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Screening for Gonorrhea and Chlamydia: A Systematic Review for the U.S. Preventive Services Task ForceScreening for Gonorrhea and Chlamydia FREE

Bernadette Zakher, MBBS; Amy G. Cantor, MD, MHS; Miranda Pappas, MA; Monica Daeges, BA; and Heidi D. Nelson, MD, MPH
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This article was published online first at www.annals.org on 23 September 2014.


From the Pacific Northwest Evidence-based Practice Center, Oregon Health & Science University, and Providence Cancer Center, Providence Health & Services, Portland, Oregon.

Disclaimer: The findings and conclusions in this article are those of the authors, who are responsible for its content, and do not necessarily represent the views of AHRQ. No statement in this article should be construed as an official position of AHRQ or the U.S. Department of Health and Human Services.

Acknowledgment: The authors thank Andrew Hamilton, MLS, MS, Oregon Health & Science University, who conducted literature searches for this systematic review. They also thank AHRQ Medical Officer Karen Lee, MD, MPH, and the USPSTF Leads Linda Baumann, PhD, RN; Kirsten Bibbins-Domingo, PhD, MD, MAS; Francisco Garcia, MD, MPH; and Michael LeFevre, MD, MSPH.

Grant Support: By AHRQ (contract HSSA 290-2007-10057-I).

Disclosures: Disclosures can be viewed at www.acponline.org/authors/icmje/ConflictOfInterestForms.do?msNum=M14-1022.

Corresponding Author: Heidi D. Nelson, MD, MPH, Pacific Northwest Evidence-based Practice Center, Oregon Health & Science University, Mailcode BICC, 3181 Southwest Sam Jackson Park Road, Portland, OR 97239-3098; e-mail, nelsonh@ohsu.edu.

Current Author Addresses: Drs. Zakher, Cantor, and Nelson; Ms. Pappas; and Ms. Daeges: Pacific Northwest Evidence-based Practice Center, Oregon Health & Science University, Mailcode BICC, 3181 Southwest Sam Jackson Park Road, Portland, OR 97239-3098.

Author Contributions: Conception and design: B. Zakher, A.G. Cantor, M. Pappas, H.D. Nelson.

Analysis and interpretation of the data: B. Zakher, A.G. Cantor, M. Pappas, H.D. Nelson.

Drafting of the article: B. Zakher, A.G. Cantor, M. Pappas, H.D. Nelson.

Critical revision of the article for important intellectual content: B. Zakher, A.G. Cantor, M. Pappas, H.D. Nelson.

Final approval of the article: B. Zakher, A.G. Cantor, M. Pappas, H.D. Nelson.

Provision of study materials or patients: H.D. Nelson.

Statistical expertise: H.D. Nelson.

Obtaining of funding: H.D. Nelson.

Administrative, technical, or logistic support: M. Pappas, M. Daeges, H.D. Nelson.

Collection and assembly of data: B. Zakher, A.G. Cantor, M. Pappas, M. Daeges, H.D. Nelson.


Ann Intern Med. 2014;161(12):884-893. doi:10.7326/M14-1022
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Background: Previous research has supported screening for gonorrhea and chlamydia in asymptomatic, sexually active women (including pregnant women) who are younger than 25 years or at increased risk but not in other patient populations.

Purpose: To update the 2005 and 2007 systematic reviews for the U.S. Preventive Services Task Force on screening for gonorrhea and chlamydia in men and women, including pregnant women and adolescents.

Data Sources: MEDLINE (1 January 2004 to 13 June 2014), Cochrane databases (May 2014), ClinicalTrials.gov, and reference lists.

Study Selection: English-language trials and observational studies about screening effectiveness, test accuracy, and screening harms.

Data Extraction: Extracted study data were confirmed by a second investigator, and study quality and applicability were dual-rated using prespecified criteria.

Data Synthesis: Screening a subset of asymptomatic young women for chlamydia in a good-quality trial did not significantly reduce the incidence of pelvic inflammatory disease over the following year (relative risk, 0.39 [95% CI, 0.14 to 1.08]); however, 1 previous trial reported a reduction. An observational study evaluating a risk prediction tool to identify persons with chlamydia in high-risk populations had low predictive ability and applicability. In 10 new studies of asymptomatic patients, nucleic acid amplification tests demonstrated sensitivity of 86% or greater and specificity of 97% or greater for diagnosing gonorrhea and chlamydia, regardless of specimen type or test.

Limitations: There were few relevant studies of screening benefits and harms. Only screening tests and methods cleared by the U.S. Food and Drug Administration for current clinical practice were included to determine diagnostic accuracy.

Conclusion: Chlamydia screening in young women may reduce the incidence of pelvic inflammatory disease. Nucleic acid amplification tests are accurate for diagnosing gonorrhea and chlamydia in asymptomatic persons.

Primary Funding Source: Agency for Healthcare Research and Quality.


In 2005, on the basis of epidemiologic studies of screening and studies of the diagnostic accuracy of screening tests (13), the U.S. Preventive Services Task Force (USPSTF) recommended screening for gonorrhea in all sexually active or pregnant women at increased risk for infection (4). It recommended against routine screening in low-risk men and nonpregnant women and found insufficient evidence to recommend for or against routine screening in high-risk men and low-risk pregnant women.

In 2007, on the basis of studies of the effectiveness of screening, harms, and diagnostic accuracy of screening tests (13), the USPSTF recommended screening for chlamydia in all sexually active or pregnant women younger than 25 years and in older, high-risk women (5). It recommended against routine screening in low-risk women, regardless of pregnancy status, and found insufficient evidence to recommend for or against screening in men.

Gonorrhea and chlamydia are the 2 most commonly reported sexually transmitted infections (STIs) in the United States (6). In 2012, totals of 334 826 cases of gonorrhea and 1 422 976 cases of chlamydia were reported to the Centers for Disease Control and Prevention (6). However, the true incidence of gonorrhea and chlamydia is difficult to estimate because most infections are undetected.

In women, gonococcal and chlamydial infections are most often asymptomatic but can cause cervicitis and complications of pelvic inflammatory disease (PID), ectopic pregnancy, infertility, and chronic pelvic pain (67). In men, these infections can cause urethritis and epididymitis (6, 8). Most men with gonococcal urethritis are symptomatic, prompting timely treatment that prevents serious complications (9). However, gonococcal infections at extragenital sites, including the pharynx and rectum, and genital chlamydial infections are typically asymptomatic. Gonorrhea and chlamydia can also facilitate HIV transmission in both men and women (6, 1011). Infection with either gonorrhea or chlamydia in pregnant women can lead to adverse neonatal outcomes, including preterm birth and transmission of infection to the newborn. Chlamydial infection also causes neonatal ophthalmia and pneumonia in infants.

