Skip directly to site content Skip directly to page options Skip directly to A-Z link Skip directly to A-Z link Skip directly to A-Z link
Volume 29, Number 10—October 2023
Research

Treponema pallidum Detection at Asymptomatic Oral, Anal, and Vaginal Sites in Adults Reporting Sexual Contact with Persons with Syphilis

On This Page
Methods
Results
Discussion
Cite This Article
Figures
Figure
Tables
Table 1
Table 2
Table 3
Table 4
Table 5
Downloads
Article
RIS [TXT - 2 KB]
Article Metrics
Metric Details
Related Articles
Locally Acquired Lyme Disease, North Carolina
Acute Gastroenteritis Associated with Norovirus GII.8[P8], Thailand, 2023
Investigation of Possible Link Between Interferon-α and Lyme Disease
More articles on Lyme Disease
Author affiliations: Melbourne Sexual Health Centre, Alfred Health, Melbourne, Victoria, Australia (E.T. Aung, C.K. Fairley, J.M. Towns, R. Wigan, E.P.F. Chow, M.Y. Chen); Central Clinical School, Monash University, Melbourne (E.T. Aung, C.K. Fairley, J.M. Towns, E.P.F. Chow, M.Y. Chen); The Doherty Institute for Infection and Immunity, Melbourne (D.A. Williamson); Victorian Infectious Diseases Reference Laboratory, Melbourne (D.A. Williamson, F. Azzato); Melbourne School of Population and Global Health, The University of Melbourne, Melbourne (E.P.F. Chow)

Cite This Article

Abstract

We investigated Treponema pallidum PCR positivity at mucosal sites (oral, anal, and vaginal sites) among adults who had sexual contact with a person with syphilis (syphilis contacts). All syphilis contacts had oral rinse and swab samples collected for testing. Men who have sex with men had anal swab and women had vaginal swab samples collected for testing, regardless of the presence of lesions. Of 407 persons tested, 42 (10%) had early syphilis diagnosed; of those, 19 (45%) tested positive by PCR from any anatomic site and had a positive serologic test. T. pallidum was positive from vaginal samples in 3 women, anal samples in 3 men, and oral cavity samples in 2 women and 3 men, without symptoms at those sites. Three women had no prior syphilis serologic test. T. pallidum detection at asymptomatic mucosal sites suggests early syphilis infections, particularly in cases that would conventionally be staged as latent syphilis of unknown duration.

Syphilis, caused by Treponema pallidum, results in substantial disease and death if left untreated. The World Health Organization (WHO) estimated a global burden of 6 million new syphilis infections in 2018, and syphilis remains a major public health challenge (1). High incidence of syphilis continues to persist among men who have sex with men (MSM) in high-income countries (2,3). Increases in syphilis among heterosexual populations and congenital syphilis have also been reported in many countries, including Australia (4). Early detection and treatment are essential in reducing the infectious period and transmission. Developing interventions aimed at improving syphilis control, including methods that can detect syphilis infection as early as possible, is essential.

To identify early syphilis infection, persons who are at risk for syphilis infection should undergo screening. The conventional method for syphilis screening involves serologic testing, which consists of detecting T. pallidum antibodies by using T. pallidum–specific and nonspecific tests (5,6). However, a challenge with this method is the window period between the infection onset and the appearance of antibodies in very early syphilis, which can lead to a negative serologic result during that period, causing the infection to go undetected. Moreover, the sensitivity and specificity of T. pallidum–specific and –nonspecific serologic tests for syphilis vary by stages of infection (7,8). For example, T. pallidum–nonspecific tests are less sensitive in detecting primary syphilis (62%–78%) than in detecting secondary syphilis (97%–100%) (7). T. pallidum–specific tests such as immunoassays have a wide range of sensitivities for detecting primary syphilis (78%–96%), varying according to the specific immunoassay used (9). Furthermore, those T. pallidum–specific immunoassays demonstrate persistent presence of treponemal antibodies in patients previously treated for syphilis (9), which can sometimes pose challenges in identifying a very early new syphilis infection when treponemal antibodies are present and T. pallidum–nonspecific tests are nonreactive. Therefore, laboratory methods that can enhance detection of very early syphilis infections are needed.

