denaturation at 95°C, 1-min annealing at 55°C, 1-min extension at 72°C; a 5-min final extension at 72°C; and a hold step at 15°C. A subset of 56 specimens were amplified with an alternate amplification profile (rapid amplification) as follows: a 9-min AmpliTaq Gold activation at 95°C followed by 40 cycles of denaturation for 20 s at 95°C, annealing for 20 s at 55°C, and terminal extension for 30 s at 72°C; followed by a 5-minute extension at 72°C and a hold step at 15°C. After removal from the thermal cycler, samples were stored at 4°C.
The general principle of immobilized probe hybridization has been described elsewhere (4, 21), and a schematic of the procedure is presented in Fig. 1. Generally, the probes were diluted into a coating buffer (50 mM 3-[cyclohexylamino]-1-propanesulfonic acid [CAPS] and 0.1 g of orange dye II per liter) and applied to a plastic-backed nylon membrane strip with a pump mechanism which delivers controlled amounts of probe to the membrane. The HPV genotyping strip contains 29 probe lines plus one reference ink line, detecting 27 individual HPV genotypes and two concentrations of the-globin control probe. Two
bovine serum albumin (BSA)-conjugated probes per HPV type,
corresponding to each of two hypervariable regions within the MY09/MY11
amplicon, are deposited in a single line for each of the following HPV
types: 16, 18, 26, 31, 33, 35, 39, 42, 45, 51 to 59, 66, 68, MM4, MM7,
MM8, and MM9. HPV types 6, 11, 40, and the -globin controls have a
single probe deposited per line. Subsequent to this study, HPV 51A has
been removed from the HPV 51 pool, due to apparent cross-reactivity with nonspecific amplicon. The configuration of the genotyping strip is
diagrammed in Fig. 2, and the probe
sequences are listed in Table 1. The
high- and low-risk HPV types are visually separated by
-globin control lines such that all types between the reference and
-globin control lines are associated with high cancer risk and all
types beyond the control lines are associated with low or no cancer
risk. Disease association was defined according to the International
Biological Study on Cervical Cancer (3). In the
International Biological Study on Cervical Cancer, HPV types were
considered high risk if detected as a single HPV infection within an
invasive cancer. One exception is an HPV 6 which was found alone in a
single invasive tumor; we still considered HPV 6 to be an HPV with low
oncogenic potential, and it remains in the low-risk category within our
present study.
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Analytic sensitivity of the HPV-type spectrum detected for both dot blot and line blot assays was determined by serial dilution of HPV plasmid or M13 phage clones amplified in a background of 12.5 ng of human cellular DNA from the K562 cell line (ATCC CCL243). HPV types 58, 59, 61, 62, 64, and 67 were provided by T. Matsukura; HPVs 33, 39, 42, 54, 55, 66, 68, and 70 were from G. Orth; HPVs 6, 11, 16, 18, 53, and 57 were from E. M. de Villiers; HPV 52 was from W. Lancaster; HPV 26 was from R. Ostrow; HPV 45 was from K. Shah; and HPV 51 was from S. Silverstein. Clinical HPV types, including MM4 (W13B), MM7 (P291), MM8 (P155), and MM9 (P238A) had been previously cloned as PCR fragments of approximately 450 bp (16). Additional sensitivities were determined in precharacterized cervical specimens. Sensitivities were virtually identical by both dot and line blot assays, ranging from 10 to 100 genomes per PCR for HPV types 6, 11, 16, 18, 31, 33, 39, 45, 51, 52, 58, 59, 66, and 68 and from ~500 to 1,000 genomes per PCR for HPV types 26, 35, 40, 42, and 53 to 57. Variation in sensitivity among the genotypes reflects the number and position of mismatched bases in the primer-binding region at nondegenerate sites.
The specificity of HPV genotype discrimination was tested by hybridization of 500 ng (determined by gel quantitation) of amplified product to the HPV genotyping strips. Specificity of typing was excellent, with negligible background or cross-reactivity.