Age is a strong predictor of risk for both gonorrhea and chlamydia, and infection rates are greatest among persons aged 15 to 24 years (6). Although rates are greater for women than men (108.7 cases of gonorrhea per 100 000 women vs. 105.8 per 100 000 men; 643.3 cases of chlamydia per 100 000 women vs. 262.6 per 100 000 men), rates have increased more rapidly among men in recent years (6). Other risk factors include having new or multiple sex partners or a partner with an STI, inconsistent condom use, and history of previous or coexisting STIs (12). These risk factors are often used to define persons at increased risk in screening recommendations. Rates differ among population subgroups, and black and Hispanic persons generally have greater rates of infections compared with white persons (6, 12). Men who have sex with men who were tested in STD Surveillance Network clinics in 2012 had median prevalence rates of 16.4% for gonorrhea and 12.0% for chlamydia (6).

This systematic review is an update of previous reviews for the USPSTF (13). It focuses on new studies of the effectiveness and adverse effects of gonorrhea and chlamydia screening in asymptomatic men and women, including pregnant women and adolescents, as well as the diagnostic accuracy of screening tests.

Methods are further described in a technical report (13). We followed a standard protocol consistent with the Agency for Healthcare Research and Quality (AHRQ) methods for systematic reviews (14). On the basis of evidence gaps identified from previous reviews (13), the USPSTF and AHRQ determined the key questions for this update (15). The investigators created analytic frameworks incorporating the key questions and outlining the patient populations, interventions, outcomes, and potential adverse effects (Supplements 1 and 2). A work plan was externally reviewed and modified but was not registered.

The target populations were asymptomatic, sexually active men and women, including pregnant women and adolescents. The key questions focused on the effectiveness of screening compared with not screening in preventing adverse health outcomes, effectiveness of different screening strategies, diagnostic accuracy of screening tests, and potential harms of screening. Screening strategies included selective screening of high-risk groups, sampling from various anatomical sites, cotesting for concurrent STIs (including HIV), and using different screening intervals, among others. Outcomes included reduction of complications of infection and transmission or acquisition of disease, including gonorrhea, chlamydia, and HIV. For pregnant women, outcomes also included reduction in maternal complications and adverse pregnancy and infant outcomes. Harms of screening included labeling, anxiety, false-positive and false-negative test results, and other consequences of testing. The efficacy and harms of antibiotic treatments were well-established and were not further evaluated.

Data Sources and Searches

We searched Ovid MEDLINE (1 January 2004 to 13 June 2014), the Cochrane Central Register of Controlled Trials (May 2014), the Cochrane Database of Systematic Reviews (May 2014), the Health Technology Assessment Database (May 2014), the Database of Abstracts of Reviews of Effects (May 2014), and ClinicalTrials.gov (May 2014) and reviewed reference lists for additional citations (13). Search terms are provided in Supplement 3.

Study Selection

Abstracts were selected for full-text review if they included asymptomatic, sexually active men and women, including pregnant women and adolescents; were relevant to a key question; and met additional prespecified inclusion criteria for each key question (13). Although this update was intended to evaluate studies published since the previous USPSTF reviews, the scope, key questions, and inclusion criteria differ across reviews, resulting in the inclusion of older studies that have not been previously reviewed. We included only English-language articles and excluded studies that were published as abstracts only or did not report original data. The selection of studies is summarized in a literature flow diagram Supplement 4. Two reviewers independently evaluated each study to determine inclusion eligibility.

Only randomized, controlled trials (RCTs) and controlled observational studies were included to evaluate the effectiveness of screening, whereas uncontrolled observational studies were also included to determine adverse effects. Studies of screening strategies were included if they adequately described the study population and comparison groups, features of the screening program, and outcome measures. Inclusion criteria were less restrictive for effectiveness studies than diagnostic accuracy studies because the main comparison concerned outcomes related to the overall approach of screening compared with nonscreening rather than the characteristics of the individual tests.

Studies of the accuracy of diagnostic tests were included if they evaluated screening tests in asymptomatic participants using technologies and methods that have been cleared by the U.S. Food and Drug Administration (FDA) and are available for clinical practice in the United States. These inclusion criteria reflect the scope of the USPSTF recommendations about technologies and medications. On the basis of these criteria, rectal, pharyngeal, and self-collected vaginal specimens obtained in nonclinical settings and point-of-care or in-house tests were excluded. Tests that were previously cleared and subsequently removed from the U.S. market (such as the ligase chain reaction test) were also excluded (16). Included studies used credible reference standards, adequately described the study population, defined positive test results, and reported performance characteristics of tests (such as sensitivity and specificity) or provided data to calculate them.

Data Abstraction and Quality Rating

A single investigator abstracted details about study design, patient population, comparison groups, setting, screening method, analysis, follow-up, and results. A second investigator reviewed data abstraction for accuracy. By using prespecified criteria for RCTs, cohort, and diagnostic accuracy studies developed by the USPSTF (14), 2 investigators independently rated the quality of studies (good, fair, or poor) and resolved discrepancies by consensus.

Data Synthesis and Analysis

Two independent reviewers assessed the internal validity (quality) of the body of evidence for the new studies for each key question using methods developed by the USPSTF, on the basis of the number, quality, and size of studies; consistency of results among studies; and directness of evidence (1415). Statistical meta-analysis was not done because of methodological limitations of the studies and heterogeneity in study designs, interventions, populations, and other factors. Studies included in previous reviews were reviewed for consistency with current results; however, lack of studies and differences in scope, key questions, and inclusion criteria limited aggregate synthesis with the updated evidence.

Role of the Funding Source

This research was funded by AHRQ under a contract to support the work of the USPSTF. The investigators worked with USPSTF members and AHRQ staff to develop and refine the scope, analytic frameworks, and key questions; resolve issues during the project; and finalize the report. AHRQ had no role in study selection, quality assessment, synthesis, or development of conclusions. AHRQ provided project oversight; reviewed the draft report; and distributed the draft for peer review, including to representatives of professional societies and federal agencies. AHRQ performed a final review of the manuscript to ensure that the analysis met methodological standards. The investigators are solely responsible for the content and the decision to submit the manuscript for publication.

Effectiveness of Screening Asymptomatic Men and Nonpregnant Women, Including Adolescents

No studies of gonorrhea screening met inclusion criteria for the previous USPSTF reviews or this update. The 2001 (1) and 2007 (3) USPSTF reviews on chlamydia screening identified 2 trials of screening women at increased risk for chlamydia (1718) (Table 1 and Supplement 5). Incidence of PID was significantly reduced among women screened in a good-quality RCT of 2607 women aged 18 to 34 years who were recruited from an HMO in the United States (relative risk [RR], 0.44 [95% CI, 0.20 to 0.90]) (1718). Reductions were of borderline statistical significance in a poor-quality RCT of Danish students (RR, 0.50 [CI, 0.23 to 1.08]) (1718).