Nucleic acid amplification tests (NAATs) such as PCR for T. pallidum have been shown to be highly sensitive for the detection of primary syphilis lesions (1014), showing sensitivity ranging from 80% to 95% (1317). Recent studies have shown T. pallidum is detectable by PCR not only from primary syphilis lesions at genital sites but also from other sites and sample types, including the anal canal, oral cavity, saliva, and urine (14,1823). A study from the Netherlands detected T. pallidum by PCR in various mucosal tissues and body fluids in the early stages of syphilis, even in the absence of lesions (20). Those findings indicate that PCR can detect T. pallidum in the early stages of syphilis, with or without lesions at various mucosal sites. Consequently, PCR may be useful in detecting syphilis in asymptomatic persons at high risk before seroconversion takes place.

In this study, we undertook PCR testing for T. pallidum from adults who reported sexual contact with a person with syphilis by using oral, vaginal, and anal samples, even when symptoms and signs of syphilis were not reported from those sites. We hypothesized that some of those persons would have very early syphilis infection and T. pallidum would be detectable from those sites in the absence of lesions. We sought to determine whether PCR detection at those locations might precede the appearance of syphilis antibodies on serologic testing.

Methods

In this cross-sectional study, we included men and women who reported sexual contact with a person with syphilis infection (hereafter, syphilis contacts), provided consent to having PCR testing for syphilis, and visited the Melbourne Sexual Health Centre (MSHC) during November 2018–March 2020. The study was approved by the Alfred Hospital Ethics Committee, Melbourne, Australia (project no. 474/18). MSHC is a public sexual health and HIV clinic in the state of Victoria, Australia, and provides ≈50,000 consultations/year. The clinic has an electronic medical record system that stores demographic and epidemiologic data.

Clients seeking care at the clinics were evaluated by a nurse after their registration. The nurse typically collects a brief account of the clients’ current condition and adds this information to their medical records before assigning them to healthcare professionals. Persons who had been in sexual contact with someone diagnosed with syphilis were identified on the basis of their own report. Those persons were notified about their exposure through either anonymous text messages or direct communication from the persons who had been in contact with them.

Contacts of syphilis were provided with a plain-language participant information sheet explaining PCR testing from mucosal sites. Verbal consent was obtained from those who agreed to have the T. pallidum PCR tests from the mucosal sites. The clinicians collected oral swab samples (all participants), anal swab samples (MSM only), and vaginal swab samples (women only) by using the Universal Transport Medium swab (Copan Italia, https://www.copangroup.com) for T. pallidum PCR testing. Participants also self-collected an oral rinse by gargling 10 mL of sterile water for T. pallidum PCR (i.e., mucosal screening PCR tests). T. pallidum PCR testing also was performed on swab samples taken from any syphilis lesions present (i.e., lesion PCR tests).

Participants who reported having symptoms suggestive of syphilis, such as anogenital or oral lesions, were examined by the clinician at the respective sites, and swab samples were taken from any lesion for T. pallidum PCR testing. Vaginal examinations were performed by using speculum if a woman reported any genital lesions or symptoms, and anoscopic examination was performed where a participant reported an anorectal lesion. Whether or not a participant required vaginal speculum or anoscopic examination was a decision made by the clinician on clinical grounds. We collected data on clinical examination findings retrospectively.

All participants had syphilis serologic testing performed and were offered syphilis treatment with intramuscular benzathine penicillin (2.4 mU single dose) or doxycycline (100 mg 2×/d for 2 weeks) for those with penicillin allergy. The participants were offered routine chlamydia and gonorrhea testing according to sexual transmitted infection (STI) testing guidelines depending on their sexual risk (25,26). If persons were diagnosed with syphilis infection and considered to have latent syphilis of unknown duration, they were asked to return for further treatment with a total of 3 doses of weekly benzathine penicillin (or 4 weeks of doxycycline for those with penicillin allergy).

We defined MSM as men who have sex with men or with transwomen and bisexual as either men or women who had sex with both men and women (including transgender persons). We defined heterosexual as either men or women who had sex only with the opposite sex. We defined sexuality on the basis of self-reported sexual practice in the last 12 months and not on sexual identity.

E.T.A. reviewed medical records to capture information on types of partners (regular vs. casual), type of sex (anal, vaginal, or oral sex), condom use (condomless vs. with condoms), and signs and symptoms of syphilis at consultation. The information on types of partners was self-reported, and no formal definition of regular and casual partners was used in the study. Some participants might have defined regular partners as romantic partners (e.g., boyfriends or husbands) or casual sexual partners as regular contacts without romantic attachment (24).

