Diagnosis of Vaginitis - CAM 269HB
Description:
Vaginitis is defined as inflammation of the vagina with symptoms of discharge, itching, and discomfort often due to a disruption of the vaginal microflora. The most common infections are bacterial vaginosis, Candida vulvovaginitis, and trichomoniasis (Sobel, 1999). Other causes include vaginal atrophy in postmenopausal women, cervicitis, foreign body, irritants, and allergens (Sobel, 2023c).
Bacterial vaginosis (BV) is characterized by a shift in microbial species from the normally dominant hydrogen-peroxide producing Lactobacillus species to Gardnerella vaginalis and anaerobic commensals (Eschenbach et al., 1989; Hill, 1993; Lamont et al., 2011; Ling et al., 2010; Sobel, 2023a).
Vulvovaginal candidiasis (VVC) is usually caused by Candida albicans but can occasionally be caused by other Candida species (CDC, 2021d). It is the second most common cause of vaginitis symptoms (after BV) and accounts for approximately one-third of vaginitis cases (Sobel, 2023b; Workowski & Bolan, 2015).
Trichomoniasis is caused by the flagellated protozoan Trichomonas vaginalis, which principally infects the squamous epithelium in the urogenital tract: vagina, urethra, and paraurethral glands (Kissinger, 2015; Sobel & Mitchell, 2023).
Regulatory Status
A search of the term “vaginitis” on the FDA Device database on Jan. 29, 2021 yielded 145 records. Additionally, many labs have developed specific tests that they must validate and perform in house. These laboratory-developed tests (LDTs) are regulated by the Centers for Medicare & Medicaid Services (CMS) as high-complexity tests under the Clinical Laboratory Improvement Amendments of 1988 (CLIA ’88). The U.S. Food and Drug Administration has not approved or cleared this test as an LDT; however, FDA clearance or approval is not currently required for clinical use.
Policy:
Application of coverage criteria is dependent upon an individual’s benefit coverage at the time of the request.
- For individuals with symptoms of vaginitis, testing of pH, testing for the presence of amines, saline wet mount, hydrogen peroxide (KOH) wet mount, and microscopic examination of vaginal fluids is considered MEDICALLY NECESSARY.
- For individuals with symptoms of vaginitis, direct probe DNA-based identification of Gardnerella, Trichomonas, and Candida (e.g., BD Affirm™ VPIII) is considered MEDICALLY NECESSARY.
- For individuals with clinical signs and symptoms of vaginitis but with negative findings on wet-mount preparations and a normal pH test, vaginal cultures for Candida species for the diagnosis of vulvovaginal candidiasis is considered MEDICALLY NECESSARY.
- For individuals with symptoms of vaginitis, measurement of sialidase activity in vaginal fluid for the diagnosis of bacterial vaginosis is considered MEDICALLY NECESSARY.
- For individuals with symptoms of vaginitis, nucleic acid amplification testing (NAAT) or polymerase chain reaction (PCR)-based identification of Trichomonas vaginalis is considered MEDICALLY NECESSARY.
- For individuals with risk factors for trichomoniasis (new or multiple partners; history of sexually transmitted infections (STIs), especially HIV; exchange of sex for payment; incarceration; injection drug use), screening for Trichomonas is considered MEDICALLY NECESSARY.
- For individuals with complicated vulvovaginal candidiasis (VVC), polymerase chain reaction (PCR) based identification of Candida to confirm clinical diagnosis and identify non-albicans Candida MEETS COVERAGE CRITERIA.
- For individuals with symptoms of bacterial vaginosis (BV), NAAT specific to the diagnosis of BV (e.g., Aptima® BV; OneSwab® BV Panel PCR with Lactobacillus Profiling by qPCR; SureSwab® Advanced BV, TMA) and single or multitarget PCR testing for the diagnosis of BV is considered MEDICALLY NECESSARY.
- NAAT panel testing designed to detect more than one type of vaginitis (VVC, BV, and/or trichomoniasis; e.g., BD MAX™ Vaginal Panel, NuSwab® VG, Xpert® Xpress MVP) is considered MEDICALLY NECESSARY.
- For asymptomatic individuals, including asymptomatic pregnant individuals at an average or high risk for premature labor, screening for trichomoniasis and bacterial vaginosis is considered NOT MEDICALLY NECESSARY.
The following does not meet coverage criteria due to a lack of available published scientific literature confirming that the test(s) is/are required and beneficial for the diagnosis and treatment of a patient’s illness.
- For individuals with symptoms of vaginitis, rapid identification of Trichomonas by enzyme immunoassay is considered NOT MEDICALLY NECESSARY.
- Testing for microorganisms involved in vaginal flora imbalance and/or infertility using molecular-based panel testing is considered NOT MEDICALLY NECESSARY.
- All other tests for vaginitis not addressed above is considered NOT MEDICALLY NECESSARY.
Table of Terminology
Term |
Definition |
AAFP |
American Academy of Family Physicians |
ACOG |
American College of Obstetrics and Gynaecology |
ASM |
American Society for Microbiology |
AV |
Aerobic vaginitis |
BV |
Bacterial vaginosis |
BVAB |
BV associated bacteria |
CDC |
Centers for Disease Control and Prevention |
CLIA |
Clinical Laboratory Improvement Amendments |
CMS |
Centers for Medicare and Medicaid |
DNA |
Deoxyribose nucleic acid |
DOS |
Date of service |
HIV |
Human Immunodeficiency Virus |
IDSA |
Infectious Diseases Society of America |
LDTs |
Laboratory developed tests |
MDL |
Medical Diagnostic Laboratories |
NAAT |
Nucleic acid amplification testing |
NPV |
Negative predictive value |
OADS |
Office of the Associate Director for Science |
PCR |
Polymerase chain reaction |
PMNs |
Polymorphonuclear cells |
PPV |
Positive predictive value |
RTPCR |
Real-time polymerase chain reaction |
SOGC |
Society Of Obstetricians and Gynaecologists of Canada |
STDs |
Sexually transmitted diseases |
TMA |
Transcription-mediated amplification |
TV |
Trichomonas vaginalis |
USPSTF |
U.S. Preventive Services Task Force |
VVC |
Vulvovaginal candidiasis |
Rationale
Vaginitis is characterized by several symptoms including odor, itching, abnormal vaginal discharge, burning and irritation; this inflammatory ailment is considered the most common gynecologic diagnosis in primary care as most women experience vaginitis at least once in their lives (Paladine & Desai, 2018). A diagnosis of vaginitis can be given based on a combination of symptoms, physical examination, and office or laboratory-based testing methods.
The squamous epithelium of the vagina in premenopausal women is rich in glycogen, a substrate for lactobacilli, which create an acidic vaginal environment (pH 4.0 to 4.5). This acidity helps maintain the normal vaginal flora and inhibits growth of pathogenic organisms. Disruption of the normal ecosystem by menstrual cycle, sexual activity, contraceptive, pregnancy, foreign bodies, estrogen level, sexually transmitted diseases, and use of hygienic products or antibiotics can lead to development of vaginitis. Bacterial vaginosis (BV), vulvovaginal candidiasis (VVC), and trichomoniasis are the three most common infections responsible for vaginitis. Other causes include: vaginal atrophy in postmenopausal women, cervicitis, foreign body, irritants and allergens (Sobel, 2023c).
Bacterial vaginosis is caused by an imbalance of naturally occurring vaginal bacteria, characterized by both a change in the most common type of bacteria present, along with an increase in the total number of bacteria present. Normal vaginal microbiota is dominated by the species Lactobacilli, which are known to produce hydrogen peroxide and lactic acid, which help to keep the acidic vaginal environment below pH 4.5 (Jones, 2019; Kairys & Garg, 2020). Though the origin of vaginal bacterial infections is still unclear, it is believed that most of such infections are the result of another bacteria, Gardnerella vaginalis, creating a biofilm which allows opportunistic bacteria to grow within the vagina, causing a decrease in the Lactobacilli and subsequent disruption of the pH of the system. An entire host of etiologic organisms have been identified as possible instigators and exacerbators, including Atopobium vaginae, Megasphaera phylotype 1 and 2, Leptotrichia aminionii, Mobiluncus spp, Prevotella spp, Mycoplasma hominis, Bacteroides spp, Sneathia, and BV-associated bacteria (BVAB) 1, 2, and 3, though as aforementioned the causative mechanism and the interaction between these species are still uncertain (Jones, 2019).
