Abstract
Purpose
Annual screening for asymptomatic infections with Chlamydia trachomatis (CT) and Neisseria gonorrhoeae (NG) is recommended by international guidelines in people living with HIV but uptake in routine care remains poor. This study analyzed the effects of the implementation of a CT/NG screening program in a primary HIV treatment center.
Methods
In this single-center cohort study, we included men having sex with men (MSM) living with HIV during the study period from January 2016 to December 2019. From January 2018 on, annual sexual health counseling including CT/NG screening was proactively offered to all MSM presenting at the center. CT/NG screening rates, test positivity rates and case detection rates in the years 2018 and 2019 were compared to those in the years 2016 and 2017.
Results
A total of 234 patients were enrolled in the study contributing to 798.7 patient years (py) during the four-year study period. Screening rates increased from 3.1% and 3.9% in 2016 and 2017 to 51.1% in 2018 and decrease to 35.4% in 2019. Over the study period, 19.7% (46/234) had at least one positive CT/NG result. After the intervention, case detection per 100 py increased for CT (2016: 2.6, 2017: 3.7, 2018: 7.7, 2019: 7.1) and NG (2016: 3.2, 2017: 3.1, 2018: 5.3, 2019: 7.6). The number needed to test was 8.9 for CT and 10.4 for NG.
Conclusion
Regular CT/NG screening is feasible in a primary care setting, leads to an increase in case detection and may contribute to decrease transmission and complications of CT/NG.
Trial registration
The trial is registered in ClinicalTrials.gov (NCT02149004).
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Introduction
The increasing incidence of sexually transmitted infections (STIs) is a growing problem in men having sex with men (MSM), especially in those being infected with HIV, [1,2,3,4,5,6]. Epidemiological data from 2018 and 2020 of several large cities in Germany showed high prevalence for infection with Chlamydia trachomatis (8.8–9.9%), Neisseria gonorrhoeae (6.8–8.9%) and for Syphilis (1.4%) in MSM with HIV-infection, most of them reporting no symptoms (68–91%) [3, 7, 8]. The often asymptomatic course is a hallmark of many STIs; hence, a significant proportion of STIs remain undetected and serve as a reservoir for further transmission. Moreover, untreated STIs may eventually result in serious long-term sequelae. Thus, implementation of annual STI screening tests for asymptomatic STIs in MSM with HIV-infection is recommended by European guidelines as they may be beneficial for patients’ health, block transmission chains, and reduce STI prevalence [9,10,11,12,13,14].
Whereas data are lacking in Germany, studies from UK, USA, and Canada suggest that STI testing uptake in HIV cohorts remains suboptimal, especially in MSM [15,16,17,18]. In a multicenter study in several HIV cohorts in USA, annual testing rate for NG/CT was only 39% of patients engaged in care compared to 77% testing rate for syphilis, although most patients reported sexual behavior with a higher possibility for STI transmission [17].
Increasing rates of CT/NG testing in HIV clinics may be achieved by reduction of barriers at the clinician, patient, and system level [19]. Much of the above-mentioned contrast between syphilis and CT/NG testing coverage may stem from physician’s lack of time and discomfort with sexual history taking and collection of STI swabs [20, 21]. A survey analyzing the patients’ satisfaction with sexual and reproductive health (SRH) services in HIV primary care identified shortage of time, a lack of service providers’ initiative, and patients’ difficulty to address SRH topics as most relevant hindering factors for satisfying SRH services [22]. Structural or systems level interventions appear to be more effective and sustainable to improve STI screening rates than interventions on patients or clinicians level [23]. Strategic placement of specimen collection materials or automatic collection of STI specimens as part of a routine visit, the use of electronic health reminders for providers and patient reminders for screening or rescreening were among the most effective tools to enhance rates of STI testing [23]. However, effect of interventions may differ depending on the targeted population and the setting. In the setting of primary HIV care, patients are generally closely followed up over years with several annual routine appointments allowing high quality patient-provider relationships. To our knowledge, only two studies evaluated the effect of a system level intervention to increase CT/NG in the setting of HIV care [24, 25]. Introducing a combined annual anal cytology and CT/NG screening program was associated with an increased CT/NG testing rate during the short-term follow-up of 3 months.