Laboratory Methods

We tested specimens at the Victorian Infectious Diseases Reference Laboratory (VIDRL; Melbourne, VIC, Australia), by using a TaqMan real-time PCR (ThermoFisher, https://www.thermofisher.com) targeting the polA gene of T. pallidum (15). We extracted DNA by using the Quick DNA/RNATM MagBead Extraction kit (Zymo Research, https://www.zymoresearch.com) on the Tecan Freedom EVO 100 automated system (Tecan, https://lifesciences.tecan.com). The PCR was designed at VIDRL by using the Primer Express software program (ThermoFisher, https://www.thermofisher.com), and the details of the T. pallidum PCR testing are described elsewhere (15). For a positive T. pallidum PCR sample, we reported a cycle threshold, which reflects the amount of nucleic acid in the sample.

We assessed serologic testing for syphilis by using a chemiluminescence immunoassay (CLIA) (DiaSorin, https://www.diasorin.com) and then confirmed results by using T. pallidum Particle Agglutination assay (TPPA) (https://www.fujirebio.com) and Rapid Plasma Reagin (RPR) (Becton Dickinson, https://www.bd.com). We performed routine screening for chlamydia and gonorrhea with NAAT by using Hologic Panther System Aptima Combo 2 assay (Hologic https://www.hologic.com) on the urine samples, vaginal swab samples, pharyngeal swab samples, and anal swab samples. We performed those screenings in line with MSHC testing guidelines and Australia’s STI guidelines (25,26). We obtained separate anal and oral swab samples for T. pallidum PCR and chlamydia and gonorrhea testing. We tested for herpes simplex virus from genital lesions by using an in-house TaqMan real-time PCR, targeting the glycoprotein B gene. We tested for Mycoplasma genitalium by using the ResistancePlus MG Assay (SpeeDx, https://plexpcr.com). We performed HIV screening by using the DiaSorin Liaison XL Murex HIV Ab/Ag chemiluminescence immunoassay (4th generation) and confirmed results by using Western blot.

Identifying of Syphilis Cases

We identified all new syphilis cases by using laboratory classifications for early infectious syphilis and latent syphilis from the Australia Department of Health and the US Centers for Disease Control and Prevention (27,28). Of note, early latent syphilis in Australia is defined as syphilis infection acquired within the previous 24 months with no clinical evidence of syphilis (28). Staging of syphilis was undertaken by a senior sexual health physician, who determined the staging on the basis of the medical record and laboratory results, including results from external healthcare services.

Statistical Analysis

We reported categorical variables as frequencies and percentages and continuous variables as medians and interquartile ranges (IQRs). We defined syphilis diagnosis as testing positive by T. pallidum PCR, serologic testing, or both. We calculated 95% CIs for syphilis diagnoses by using a binomial proportion CI. The study was stopped in March 2020 because of the COVID-19 pandemic. We performed all analyses by using Stata version 16 (StataCorp LLC, https://www.stata.com).

Results

A total of 407 contacts had >1 specimen for PCR screening (oral and anal in MSM, oral in heterosexual men, and oral and vaginal in women). Of the 407 contacts, 339 were MSM, 22 were heterosexual men, 20 were heterosexual women, 1 was a bisexual woman, and 25 were bisexual men. Among the contacts living with HIV (16%, n = 67), most were MSM (94%, n = 63); one third of contacts (33%, n = 134) were using HIV preexposure prophylaxis. One fifth of the contacts (20%, n = 85) had a history of syphilis infection, and a small number (9%, n = 35) reported ever injecting drugs. The median age of the syphilis contacts was 32 years (IQR 27–40 years).

Nearly half (47%, n = 193) of the contacts reported having a casual partner as their syphilis contact, whereas 35% (n = 144) reported a regular partner as the contact. Most (71%, n = 290) contacts reported condomless sex during anal or vaginal sex, and 17% (n = 69) had signs or symptoms suggestive of syphilis (Table 1).

Figure

Flowchart of syphilis infections among men and women who had contact with persons who had syphilis, categorized by positive PCR and serologic test results and presence or absence of symptoms, in retrospective study of patients who visited the Melbourne Sexual Health Centre, Melbourne, Victoria, Australia, during November 2018–March 2020.

Figure. Flowchart of syphilis infections among men and women who had contact with persons who had syphilis, categorized by positive PCR and serologic test results and presence or absence of symptoms,...