Laboratory documentation of the etiology of vaginitis is important before initiating therapy, given the nonspecific nature and considerable overlap of the symptoms (Anderson et al., 2004; Ellis et al., 2001; Landers et al., 2004). Diagnostic testing enables targeted treatment, increases therapeutic compliance, and increases the likelihood of partner notification (Sobel, 2023c; Workowski & Bolan, 2015).
Measurement of vaginal pH is the primary initial finding that drives the diagnostic. The pH of the normal vaginal secretions in premenopausal women with relatively high estrogen levels is 4.0 to 4.5. The pH of normal vaginal secretions in premenarchal and postmenopausal women in whom estrogen levels are low is ≥ 4.7. An elevated pH in a premenopausal woman suggests infections, such as BV (pH>4.5) or trichomoniasis (pH 5 to 6) and helps to exclude Candida vulvovaginitis (pH 4 to 4.5). Vaginal pH may also be altered by lubricating gels, semen, douches, intravaginal medications and in pregnant women, leakage of amniotic fluid (Anderson et al., 2004; Sobel, 2023c).
There are several challenging aspects to the diagnosis of the etiology of vaginitis based on clinical symptoms. Vaginitis is a global term for nonspecific syndrome and must be narrowed down to the distinct causative factors. Traditional methods have included microscopy, pH testing, amine ‘whiff’ test, and the Amsel criteria, depending on the suspected etiology. However, physicians may find in-office microscopy to be unavailable, time-consuming, and/or inconclusive in achieving a diagnosis — some estimates hold that misdiagnosis of vulvovaginitis approaches 50% (Brown & Drexler, 2020). As another confounding factor, coinfections are common in vaginitis, adding difficulty in diagnosis of the three most common organisms if there is mixed vaginitis or coinfection (Sobel, 2023c).
Even though studies have shown that PCR methods have a higher specificity and sensitivity than culture and shorter turn-around time in identifying Candida (Diba et al., 2012; Mahmoudi Rad et al., 2012; Tabrizi et al., 2006; Weissenbacher et al., 2009), their use may be adding to clinical non-specificity. Tabrizi et al. (2006) reported that PCR “detected four additional Candida albicans, three Candida parapsilosis and one Candida tropicalis when compared with culture. All but one case additionally detected by PCR were found in patients with no VVC symptoms (Tabrizi et al., 2006).” These data support the earlier findings by Giraldo et al. (2000) where, unlike culture testing, “Candida was identified by PCR in a similar proportion of patients with previous recurrent vulvovaginal candidiasis (30%) and in controls (28.8%).” Taken together, these studies indicate that, even though PCR is more sensitive than culture, it may be identifying cases of Candida in asymptomatic women that are clinically irrelevant.
Overall, microscopy has lower sensitivities and negative predictive values for BV, candidiasis, and trichomoniasis, and yeast when compared to NAAT and culture, respectively (Sobel, 2023c). The use of established molecular diagnostic tests as an alternative to traditional methods is an opportunity to improve the diagnosis and management of vaginitis; NAAT tests have already improved detection of trichomoniasis (Sobel, 2023c).
Proprietary Tests
DNA hybridization probe tests
As previously stated, microscopy, rather than bacterial culture, is the standard of care for diagnosing BV, and commercially available tests are available in the absence of microscopy but are not widely used. A study of 176 women using the Affirm VP III test (a DNA hybridization probe test that identifies high concentrations of G. vaginalis) reported comparable results to wet mount examination with no false positives and only three false negatives for T. vaginalis, and three false positives and four false negatives for G. vaginalis (Briselden & Hillier, 1994). This test “takes less than one hour to perform and is the best option when findings on physical examination suggest BV … but microscopy cannot be performed to look for clue cells (Sobel, 2023a).”
Trichomoniasis
The OSOM Trichomonas vaginalis (TV) Rapid Test by Sekisui Diagnostics is “an antigen-detection test that uses immunochromatographic capillary flow dipstick technology that can be performed at the POC [point of care]”(CDC, 2021c). The diagnostic accuracy of the OSOM TV Rapid assay was tested against the common laboratory-based Anyplex II STI-7 Detection in a South African cross-sectional study; all irregular results were further tested with the Fast Track Diagnostics (FTD) STD9 assay (Garrett et al., 2019). Vaginal swabs from 247 women were tested for this study. “The sensitivity and specificity of OSOM TV were 75.0% (45.0-100) and 100% (100-100)”, respectively, showing a very high specificity and lower sensitivity (Garrett et al., 2019).
Bacterial Vaginosis tests
AMPLISwab™
The AMPLISwab™ by MedLabs is a comprehensive test created to assess the different organisms responsible for a variety of female genital tract infections, including causative pathogens for cervicitis, nongonococcal urethritis, pelvic inflammatory disease and infertility, sexually transmitted infections, and vaginitis (e.g., bacterial vaginosis, candidiasis and trichomoniasis). The test requires one swab to test for 23 total organisms, broken down into four categories (7 yeast, 12 bacteria and 1 reference bacteria, 1 parasite, and 2 types of herpes viruses), employing testing methodologies such as automated DNA/RNA extraction, transcription-mediated amplification (Schwebke et al.), and real-time polymerase chain reaction (RT-PCR) for the quantification of select organisms implicated in bacterial vaginosis (MedLabs, 2015).
Aptima® BV
The Aptima® Assay by Hologic is a NAAT that identifies BV. “NAAT detects 3x more mixed infections cases than clinical diagnosis with wet mount and Amsel’s criteria” (Hologic, 2023). The Aptima BV Assay is a NAAT that utilizes real time transcription-mediated amplification (Schwebke et al.) for the detection and quantification of ribosomal RNA from BV-associated bacteria: Lactobacillus (L. gasseri, L. crispatus, and L. jensenii), Gardnerella vaginalis, and Atopobium vaginae. “The assay reports a qualitative result for BV and does not report results for individual organisms. The assay is intended to aid in the diagnosis of BV on the automated Panther system using clinician-collected and patient-collected vaginal swab specimens from females with a clinical presentation consistent with vaginitis and/or vaginosis” (FDA, 2019a).
OneSwab®
OneSwab® by Medical Diagnostic Laboratories (MDL) uses real-time PCR and qPCR to output a graphical representation of the relative concentrations of the microbial flora. The Bacterial Vaginosis (with Lactobacillus profiling) qPCR test results are then reported in a text based and graphical format. The graphic format includes a representation of the results of all the quantitative tests included in the panel. The relative ratios of DNA species in the give sample in proportion to one another reflect the relative concentrations of different bacteria in vaginal specimens. According to the website, the panel includes assays to detect Gardnerella vaginalis and Atopobium vaginae, which are established BV organisms. NAAT is 95% sensitive and 99% specific for these organisms. In addition, two new assays to detect Megasphaera species and Bacterial Vaginosis-Associated Bacterium 2 (BVAB2) are included in the Bacterial Vaginosis (with Lactobacillus profiling) panel. According to MDL, using NAAT to detect either of these two organisms is up to 99% sensitive and 94% specific for the diagnosis of BV when compared to Amsel Criteria and Nugent Score (MDLabs, 2022). Of note, the sensitivity and specificity just described are for the use of NAAT in detecting these microorganisms, as reported by Fredricks et al. (2007), and are not necessarily the sensitivity and specificity of the MDL OneSwab® for BV.
SureSwab® Advanced Bacterial Vaginosis (BV), TMA
The SureSwab® (Quest Diagnostics, Inc.) Advanced Bacterial Vaginosis (BV), TMA uses real time TMA to screen for microorganisms involved in BV vaginal flora imbalances, including Lactobacillus species, Atopobium vaginae, and Gardnerella vaginalis from a single vaginal swab. It reports a qualitative result for BV and does not report results for individual organisms. The swab can be collected either by a physician or the patient (Quest, 2022a).