To test the utility of the line blot HPV detection method in clinical samples, we analyzed 359 specimens collected in Digene specimen transport medium. Type-specific oligonucleotide probe results obtained by the standard MY09-MY11-HMB01 dot blot hybridization method were compared to those obtained using the MYB09-MYB11-BHMB01 reverse line blot method. Two separate aliquots of each digested STM sample were taken and processed independently at the two participating laboratory sites, where all aliquots were amplified by using the ultrasensitive amplification profile (see Materials and Methods). Thirty-two HPV-positive and 24 HPV-negative samples determined by the ultrasensitive cycle system were randomly chosen for analysis by the short cycle profile, in which the time at each temperature step in the thermal profile was shortened. Samples were amplified separately for dot and line blot detection because of the requirement of unlabeled versus labeled primers in the dot and line blot detection methods, respectively. Investigators performing the two assays were blinded to results until all interpretations were final.
Of the 359 samples evaluated, 30 were excluded because of false signal generation from the ECL substrate (1), presumably caused by pseudoperoxidases in the sample, thus precluding interpretation of the dot blot results. The results from the remaining 329 samples are presented.
The HPV prevalence in this population was 24.0 and 25.5% by the dot blot and line blot detection methods, respectively. Table 2 represents the overall HPV concordance between the two detection formats. Agreement for HPV-positive results was good, with a kappa statistic of 0.78. Type-specific agreement between the two methods was good, with total concordance ranging from 97 to 100%. Within the HPV-positive samples, multiple HPV types were detected in 10.7 and 8.5% of specimens by the dot blot and line blot detection methods, respectively. A comparison of the results from 56 samples that were amplified and detected with a long and short cycle profile is presented in Table 3. Only 49 of the 56 samples were included in the final analysis due to false ECL signals on the dot blot. As expected, the agreement between the two amplification profiles reflected the increase in detection of low levels of HPV with the longer, ultrasensitive profile. Only the line blot results for rapid versus ultrasensitive amplification profiles are shown; however, the dot blot results were virtually identical (87.8% agreement, kappa = 0.75 for both line and dot blot). Further analysis of HPV data for both line and dot HPV assay was conducted based on recorded intensities. Signal intensity scores were as follows: 1, strong; 2, medium; 3, weak; 4, very weak; and 0, negative. Stratified analyses by signal intensity revealed that a short versus a long profile resulted in discordance within HPV-positive specimens designated 3, 4, and 0 (i.e., weak or negative) for both the line and dot blot assays.
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Assays of samples with discrepant results were repeated by line blot.
Results by line blot were consistent after repeat analysis, with the
exception of weak-positive signals, which were inconsistently amplified. To ascertain the possibility of irreproducibility due to
sampling error from low concentrations of viral DNA, we added HPV 16 plasmid DNA to a PCR premix for a final concentration of 1.27 × 10
4 fg/µl, the equivalent of a single target per
100-µl reaction mixture. This mixture was aliquotted to 80 PCR tubes
and amplified under sensitive amplification profiles. Analysis of the
products by strip analysis indicated that only 42 of 80, or 52.5%,
were positive for HPV DNA. Human DNA was included at a concentration of
2.5 ng per PCR and was amplified in all 80 reactions.
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DISCUSSION |
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We compared our reformatted line blot system to the established dot blot assay to evaluate its performance. In general, the results from this comparison are highly concordant, both for overall HPV DNA detection and for genotype-specific discrimination. Most of the signals from the few discrepant samples were weak, suggesting low concentration of viral DNA, with disagreement likely attributable to sampling error and variable amplification of low levels of HPV DNA. This explanation is substantiated by the following observations. First, the design of the study required each laboratory to prepare, amplify, and detect each sample separately. This procedure creates at least three separate circumstances wherein subaliquots of each sample were transferred to a subsequent step in the protocol. The likelihood of each transfer containing equivalent concentrations of HPV DNA is low. Second, the discrepant results were evenly distributed between the two methods, indicating that neither method had a propensity toward false-negative or false-positive results. Third, we demonstrated in a controlled experiment that a homogeneous mixture of low-copy DNA yielded a positive result in only 52.5% (42 of 80) of the reactions tested. Based on these results, we attribute most discrepancies to random sampling error, except those for HPV types 51, 52, 54, and MM9. In these cases, the more-discordant detection rates were attributed to differences in type-specific amplification efficiencies among degenerate primer lots (data not shown).