A total of 42 contacts (10%, 95% CI 8%–14%) had syphilis infection diagnosed (case-patients) (Figure). Of those, 33 were MSM, 5 were women, 2 were heterosexual men, and 3 were bisexual men. Syphilis was detected by positive serologic testing alone in the absence of positive PCR in 21 cases (50%, 95% CI 34%–66%). Nineteen cases (45%, 95% CI 30%–61%) were detected by positive serologic tests together with positive T. pallidum PCR; 9 of those case-patients had T. pallidum detected by PCR from >1 mucosal sites (oral, anal, or vaginal) in the absence of lesions at these sites (Table 2). The remaining 10 of the 19 case-patients had signs and symptoms suggestive of syphilis and were T. pallidum–positive from mucosal sites, lesions sites, or both (Table 3). Of the 42 syphilis case-patients, 2 had T. pallidum PCR detected from penile lesions with a negative serologic test. Because those 2 case-patients had T. pallidum PCR detected only from lesion PCR tests, they are not discussed further.

Syphilis Cases Detected by T. pallidum PCR and Serologic Testing

Among the 9 asymptomatic case-patients (i.e., PCR positive and no visible lesions), 4 were women, 4 were MSM, and 1 was a bisexual man. The median age was 27 years (IQR 24–31 years). T. pallidum PCR was detected from >1 of the mucosal screening PCR tests (58% [95% CI 37%–78%], 14/24): oral swab, oral rinse, anal swab, or vaginal swab (Table 2). The RPR titer ranged from nonreactive to 1:256 (median RPR 1:32, IQR 1:8–1:128).

Among the 10 symptomatic case-patients (i.e., PCR positive and visible lesions), 1 was a woman, 8 were MSM, and 1 was a bisexual man. The median age was 32 years (IQR 24–39 years). In this group, 69% (95% CI 52%–83%, 27/39) of T. pallidum PCR specimens were positive from the mucosal screening PCR tests, the lesion PCR tests, or both. The RPR titer ranged from 1:32 to 1:256 (median RPR 1:64, IQR 1:32–1:128) (Table 3). Of the 10 symptomatic case-patients, 7 had positive PCR from mucosal screening sites with or without positive PCR from lesion sites. Among these 7 case-patients, 5 had positive PCR only from mucosal screening sites; 3 had signs and symptoms of secondary syphilis. Two case-patients had positive PCR from both mucosal screening sites and lesion sites (Table 3).

Syphilis Cases Detected by Positive Serologic Tests in the Absence of T. pallidum PCR Detection

Twenty-one case-patients had positive syphilis serologic tests but no positive T. pallidum screening results (lesion PCR was not performed) (Table 4). This group included 19 MSM, 1 heterosexual man, and 1 bisexual man. The median age in this group was 33 years (IQR 28–40 years). Most (86%, 18/21) were asymptomatic for syphilis except 3 case-patients. Two men with symptoms had secondary syphilis diagnosed and had a generalized body rash. One man with symptoms had a headache and blurred vision, consistent with symptoms of neurosyphilis, and a resolving body rash. T. pallidum lesion PCR tests were not performed on the 3 men with symptoms. The RPR titer ranged from nonreactive to 1:128 (median RPR 1:4, IQR nonreactive to 1:32).

Positivity of T. pallidum PCR

The positivity of T. pallidum PCR from the mucosal screening tests (oral, anal, and vaginal sites) was 3% (95% CI 2%–5%; n = 24) from 776 specimens, whereas the positivity from the suspected syphilis lesions was 16% (95% CI 7%–30%; n = 8) from 50 specimens tested from various sites, such as the penis, perianal, scrotum, and tongue (Table 5). The concordance of oral rinse (2%, 8/387) and oral swab (3%, 11/352) PCR was 99% (n = 352/355).

Presence or Absence of Signs and Symptoms of Syphilis

Among 338 asymptomatic contacts, 8% (27, 95% CI 5–11) had syphilis infection diagnosed on the basis of positive serologic tests with or without positive T. pallidum PCR results. Of the 338 contacts, 56% (180/338) received an examination. Among 69 contacts with signs and symptoms of syphilis, 22% (15, 95% CI 13–33) had syphilis infection diagnosed on the basis of positive serologic tests, positive T. pallidum PCR, or both.