OSOM® BVBlue®
The OSOM® BVBlue® chromogenic diagnostic point-of-care test is a CLIA-waived test with a reported 10 minute read time. The test detects “elevated vaginal fluid sialidase activity, an enzyme produced by bacterial pathogens associated with bacterial vaginosis including Gardnerella, Bacteroides, Prevotella, and Mobiluncus. 92.8% sensitive, 98% specific versus Gram Stain with a 1-minute hands-on-time, and instant color change provides clear easy-to-read results” (Diagnostics, 2023).
Combination panel tests for Vaginitis/Vaginosis
Aptima® CV/TV
Aptima® CV/TV assays are NAAT tests that identify “vulvovaginal candidiasis (Candida vaginitis or CV) and Trichomoniasis (Trichomonas vaginalis or TV) in symptomatic women from one vaginal sample. NAAT detects 3x more mixed infections cases than clinical diagnosis with wet mount and Amsel’s criteria. These tests detect and qualitatively report results for the following organisms: Candida species group (C. albicans, C. tropicalis, C. parapsilosis, C. dubliniensis), Candida glabrata, Trichomonas vaginalis” (Hologic, 2023).
SureSwab®
SureSwab® Advanced Vaginitis, TMA is a test for “vaginitis, including bacterial vaginosis, vulvovaginal candidiasis (Candidiasis species), and trichomoniasis (Trichomonas vaginalis) (Quest, 2022c). In an even more expansive combination test package, Quest offers a “SureSwab® Advanced Vaginitis Plus, TMA” assay which, in addition to detecting organisms associated with BV, trichomoniasis, and candidiasis, also detects Chlamydia trachomatis and Neisseria gonorrhoeae (Quest, 2022b).
BD MAX™ Vaginal Panel
The BD MAX™ Vaginal Panel as “an automated qualitative in vitro diagnostic test for the direct detection of DNA targets from bacteria associated with BV (qualitative results reported based on detection and quantitation of targeted organism markers), Candida species associated with vulvovaginal candidiasis, and Trichomonas vaginalis from vaginal swabs in patients who are symptomatic for vaginitis/vaginosis. The test utilizes real-time PCR for the amplification of specific DNA targets and utilizes fluorogenic target-specific hybridization probes to detect and differentiate DNA” (FDA, 2016).
Analytical Validity
Microscopic examination of normal vaginal discharge reveals a predominance of squamous epithelial cells, rare polymorphonuclear leukocytes (PMNs), and Lactobacillus species. The primary goal of the examination is to look for candidal buds or hyphae, motile trichomonads, epithelial cells studded with adherent coccobacilli (clue cells), and increased numbers of PMNs (Sobel, 2023c). The microscopic evaluation of BV is usually based on Amsel criteria (Amsel et al., 1983). Amsel criteria state that the presence of at least three out of the following four criteria are indicative of a BV diagnosis: increased homogeneous thin vaginal discharge, pH secretion > 4.5, amine odor when potassium hydroxide 10% solution is added to a vaginal secretion sample, and the presence of clue cells in wet preparations (Amsel et al., 1983). If clinical criteria are used to define infection, then reported sensitivity may range from 62 to 100 percent (Spiegel, 1991). Using Gram's stain as the standard for diagnosing BV, the sensitivity of Amsel criteria for diagnosis of BV is over 90 percent and specificity is 77 percent (Landers et al., 2004). The Nugent score is also available as a Gram staining scoring system to diagnose BV based on vaginal swab samples (Amegashie et al., 2017). Because BV represents complex changes in the vaginal flora, vaginal culture has no role in diagnosis. If microscopy is not available, commercial diagnostic testing methods (e.g., rapid antigen and nucleic acid amplification tests) are used for confirming the clinical suspicion of BV. Polymerase chain reaction (PCR)-based assays to quantify BV-associated bacteria (Cartwright et al., 2012; Menard et al., 2008) have good sensitivity and specificity compared with standard clinical tests (Dumonceaux et al., 2009; Menard et al., 2010). However, they are expensive and of limited utility (Sobel, 2023a).
Trichomoniasis can be diagnosed by the presence of motile trichomonads on wet mount, but it is identified in only 60 to 70 percent of culture-confirmed cases. Culture on Diamond's medium was considered the gold standard method for diagnosing a T. vaginalis infection (Workowski & Bolan, 2015); however, nucleic acid amplification tests (Baron et al., 2013) have become the accepted gold standard for the diagnosis of T. vaginalis. One study found the sensitivities for T. vaginalis using wet mount, culture, rapid antigen testing, and transcription-mediated amplification testing were 65, 96, 90, and 98 percent, respectively (Huppert et al., 2007). Coexistence of T. vaginalis and BV pathogens is common, with coinfection rates of 60 to 80 percent (Sobel & Mitchell, 2023; Sobel et al., 2013).
Microscopy is negative in up to 50 percent of patients with culture-confirmed VVC (Sobel, 1985). Since there are no reliable point of care tests for Candida available in the United States (Abbott, 1995; Chatwani et al., 2007; Dan et al., 2010; Hopwood et al., 1985; Marot-Leblond et al., 2009; Matsui et al., 2009), culture must be obtained. PCR methods have high sensitivity and specificity and a shorter turn-around time than culture (Diba et al., 2012; Mahmoudi Rad et al., 2012; Tabrizi et al., 2006; Weissenbacher et al., 2009), but they are costly and offer no proven benefit over culture in symptomatic women (Sobel, 2023b).
Lynch et al. (2019) collected vaginal swabs from 93 women in a cross-sectional study; results from microscopy were compared to two molecular approaches (a qPCR assay with a BV interpretive algorithm and a microbiome profiling test of the 16S rRNA gene produced by Illumina) (Lynch et al., 2019). Results show that “Microscopy plus BV Nugent score had 76% overall agreement with the qPCR plus BV interpretive algorithm method”; further, “Microscopic identification of Candida versus that by qPCR had 94% agreement (9 positive, 78 negative) (Lynch et al., 2019).” The qPCR assays gave additional information regarding the types of bacteria present, and the 16S microbiome analysis identified differentiating patterns between BV, aerobic vaginitis (AV), and Lactobacillus type infections.
Cartwright et al. (2018) have published data regarding the clinical validity of a PCR-based assay for the detection of BV. This multicenter study included 1579 patients and compared PCR results to samples realized by both the Nugent gram stain and a clinical evaluation using Amsel criteria. Next-generation sequencing was used to confirm differing results. After the resolution of discordant test results using next-generation sequencing, the BV-PCR assay reported a sensitivity of 98.7%, a specificity of 95.9%, a positive predictive value of 92.9% and a negative predictive value of 96.9% (Cartwright et al., 2018). These results show that this PCR-based assay can diagnose BV in symptomatic women efficiently.
Gaydos et al. (2017) conducted a cross-sectional, multi-site study into the clinical validation of this system (n=1740 symptomatic women) reported a sensitivity and specificity of 90.9% and 94.1%, respectively for the Candida group and 90.5% sensitivity and 85.8% specificity for BV. For C. glabrata specifically, the assay had only 75.9% sensitivity but 99.7% specificity. For trichomoniasis, the sensitivity and specificity were 93.1% and 99.3%, respectively (Gaydos et al., 2017). These researchers also compared the results of this test to clinician assessment. Again, to qualify for the study, the women must have at least one symptom of BV. Using Amsel’s criteria, the investigational test sensitivity was 92.7% as compared to the 75.6% sensitivity of the clinician assessment. The authors conclude, “The investigational test showed significantly higher sensitivity for detecting vaginitis, involving more than one cause, than did clinician diagnosis. Taken together, these results suggest that a molecular investigational test can facilitate accurate detection of vaginitis (Schwebke et al., 2018).” It should be noted, however, that these studies only included symptomatic women, and, therefore, the possible clinical non-specificity (i.e., instances where an asymptomatic woman would test positive) is not addressed. Sherrard (2019) compared BV, candidiasis, and trichomoniasis diagnostic results from the BD MAX Vaginal Panel to a current test used in a UK specialist sexual health service center. The authors reported that the BD MAX Vaginal Panel had a sensitivity of 86.4% and specificity of 86.0% for Candida species, and a sensitivity of 94.4% and specificity of 79% for BV; the specificity for BV was lower in this study than what has been previously reported (Sherrard, 2019).