In this study, we report the long-term effects of a system level intervention to increase CT/NG screening in a primary HIV care clinic in a mid-size city in Germany. Up from January 2018, patients were offered annual physician initiated sexual health counseling including syphilis and CT/NG screening and instructions for future low-threshold, self-collected CT/NG testing at patient’s discretion. Rates of CT/NG screening, CT/NG test positivity, and CT/NG diagnosis in a period of 2 years post implementation were compared to a 2-year pre-implementation period.
Methods
Ethics statement
The study received ethics approval from the institutional review board of the University Medical Center of the University of Freiburg (No.: 469/17/Date: 10. Oct. 2017). All PLWH were recruited in an outpatient care setting in Freiburg and provided written informed consent.
Study site/setting
This is a single-center, retrospective, longitudinal cohort study comparing a pre-intervention (01/2016–12/2017) and intervention period (01/2018–12/2019). The study took place at a specialized HIV primary care center caring for about 900 adult patients living with HIV situated in Freiburg, a regional metropolis in the south west of Germany (population of the region 2016: 2,239,734 [26]). Clinically stable patients generally present once per quarter for routine follow-up including medical history, directed physical exam, laboratory testing, and drug supply.
All HIV seropositive MSM > 18 years presenting between January 2018 and December 2019 having provided informed consent were enrolled in the study, and data were subsequently extracted from their electronic medical records. For the calculation of the months with viral load below the level of detection (VLbLOD), a blip of viremia was allowed with once detectable HIV-RNA up to 200 copies/ml [27]. Relationship status was determined by the number of sexual partners and the presence of one stable partner (changing partner = multiple sexual partners, no stable one; open relationship = multiple sexual partners, but one predominantly partner; monogamous = one stable sexual partner; group sex = frequent multiple sexual partners at the same time).
Patients were grouped in two groups according if they had a positive tests for CT or NG over the whole study period. The rate of positive tests was calculated per one hundred patient years summarizing the results of all patients counted for every year of inclusion. To assess the effort for receiving positive test results, we calculated a number needed to test according to the following formula:
Intervention
From January 2018 on, all patients were assigned to an intervention consisting in a prolonged consultation of 30 min including among others screening for risk of renal, bone, cardiovascular disease [28]. Additionally, all MSM were offered a semi-structured interview assessing relationship status (monogamous vs. changing partner vs. group sex vs. open relationship), sexual practices (active vs. not active anal sex), and condom use (always vs. not always vs. no) as well as STI screening consisting of syphilis serology (TPHA, confirmed by immunoblot; VDRL as activity parameter) and pooled nucleic acid amplification tests (NAAT) for CT and NG from oropharyngeal, urethral, and anorectal swabs. MSM were introduced to self-collection of samples and encouraged to ask for STI screening at their discretion. Clinician initiated sexual health counseling and STI testing was offered on an annual basis. Before 2018 STI counseling and testing was offered at clinician discretion depending on the sexual history or patient’s initiative and not included in a structural sexual health assessment. The included cases in the pre-screening era were asymptomatic. In case of a positive test result, the corresponding patient was informed and treated according to the respective guideline.
Statistical analysis
For assessment of differences between sociodemographic, behavioral, and HIV-specific factors, Fisher’s exact test or Chi-square test for categorical variables and Mann–Whitney U test for continuous variables were used to detect differences between groups. To further investigate the association between different factors and the risk of a positive STI test, a multivariable binominal logistic regression model was calculated. The outcome variable was defined as “Having at least one positive test for CT or NG” vs. “Having no positive test for CT or NG.” Variables were included showing a significant difference in a univariate binominal logistic regression. More than 10 observations per independent variable could be included and collinearity was checked via Variance Inflation Factor. To control for differences in the frequency of testing between different patients, the number of tests was included as a covariate term.
Differences between the pre-intervention time period (2016 and 2017) and the intervention time period (2018 and 2019) were assessed summarizing these periods for the average positive test count per quartal and analyzed by univariate linear regression. This was done to identify trends in the rate of positive tests which may be explained by underlying changes in STI incidence.
p values < 0.05 were considered to show statistical significance. All data analyses were done with pseudonymized data using R and R Studio (version 4.0.2) [29].
Results
Cohort characteristics
Our recruited cohort was comprised of 235 MSM living with HIV, whereat one patient was excluded because of missing data. In total of 234 MSM living with HIV contributed to 798.7 patient years (py) during the 4-year study period. Patients were followed up for a median of 4 years (Min–Max: 0.1–4.0 years). The median age at enrollment was 47 years (1.Q.–3.Q: 38–53 years), median time since HIV diagnosis was 6 years (1.Q.–3.Q: 3–11 years), and all patients but one were on ART since a median of 3 years (1.Q.–3.Q: 1–5 years, Table 1).