Co-infection with Other STIs

A total of 32 contacts (8%, 32/407) had >1 STI other than syphilis diagnosed. All of them were MSM, and among them, 6 had syphilis diagnosed. Five had syphilis diagnosed on positive PCR and serologic testing, whereas 1 had syphilis diagnosed on a positive serologic test alone. Among the 32 contacts, 17 were positive for chlamydia, and 12 contacts were positive for gonorrhea. Five contacts were positive for Mycoplasma genitalium infection, and 2 contacts tested positive for anal herpes simplex virus. Among the STIs other than syphilis, anorectal chlamydia was the most common infection (n = 15).

Discussion

In this study of men and women reporting sexual contact with a person with syphilis, we did not identify any persons with PCR detection of T. pallidum from oral, anal, or vaginal sites where serologic testing was negative, indicating that using PCR for screening of syphilis contacts at mucosal sites might not provide any additional benefit over existing syphilis screening using serologic testing. However, we found a proportion of men and women who tested positive for T. pallidum by PCR from the oral cavity, anus, or vagina in the absence of signs or symptoms of syphilis at those sites or elsewhere. In some cases, serologic testing for syphilis was positive in the absence of negative serologic testing within the previous 2 years. Those persons would conventionally be staged as having latent syphilis of unknown duration, and they probably were treated for possible late latent infection. However, detection of T. pallidum by PCR from oral, anal, or vaginal sites, in conjunction with the syphilis contact status, suggests that those infections probably were early asymptomatic infections.

The findings indicate that PCR-based testing for T. pallidum at mucosal sites may be useful in assisting with staging of syphilis infection. Consequently, this approach could provide guidance to clinicians and patients regarding treatment duration. Furthermore, T. pallidum PCR testing at mucosal sites has the potential to aid in partner notification, particularly in cases where an early infectious syphilis is diagnosed and the duration of infection is uncertain. T. pallidum PCR may complement current methods of staging, which rely on various factors, including the presence of signs of early syphilis, the patient’s history of syphilis and treatment, sexual history (including contact with a partner with syphilis infection), and past and current laboratory results (including serologic testing and direct detection methods using molecular assays).

We identified several asymptomatic women who had positive syphilis serologic testing and PCR detection of T. pallidum from the mucosal screening sites (the vagina, oral cavity, or both). Those women had never been serologically tested for syphilis before or had been tested >2 years previously. We also identified several asymptomatic MSM who had positive syphilis serologic testing and PCR detection of T. pallidum from the anus, oral cavity, or both. In contrast to the women, all those men had been serologically tested for syphilis within the previous 2 years. The difference in serologic testing between women and men reflects frequent serologic screening for syphilis being well established among MSM in Australia but less so among women in urban centers because syphilis has only emerged as a major public health concern among women in that setting in recent years.

Several studies have examined the role of NAAT in syphilis screening (20,29). A US study compared the use of transcription-mediated amplification (TMA) assay performed on rectal and pharyngeal mucosa in MSM with routine serologic testing and found 2 additional syphilis cases diagnosed on TMA testing before positive serologic testing (29). Patients in both cases had TMA detection in rectal swabs: 1 did not have symptoms, and the other had anal symptoms. In contrast, our study did not identify syphilis cases diagnosed on T. pallidum PCR from mucosal sites before positive serologic testing.

In our study, we found that 40% of the 42 confirmed early syphilis cases among men and women had PCR detection of T. pallidum from >1 of the mucosal sites (oral, anus, and vagina), with or without lesions at these sites. Of note, we show PCR detection of T. pallidum in asymptomatic women. T. pallidum detection by PCR in women has been shown in other studies but predominantly from genital lesions (16,3032). The presence of T. pallidum at those mucosal sites may represent the site of inoculation (and hidden primary lesions) or dissemination from a distant site (19). Several other recent studies showed that T. pallidum can be detected from the oral cavity or anus of men and women with early syphilis infection (1823). Detection of T. pallidum by PCR was reported in ≈24% of 200 MSM with confirmed early syphilis infection with or without lesions at the oral cavity and anus (18). Those studies suggest that syphilis probably is infectious from oral, anal, and vaginal sites in the absence of local signs and symptoms.

The first limitation of our study is that it was terminated prematurely because of the COVID-19 pandemic, which limited the sample size. The number of women in the study was small because the clinic population was predominantly male, and fewer women attended. The sexual partners reported by contacts might not have actually had syphilis, given that we were unable to confirm their diagnosis; if so, we may have overestimated syphilis infections in this study group. Not all contacts who self-reported that they were asymptomatic had examination of oral, vaginal, and anal sites by the clinician (46% did not undergo examination), which could have led to occult lesions at those sites being missed. The T. pallidum PCR we used might have lower sensitivity than other T. pallidum molecular assays, such as TMA, resulting in a lower number of PCR-positive mucosal screening tests (29,33). Further, current data are not sufficient to indicate that T. pallidum PCR positivity at a mucosal site is a proof of early syphilis infection. T. pallidum might reflect contamination from very recent sexual intercourse with a person with syphilis infection, such as residual semen at the mucosal site.