Sumeksri et al. (2005) conducted a study correlated to the OSOM® BVBlue® test. 173 pregnant women reported a sensitivity and specificity of 94% and 96% respectively, as compared to Gram stain score. These results were comparable to the previously reported values of 91.7% sensitivity and 97.8% specificity in an earlier, smaller study of non-menstruating women (n = 57) (Myziuk et al., 2003). A larger study (n = 288 women) reported a sensitivity of 88% and specificity of 91% as compared to the Amsel criteria. The authors of this report concluded that women who “are not in settings where the conventional diagnostic methods are either practical or possible … would greatly benefit from access to rapid and reliable point-of-care tests to improve the diagnosis and management of BV (Bradshaw et al., 2005).”
Clinical Utility and Validity
Anand et al. (2020) investigated the accuracy of Papanicolaou smear to diagnose bacterial vaginosis infection in women with women with clinically evident genital infection using the Nugent score on Gram-stained smear as the gold standard. In a prospective blinded cross-sectional study of 254 nonpregnant women between the ages of 30 and 50 conducted between August 2016 and August 2018, the researchers found that using the Nugent score for diagnosing BV as the gold standard, the Pap smears showed sensitivity and specificity of 70.9% (CI: 61.5% – 79.2%) and 56.8% (CI: 48.2% – 65.2%), respectively. Moreover, they found that the positive percent value was 56.5% (CI: 47.8% – 64.9%), while the negative percent value was 71.2% (CI: 61.8% – 79.4%). These results indicated to the authors that though Pap smears are generally reserved for cervical cancer, the “Pap smear may serve as a means of diagnosing BV [bacterial vaginosis] infection in resource-constrained countries like India” (Anand et al., 2020).
Hilbert et al. (2016) performed a prospective longitudinal study on the use of molecular assays for the accurate detection and diagnosis of bacterial vaginosis using MDL OneSwab®. The authors quantified nine organisms associated with vaginal health or disease (Gardnerella vaginalis, Atopobium vaginae, BV-associated bacteria 2 (BVAB2, an uncultured member of the order Clostridiales), Megasphaera phylotype 1 or 2, Lactobacillus iners, Lactobacillus crispatus, Lactobacillus gasseri, and Lactobacillus jensenii) in a total of 149 women were enrolled in the study. DNA was extracted from clinical specimens using mechanical disruption and the QIAamp mini-kit from Qiagen; qPCR assay was used to quantify BV microbes and Lactobacillus species. Though the authors evaluated a broad variety of organisms with the potential to be diagnostic markers, results from the study indicated a sensitivity of 92% and specificity of 95% for three that were predictive of diagnosis of BV: G. vaginalis, A. vaginae, and Megasphaera phylotypes 1 and 2; outcomes were 94% PPV, and 94% NPV for BV. The authors summarized their findings by describing the molecular assay as a highly specific laboratory test to identify bacterial vaginosis (Hilbert et al., 2016).
The Aptima BV and Aptima Candida/Trichomonas vaginitis (CV/TV) NAAT molecular tests detect and qualitatively report results using a proprietary algorithmic analysis. Pathogens addressed by the test include: Candida species group (C. albicans, C. tropicalis, C. parapsilosis, C. dubliniensis), Candida glabrata, Lactobacillus, Gardnerella vaginalis, Atopobium vaginae, and Trichomonas vaginalis (Hologic, 2022). Hologic announced the FDA approval of the Aptima BV and Aptima CV/TV vaginitis tests in 2019 (Hologic, 2019). Schwebke et al. (2020) performed a multicenter, prospective clinical study to validate the performance of the Aptima BV and Aptima CV/TV test for bacterial vaginosis, vulvovaginal candidiasis, and trichomonas vaginitis. A total of 1,519 subjects were enrolled in the study. The authors reported sensitivity and specificity for the investigational tests when it came to provider-collected samples at 95.0% and 89.6% for BV. When it came to Candida species, sensitivity and specificity was 91.7% and 94.9% respectively; C. glabrata sensitivity and specificity was 84.7% and 99.1%; 96.5% and 94.1% for T. vaginalis. Patient-collected samples showed similar ranges of sensitivity and specificity. In conclusion, the authors wrote, “In a secondary analysis, clinicians' diagnoses, in-clinic assessments, and investigational-assay results were compared to gold standard reference methods. Overall, the investigational assays had higher sensitivity and specificity than clinicians' diagnoses and in-clinic assessments, indicating that the investigational assays were more predictive of infection than traditional diagnostic methods” (Schwebke et al., 2020).
There has been increasing literature and reviews regarding both NAAT and DNA hybridization probe proprietary-based diagnostic performance in the identification of bacterial vaginosis. A study by Richter et al. (2019) compared the performance of three molecular diagnostic assays. The assays included in the study were BD Affirm, Hologic ASR BV Assay, and the Aptima IVD BV Assay. A total of 111 women were enrolled in the study. Women had been given an Affirm test by their provider after describing symptoms that indicated a form of vaginitis. After the collection of additional specimens, samples were run on the different assays. As predicted by clinicians, BV was the most common outcome of diagnosis for 45 of the patients (71%). The sensitivity and specificity for the Hologic ASR assay (diagnosing BV) was 75.6% and 81.8%. The Affirm assay had a sensitivity and specificity of 86.7% and 60.6% for BV, while the Aptima BV IVD assay showed sensitivities and specificities of 84.4% and 86.3%. According to the study, of the 3 molecular assays that were evaluated, “Aptima BV IVD demonstrated the highest specificity, which may reflect value for the A. vaginae target unique to that assay.” The study also noted that “although assays that incorporate more bacterial targets are attractive since they reflect the bacterial diversity that has been reported in BV, it is uncertain whether they will provide better diagnostic accuracy to offset the higher cost usually charged for additional targets” (Richter et al., 2019).
One population health population study initiated by Kong et al. (2021) noted that molecular testing is both a sensitive and specific approach to testing and also a welcome tool for providers using labor-intensive traditional practices. The authors address the issue of poor compliance by providers with established gold standard guidelines such as the Amsel criteria, as well as a varied and divergent approaches to office diagnostics. The widespread availability of molecular testing could help accomplish the diagnosis of vaginitis in a single visit. The authors conclude that “compared to CE, molecular tests offer high sensitivity and specificity that provide a precise treatment route. In addition to improved accuracy, recent evidence demonstrates that the combination of sensitive and specific laboratory testing as well as careful patient evaluation have the potential to reduce unnecessary follow-up visits and improve patient care” (Kong et al., 2021).
Centers for Disease Control and Prevention (CDC)
The CDC published updated guidelines for diseases characterized by vulvovaginal itching, burning, irritation, odor or discharge in their Sexually Transmitted Infections Treatment Guidelines, 2021 (CDC, 2021b). These guidelines state that “obtaining a medical history alone has been reported to be insufficient for accurate diagnosis of vaginitis and can lead to inappropriate administration of medication. … Therefore, a careful history, examination, and laboratory testing to determine the etiology of any vaginal symptoms are warranted. Information regarding sexual behaviors and practices, sex of sex partners, menses, vaginal hygiene practices (e.g., douching), and self-treatment with oral and intravaginal medications or other products should be elicited.”
The CDC notes that “in the clinician’s office, the cause of vaginal symptoms can often be determined by pH, a potassium hydroxide (KOH) test, and microscopic examination of a wet mount of fresh samples of vaginal discharge.” However, the guidelines conclude that “in settings where pH paper, KOH, and microscopy are unavailable, a broad range of clinical laboratory tests … can be used.”
For the evaluation of BV, the CDC recommends that “BV can be diagnosed by the use of clinical criteria (i.e., Amsel’s Diagnostic Criteria) or by determining the Nugent score from a vaginal Gram stain”(CDC, 2021a). Additional tests are available: “The Osom BV Blue test (Diagnostics) detects vaginal sialidase activity. The Affirm VP III (Becton Dickinson) is an oligonucleotide probe test that detects high concentrations of G. vaginalis nucleic acids (> 5 x 105 CFU of G. vaginalis/mL of vaginal fluid) for diagnosing BV, Candida species, and T. vaginalis. This test has been reported to be most useful for symptomatic women in conjunction with vaginal pH measurement and presence of amine odor. ... Finally, the FemExam Test Card (Cooper Surgical) measures vaginal pH, presence of trimethylamine (a metabolic by-product of G. vaginalis), and proline aminopeptidase. ... This test has primarily been studied in resource-poor settings, and although it has been reported to be beneficial compared with syndromic management, it is not a preferred diagnostic method for BV diagnosis”(CDC, 2021a). The guidelines also state that due to insufficient evidence, “routine screening for BV among asymptomatic pregnant women at high or low risk for preterm delivery for preventing preterm birth is not recommended,”(CDC, 2021a), which is in compliance with the 2008 USPSTF recommendations (USPSTF, 2008).