Detection of C. trachomatis, N. gonorrhoeae, and active syphilis
Positive results for CT were found in 12.8% (43/335) of all CT screening tests and 13.2% (31/234) of all patients during the study period between January 2016 and December 2019 (Tables 1 and 2). The rate of positive results for NG was 11.4% (39/341) of all NG screening tests and 10.7% (25/234) of all patients during the whole 4 years. Therefore, regarding CT 5.4 positive tests per one hundred patient years were found, quite similar to the rate of NG with 4.9 positive tests per one hundred patient years. Active Treponema pallidum infection (aTP) was diagnosed in 14.1% (33/234) of patients during the 4 years resulting in 5.9 aTP cases per one hundred patient years. Of all included patients, 23.1% (54/234) had at least once a positive test result for CT, NG, or aTP infection unnoted of the testing indication.
Effect of intervention on frequency of C. trachomatis and N. gonorrhoeae screening
In all, 62.0% of patients underwent screening for CT and NG at least once between 2016 and 2019 (Table 2, Supplement Fig. 1). After implementation of the intervention in January 2018, the proportion of yearly tested patients sharply increased from 3.1% in 2016 and 3.9% in 2017 to 51.1% in 2018 (p < 0.001) and decrease to 35.4% in 2019. There was a continuously high proportion of patients screened for syphilis throughout the whole study period.
Effect of the intervention on detection of C. trachomatis, N. gonorrhoeae, and active syphilis
After the implementation of the intervention, the positivity rates for CT and NG were approximately bisected, whereas the proportion of positive tested patients roughly doubled (Table 2). The rate of positive tests for aTP and the proportion of positive tested patients dropped after the intervention).
We also checked for a background trend by univariate linear regression of increasing number of the different STIs by quartal, but no significant increment of positive tests was found for the period before the start of the screening and after. The rate of positive tests before and after the regular screening start is shown in Fig. 1.
Number of positive tests and test positivity rate by quartal. The figure shows the proportion of positive tests [A: Chlamydia trachomatis (CT), C: Neisseria gonorrhoeae (NG)] and the total number of positive test per 100 person years [B: Chlamydia trachomatis (CT), D: Neisseria gonorrhoeae (NG)] by quartal before (blue) and after (orange) introducing of a low-threshold STI screening in men having sex with men in a German HIV cohort
We further calculated the number needed to test (NNT) to detect one case of an asymptomatic STI after the start of the screening. NNT was 8.9, 10.4, and 47.6 for one case of CT, NG, and aTP, respectively.
Whom to screen?
In the following, we compare patients with at least one positive test result for an infection by CT or NG to those with no detected infection (Table 1). Here we found a significant higher proportion of patients having changing sexual partners (p = 0.010) and a significant lower proportion having a monogamous relationship (p = 0.015). While this was also the case for patient with recurrent infection (changing partners p = 0.002, not monogamous p = 0.001), for aTP infections no significant differences could be identified.
To identify risk factors for having at least one positive screening test for CT or NG out of a set of eligible variables, we performed a univariate logistic regression analysis and subsequently a multivariate logistic regression (Table 3). Significant univariate predictors for at least one positive test result included in the multivariate regression were time living with HIV (OR 1.08; p = 0.007), having changing sexual partners (OR 4.00; p < 0.001), being between 30 and 40 years old (OR 0.43; p = 0.012) and living in a monogamous relationship (OR 0.19; p < 0.001). Overall, the model (Nagelkerke R2 = 0.606) showed only a poor improvement over the baseline model with only the number of performed tests for CT or NG (Likelihood ratio test p = 0.2815) and therefore no clear defined risk groups. ROC curve analysis for different cut-off points of numerical variables like age, CD4 count or time since HIV diagnosis also showed no favorable cut-off with a sensitivity of about 75% combined with a specificity of 50%.
Whom to re-screen repeatedly, and when?