One new RCT of chlamydia screening in women (but none in men) met inclusion criteria for this update. The Prevention of Pelvic Infection trial was a good-quality RCT of 2529 sexually active young women recruited from universities in the United Kingdom (mean age, 21 years [range, 16 to 27 years]) (19) (Table 1 and Supplement 5). Participants provided chlamydia tests using self-collected vaginal swabs. Specimens from participants randomly assigned to the screening group were immediately tested for chlamydia, whereas specimens from control participants were tested 1 year later. After 1 year, 94% of participants completed questionnaires about symptoms of PID and sexual behavior during the previous year. Medical records of women suspected of having PID on the basis of their questionnaire responses were reviewed by 3 blinded genitourinary physicians for diagnostic confirmation.

During follow-up, PID occurred in 1.3% of screened versus 1.9% of control participants (RR, 0.65 [CI, 0.34 to 1.22]) (19). Among a subgroup of participants who reported no symptoms during the 6 months before the study (that is, pelvic pain, dyspareunia, abnormal vaginal bleeding, or discharge), 0.6% (5 of 787) of screened participants versus 1.6% (14 of 861) of control participants developed PID during follow-up (RR, 0.39 [CI, 0.14 to 1.08]) (Kerry S. Personal communication.). In this trial, 79% (30 of 38) of PID cases occurred in women who tested negative at baseline. In addition, 22% of participants were tested for chlamydia outside of the study protocol during follow-up.

Effectiveness of Screening Strategies

Previous reviews did not directly address the effectiveness of different screening strategies but summarized risk factors associated with gonococcal and chlamydial infections (12). An observational study comparing 9 sets of selective screening criteria for chlamydial infection among women attending family planning and STI clinics in the United States (20) indicated that age alone had similar or better sensitivity and specificity as more extensive criteria. In this study, nearly 80% of cases were identified while testing 50% of the population when using an age cutoff of 22 years or younger.

Only 1 new study of screening strategies met inclusion criteria. An observational study conducted in the Netherlands evaluated a risk prediction tool to identify persons infected with chlamydia in high-risk populations (21). Screening criteria were developed on the basis of questionnaire responses from sexually active participants who were subsequently tested for chlamydia and included items on age, education, ethnicity, lifetime sex partners, and condom use. When applied to high-risk populations, this risk tool was not an accurate predictor of infection (area under the receiver-operating characteristic curve, 0.66 to 0.68). The applicability of this study to U.S. populations is also limited.

Diagnostic Accuracy of Screening Tests for Gonorrhea and Chlamydia

The previous reviews reported high sensitivity and specificity in studies of the diagnostic accuracy of gonorrhea and chlamydia tests (12). However, several studies included symptomatic persons and non–nucleic acid amplification tests (non-NAATs), including tests that are not currently available, diminishing their clinical applicability.

Ten new fair-quality studies reporting test characteristics of FDA-cleared NAATs met inclusion criteria (Table 2 and Supplements 6 and 7): 6 for gonorrhea (2227) and 8 for chlamydia (2224, 2731). Methodological limitations include unclear descriptions of sampling methods, whether interpretations of the screening test were independent of the reference standard (2225, 2830), and whether the analysis included participants with uninterpretable results (22, 2425, 28, 30). Three studies described additional methodological difficulties related to the reference standard (29) and technical approach (25, 28). Most studies reported more than 5% prevalence of infection among participants, although rates were lower in 3 studies (24, 2627). Although sensitivity varied, specificity was high (≥97%) across all studies for gonorrhea and chlamydia in men and women, regardless of specimen or test.

Table Jump PlaceholderTable 2. Diagnostic Accuracy Studies (2004–2013) of Nucleic Acid Amplification Tests for Gonorrhea and Chlamydia Screening 
Gonorrhea Tests

For women, 4 studies testing endocervical specimens using transcription-mediated amplification (TMA); polymerase chain reaction (PCR), including a new rapid test (27); or strand displacement amplification (SDA) reported sensitivities ranging from 90.0% to 100.0% (2427) (Figure 1). Sensitivity using self-collected vaginal specimens obtained in a clinician's office was 98.0% by TMA (26) and 100% by PCR (27). Results of female urine specimens using TMA, PCR, or SDA ranged from 78.6% to 100% (2425, 27). However, the study reporting the lowest sensitivities for urine used urine volumes larger than recommended by the manufacturer of the screening test (25). When recommended urine volumes were used in a second study, the sensitivity of the same TMA test improved from 78.6% to 95.7% (24).

Grahic Jump Location
Figure 1.

Diagnostic accuracy of nucleic acid amplification tests for gonorrhea screening in men and women.

* The study reporting lower sensitivities for urine specimens in women (78.6% and 82.1%) used urine volumes that were larger than recommended (25), differing from the other studies.

† Two studies produced identical data points for tests of the endocervix.

‡ Three data points for urethral specimens and 3 data points for urine specimens.

§ Two data points for urethral specimens.

Grahic Jump Location

For men, testing urethral specimens with SDA and TMA and testing urine using TMA, SDA, or PCR resulted in similarly high sensitivities across tests in 4 studies (urethral specimen, 100%; urine, 90.0% to 100%) (2223, 25, 27) (Figure 1).

Chlamydia Tests

Among 5 studies of endocervical specimens, sensitivity of TMA was 89.0% to 97.1%, SDA was 86.4% to 96.2%, and PCR was 86.4% to 95.8% (24, 2728, 3031) (Figure 2). Clinician-collected vaginal swabs tested with TMA and PCR provided sensitivities of 89.9% and 98.8% (28), and self-collected vaginal swabs from clinical settings provided sensitivities of 97.0% with TMA (31) and 90.7% (28) and 98.0% (27) with PCR. Female urine samples tested with TMA, PCR, and SDA provided sensitivities of 72.0% to 98.2% (24, 2728, 30). Lower sensitivities for urine samples using TMA (72.0%) and PCR (84.0%) were reported in a study that experienced technical and specimen processing errors (28).

Grahic Jump Location
Figure 2.

Diagnostic accuracy of nucleic acid amplification tests for chlamydia screening in men and women.

* The study reporting lower sensitivities for urine specimens in women (72.0% and 84.0%) experienced technical and specimen-processing errors (27), differing from the other studies.

Grahic Jump Location

A single study of PCR reported sensitivities that were markedly lower than other studies (29), and results were not included in Figure 2. This study used a more conservative approach to analysis that required complete sets of results from 9 testing strategies. Also, the reference standard included positive NAAT results from 2 separate specimens. When a specimen-specific reference standard was used, sensitivities were similar to other studies (data were not provided).