Regarding NAATs for BV, the CDC states that “BV NAATs should be used among symptomatic women only (e.g., women with vaginal discharge, odor, or itch) because their accuracy is not well defined for asymptomatic women. Despite the availability of BV NAATs, traditional methods of BV diagnosis, including the Amsel criteria, Nugent score, and the Affirm VP III assay, remain useful for diagnosing symptomatic BV because of their lower cost and ability to provide a rapid diagnosis. Culture of G. vaginalis is not recommended as a diagnostic tool because it is not specific. Cervical Pap tests have no clinical utility for diagnosing BV because of their low sensitivity and specificity” (CDC, 2021a).
The CDC provides information on multiple BV NAATs that are available and notes that “these tests are based on detection of specific bacterial nucleic acids and have high sensitivity and specificity for BV (i.e., G. vaginalis, A. vaginae, BVAB2, or Megasphaera type 1) and certain lactobacilli (i.e., Lactobacillus crispatus, Lactobacillus jensenii, and Lactobacillus gasseri). They can be performed on either clinician- or self-collected vaginal specimens with results available in < 24 hours, depending on the availability of the molecular diagnostic platform. Five quantitative multiplex PCR assays are available: Max Vaginal Panel (Becton Dickinson), Aptima BV (Hologic), NuSwab® VG (LabCorp), OneSwab® BV Panel PCR with Lactobacillus Profiling by qPCR (Medical Diagnostic Laboratories), and SureSwab® BV (Quest Diagnostics). Two of these assays are FDA cleared (BD Max Vaginal Panel and Aptima BV), and the other three are laboratory-developed tests. The Max Vaginal Panel provides results by an algorithmic analysis of molecular DNA detection of Lactobacillus species (L. crispatus and L. jensenii) in addition to G. vaginalis, A. vaginae, BVAB2, and Megasphaera type 1. This test has 90.5% sensitivity and 85.8% specificity for BV diagnosis, compared with Amsel criteria and Nugent score. It also provides results for Candida species and T. vaginalis. The Aptima BV detects G. vaginalis, A. vaginae, and certain Lactobacillus species including L. crispatus, L. jensenii, and L. gasseri, with sensitivity and specificity ranging from 95.0% to 97.3% and 85.8% to 89.6%, respectively (using either clinician- or patient-collected vaginal swabs). The three laboratory-developed tests (NuSwab® VG, OneSwab® BV Panel PCR with Lactobacillus Profiling by qPCR, and SureSwab® BV) have to be internally validated before use for patient care yet have good sensitivity and specificity, similar to FDA-cleared assays” (CDC, 2021a).
For the evaluation of vulvovaginal candidiasis, the CDC recommends: “Examination of a wet mount with KOH preparation should be performed for all women with symptoms or signs of VVC, and women with a positive result should be treated. For those with negative wet mounts but existing signs or symptoms, vaginal cultures for Candida should be considered” (CDC, 2021d). The most current guidelines for VVC diagnosis state that “vaginal culture or PCR should be obtained from women with complicated VVC to confirm clinical diagnosis and identify non–albicans Candida” (CDC, 2021d).
For the evaluation of trichomoniasis, the CDC recommends: “Diagnostic testing for T. vaginalis should be performed for women seeking care for vaginal discharge. … Wet-mount microscopy traditionally has been used as the preferred diagnostic test for T. vaginalis among women because it is inexpensive and can be performed at the POC; however, it has low sensitivity (44% – 68%) compared with culture. ... More highly sensitive and specific molecular diagnostic options are available, which should be used in conjunction with a negative wet mount when possible. NAATs are highly sensitive, detecting more T. vaginalis infections than wet-mount microscopy among women. ... The OSOM® trichomonas rapid test (Diagnostics) is an antigen-detection test that uses immunochromatographic capillary flow dipstick technology that can be performed at the POC by using clinician-obtained vaginal specimens. Results are available in approximately 10 – 15 minutes, with sensitivities of 82% – 95% and specificity of 97% – 100%, compared with wet mount, culture, and transcription-mediated amplification. ... The Solana trichomonas assay (Quidel) is another rapid test for the qualitative detection of T. vaginalis DNA and can yield results < 40 minutes after specimen collection ... The Amplivue trichomonas assay (Quidel) is another rapid test providing qualitative detection of T. vaginalis that has been FDA cleared for vaginal specimens from symptomatic and asymptomatic women”(CDC, 2021c) and “the Affirm VP III (Becton Dickinson) is an oligonucleotide probe test that detects high concentrations of G. vaginalis nucleic acids (> 5 x 105 CFU of G. vaginalis/mL of vaginal fluid) for diagnosing BV, Candida species, and T. vaginalis. This test has been reported to be most useful for symptomatic women in conjunction with vaginal pH measurement and presence of amine odor (sensitivity of 97%); specificity is 81% compared with Nugent” (CDC, 2021a).
In the Sexually Transmitted Infections Treatment Guidelines, 2021, the CDC also mentions the FDA-cleared Aptima T. vaginalis assay that may be used for detection of T. vaginalis from symptomatic or asymptomatic women (CDC, 2021c).
American Academy of Family Physicians (AAFP)
The AAFP published an article (Hainer & Gibson, 2011) on the diagnosis of vaginitis which states that: “Physicians traditionally diagnose vaginitis using the combination of symptoms, physical examination, pH of vaginal fluid, microscopy, and the whiff test. When combined, these tests have a sensitivity and specificity of 81 and 70 percent, respectively, for BV; 84 and 85 percent for vulvovaginal candidiasis; and 85 and 100 percent for trichomoniasis when compared with the DNA probe standard. …A cost-effectiveness analysis of diagnostic strategies for vaginitis undiagnosed by pelvic examination, wet-mount preparation, and related office tests showed that the least expensive strategy was to perform yeast culture, gonorrhea and chlamydia probes at the initial visit, and Gram stain and Trichomonas culture only when the vaginal pH exceeded 4.9. Other strategies cost more and increased duration of symptoms by up to 1.3 days” (Hainer & Gibson, 2011).
In 2018, the AAFP published the following guidelines:
- “Symptoms alone cannot differentiate between the causes of vaginitis. Office-based or laboratory testing should be used with the history and physical examination findings to make the diagnosis. (C evidence rating)
- Do not obtain culture for the diagnosis of bacterial vaginosis because it represents a polymicrobial infection. (C evidence rating)
- Nucleic acid amplification testing is recommended for the diagnosis of trichomoniasis in symptomatic or high-risk women. (C evidence rating)” (Paladine & Desai, 2018).
U.S. Preventive Services Task Force Recommendations (USPSTF)
In 2020, the USPSTF published recommendations discouraging the use of screening for BV in pregnancy: “The USPSTF recommends against screening for bacterial vaginosis in pregnant persons not at increased risk for preterm delivery”. On a similar note, the USPSTF maintains its 2008 recommendation stating “that the current evidence is insufficient to assess the balance of benefits and harms of screening for bacterial vaginosis in pregnant persons at increased risk for preterm delivery” (Owens et al., 2020).
American College of Obstetrics and Gynecology (ACOG)
ACOG published recommendations (ACOG, 2006) for the evaluation of vaginitis in 2006, and reaffirmed in 2017 (ACOG, 2017, 2018), which state: “Evaluation of women with vaginitis should include a focused history about the entire spectrum of vaginal symptoms, including change in discharge, vaginal malodor, itching, irritation, burning, swelling, dyspareunia, and dysuria.” Further, “During speculum examination, samples should be obtained for vaginal pH, amine (“whiff”) test, and saline (wet mount) and 10% potassium hydroxide (KOH) microscopy. The pH and amine testing can be performed either through direct measurement or by colorimetric testing.” With a Level B recommendation, ACOG states, “Microscopy is the first line for diagnosing vulvovaginal candidiasis and trichomoniasis. In selected patients, culture for yeast and T. vaginalis should be obtained in addition to standard office-based testing.” Additionally, “A vaginal Gram stain for Nugent scoring of the bacterial flora may help to identify patients with BV. Other currently available ancillary tests for diagnosing vaginal infections include rapid tests for enzyme activity from BV-associated organisms, Trichomonas vaginalis antigen, and point-of care testing for DNA of G. vaginalis, T. vaginalis, and Candida species; however, the role of these tests in the proper management of patients with vaginitis is unclear. Depending on risk factors, DNA amplification tests can be obtained for Neisseria gonorrhoeae and Chlamydia trachomatis”(ACOG, 2006).