Overall, we conclude that T. pallidum PCR screening from mucosal sites (oral, anus, and vagina) may not have added benefit over screening using serologic testing. It may, however, have a role in assisting with syphilis staging, particularly in the absence of syphilis lesions. A positive PCR result from asymptomatic mucosal sites may help identify early infections in persons who would otherwise be classified as having latent syphilis of unknown duration. However, such an interpretation requires a correlation with additional sexual behavioral information and the broader clinical context. T. pallidum PCR screening at mucosal sites may be especially relevant in populations that do not undergo regular syphilis screening with serologic testing.

Dr. Aung is a sexual health physician and a PhD candidate at Melbourne Sexual Health Centre and Monash University, Australia. Her research focuses on syphilis epidemiology and early detection.

Top

Acknowledgments

We thank Darren Lee, who assisted with data entry and registry of specimens at VIDRL. We also acknowledge the clinicians from the Melbourne Sexual Health Centre who assisted with collection of specimens.

The data for this study are not publicly available because of privacy and ethical restrictions; however, data will be made available on reasonable request to the corresponding author, with the permission of the Alfred Hospital Ethics Committee. Restrictions apply to the availability of the data, which were used under license for this study.

This study was supported by Australia’s National Health and Medical Research Council (NHMRC) Partnership Project Grant (APP2003399). E.P.F.C. is supported by an NHMRC Emerging Leadership Investigator Grant (GNT1172873). D.A.W. is supported by an NHMRC Investigator Grant (APP1174555). C.K.F. is supported by an NHMRC Leadership Investigator Grant (GNT1172900). M.Y.C. and J.M.T. are supported by an NHMRC Partnership Project Grant (APP2003399). E.T.A. is supported by an Australia Government’s Research Training Program scholarship from Monash University and a Research Entry Scholarship from the Chapter of Sexual Health Medicine, Royal Australasian College of Physicians.

Author contributions: M.Y.C. and E.P.F.C. designed the study. M.Y.C., E.P.F.C., C.K.F. and R.W. coordinated the study and contributed to the development of the study protocol. D.A.W. and F.A. performed laboratory testing. E.T.A. collected data, performed the analysis of the data, performed chart review, wrote the first draft of the manuscript, and revised the manuscript. All authors reviewed and edited the manuscript. All authors read and approved the final manuscript.