We also evaluated the effect of amplification conditions on the low-end sensitivity of the assay by decreasing the time spent at each thermal cycling step in the amplification profile. The results confirm that the discrepancies predominate among the low-copy, or weak, positives, while all other results are consistent, independent of the profile used. These results reflect the inherent variability in sensitivity that results from seemingly minor changes in protocol. Thus, it is recommended that changes to standardized protocols be accompanied by revalidated assays and appropriately redefined performance criteria.
It has been clearly demonstrated that accurate measurement of even minute levels of HPV DNA is critical for a comprehensible evaluation of the natural history of HPV infection (7). Use of a nonamplified method can dramatically skew the strength and even the existence of important epidemiologic associations. Thus, amplification methods, including consensus, or general, primer PCR have been adopted for the majority of epidemiological studies (11, 20, 22). While the use of PCR methods can increase the molecular sensitivity of HPV DNA detection, the issue of misclassification remains (8, 9, 19). It is important not only to increase the sensitivity relative to detectable levels of virus but also to increase sensitivity by increasing the spectrum of HPV genotypes detected, a goal met by consensus primer PCR assays. However, previously described consensus PCR methods that utilized dot blot formats are too laborious to allow for the rapid evaluation of genotype-specific infections in large population studies. As a result, some investigators have combined genotyping probes into mixtures of presumably related HPV types in an attempt to reduce the number of hybridizations required. For example, HPV 18 and 45 are often combined, the HR HPV 50s are combined, the HR HPV 30s are combined, etc. Assumptions have to be made regarding the validity of these groupings. Groupings have historically been made according to anecdotal observations of disease relatedness and more recently according to phylogenetic relatedness. While these assumptions are reasonable for grouping related viruses, the information obtained from such groupings is inherently biased. Given that slight misclassification of HPV-type status may have dramatic effects on the interpretation of far-more-subtle associations, some of which are also prone to measurement error, it is clearly important to develop accurate discriminatory HPV-typing systems.
The PCR-based line blot HPV detection method described here allows sensitive amplification of a broad spectrum of HPV genotypes and accurate discrimination between 27 of those types. Subsequent to this report, our collaborative efforts have extended the HPV type-specific discrimination of this novel line blot to an additional 12 HPV types (data not shown). Thus, disease associations can be more accurately defined, since discrete and comprehensive genotyping information is available, without confounding due to potential misclassification. Also, since the central role of HPVs in the etiology of cervical cancer has been defined, natural history studies of HPV infection will now address more difficult issues, such as persistence, transmissibility, and immunologic responses. All these parameters are adequately studied only in an HPV type-specific or perhaps even in an HPV variant-specific manner.
In addition to natural history studies of HPV infection, the success of HPV DNA testing in patient management and cancer screening strategies is dependent upon the methodology used. The key to improving the current standard of Pap screening may be to significantly increase the specificity of cytology-based screening, without a concomitant decrease in sensitivity. It is believed that an HPV DNA testing method with both high-positive and negative predictive value will serve to increase both the sensitivity and specificity of cervical cancer screening. Furthermore, the amplification and detection protocols used with the line blot detection method are compatible with automation, facilitating the use of this method in large-scale studies or screening. The ability to visually categorize high- versus low-risk HPV infection rapidly by the line blot supports the use of a detailed and informative research assay for routine clinical screening and patient management purposes.