Sensitivities for male urethral and urine specimens were consistently high, regardless of test, across 4 studies reporting sensitivities from 86.1% to 100% for TMA, SDA, or PCR (2223, 27, 30) (Figure 2).

Harms of Screening Asymptomatic Men and Nonpregnant Women, Including Adolescents

The previous reviews indicated low false-positive and false-negative results for screening tests (13) that were confirmed by the 10 new diagnostic accuracy studies described earlier. In the new studies without major methodological limitations, false-positive result rates for gonorrhea and chlamydia were 3% or lower, and false-negative result rates ranged from 0% to 9% for gonorrhea and 0% to 14% for chlamydia across all NAATs and specimen types (2231).

A previous review (3) included results of qualitative interviews about the experience of chlamydia testing from women having opportunistic screening (32). Although many women believed that screening was beneficial and important, common responses to a positive test result included feeling dirty, ashamed of passing on the infection, and suspicious about the origins of the infection.

Benefits and Harms of Screening Asymptomatic Pregnant Women

As in the previous reviews (23), no studies reported the benefits or harms of screening pregnant women specifically.

No studies were available to address several key questions, including the effectiveness of screening for gonorrhea in all population groups and screening for chlamydia in men, pregnant women, and adolescents specifically; the effectiveness of screening strategies; and harms of screening unrelated to the diagnostic accuracy of tests.

Only 1 new trial evaluated the effectiveness of screening for chlamydia in nonpregnant women (19) (key question 1). In the Prevention of Pelvic Infection trial, screening a subset of asymptomatic young women for chlamydia did not significantly reduce PID over the following year compared with no screening (RR, 0.39 [CI, 0.14 to 1.08]). Although it met the criteria for good quality, the trial was limited by inadequate recruitment, testing for chlamydia outside of the study protocol during follow-up in nearly one quarter of participants, and difficulties in ascertaining PID cases. These limitations imply that the study may have been underpowered and the intervention effects attenuated. In addition, most cases of PID occurred in women who tested negative at baseline, suggesting that frequent targeted screening of women at greater risk for infection, including those with new sexual partners or a recent history of chlamydia, may be more important than 1-time routine screening.

Two earlier trials also evaluated the incidence of PID after chlamydia screening of women at increased risk (1718). Although a good-quality trial in the United States reported a statistically significant reduction in PID incidence in the screened versus usual care group after 1 year of follow-up (RR, 0.44 [CI, 0.20 to 0.90]) (1718), reduction in PID incidence was not statistically significant in a poor-quality trial in Denmark comparing 1-time home-based screening with usual care (1718). Although all 3 trials reported point estimates suggesting reduced PID, only the U.S. trial showed a statistically significant reduction. This trial met criteria for good quality, is the largest trial, and is the most applicable to clinical practice in the United States.

Additional relevant studies of screening did not meet inclusion criteria because they did not provide results for asymptomatic participants or reported infection rates rather than health outcomes. These studies found no significant improvements in clinical outcomes among those screened for chlamydia, including a large Danish trial of more than 30 000 young men and women (33), a retrospective population-based cohort study of more than 40 000 Swedish women (34), and a register-based screening trial of more than 300 000 men and women in the Netherlands (35). A time trend analysis of a U.S. managed care population between 1997 and 2007 indicated increased cases of chlamydia for both men and women but decreased PID (36). It is not clear how screening influenced these outcomes.

The only new study addressing the effectiveness of different screening strategies (key question 2) was an observational study evaluating a risk prediction tool to identify persons with chlamydia in high-risk populations (21). However, the tool was not an accurate predictor and its relevance to current practice in the United States is uncertain. An older observational study comparing 9 sets of selective screening criteria for chlamydial infection among women (20) supported age-based screening in current guidelines but has not been updated by newer research. Future studies to address this key question would compare the effectiveness of screening versus not screening in populations with different levels of risk; include specimens from different anatomical sites; include cotesting for concurrent STIs, including HIV; and evaluate different screening intervals.

Ten studies of the diagnostic accuracy of screening tests met inclusion criteria (2226, 2831, 37) (key question 3). The current review differs from previous reviews (12) by including only results from asymptomatic participants, a focus that is more clinically relevant to screening populations. Various types of NAATs are highly accurate in diagnosing gonorrhea and chlamydia in asymptomatic persons, regardless of specimen, site, or test (2225, 28, 30, 37). Sensitivity was 85% or greater and specificity was 97% or greater in studies without major methodological limitations, resulting in generally low false-negative and false-positive results. The high accuracy of NAATs reported by these studies is consistent with previous reviews (12) and is the basis for the Centers for Disease Control and Prevention's recommendation to use NAATs for gonorrhea and chlamydia testing (38).

Several studies of harms did not meet inclusion criteria for the update because they focused on the effects of receiving a positive test result, included symptomatic participants, and lacked comparison groups (3942) (key question 4). In these studies, persons testing positive for chlamydia had greater anxiety (3940, 42) and more partner break-ups (3940) than those testing negative, who were generally relieved (40, 42).

No studies meeting inclusion criteria addressed screening in pregnant women despite the need for additional research in this population. For example, testing during the first trimester may not be sufficient, based on findings from an observational study suggesting that chlamydia test results during the first trimester may not predict chlamydia status during the third trimester (43). Although studies of repeated testing have been conducted in high-risk populations (44), more research is warranted to further evaluate the value of repeated testing during pregnancy to reduce potential complications, such as preterm delivery and premature rupture of membranes (45).

Limitations of this review include using only English-language articles, which could result in language bias, although we did not identify non–English-language studies that otherwise met inclusion criteria in our searches. We included only studies with asymptomatic participants and settings and tests applicable to current practice in the United States to improve clinical relevance for the USPSTF, excluding much research in the field. Studies were lacking for most key questions, and the number, quality, and applicability of studies varied widely. Also, the available screening trials evaluated only PID as the main outcome, and other outcomes are also important.

Nucleic acid amplification tests have been cleared by the FDA for use with male and female urine, endocervical, and male urethral specimens, and some NAATs are cleared for clinician- and self-collected vaginal specimens in clinical settings. Studies have also reported similar test characteristics for nurse- and patient-collected rectal swabs in men who have sex with men (26, 2829, 31, 46). Additional studies of NAATs using self-collected specimens could provide more evidence for FDA clearance of this technique and increase testing access and acceptability. This could potentially expand screening strategies to home-based, mail-in, or Internet-based screening and encourage the uptake of screening among persons at increased risk.