With 7.7% (18/234) a significant proportion of the cohort was tested repeatedly positive by CT/NG screening during the study period. In total, 12 cases in 8 patients of repeated positive CT screening tests and 14 cases in 11 patients for NG were found, compared to 14 cases of aTP in 11 patients, despite more tests for aTP. Nevertheless, the larger proportion of positive patients were positive only once for any STI (53.0% (35/66)), but still a large proportion of positive tests were caused by patients with multiple positive screening tests (25.8% of all CT (8/31), 40.0% of all NG (10/25) and 33.3% of all aTP (11/33)) positive patients). The median time between two positive tests of all pathogens was about 279 days (1.Q–3.Q.: 120–457 days), higher for two positive tests for CT (median difference = 317 days), a bit lower for NG tests (median difference = 270.5 days) and much higher for aTP tests (median difference = 405 days). Differentiated for subgroups the median time between two positives tests for any STI time points varied widely for different sexual behavior (changing partners = 161 days [1.Q.–3.Q.: 77–384 days], open relationship = 309 days [1.Q.–3.Q.: 125–409.8 days] monogamous = 397 days [1.Q.–3.Q.: 167.5–886.8 days]) but were quite stable for age groups (30–40 years: 298 days [1.Q.–3.Q.: 91–397 days], 40–50 years: 281 days [1.Q.–3.Q.: 119–495.5 days], ≥ 50 years: 270.5 days [1.Q.–3.Q.: 223.5–395.5 days]).
To identify patient characteristics that could help to test patients with a high risk of having repeated STIs, we performed a second univariate logistic regression analysis with subsequent multivariate logistic regression (not shown in detail). Significant predictors for repeated positive testing visits in the multivariate logistic regression were only the time on ART (aOR = 0.47; p = 0.0417) and the number of performed CT/NG tests (aOR 2.05; p = 0.0003). Overall, the model showed a moderate fit (Nagelkerke R2 = 0.706, Likelihood ratio test p = 0.0040).
Discussion
Introducing periodic sexual health counseling and low-threshold, self-collected CT/NG screening in a primary HIV care setting showed sustained increasing CT/NG testing rates resulting in a sustained increase in case detection despite a drop in CT/NG test positivity. The proportion of patients with CT or NG were slightly higher compared to other cross-sectional studies, but comparable to one Irish study [3, 7, 8, 30]. To our best knowledge, this is currently the largest study evaluating the long-term effect of a systemic intervention to increase CT/NG screening rates in the setting of primary HIV care.
Since MSM with HIV are often exposed to discrimination and stigmatization and sexual health topics still represent a taboo issue, the use of STI related health care by MSM is still effectively influenced by shame and fear of homophobic reactions [31]. In our intervention, providers proactively addressed sexual health in a stigma-free approach creating a supportive environment, which may have encouraged many patients to openly discuss their issues and claim sexual health diagnostics. In addition, introducing and promoting of self-collection of swabs may have substantially contributed to the increase in CT/NG screening rates as it reduces workload for providers and enhances patient comfort and autonomy. Self-collected specimens show comparable sensitivity compared to provider-collected swabs [32, 33]. Our results show that this intervention on a system level yielded a substantial and persistent increase in CT/NG screening rates in the setting of primary HIV care. Interestingly, CT/NG screening rates dropped in the second year after the introduction of the intervention, while syphilis screening rate remained high. Reduced testing is probably explained by patient-perceived lower risk of infection in the follow-up testing. Indeed, especially in NG, case detection and proportion of positive tested patients increased in the second year. The long-term screening rate of 35.4% achieved in our study is in line with those published in other studies of 32–39% [15, 18, 34] and may cover most of the 42% of the population at risk of STI stating living in an open partnership or having changing partners.
Concerns exist that increased CT/NG testing rates may be countered by declines in NG/CT test positivity failing to increase overall CT/NG case detection [18, 34]. Our study showed a relevant decline in test positivity rates and increased case detection in the MSM cohort confirming results from Berry et al. showing increased case detection in the entire HIV cohort but most pronounced in the subgroup of MSM. The selection of asymptomatic patients tested in the pre-screening era was mainly driven by the clinicians discretion, which resulted in a higher test positivity rate but presumably in a less higher detection rate of CT/NG cases. At the same time, the screening program showed a quite high efficiency with low number of patients needed to screen to find one CT/NG case. Efficiency could further be increased focusing on MSM at elevated risk allowing reducing costs and workload. In line with previous studies, we identified a more recent diagnosis of HIV-infection, higher CD4 count, and changing sexual partners as predictors of asymptomatic STI [34,35,36].