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ACKNOWLEDGMENTS |
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This work was funded in part by a grant to C.M.W. from the National Institutes of Health (AI32917).
We thank William C. Hunt for performing the statistical analysis, Susan Eaton for excellent technical support, and the Roche Molecular Systems DNA synthesis group for oligonucleotide support.
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FOOTNOTES |
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* Corresponding author. Mailing address: Roche Molecular Systems, Inc., 1145 Atlantic Ave., Alameda, CA 94501. Phone: (510) 814-2938. Fax: (510) 522-1285. E-mail: raymond.apple{at}roche.com.
Present address: Department of Epidemiology, School of Hygiene and
Public Health, Johns Hopkins University, Baltimore, MD 21205.
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Discussion
References
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Journal of Clinical Microbiology, October 1998, p. 3020-3027, Vol. 36, No. 10
0095-1137/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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18: 1986-1992
[Abstract] [Full Text] -
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Goodman, M. T., Shvetsov, Y. B., McDuffie, K., Wilkens, L. R., Zhu, X., Thompson, P. J., Ning, L., Killeen, J., Kamemoto, L., Hernandez, B. Y.
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Giuliano, A. R., Lazcano-Ponce, E., Villa, L. L., Flores, R., Salmeron, J., Lee, J.-H., Papenfuss, M. R., Abrahamsen, M., Jolles, E., Nielson, C. M., Baggio, M. L., Silva, R., Quiterio, M.
(2008). The Human Papillomavirus Infection in Men Study: Human Papillomavirus Prevalence and Type Distribution among Men Residing in Brazil, Mexico, and the United States. Cancer Epidemiol. Biomarkers Prev.
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Castle, P. E., Solomon, D., Wheeler, C. M., Gravitt, P. E., Wacholder, S., Schiffman, M.
(2008). Human Papillomavirus Genotype Specificity of Hybrid Capture 2. J. Clin. Microbiol.
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Safaeian, M, Kiddugavu, M, Gravitt, P E, Gange, S J, Ssekasanvu, J, Murokora, D, Sklar, M, Serwadda, D, Wawer, M J, Shah, K V, Gray, R
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Safaeian, M., Kiddugavu, M., Gravitt, P. E., Gange, S. J., Ssekasanvu, J., Murokora, D., Sklar, M., Serwadda, D., Wawer, M. J., Shah, K. V., Gray, R.
(2008). Determinants of Incidence and Clearance of High-Risk Human Papillomavirus Infections in Rural Rakai, Uganda. Cancer Epidemiol. Biomarkers Prev.
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Vaccarella, S., Herrero, R., Snijders, P. J F, Dai, M., Thomas, J. O, Hieu, N. T., Ferreccio, C., Matos, E., Posso, H., de Sanjose, S., Shin, H. R., Sukvirach, S., Lazcano-Ponce, E., Munoz, N., Meijer, C. J L M, Franceschi, S., the IARC HPV Prevalence Surveys (IHPS) Study Group,
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Nishiwaki, M., Yamamoto, T., Tone, S., Murai, T., Ohkawara, T., Matsunami, T., Koizumi, M., Takagi, Y., Yamaguchi, J., Kondo, N., Nishihira, J., Horikawa, T., Yoshiki, T.
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Castle, P. E., Gravitt, P. E., Solomon, D., Wheeler, C. M., Schiffman, M.
(2008). Comparison of Linear Array and Line Blot Assay for Detection of Human Papillomavirus and Diagnosis of Cervical Precancer and Cancer in the Atypical Squamous Cell of Undetermined Significance and Low-Grade Squamous Intraepithelial Lesion Triage Study. J. Clin. Microbiol.
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Stevens, M. P., Garland, S. M., Rudland, E., Tan, J., Quinn, M. A., Tabrizi, S. N.
(2007). Comparison of the Digene Hybrid Capture 2 Assay and Roche AMPLICOR and LINEAR ARRAY Human Papillomavirus (HPV) Tests in Detecting High-Risk HPV Genotypes in Specimens from Women with Previous Abnormal Pap Smear Results. J. Clin. Microbiol.