Limiting our review to FDA-cleared tests excluded studies of rectal and pharyngeal specimens that also demonstrate high accuracy in studies of NAATs (26, 2829, 31, 46) and are currently recommended by the Centers for Disease Control and Prevention (38). Expanding the range of specimen types for screening has the potential to increase identification of infected persons, especially asymptomatic men who have sex with men, for whom nearly 90% of all gonococcal infections are in nongenital sites (47). Among this population, NAATs have greater sensitivity at extragenital sites compared with culture, potentially because of lower bacterial loads at the pharynx and rectum (4849). In a study of men who have sex with men, 85% of rectal infections were asymptomatic and only detectable with routine screening (50). Urethral testing alone missed 84% of chlamydial and gonococcal infections compared with 9.8% missed by rectal and pharyngeal testing in another study (47).

In summary, screening for chlamydia may reduce the incidence of PID in young women. Risk prediction tools may be useful in identifying persons with infections but require validation in the populations of intended use. Nucleic acid amplification tests are accurate for diagnosing gonorrhea and chlamydia in asymptomatic persons, regardless of specimen, site, or test. Further research is needed to determine the effectiveness of screening in multiple populations and on various clinical outcomes, including but not limited to PID; effective screening strategies; and harms of screening.

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Centers for Disease Control and Prevention (CDC). Recall of LCx Neisseria gonorrhoeae assay and implications for laboratory testing for N. gonorrhoeae and Chlamydia trachomatis. MMWR Morb Mortal Wkly Rep. 2002; 51:709.
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Scholes D, Stergachis A, Heidrich FE, Andrilla H, Holmes KK, Stamm WE. Prevention of pelvic inflammatory disease by screening for cervical chlamydial infection. N Engl J Med. 1996; 334:1362-6.
PubMed
CrossRef
 
Ostergaard L, Andersen B, Møller JK, Olesen F. Home sampling versus conventional swab sampling for screening of Chlamydia trachomatis in women: a cluster-randomized 1-year follow-up study. Clin Infect Dis. 2000; 31:951-7.
PubMed
CrossRef
 
Oakeshott P, Kerry S, Aghaizu A, Atherton H, Hay S, Taylor-Robinson D, et al. Randomised controlled trial of screening for Chlamydia trachomatis to prevent pelvic inflammatory disease: the POPI (Prevention of Pelvic Infection) trial. BMJ. 2010; 340:c1642.
PubMed
CrossRef
 
Miller WC, Hoffman IF, Owen-O'Dowd J, McPherson JT, Privette A, Schmitz JL, et al. Selective screening for chlamydial infection: which criteria to use? Am J Prev Med. 2000; 18:115-22.
PubMed
CrossRef
 
Götz HM, Veldhuijzen IK, Habbema JD, Boeke AJ, Richardus JH, Steyerberg EW. Prediction of Chlamydia trachomatis infection: application of a scoring rule to other populations. Sex Transm Dis. 2006; 33:374-80.
PubMed
CrossRef
 
Chernesky MA, Martin DH, Hook EW, Willis D, Jordan J, Wang S, et al. Ability of new APTIMA CT and APTIMA GC assays to detect Chlamydia trachomatis and Neisseria gonorrhoeae in male urine and urethral swabs. J Clin Microbiol. 2005; 43:127-31.
PubMed
CrossRef
 
Taylor SN, Liesenfeld O, Lillis RA, Body BA, Nye M, Williams J, et al. Evaluation of the Roche cobas CT/NG test for detection of Chlamydia trachomatis and Neisseria gonorrhoeae in male urine. Sex Transm Dis. 2012; 39:543-9.
PubMed
CrossRef
 
Van Der Pol B, Liesenfeld O, Williams JA, Taylor SN, Lillis RA, Body BA, et al. Performance of the cobas CT/NG test compared to the Aptima AC2 and Viper CTQ/GCQ assays for detection of Chlamydia trachomatis and Neisseria gonorrhoeae. J Clin Microbiol. 2012; 50:2244-9.
PubMed
CrossRef
 
Van Der Pol B, Taylor SN, Lebar W, Davis T, Fuller D, Mena L, et al. Clinical evaluation of the BD ProbeTec Neisseria gonorrhoeae Qx amplified DNA assay on the BD Viper system with XTR technology. Sex Transm Dis. 2012; 39:147-53.
PubMed
CrossRef
 
Stewart CM, Schoeman SA, Booth RA, Smith SD, Wilcox MH, Wilson JD. Assessment of self taken swabs versus clinician taken swab cultures for diagnosing gonorrhoea in women: single centre, diagnostic accuracy study. BMJ. 2012; 345:e8107.
PubMed
CrossRef
 
Gaydos CA, Van Der Pol B, Jett-Goheen M, Barnes M, Quinn N, Clark C, et al, CT/NG Study Group. Performance of the Cepheid CT/NG Xpert Rapid PCR Test for Detection of Chlamydia trachomatis and Neisseria gonorrhoeae. J Clin Microbiol. 2013; 51:1666-72.
PubMed
CrossRef
 
Schachter J, McCormack WM, Chernesky MA, Martin DH, Van Der Pol B, Rice PA, et al. Vaginal swabs are appropriate specimens for diagnosis of genital tract infection with Chlamydia trachomatis. J Clin Microbiol. 2003; 41:3784-9.
PubMed
CrossRef
 
Shrier LA, Dean D, Klein E, Harter K, Rice PA. Limitations of screening tests for the detection of Chlamydia trachomatis in asymptomatic adolescent and young adult women. Am J Obstet Gynecol. 2004; 190:654-62.
PubMed
CrossRef
 
Taylor SN, Van Der Pol B, Lillis R, Hook EW 3rd, Lebar W, Davis T, et al. Clinical evaluation of the BD ProbeTec Chlamydia trachomatis Qx amplified DNA assay on the BD Viper system with XTR technology. Sex Transm Dis. 2011; 38:603-9.
PubMed
CrossRef
 
Schoeman SA, Stewart CM, Booth RA, Smith SD, Wilcox MH, Wilson JD. Assessment of best single sample for finding chlamydia in women with and without symptoms: a diagnostic test study. BMJ. 2012; 345:e8013.
PubMed
CrossRef
 
Pimenta JM, Catchpole M, Rogers PA, Hopwood J, Randall S, Mallinson H, et al. Opportunistic screening for genital chlamydial infection. II: prevalence among healthcare attenders, outcome, and evaluation of positive cases. Sex Transm Infect. 2003; 79:22-7.
PubMed
CrossRef
 
Andersen B, van Valkengoed I, Sokolowski I, Møller JK, Østergaard L, Olesen F. Impact of intensified testing for urogenital Chlamydia trachomatis infections: a randomised study with 9-year follow-up. Sex Transm Infect. 2011; 87:156-61.
PubMed
CrossRef
 