Top

References

  1. World Health Organization. Report on global sexually transmitted infection surveillance, 2018. Geneva: World Health Organization; 2018.
  2. Tsuboi  M, Evans  J, Davies  EP, Rowley  J, Korenromp  EL, Clayton  T, et al. Prevalence of syphilis among men who have sex with men: a global systematic review and meta-analysis from 2000-20. Lancet Glob Health. 2021;9:e11108. DOIPubMedGoogle Scholar
  3. Kojima  N, Klausner  JD. An update on the global epidemiology of syphilis. Curr Epidemiol Rep. 2018;5:2438. DOIPubMedGoogle Scholar
  4. Aung  ET, Chen  MY, Fairley  CK, Higgins  N, Williamson  DA, Tomnay  JE, et al. Spatial and temporal epidemiology of infectious syphilis in Victoria, Australia, 2015–2018. Sex Transm Dis. 2021;48:e17882. DOIPubMedGoogle Scholar
  5. Luo  Y, Xie  Y, Xiao  Y. Laboratory diagnostic tools for syphilis: current status and future prospects. Front Cell Infect Microbiol. 2021;10:574806. DOIPubMedGoogle Scholar
  6. Peeling  RW, Mabey  D, Kamb  ML, Chen  X-S, Radolf  JD, Benzaken  AS. Syphilis. Nat Rev Dis Primers. 2017;3:17073. DOIPubMedGoogle Scholar
  7. Tuddenham  S, Katz  SS, Ghanem  KG. Syphilis laboratory guidelines: performance characteristics of nontreponemal antibody tests. Clin Infect Dis. 2020;71(Suppl 1):S2142. DOIPubMedGoogle Scholar
  8. Park  IU, Tran  A, Pereira  L, Fakile  Y. Sensitivity and specificity of treponemal-specific tests for the diagnosis of syphilis. Clin Infect Dis. 2020;71(Suppl 1):S1320. DOIPubMedGoogle Scholar
  9. Park  IU, Fakile  YF, Chow  JM, Gustafson  KJ, Jost  H, Schapiro  JM, et al. Performance of treponemal tests for the diagnosis of syphilis. Clin Infect Dis. 2019;68:9138. DOIPubMedGoogle Scholar
  10. Heymans  R, van der Helm  JJ, de Vries  HJ, Fennema  HS, Coutinho  RA, Bruisten  SM. Clinical value of Treponema pallidum real-time PCR for diagnosis of syphilis. J Clin Microbiol. 2010;48:497502. DOIPubMedGoogle Scholar
  11. Gayet-Ageron  A, Lautenschlager  S, Ninet  B, Perneger  TV, Combescure  C. Sensitivity, specificity and likelihood ratios of PCR in the diagnosis of syphilis: a systematic review and meta-analysis. Sex Transm Infect. 2013;89:2516. DOIPubMedGoogle Scholar
  12. Gayet-Ageron  A, Ninet  B, Toutous-Trellu  L, Lautenschlager  S, Furrer  H, Piguet  V, et al. Assessment of a real-time PCR test to diagnose syphilis from diverse biological samples. Sex Transm Infect. 2009;85:2649. DOIPubMedGoogle Scholar
  13. Shields  M, Guy  RJ, Jeoffreys  NJ, Finlayson  RJ, Donovan  B. A longitudinal evaluation of Treponema pallidum PCR testing in early syphilis. BMC Infect Dis. 2012;12:353. DOIPubMedGoogle Scholar
  14. Zhou  C, Zhang  X, Zhang  W, Duan  J, Zhao  F. PCR detection for syphilis diagnosis: Status and prospects. J Clin Lab Anal. 2019;33:e22890. DOIPubMedGoogle Scholar
  15. Leslie  DE, Azzato  F, Karapanagiotidis  T, Leydon  J, Fyfe  J. Development of a real-time PCR assay to detect Treponema pallidum in clinical specimens and assessment of the assay’s performance by comparison with serological testing. J Clin Microbiol. 2007;45:936. DOIPubMedGoogle Scholar
  16. Costa-Silva  M, Coutinho  D, Sobrinho-Simões  J, Azevedo  F, Lisboa  C. Cross-sectional study of Treponema pallidum PCR in diagnosis of primary and secondary syphilis. Int J Dermatol. 2018;57:469. DOIPubMedGoogle Scholar
  17. Theel  ES, Katz  SS, Pillay  A. Molecular and direct detection tests for Treponema pallidum subspecies pallidum: a review of the literature, 1964–2017. Clin Infect Dis. 2020;71(Suppl 1):S412. DOIPubMedGoogle Scholar
  18. Towns  JM, Leslie  DE, Denham  I, Wigan  R, Azzato  F, Williamson  DA, et al. Treponema pallidum detection in lesion and non-lesion sites in men who have sex with men with early syphilis: a prospective, cross-sectional study. Lancet Infect Dis. 2021;21:132431. DOIPubMedGoogle Scholar
  19. Towns  JM, Chow  EPF, Wigan  R, Fairley  CK, Williamson  D, Azzato  F, et al. Anal and oral detection of Treponema pallidum in men who have sex with men with early syphilis infection. Sex Transm Infect. 2022;98:5704. DOIPubMedGoogle Scholar
  20. Nieuwenburg  SA, Zondag  HCA, Bruisten  SM, Jongen  VW, Schim van der Loeff  MF, van Dam  AP, et al. Detection of Treponema pallidum DNA during early syphilis stages in peripheral blood, oropharynx, ano-rectum and urine as a proxy for transmissibility. Clin Infect Dis. 2022;75:105462. DOIPubMedGoogle Scholar