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Goodman, M. T., Shvetsov, Y. B., McDuffie, K., Wilkens, L. R., Zhu, X., Franke, A. A., Bertram, C. C., Kessel, B., Bernice, M., Sunoo, C., Ning, L., Easa, D., Killeen, J., Kamemoto, L., Hernandez, B. Y.
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Feng, Q., Hawes, S. E., Stern, J. E., Dem, A., Sow, P. S., Dembele, B., Toure, P., Sova, P., Laird, P. W., Kiviat, N. B.
(2007). Promoter Hypermethylation of Tumor Suppressor Genes in Urine from Patients with Cervical Neoplasia. Cancer Epidemiol. Biomarkers Prev.
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(2007). HLA-DQB1*02-Restricted HPV-16 E7 Peptide-Specific CD4+ T-Cell Immune Responses Correlate with Regression of HPV-16-Associated High-Grade Squamous Intraepithelial Lesions. Clin. Cancer Res.
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Anderson, C E, McLaren, K M, Rae, F, Sanderson, R J, Cuschieri, K S
(2007). Human papilloma virus in squamous carcinoma of the head and neck: a study of cases in south east Scotland. J. Clin. Pathol.
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Carozzi, F., Bisanzi, S., Sani, C., Zappa, M., Cecchini, S., Ciatto, S., Confortini, M.
(2007). Agreement between the AMPLICOR Human Papillomavirus Test and the Hybrid Capture 2 Assay in Detection of High-Risk Human Papillomavirus and Diagnosis of Biopsy-Confirmed High-Grade Cervical Disease. J. Clin. Microbiol.
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Kreimer, A. R., Katki, H. A., Schiffman, M., Wheeler, C. M., Castle, P. E., for the ASCUS-LSIL Triage Study Group,
(2007). Viral Determinants of Human Papillomavirus Persistence following Loop Electrical Excision Procedure Treatment for Cervical Intraepithelial Neoplasia Grade 2 or 3. Cancer Epidemiol. Biomarkers Prev.
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Fakhry, C., D'souza, G., Sugar, E., Weber, K., Goshu, E., Minkoff, H., Wright, R., Seaberg, E., Gillison, M.
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(2006). Reproductive Factors, Oral Contraceptive Use, and Human Papillomavirus Infection: Pooled Analysis of the IARC HPV Prevalence Surveys.. Cancer Epidemiol. Biomarkers Prev.
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(2006). Assessment of MagNA Pure LC Extraction System for Detection of Human Papillomavirus (HPV) DNA in PreservCyt Samples by the Roche AMPLICOR and LINEAR ARRAY HPV Tests.. J. Clin. Microbiol.
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Coutlee, F., Rouleau, D., Petignat, P., Ghattas, G., Kornegay, J. R., Schlag, P., Boyle, S., Hankins, C., Vezina, S., Cote, P., Macleod, J., Voyer, H., Forest, P., Walmsley, S., The Canadian Women's HIV Study Group, , Franco, E.
(2006). Enhanced Detection and Typing of Human Papillomavirus (HPV) DNA in Anogenital Samples with PGMY Primers and the Linear Array HPV Genotyping Test.. J. Clin. Microbiol.
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Kreimer, A. R., Guido, R. S., Solomon, D., Schiffman, M., Wacholder, S., Jeronimo, J., Wheeler, C. M., Castle, P. E., for the ASCUS-LSIL Triage Study (ALTS) Group,
(2006). Human papillomavirus testing following loop electrosurgical excision procedure identifies women at risk for posttreatment cervical intraepithelial neoplasia grade 2 or 3 disease.. Cancer Epidemiol. Biomarkers Prev.