Low N, Egger M, Sterne JA, Harbord RM, Ibrahim F, Lindblom B, et al. Incidence of severe reproductive tract complications associated with diagnosed genital chlamydial infection: the Uppsala Women's Cohort Study. Sex Transm Infect. 2006; 82:212-8.
PubMed
CrossRef
 
van den Broek IV, van Bergen JE, Brouwers EE, Fennema JS, Götz HM, Hoebe CJ, et al. Effectiveness of yearly, register based screening for chlamydia in the Netherlands: controlled trial with randomised stepped wedge implementation. BMJ. 2012; 345:e4316.
PubMed
CrossRef
 
Scholes D, Satterwhite CL, Yu O, Fine D, Weinstock H, Berman S. Long-term trends in Chlamydia trachomatis infections and related outcomes in a U.S. managed care population. Sex Transm Dis. 2012; 39:81-8.
PubMed
CrossRef
 
Gaydos CA, Barnes M, Jett-Goheen M, Quinn N, Whittle P, Hogan T, et al. Characteristics and predictors of women who obtain rescreening for sexually transmitted infections using the www.iwantthekit.org screening programme. Int J STD AIDS. 2013; 24:736-44.
PubMed
CrossRef
 
Centers for Disease Control and Prevention. Recommendations for the laboratory-based detection of Chlamydia trachomatis and Neisseria gonorrhoeae—2014. MMWR Recomm Rep. 2014; 63:1-19.
PubMed
 
Gottlieb SL, Stoner BP, Zaidi AA, Buckel C, Tran M, Leichliter JS, et al. A prospective study of the psychosocial impact of a positive Chlamydia trachomatis laboratory test. Sex Transm Dis. 2011; 38:1004-11.
PubMed
CrossRef
 
Kangas I, Andersen B, Olesen F, Møller JK, Østergaard L. Psychosocial impact of Chlamydia trachomatis testing in general practice. Br J Gen Pract. 2006; 56:587-93.
PubMed
 
Campbell R, Mills N, Sanford E, Graham A, Low N, Peters TJ, Chlamydia Screening Studies (ClaSS) Group. Does population screening for Chlamydia trachomatis raise anxiety among those tested? Findings from a population based chlamydia screening study. BMC Public Health. 2006; 6:106.
PubMed
CrossRef
 
Low N, McCarthy A, Macleod J, Salisbury C, Campbell R, Roberts TE, et al, Chlamydia Screening Studies Project Group. Epidemiological, social, diagnostic and economic evaluation of population screening for genital chlamydial infection. Health Technol Assess.. 2007; 11:iii–iv, ix–xii, 1-165.
PubMed
CrossRef
 
Hood EE, Nerhood RC. The utility of screening for chlamydia at 34-36 weeks gestation. W V Med J. 2010; 106:10-1.
PubMed
 
Miller JM, Maupin RT, Nsuami M. Initial and repeat testing for chlamydia during pregnancy. J Matern Fetal Neonatal Med. 2005; 18:231-5.
PubMed
CrossRef
 
Blas MM, Canchihuaman FA, Alva IE, Hawes SE. Pregnancy outcomes in women infected with Chlamydia trachomatis: a population-based cohort study in Washington State. Sex Transm Infect. 2007; 83:314-8.
PubMed
CrossRef
 
Alexander S, Ison C, Parry J, Llewellyn C, Wayal S, Richardson D, et al, Brighton Home Sampling Kits Steering Group. Self-taken pharyngeal and rectal swabs are appropriate for the detection of Chlamydia trachomatis and Neisseria gonorrhoeae in asymptomatic men who have sex with men. Sex Transm Infect. 2008; 84:488-92.
PubMed
CrossRef
 
Marcus JL, Bernstein KT, Kohn RP, Liska S, Philip SS. Infections missed by urethral-only screening for chlamydia or gonorrhea detection among men who have sex with men. Sex Transm Dis. 2011; 38:922-4.
PubMed
CrossRef
 
Schachter J, Moncada J, Liska S, Shayevich C, Klausner JD. Nucleic acid amplification tests in the diagnosis of chlamydial and gonococcal infections of the oropharynx and rectum in men who have sex with men. Sex Transm Dis. 2008; 35:637-42.
PubMed
CrossRef
 
Bissessor M, Tabrizi SN, Fairley CK, Danielewski J, Whitton B, Bird S, et al. Differing Neisseria gonorrhoeae bacterial loads in the pharynx and rectum in men who have sex with men: implications for gonococcal detection, transmission, and control. J Clin Microbiol. 2011; 49:4304-6.
PubMed
CrossRef
 
Kent CK, Chaw JK, Wong W, Liska S, Gibson S, Hubbard G, et al. Prevalence of rectal, urethral, and pharyngeal chlamydia and gonorrhea detected in 2 clinical settings among men who have sex with men: San Francisco, California, 2003. Clin Infect Dis. 2005; 41:67-74.
PubMed
CrossRef
 

Figures

Grahic Jump Location
Figure 1.

Diagnostic accuracy of nucleic acid amplification tests for gonorrhea screening in men and women.

* The study reporting lower sensitivities for urine specimens in women (78.6% and 82.1%) used urine volumes that were larger than recommended (25), differing from the other studies.

† Two studies produced identical data points for tests of the endocervix.

‡ Three data points for urethral specimens and 3 data points for urine specimens.

§ Two data points for urethral specimens.

Grahic Jump Location
Grahic Jump Location
Figure 2.

Diagnostic accuracy of nucleic acid amplification tests for chlamydia screening in men and women.

* The study reporting lower sensitivities for urine specimens in women (72.0% and 84.0%) experienced technical and specimen-processing errors (27), differing from the other studies.

Grahic Jump Location

Tables

Table Jump PlaceholderTable 2. Diagnostic Accuracy Studies (2004–2013) of Nucleic Acid Amplification Tests for Gonorrhea and Chlamydia Screening 

References

Nelson HD, Helfand M. Screening for chlamydial infection. Am J Prev Med. 2001; 20:95-107.
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Glass N, Nelson HD, Villemyer K.  Screening for Gonorrhea: Update of the Evidence. Rockville, MD: Agency for Healthcare Research and Quality; 2005. Accessed at www.uspreventiveservicestaskforce.org/uspstf05/gonorrhea/gonup.pdf on 4 September 2014.
 
Meyers DS, Halvorson H, Luckhaupt S, U.S. Preventive Services Task Force. Screening for chlamydial infection: an evidence update for the U.S. Preventive Services Task Force. Ann Intern Med. 2007; 147:135-42.
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U.S. Preventive Services Task Force. Screening for gonorrhea: recommendation statement. Ann Fam Med. 2005; 3:263-7.
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U.S. Preventive Services Task Force. Screening for chlamydial infection: U.S. Preventive Services Task Force recommendation statement. Ann Intern Med. 2007; 147:128-34.
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Centers for Disease Control and Prevention.  2012 Sexually Transmitted Diseases Surveillance. Accessed at www.cdc.gov/std/stats12/toc.htm on 8 July 2014.
 