The ACOG published in 2020 Practice Bulletin Number 215 on vaginitis in nonpregnant patients. In these guidelines, the ACOG made these recommendations for diagnostic testing based on good and consistent scientific evidence (Level B):
- “The use of Amsel clinical criteria or Gram stain with Nugent scoring is recommended for the diagnosis of bacterial vaginosis.”
- “Nucleic acid amplification testing is recommended for the diagnosis of trichomoniasis.”
- “In a symptomatic patient, diagnosis of vulvovaginal candidiasis requires one of the following two findings: 1) visualization of spores, pseudohyphae, or hyphae on wet-mount microscopy or 2) vaginal fungal culture or commercial diagnostic test results positive for Candida species.”
The ACOG also published recommendations based on limited or inconsistent scientific evidence (Level B), along with a series of recommendations based on consensus and expert opinion (Level C). Those relating to diagnostic testing are reported below:
- “Patients should be retested within 3 months after treatment for T vaginalis because of the high rates of infection recurrence.” (Level B)
- “Pap tests are not reliable for the diagnosis of vaginitis. Diagnostic confirmation is recommended for incidental findings of vulvovaginal candidiasis, bacterial vaginosis, or trichomoniasis on a Pap test.” (Level B)
- “A complete medical history, physical examination of the vulva and vagina, and clinical testing of vaginal discharge (i.e., pH testing, a potassium hydroxide [KOH] “whiff test”, and microscopy) are recommended for the initial evaluation of patients with vaginitis symptoms.” (Level C)
The ACOG mentions in Bulletin Number 215 that an advanced single-swab panel test that combines multiplex PCR and DNA probe technology could be a promising alternative to microscopy for BV, trichomoniasis, and candidiasis (ACOG, 2020).
Infectious Diseases Society of America (IDSA) Clinical Practice Guidelines
IDSA has published an updated clinical guideline (Pappas et al., 2016) for the management of candidiasis in which recommendations include diagnosing vulvovaginal candidiasis before proceeding with empiric antifungal therapy. The usual diagnosis is clinical based on signs and symptoms of vaginitis such as pruritus, irritation, vaginal soreness, vulvar edema, erythema and many others. Clinical signs and symptoms are nonspecific and could be attributed to causes other than vulvovaginal candidiasis. Therefore, authors recommend confirming clinical diagnosis by a wet -mount preparation with saline and 10% KOH to demonstrate the presence of yeast and a normal pH. In cases where signs and symptoms are suggestive of vulvovaginal candidiasis, but microscopic findings and pH are negative, culture testing confirms the diagnosis according to published guidelines. The IDSA also discusses the possible use of PCR in diagnosing invasive candidiasis, even though the guidelines later state that “Cultures of blood or other samples collected under sterile conditions have long been considered diagnostic gold standards for invasive candidiasis…The role of PCR in testing samples other than blood is not established” (Pappas et al., 2016).
In the 2018 IDSA A Guide to Utilization of the Microbiology Laboratory for Diagnosis of Infectious Diseases, the IDSA states, “For vaginosis (altered vaginal flora) a Gram stain and recently available microbiome-based assays are more specific than culture and probe testing for Gardnerella vaginalis alone. … A number of point-of-care tests can be performed from a vaginal discharge specimen while the patient is in the healthcare setting. Although point-of-care tests are popular, the sensitivity and specificity for making a specific diagnosis vary widely and these assays, while rapid, are often diagnostically poor (Miller et al., 2018).” The IDSA notes that the FDA has approved the use of the Max Vaginal Panel by Becton Dickinson in symptomatic females. “Preliminary data show greater specificity of this approach compared to methods that identify only G. vaginalis, as well as consistency in both reproducible as well as standardized results” (Miller et al., 2018).
Society of Obstetricians and Gynecologists of Canada (SOGC)
The SOGC published guidelines for the screening and management of BV in pregnancy. These guidelines state that the following:
- “In symptomatic pregnant women, testing for and treatment of bacterial vaginosis is recommended for symptom resolution. Diagnostic criteria are the same for pregnant and non-pregnant women (I-A).
- Asymptomatic women and women without identified risk factors for preterm birth should not undergo routine screening for or treatment of bacterial vaginosis (I-B).
- Women at increased risk for preterm birth may benefit from routine screening for and treatment of bacterial vaginosis (I-B).
- Testing should be repeated one month after treatment to ensure that cure was achieved (III-L)” (Yudin & Money, 2017).
The SOGC also published guidelines regarding the screening and management of trichomoniasis, VVC, and BV. These guidelines state that “Bacterial vaginosis should be diagnosed using either clinical (Amsel’s) or laboratory (Gram stain with objective scoring system) criteria (II-2A)” (van Schalkwyk & Yudin, 2015).
References:
- Abbott, J. (1995). Clinical and microscopic diagnosis of vaginal yeast infection: a prospective analysis. Ann Emerg Med, 25(5), 587-591.
- ACOG. (2006). ACOG Practice Bulletin. Clinical management guidelines for obstetrician-gynecologists, Number 72, May 2006: Vaginitis. Obstet Gynecol, 107(5), 1195-1206. http://dx.doi.org/
- ACOG. (2017). College Publications. Obstet Gynecol, 129(6), 1147-1148. https://doi.org/10.1097/aog.0000000000002107
- ACOG. (2018). Practice Bulletins. American College of Obstetricians and Gynecologists. Retrieved 01/16/2019 from https://www.acog.org/Clinical-Guidance-and-Publications/Practice-Bulletins-List
- ACOG. (2020). Vaginitis in Nonpregnant Patients: ACOG Practice Bulletin, Number 215. Obstet Gynecol, 135(1), e1-e17. https://doi.org/10.1097/AOG.0000000000003604
- Amegashie, C. P., Gilbert, N. M., Peipert, J. F., Allsworth, J. E., Lewis, W. G., & Lewis, A. L. (2017). Relationship between nugent score and vaginal epithelial exfoliation. PLoS One, 12(5), e0177797. https://doi.org/10.1371/journal.pone.0177797
- Amsel, R., Totten, P. A., Spiegel, C. A., Chen, K. C., Eschenbach, D., & Holmes, K. K. (1983). Nonspecific vaginitis. Diagnostic criteria and microbial and epidemiologic associations. Am J Med, 74(1), 14-22.