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Huang, S.-L., Chao, A., Hsueh, S., Chao, F.-Y., Huang, C.-C., Yang, J.-E., Lin, C.-Y., Yan, C.-C., Chou, H.-H., Huang, K.-G., Huang, H.-J., Wu, T.-I, Tseng, M.-J., Qiu, J.-T., Lin, C.-T., Chang, T.-C., Lai, C.-H.
(2006). Comparison between the Hybrid Capture II Test and an SPF1/GP6+ PCR-Based Assay for Detection of Human Papillomavirus DNA in Cervical Swab Samples.. J. Clin. Microbiol.
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Burchell, A. N., Richardson, H., Mahmud, S. M., Trottier, H., Tellier, P. P., Hanley, J., Coutlee, F., Franco, E. L.
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(2006). Association of Condom Use, Sexual Behaviors, and Sexually Transmitted Infections With the Duration of Genital Human Papillomavirus Infection Among Adolescent Women. Arch Pediatr Adolesc Med
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(2006). Incident High-Grade Squamous Intraepithelial Lesions in Senegalese Women With and Without Human Immunodeficiency Virus Type 1 (HIV-1) and HIV-2. JNCI J Natl Cancer Inst
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(2005). Development of a General-Primer-PCR-Reverse-Line-Blotting System for Detection of Beta and Gamma Cutaneous Human Papillomaviruses. J. Clin. Microbiol.
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(2002). High Prevalence of Human Papillomavirus (HPV) Infections and High Frequency of Multiple HPV Genotypes in Human Immunodeficiency Virus-Infected Women in Brazil. J. Clin. Microbiol.
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van den Brule, A. J. C., Pol, R., Fransen-Daalmeijer, N., Schouls, L. M., Meijer, C. J. L. M., Snijders, P. J. F.
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Coutlee, F., Gravitt, P., Kornegay, J., Hankins, C., Richardson, H., Lapointe, N., Voyer, H., Franco, E.
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Giuliano, A. R., Papenfuss, M., Abrahamsen, M., Denman, C., de Zapien, J. G., Henze, J. L. N., Ortega, L., de Galaz, E. M. B., Stephan, J., Feng, J., Baldwin, S., Garcia, F., Hatch, K.
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Kornegay, J. R., Shepard, A. P., Hankins, C., Franco, E., Lapointe, N., Richardson, H., Canadian Women's HIV Study Group, , Coutlee, F.
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Lin, P., Koutsky, L. A., Critchlow, C. W., Apple, R. J., Hawes, S. E., Hughes, J. P., Toure, P., Dembele, A., Kiviat, N. B.
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Mayaud, P., Gill, D. K, Weiss, H. A, Uledi, E., Kopwe, L., Todd, J., ka-Gina, G., Grosskurth, H., Hayes, R. J, Mabey, D. C., Lacey, C. J N
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Coutlée, F., de Ladurantaye, M., Tremblay, C., Vincelette, J., Labrecque, L., Roger, M.
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Follen, M., Richards-Kortum, R.
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Nelson, J. H., Hawkins, G. A., Edlund, K., Evander, M., Kjellberg, L., Wadell, G., Dillner, J., Gerasimova, T., Coker, A. L., Pirisi, L., Petereit, D., Lambert, P. F.
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Lacey, J. V. Jr., Brinton, L. A., Abbas, F. M., Barnes, W. A., Gravitt, P. E., Greenberg, M. D., Greene, S. M., Hadjimichael, O. C., McGowan, L., Mortel, R., Schwartz, P. E., Silverberg, S. G., Hildesheim, A.
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Melchers, W. J. G., Bakkers, J. M. J .E., Wang, J., de Wilde, P. C. M., Boonstra, H., Quint, W. G. V., Hanselaar, A. G. J. M.
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Brown, D. R., Schroeder, J. M., Bryan, J. T., Stoler, M. H., Fife, K. H.
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Coutlée, F., Gravitt, P., Richardson, H., Hankins, C., Franco, E., Lapointe, N., Voyer, H., The Canadian Women's HIV Study Group,
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