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Sexually transmitted diseases treatment guidelines 2002. Centers for Disease Control and Prevention. MMWR Recomm Rep. 2002; 51:1-78.
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Workowski KA, Berman S, Centers for Disease Control and Prevention (CDC). Sexually transmitted diseases treatment guidelines, 2010. MMWR Recomm Rep. 2010; 59:1-110.
PubMed
 
Røttingen JA, Cameron DW, Garnett GP. A systematic review of the epidemiologic interactions between classic sexually transmitted diseases and HIV: how much really is known? Sex Transm Dis. 2001; 28:579-97.
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Baeten JM, Overbaugh J. Measuring the infectiousness of persons with HIV-1: opportunities for preventing sexual HIV-1 transmission. Curr HIV Res. 2003; 1:69-86.
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Datta SD, Torrone E, Kruszon-Moran D, Berman S, Johnson R, Satter-white CL, et al. Chlamydia trachomatis trends in the United States among persons 14 to 39 years of age, 1999–2008. Sex Transm Dis. 2012; 39:92-6.
PubMed
CrossRef
 
Nelson HD, Zakher B, Cantor A, Daeges M, Pappas M. Screening for Gonorrhea and Chlamydia: Systematic Review to Update the U.S. Preventive Services Task Force Recommendations. AHRQ Publication No. 13-05184-EF-1. Rockville, MD: Agency for Healthcare Research and Quality; 2014.
 
U.S. Preventive Services Task Force.  Procedure Manual. Accessed at www.uspreventiveservicestaskforce.org/uspstf08/methods/procmanual.htm on 15 April 2014.
 
Harris RP, Helfand M, Woolf SH, Lohr KN, Mulrow CD, Teutsch SM, et al, Methods Work Group, Third U.S. Preventive Services Task Force. Current methods of the U.S. Preventive Services Task Force: a review of the process. Am J Prev Med. 2001; 20:21-35.
PubMed
CrossRef
 
Centers for Disease Control and Prevention (CDC). Recall of LCx Neisseria gonorrhoeae assay and implications for laboratory testing for N. gonorrhoeae and Chlamydia trachomatis. MMWR Morb Mortal Wkly Rep. 2002; 51:709.
PubMed
 
Scholes D, Stergachis A, Heidrich FE, Andrilla H, Holmes KK, Stamm WE. Prevention of pelvic inflammatory disease by screening for cervical chlamydial infection. N Engl J Med. 1996; 334:1362-6.
PubMed
CrossRef
 
Ostergaard L, Andersen B, Møller JK, Olesen F. Home sampling versus conventional swab sampling for screening of Chlamydia trachomatis in women: a cluster-randomized 1-year follow-up study. Clin Infect Dis. 2000; 31:951-7.
PubMed
CrossRef
 
Oakeshott P, Kerry S, Aghaizu A, Atherton H, Hay S, Taylor-Robinson D, et al. Randomised controlled trial of screening for Chlamydia trachomatis to prevent pelvic inflammatory disease: the POPI (Prevention of Pelvic Infection) trial. BMJ. 2010; 340:c1642.
PubMed
CrossRef
 
Miller WC, Hoffman IF, Owen-O'Dowd J, McPherson JT, Privette A, Schmitz JL, et al. Selective screening for chlamydial infection: which criteria to use? Am J Prev Med. 2000; 18:115-22.
PubMed
CrossRef
 
Götz HM, Veldhuijzen IK, Habbema JD, Boeke AJ, Richardus JH, Steyerberg EW. Prediction of Chlamydia trachomatis infection: application of a scoring rule to other populations. Sex Transm Dis. 2006; 33:374-80.
PubMed
CrossRef
 
Chernesky MA, Martin DH, Hook EW, Willis D, Jordan J, Wang S, et al. Ability of new APTIMA CT and APTIMA GC assays to detect Chlamydia trachomatis and Neisseria gonorrhoeae in male urine and urethral swabs. J Clin Microbiol. 2005; 43:127-31.
PubMed
CrossRef
 
Taylor SN, Liesenfeld O, Lillis RA, Body BA, Nye M, Williams J, et al. Evaluation of the Roche cobas CT/NG test for detection of Chlamydia trachomatis and Neisseria gonorrhoeae in male urine. Sex Transm Dis. 2012; 39:543-9.
PubMed
CrossRef
 
Van Der Pol B, Liesenfeld O, Williams JA, Taylor SN, Lillis RA, Body BA, et al. Performance of the cobas CT/NG test compared to the Aptima AC2 and Viper CTQ/GCQ assays for detection of Chlamydia trachomatis and Neisseria gonorrhoeae. J Clin Microbiol. 2012; 50:2244-9.
PubMed
CrossRef
 
Van Der Pol B, Taylor SN, Lebar W, Davis T, Fuller D, Mena L, et al. Clinical evaluation of the BD ProbeTec Neisseria gonorrhoeae Qx amplified DNA assay on the BD Viper system with XTR technology. Sex Transm Dis. 2012; 39:147-53.
PubMed
CrossRef
 
Stewart CM, Schoeman SA, Booth RA, Smith SD, Wilcox MH, Wilson JD. Assessment of self taken swabs versus clinician taken swab cultures for diagnosing gonorrhoea in women: single centre, diagnostic accuracy study. BMJ. 2012; 345:e8107.
PubMed
CrossRef
 
Gaydos CA, Van Der Pol B, Jett-Goheen M, Barnes M, Quinn N, Clark C, et al, CT/NG Study Group. Performance of the Cepheid CT/NG Xpert Rapid PCR Test for Detection of Chlamydia trachomatis and Neisseria gonorrhoeae. J Clin Microbiol. 2013; 51:1666-72.
PubMed
CrossRef
 
Schachter J, McCormack WM, Chernesky MA, Martin DH, Van Der Pol B, Rice PA, et al. Vaginal swabs are appropriate specimens for diagnosis of genital tract infection with Chlamydia trachomatis. J Clin Microbiol. 2003; 41:3784-9.
PubMed
CrossRef
 
Shrier LA, Dean D, Klein E, Harter K, Rice PA. Limitations of screening tests for the detection of Chlamydia trachomatis in asymptomatic adolescent and young adult women. Am J Obstet Gynecol. 2004; 190:654-62.
PubMed
CrossRef
 