- Anand, K. V., Pimple, S. A., Mishra, G. A., Sahare, R. V., Pathuthara, S., Deodhar, K. K., & Shastri, S. S. (2020). Reliability of conventional Papanicolaou smear in diagnosing bacterial vaginosis among women with clinical genital infection. South Asian J Cancer, 9(1), 13-16. https://doi.org/10.4103/sajc.sajc_421_18
- Anderson, M. R., Klink, K., & Cohrssen, A. (2004). Evaluation of vaginal complaints. Jama, 291(11), 1368-1379. https://doi.org/10.1001/jama.291.11.1368
- Baron, E. J., Miller, J. M., Weinstein, M. P., Richter, S. S., Gilligan, P. H., Thomson, R. B., Jr., Bourbeau, P., Carroll, K. C., Kehl, S. C., Dunne, W. M., Robinson-Dunn, B., Schwartzman, J. D., Chapin, K. C., Snyder, J. W., Forbes, B. A., Patel, R., Rosenblatt, J. E., & Pritt, B. S. (2013). A guide to utilization of the microbiology laboratory for diagnosis of infectious diseases: 2013 recommendations by the Infectious Diseases Society of America (IDSA) and the American Society for Microbiology (ASM)(a). Clin Infect Dis, 57(4), e22-e121. https://doi.org/10.1093/cid/cit278
- Bradshaw, C. S., Morton, A. N., Garland, S. M., Horvath, L. B., Kuzevska, I., & Fairley, C. K. (2005). Evaluation of a point-of-care test, BVBlue, and clinical and laboratory criteria for diagnosis of bacterial vaginosis. J Clin Microbiol, 43(3), 1304-1308. https://doi.org/10.1128/jcm.43.3.1304-1308.2005
- Briselden, A. M., & Hillier, S. L. (1994). Evaluation of affirm VP Microbial Identification Test for Gardnerella vaginalis and Trichomonas vaginalis. J Clin Microbiol, 32(1), 148-152. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC262986/
- Brown, H., & Drexler, M. (2020). Improving the Diagnosis of Vulvovaginitis: Perspectives to Align Practice, Guidelines, and Awareness. Popul Health Manag, 23(S1), S3-s12. https://doi.org/10.1089/pop.2020.0265
- Cartwright, C. P., Lembke, B. D., Ramachandran, K., Body, B. A., Nye, M. B., Rivers, C. A., & Schwebke, J. R. (2012). Development and validation of a semiquantitative, multitarget PCR assay for diagnosis of bacterial vaginosis. J Clin Microbiol, 50(7), 2321-2329. https://doi.org/10.1128/jcm.00506-12
- Cartwright, C. P., Pherson, A. J., Harris, A. B., Clancey, M. S., & Nye, M. B. (2018). Multicenter study establishing the clinical validity of a nucleic-acid amplification-based assay for the diagnosis of bacterial vaginosis. Diagn Microbiol Infect Dis, 92(3), 173-178. https://doi.org/10.1016/j.diagmicrobio.2018.05.022
- CDC. (2021a). Bacterial Vaginosis. https://www.cdc.gov/std/treatment-guidelines/bv.htm
- CDC. (2021b). Diseases Characterized by Vulvovaginal Itching, Burning, Irritation, Odor or Discharge. https://www.cdc.gov/std/treatment-guidelines/vaginal-discharge.htm
- CDC. (2021c). Trichomoniasis. https://www.cdc.gov/std/treatment-guidelines/trichomoniasis.htm
- CDC. (2021d). Vulvovaginal Candidiasis (VVC). https://www.cdc.gov/std/treatment-guidelines/candidiasis.htm
- Chatwani, A. J., Mehta, R., Hassan, S., Rahimi, S., Jeronis, S., & Dandolu, V. (2007). Rapid testing for vaginal yeast detection: a prospective study. Am J Obstet Gynecol, 196(4), 309.e301-304. https://doi.org/10.1016/j.ajog.2006.11.025
- Dan, M., Leshem, Y., & Yeshaya, A. (2010). Performance of a rapid yeast test in detecting Candida spp. in the vagina. Diagn Microbiol Infect Dis, 67(1), 52-55. https://doi.org/10.1016/j.diagmicrobio.2009.12.010
- Diagnostics, S. (2023). OSOM® BVBLUE® Test. https://sekisuidiagnostics.com/products-all/osom-bvblue-test/
- Diba, K., Namaki, A., Ayatolahi, H., & Hanifian, H. (2012). Rapid identification of drug resistant Candida species causing recurrent vulvovaginal candidiasis. Med Mycol J, 53(3), 193-198.
- Dumonceaux, T. J., Schellenberg, J., Goleski, V., Hill, J. E., Jaoko, W., Kimani, J., Money, D., Ball, T. B., Plummer, F. A., & Severini, A. (2009). Multiplex detection of bacteria associated with normal microbiota and with bacterial vaginosis in vaginal swabs by use of oligonucleotide-coupled fluorescent microspheres. J Clin Microbiol, 47(12), 4067-4077. https://doi.org/10.1128/jcm.00112-09
- Ellis, I., Lerch, M. M., & Whitcomb, D. C. (2001). Genetic testing for hereditary pancreatitis: guidelines for indications, counselling, consent and privacy issues. Pancreatology, 1(5), 405-415.
- Eschenbach, D. A., Davick, P. R., Williams, B. L., Klebanoff, S. J., Young-Smith, K., Critchlow, C. M., & Holmes, K. K. (1989). Prevalence of hydrogen peroxide-producing Lactobacillus species in normal women and women with bacterial vaginosis. J Clin Microbiol, 27(2), 251-256. http://dx.doi.org/
- FDA. (2016). EVALUATION OF AUTOMATIC CLASS III DESIGNATION FOR BD MAX Vaginal Panel. U.S. Food and Drug Administration. https://www.accessdata.fda.gov/cdrh_docs/reviews/DEN160001.pdf
- FDA. (2019a). 510(k) Substantial Equivalence Determination Decision Memorandum: Aptima BV Assay. https://www.accessdata.fda.gov/cdrh_docs/reviews/K190452.pdf
- FDA. (2019b). 510(k) Substantial Equivalence Determination Decision Summary: BD MAX Vaginal Panel, BD MAX System. https://www.accessdata.fda.gov/cdrh_docs/reviews/K191957.pdf
- Fredricks, D. N., Fiedler, T. L., Thomas, K. K., Oakley, B. B., & Marrazzo, J. M. (2007). Targeted PCR for detection of vaginal bacteria associated with bacterial vaginosis. J Clin Microbiol, 45(10), 3270-3276. https://doi.org/10.1128/JCM.01272-07
- Garrett, N., Mitchev, N., Osman, F., Naidoo, J., Dorward, J., Singh, R., Ngobese, H., Rompalo, A., Mlisana, K., & Mindel, A. (2019). Diagnostic accuracy of the Xpert CT/NG and OSOM Trichomonas Rapid assays for point-of-care STI testing among young women in South Africa: a cross-sectional study. BMJ Open, 9(2), e026888. https://doi.org/10.1136/bmjopen-
2018-026888 - Gaydos, C. A., Beqaj, S., Schwebke, J. R., Lebed, J., Smith, B., Davis, T. E., Fife, K. H., Nyirjesy, P., Spurrell, T., Furgerson, D., Coleman, J., Paradis, S., & Cooper, C. K. (2017). Clinical Validation of a Test for the Diagnosis of Vaginitis. Obstet Gynecol, 130(1), 181-189. https://doi.org/10.1097/aog.0000000000002090
- Giraldo, P., von Nowaskonski, A., Gomes, F. A., Linhares, I., Neves, N. A., & Witkin, S. S. (2000). Vaginal colonization by Candida in asymptomatic women with and without a history of recurrent vulvovaginal candidiasis. Obstet Gynecol, 95(3), 413-416. https://www.ncbi.nlm.nih.gov/pubmed/?term=10711554%5Buid%5D
- Hainer, B. L., & Gibson, M. V. (2011). Vaginitis: Diagnosis and Treatment. American Family Physician, 83(7), 807-815. /afp/2011/0401/p807.pdf
- Hilbert, D. W., Smith, W. L., Chadwick, S. G., Toner, G., Mordechai, E., Adelson, M. E., Aguin, T. J., Sobel, J. D., & Gygax, S. E. (2016). Development and Validation of a Highly Accurate Quantitative Real-Time PCR Assay for Diagnosis of Bacterial Vaginosis. J Clin Microbiol, 54(4), 1017-1024. https://doi.org/10.1128/jcm.03104-15
- Hill, G. B. (1993). The microbiology of bacterial vaginosis. Am J Obstet Gynecol, 169(2 Pt 2), 450-454.
- Hologic. (2019). FDA Clearance of Aptima BV and Aptima CV/TV Molecular Assays Ushers in New Era of Comprehensive and Objective Diagnostic Testing for Vaginitis https://investors.hologic.com/press-releases/press-release-details/2019/FDA-Clearance-of-Aptima-BV-and-Aptima-CVTV-Molecular-Assays-Ushers-in-New-Era-of-Comprehensive-and-Objective-Diagnostic-Testing-for-Vaginitis/default.aspx
- Hologic. (2022). Aptima® BV and CV/TV Assay. Hologic, Inc. Retrieved 08/08/2022 from https://hologicwomenshealth.com/products/aptimabvandcvtvassay/
- Hologic. (2023). Aptima® BV and CV/TV Assay. https://hologicwomenshealth.com/products/aptimabvandcvtvassay/
- Hopwood, V., Evans, E. G., & Carney, J. A. (1985). Rapid diagnosis of vaginal candidosis by latex particle agglutination. J Clin Pathol, 38(4), 455-458.