  21. Tantalo  LC, Mendoza  H, Katz  DA, Sahi  SK, Marra  CM. Detection of Treponema pallidum DNA in oropharyngeal swabs and whole blood for syphilis diagnosis. Sex Transm Dis. 2021;48:9158. DOIPubMedGoogle Scholar
  22. Wang  C, Hu  Z, Zheng  X, Ye  M, Liao  C, Shang  M, et al. A new specimen for syphilis diagnosis: evidence by high loads of Treponema pallidum DNA in saliva. Clin Infect Dis. 2021;73:e32508. DOIPubMedGoogle Scholar
  23. Yang  CJ, Chang  SY, Wu  BR, Yang  SP, Liu  WC, Wu  PY, et al. Unexpectedly high prevalence of Treponema pallidum infection in the oral cavity of human immunodeficiency virus-infected patients with early syphilis who had engaged in unprotected sex practices. Clin Microbiol Infect. 2015;21:787.e17. DOIPubMedGoogle Scholar
  24. Bellhouse  C, Walker  S, Fairley  CK, Chow  EP, Bilardi  JE. Getting the terminology right in sexual health research: the importance of accurately classifying fuck buddies among men who have sex with men. Sex Transm Infect. 2018;94:4879. DOIPubMedGoogle Scholar
  25. The Australasian Society for HIV, Viral Hepatitis and Sexual Health Medicine. Australian STI management guidelines for use in primary care. 2021 [cited 2023 Aug 1]. https://www.sti.guidelines.org.au
  26. Melbourne Sexual Health Centre. Testing guidelines. 2021 [cited 2023 Aug 1]. https://www.mshc.org.au/health-professionals/testing-guidelines
  27. Workowski  KA, Bachmann  LH, Chan  PA, Johnston  CM, Muzny  CA, Park  I, et al. Sexually transmitted infections treatment guidelines, 2021. MMWR Recomm Rep. 2021;70:1187. DOIPubMedGoogle Scholar
  28. Public Health Laboratory Network Australian Government Department of Health. Syphilis laboratory case definition, 2012 [cited 2023 Feb 20]. http://www.health.gov.au/ internet/main/publishing.nsf/Content/cda-phln-syphilis.htm
  29. Golden  M, O’Donnell  M, Lukehart  S, Swenson  P, Hovey  P, Godornes  C, et al. Treponema pallidum nucleic acid amplification testing to augment syphilis screening among men who have sex with men. J Clin Microbiol. 2019;57:e0057219. DOIPubMedGoogle Scholar
  30. Mehta  SD, Pradhan  AK, Green  SJ, Naqib  A, Odoyo-June  E, Gaydos  CA, et al. Microbial diversity of genital ulcers of HSV-2 seropositive women. Sci Rep. 2017;7:15475. DOIPubMedGoogle Scholar
  31. Noguchi  H, Tokumitsu  T, Kuroki  E, Minematsu  E, Asada  Y, Kuroda  S, et al. Detection of Treponema pallidum by immunocytochemistry of cervical smear: A case report. Diagn Cytopathol. 2021;49:E4436. DOIPubMedGoogle Scholar
  32. Grange  PA, Gressier  L, Dion  PL, Farhi  D, Benhaddou  N, Gerhardt  P, et al. Evaluation of a PCR test for detection of treponema pallidum in swabs and blood. J Clin Microbiol. 2012;50:54652. DOIPubMedGoogle Scholar
  33. Getman  D, Lin  M, Barakat  N, Skvoretz  R, Godornes  C, Swenson  P, et al. Analytical performance characteristics of a new transcription-mediated amplification assay for Treponema pallidum. J Clin Microbiol. 2021;59:e0051121. DOIPubMedGoogle Scholar

Top

Figure
Tables

Top

Cite This Article

DOI: 10.3201/eid2910.230660

Original Publication Date: September 13, 2023

1These senior authors contributed equally to this article.

Table of Contents – Volume 29, Number 10—October 2023

EID Search Options
presentation_01 Advanced Article Search – Search articles by author and/or keyword.
presentation_01 Articles by Country Search – Search articles by the topic country.
presentation_01 Article Type Search – Search articles by article type and issue.

Top

Comments

Please use the form below to submit correspondence to the authors or contact them at the following address:

Ei T Aung, Melbourne Sexual Health Centre, 580 Swanston St, Carlton, 3053, Victoria, Australia

Send To

10000 character(s) remaining.

Top

Page created: August 31, 2023
Page updated: September 20, 2023
Page reviewed: September 20, 2023
The conclusions, findings, and opinions expressed by authors contributing to this journal do not necessarily reflect the official position of the U.S. Department of Health and Human Services, the Public Health Service, the Centers for Disease Control and Prevention, or the authors' affiliated institutions. Use of trade names is for identification only and does not imply endorsement by any of the groups named above.
file_external