Taylor SN, Van Der Pol B, Lillis R, Hook EW 3rd, Lebar W, Davis T, et al. Clinical evaluation of the BD ProbeTec Chlamydia trachomatis Qx amplified DNA assay on the BD Viper system with XTR technology. Sex Transm Dis. 2011; 38:603-9.
PubMed
CrossRef
 
Schoeman SA, Stewart CM, Booth RA, Smith SD, Wilcox MH, Wilson JD. Assessment of best single sample for finding chlamydia in women with and without symptoms: a diagnostic test study. BMJ. 2012; 345:e8013.
PubMed
CrossRef
 
Pimenta JM, Catchpole M, Rogers PA, Hopwood J, Randall S, Mallinson H, et al. Opportunistic screening for genital chlamydial infection. II: prevalence among healthcare attenders, outcome, and evaluation of positive cases. Sex Transm Infect. 2003; 79:22-7.
PubMed
CrossRef
 
Andersen B, van Valkengoed I, Sokolowski I, Møller JK, Østergaard L, Olesen F. Impact of intensified testing for urogenital Chlamydia trachomatis infections: a randomised study with 9-year follow-up. Sex Transm Infect. 2011; 87:156-61.
PubMed
CrossRef
 
Low N, Egger M, Sterne JA, Harbord RM, Ibrahim F, Lindblom B, et al. Incidence of severe reproductive tract complications associated with diagnosed genital chlamydial infection: the Uppsala Women's Cohort Study. Sex Transm Infect. 2006; 82:212-8.
PubMed
CrossRef
 
van den Broek IV, van Bergen JE, Brouwers EE, Fennema JS, Götz HM, Hoebe CJ, et al. Effectiveness of yearly, register based screening for chlamydia in the Netherlands: controlled trial with randomised stepped wedge implementation. BMJ. 2012; 345:e4316.
PubMed
CrossRef
 
Scholes D, Satterwhite CL, Yu O, Fine D, Weinstock H, Berman S. Long-term trends in Chlamydia trachomatis infections and related outcomes in a U.S. managed care population. Sex Transm Dis. 2012; 39:81-8.
PubMed
CrossRef
 
Gaydos CA, Barnes M, Jett-Goheen M, Quinn N, Whittle P, Hogan T, et al. Characteristics and predictors of women who obtain rescreening for sexually transmitted infections using the www.iwantthekit.org screening programme. Int J STD AIDS. 2013; 24:736-44.
PubMed
CrossRef
 
Centers for Disease Control and Prevention. Recommendations for the laboratory-based detection of Chlamydia trachomatis and Neisseria gonorrhoeae—2014. MMWR Recomm Rep. 2014; 63:1-19.
PubMed
 
Gottlieb SL, Stoner BP, Zaidi AA, Buckel C, Tran M, Leichliter JS, et al. A prospective study of the psychosocial impact of a positive Chlamydia trachomatis laboratory test. Sex Transm Dis. 2011; 38:1004-11.
PubMed
CrossRef
 
Kangas I, Andersen B, Olesen F, Møller JK, Østergaard L. Psychosocial impact of Chlamydia trachomatis testing in general practice. Br J Gen Pract. 2006; 56:587-93.
PubMed
 
Campbell R, Mills N, Sanford E, Graham A, Low N, Peters TJ, Chlamydia Screening Studies (ClaSS) Group. Does population screening for Chlamydia trachomatis raise anxiety among those tested? Findings from a population based chlamydia screening study. BMC Public Health. 2006; 6:106.
PubMed
CrossRef
 
Low N, McCarthy A, Macleod J, Salisbury C, Campbell R, Roberts TE, et al, Chlamydia Screening Studies Project Group. Epidemiological, social, diagnostic and economic evaluation of population screening for genital chlamydial infection. Health Technol Assess.. 2007; 11:iii–iv, ix–xii, 1-165.
PubMed
CrossRef
 
Hood EE, Nerhood RC. The utility of screening for chlamydia at 34-36 weeks gestation. W V Med J. 2010; 106:10-1.
PubMed
 
Miller JM, Maupin RT, Nsuami M. Initial and repeat testing for chlamydia during pregnancy. J Matern Fetal Neonatal Med. 2005; 18:231-5.
PubMed
CrossRef
 
Blas MM, Canchihuaman FA, Alva IE, Hawes SE. Pregnancy outcomes in women infected with Chlamydia trachomatis: a population-based cohort study in Washington State. Sex Transm Infect. 2007; 83:314-8.
PubMed
CrossRef
 
Alexander S, Ison C, Parry J, Llewellyn C, Wayal S, Richardson D, et al, Brighton Home Sampling Kits Steering Group. Self-taken pharyngeal and rectal swabs are appropriate for the detection of Chlamydia trachomatis and Neisseria gonorrhoeae in asymptomatic men who have sex with men. Sex Transm Infect. 2008; 84:488-92.
PubMed
CrossRef
 
Marcus JL, Bernstein KT, Kohn RP, Liska S, Philip SS. Infections missed by urethral-only screening for chlamydia or gonorrhea detection among men who have sex with men. Sex Transm Dis. 2011; 38:922-4.
PubMed
CrossRef
 
Schachter J, Moncada J, Liska S, Shayevich C, Klausner JD. Nucleic acid amplification tests in the diagnosis of chlamydial and gonococcal infections of the oropharynx and rectum in men who have sex with men. Sex Transm Dis. 2008; 35:637-42.
PubMed
CrossRef
 
Bissessor M, Tabrizi SN, Fairley CK, Danielewski J, Whitton B, Bird S, et al. Differing Neisseria gonorrhoeae bacterial loads in the pharynx and rectum in men who have sex with men: implications for gonococcal detection, transmission, and control. J Clin Microbiol. 2011; 49:4304-6.
PubMed
CrossRef
 
Kent CK, Chaw JK, Wong W, Liska S, Gibson S, Hubbard G, et al. Prevalence of rectal, urethral, and pharyngeal chlamydia and gonorrhea detected in 2 clinical settings among men who have sex with men: San Francisco, California, 2003. Clin Infect Dis. 2005; 41:67-74.
PubMed
CrossRef
 

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Supplements

Supplemental Content
Supplement 1. Analytic framework and key questions for screening men and nonpregnant women, including adolescents.
Supplemental Content
Supplement 2. Analytic framework and key questions for screening pregnant women.
Supplemental Content
Supplement 3. MEDLINE Search Strategies
Supplemental Content
Supplement 4. Literature flow diagram.
Supplemental Content
Supplement 5. Randomized, Controlled Trials of Screening for Chlamydia to Reduce Adverse Health Outcomes
Supplemental Content
Supplement 6. Diagnostic Accuracy of Nucleic Acid Amplification Tests for Gonorrhea Screening
Supplemental Content
Supplement 7. Diagnostic Accuracy of Nucleic Acid Amplification Tests for Chlamydia Screening

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