Patients with CT or NG infection more often showed a higher CD4 count even with a lower time on ART, maybe reflecting a “healthier” state and therefore maybe a sexual more active part of our population. But previous studies also showed a higher rate of disclosure of HIV status to secondary partners if the CD4 count is known [37]. The association with positive tests could probably be explained by a higher level of “perceived security” by the patients if having higher cell counts and subsequently impaired protection measures, highlighting the importance of differentiated education about other sexual health risks.
Limiting CT/NG screening to MSM with arbitrarily set cutoffs with, e.g., CD4 > 350, age < 40 years, time since HIV diagnosis < 6 years would have missed a substantial part of positive cases. In addition, even patients denying sexual activities were at risk of both infection and reinfection, questioning the reliability of sexual history obtained in the clinic setting. Limiting screening to patients depending only on their sexual history could therefore be misguiding. Thus, considering the high CT/NG incidence and the increased case detection after introduction of the intervention, a broad approach of annual CT/NG screening as recommended in European guidelines seems to be reasonable at least in MSM [14].
Limitations
No update on demographical data and information about sexual practice were available during the whole 4 years. Therefore, changes in the reported behavior or clinical information could have happened with an important impact on the risk for acquiring a STI, like breaking up monogamous relationship and now have changing partners or non-compliance to medication intake with a higher viral load and thereby higher immunosuppression. However, reports on sexual activity in Germany showed a quite stable sexual behavior over longer time periods [38]. Due to the retrospective study design including all MSM > 18 who presented from 01/2018 to 12/2019 at the center having provided broad informed consent for retrospective data analysis, selection bias appears unlikely, but cannot be fully excluded. Moreover, even if we have seen no clear background trend between the two study phases suggesting a significant change in STI incidence, a changing baseline incidence of STIs cannot be excluded. A decline in the number of STIs by identification and treatment could be counterbalanced by an overall increase in STI incidence and therefore a higher rate of reinfection [1].
Nevertheless, we are reporting real-world data with real-world challenges: this intervention took place in a busy primary HIV care service on a voluntary basis not restricted by study protocols. This resulted in a fluctuating adherence to the screening frequency as previously reported [39], but shows also the performance and possibilities for such screening programs in the real-world setting.
Conclusion
In summary, we could show that CT/NG screening is feasible in a primary HIV care setting yielding a considerable high incidence of STIs with a low number needed to test in our population of MSM living with HIV. Routine CT/NG screening in vulnerable populations in primary HIV care might be an important contribution to tackle rising STI incidence in Germany and elsewhere. This screening model was only evaluated for the group of MSM living with HIV. Evaluation in and extension to other vulnerable groups, like commercial sex workers, seems warranted.
Data availability
Data are available upon request.
Abbreviations
- 100py:
-
100 Patient years
- aOR:
-
Adjusted odds ratio
- ART:
-
Anti-retroviral therapy
- aTP:
-
Active Treponema pallidum infection
- CI:
-
Confidence interval
- CT:
-
Chlamydia trachomatis
- df:
-
Degrees of freedom
- HIV:
-
Human immunodeficiency virus
- IQR:
-
Interquartile range
- MSM:
-
Men who have sex with men
- VLbLOD:
-
Months viral load below level of detection
- NG:
-
Neisseria gonorrhea
- OR:
-
Odds ratio
- PrEP:
-
Pre-exposure prophylaxis
- pTP:
-
Past Treponema pallidum infection
- SE:
-
Standard error
- STI:
-
Sexually transmitted infection
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Conceptualization: MM and SU; Methodology: MM and PM; Formal analysis and investigation: PM; Writing—original draft preparation: MM and PM; Writing—review and editing: MM, SR, and WK; Resources: SU; Supervision: MM and SR.
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The study was approved by the Ethical committee of the University of Freiburg (No.: 469/17, date: 10.10.2017) and performed according to the Declaration of Helsinki and its later amendments.
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Mathé, P.J.G., Usadel, S., Rieg, S. et al. Long-term follow-up after introduction of a systematic sexually transmitted infection screening program for men having sex with men living with HIV in a primary care setting: uptake, STI incidence, and risk factors for infection and reinfection. Infection 51, 897–907 (2023). https://doi.org/10.1007/s15010-022-01946-0
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DOI: https://doi.org/10.1007/s15010-022-01946-0