- Huppert, J. S., Mortensen, J. E., Reed, J. L., Kahn, J. A., Rich, K. D., Miller, W. C., & Hobbs, M. M. (2007). Rapid antigen testing compares favorably with transcription-mediated amplification assay for the detection of Trichomonas vaginalis in young women. Clin Infect Dis, 45(2), 194-198. https://doi.org/10.1086/518851
- Jones, A. (2019). Bacterial Vaginosis: A Review of Treatment, Recurrence, and Disparities. The Journal for Nurse Practitioners, 15(6), 420-423. https://doi.org/https://doi.org/10.1016/j.nurpra.2019.03.010
- Kairys, N., & Garg, M. (2020). Bacterial Vaginosis. StatPearls [Internet]. https://www.ncbi.nlm.nih.gov/books/NBK459216/
- Kissinger, P. (2015). Epidemiology and treatment of trichomoniasis. Curr Infect Dis Rep, 17(6), 484. https://doi.org/10.1007/s11908-015-0484-7
- Kong, A. M., Jenkins, D., Troeger, K. A., Kim, G., & London, R. S. (2021). Diagnostic Testing of Vaginitis: Improving the Value of Care. Population Health Management, 24(4), 515-524. https://doi.org/10.1089/pop.2021.0143
- Lamont, R. F., Sobel, J. D., Akins, R. A., Hassan, S. S., Chaiworapongsa, T., Kusanovic, J. P., & Romero, R. (2011). The vaginal microbiome: new information about genital tract flora using molecular based techniques. Bjog, 118(5), 533-549. https://doi.org/10.1111/j.1471-0528.2010.02840.x
- Landers, D. V., Wiesenfeld, H. C., Heine, R. P., Krohn, M. A., & Hillier, S. L. (2004). Predictive value of the clinical diagnosis of lower genital tract infection in women. Am J Obstet Gynecol, 190(4), 1004-1010. https://doi.org/10.1016/j.ajog.2004.02.015
- Ling, Z., Kong, J., Liu, F., Zhu, H., Chen, X., Wang, Y., Li, L., Nelson, K. E., Xia, Y., & Xiang, C. (2010). Molecular analysis of the diversity of vaginal microbiota associated with bacterial vaginosis. BMC Genomics, 11, 488. https://doi.org/10.1186/1471-2164-11-488
- Lynch, T., Peirano, G., Lloyd, T., Read, R., Carter, J., Chu, A., Shaman, J. A., Jarvis, J. P., Diamond, E., Ijaz, U. Z., & Church, D. (2019). Molecular Diagnosis of Vaginitis: Comparing Quantitative PCR and Microbiome Profiling Approaches to Current Microscopy Scoring. J Clin Microbiol, 57(9). https://doi.org/10.1128/jcm.00300-19
- Mahmoudi Rad, M., Zafarghandi, A., Amel Zabihi, M., Tavallaee, M., & Mirdamadi, Y. (2012). Identification of Candida species associated with vulvovaginal candidiasis by multiplex PCR. Infect Dis Obstet Gynecol, 2012, 872169. https://doi.org/10.1155/2012/872169
- Marot-Leblond, A., Nail-Billaud, S., Pilon, F., Beucher, B., Poulain, D., & Robert, R. (2009). Efficient diagnosis of vulvovaginal candidiasis by use of a new rapid immunochromatography test. J Clin Microbiol, 47(12), 3821-3825. https://doi.org/10.1128/jcm.01168-09
- Matsui, H., Hanaki, H., Takahashi, K., Yokoyama, A., Nakae, T., Sunakawa, K., & Omura, S. (2009). Rapid detection of vaginal Candida species by newly developed immunochromatography. Clin Vaccine Immunol, 16(9), 1366-1368. https://doi.org/10.1128/cvi.00204-09
- MDLabs. (2022). 166 Bacterial Vaginosis Panel by Real-Time PCR (with Lactobacillus Profiling by qPCR). https://www.mdlab.com/resources/testing-menu/?code=166
- MedLabs. (2015). AMPLISwab™ Women's Health. MEDLABS DIAGNOSTICS. Retrieved 2/4/2021 from http://www.medlabdx.com/AmpliSwab.html
- Menard, J. P., Fenollar, F., Henry, M., Bretelle, F., & Raoult, D. (2008). Molecular quantification of Gardnerella vaginalis and Atopobium vaginae loads to predict bacterial vaginosis. Clin Infect Dis, 47(1), 33-43. https://doi.org/10.1086/588661
- Menard, J. P., Mazouni, C., Fenollar, F., Raoult, D., Boubli, L., & Bretelle, F. (2010). Diagnostic accuracy of quantitative real-time PCR assay versus clinical and Gram stain identification of bacterial vaginosis. Eur J Clin Microbiol Infect Dis, 29(12), 1547-1552. https://doi.org/10.1007/s10096-010-1039-3
- Miller, J. M., Binnicker, M. J., Campbell, S., Carroll, K. C., Chapin, K. C., Gilligan, P. H., Gonzalez, M. D., Jerris, R. C., Kehl, S. C., Patel, R., Pritt, B. S., Richter, S. S., Robinson-Dunn, B., Schwartzman, J. D., Snyder, J. W., Telford, I. I. I. S., Theel, E. S., Thomson, J. R. B., Weinstein, M. P., & Yao, J. D. (2018). A Guide to Utilization of the Microbiology Laboratory for Diagnosis of Infectious Diseases: 2018 Update by the Infectious Diseases Society of America and the American Society for Microbiology. Clinical Infectious Diseases, ciy381-ciy381. https://doi.org/10.1093/cid/ciy381
- Myziuk, L., Romanowski, B., & Johnson, S. C. (2003). BVBlue test for diagnosis of bacterial vaginosis. J Clin Microbiol, 41(5), 1925-1928. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC154737/
- Owens, D. K., Davidson, K. W., Krist, A. H., Barry, M. J., Cabana, M., Caughey, A. B., Donahue, K., Doubeni, C. A., Epling, J. W., Jr., Kubik, M., Ogedegbe, G., Pbert, L., Silverstein, M., Simon, M. A., Tseng, C. W., & Wong, J. B. (2020). Screening for Bacterial Vaginosis in Pregnant Persons to Prevent Preterm Delivery: US Preventive Services Task Force Recommendation Statement. Jama, 323(13), 1286-1292. https://doi.org/10.1001/jama.2020.2684
- Paladine, H. L., & Desai, U. A. (2018). Vaginitis: Diagnosis and Treatment. Am Fam Physician, 97(5), 321-329. https://www.aafp.org/afp/2018/0301/p321.html
- Pappas, P. G., Kauffman, C. A., Andes, D. R., Clancy, C. J., Marr, K. A., Ostrosky-Zeichner, L., Reboli, A. C., Schuster, M. G., Vazquez, J. A., Walsh, T. J., Zaoutis, T. E., & Sobel, J. D. (2016). Clinical Practice Guideline for the Management of Candidiasis: 2016 Update by the Infectious Diseases Society of America. Clin Infect Dis, 62(4), e1-50. https://doi.org/10.1093/cid/civ933
- Quest. (2022a). SureSwab® Advanced Bacterial Vaginosis (BV), TMA. Quest Diagnostics, Inc. Retrieved 09/22/2022 from https://testdirectory.questdiagnostics.com/test/test-detail/10016/sureswab-advanced-bacterial-vaginosis-bv-tma?q=sureswab&cc=MASTER
- Quest. (2022b). SureSwab® Advanced Vaginitis Plus, TMA. Quest Diagnostics, Inc. Retrieved 09/09/2022 from https://testdirectory.questdiagnostics.com/test/test-detail/10120/sureswab-advanced-vaginitis-plus-tma?q=sureswab&cc=MASTER
- Quest. (2022c). SureSwab® Advanced Vaginitis, TMA. Quest Diagnostics, Inc. Retrieved 09/09/2022 from https://testdirectory.questdiagnostics.com/test/test-detail/10119/sureswab-advanced-vaginitis-tma?p=r&q=sureswab&cc=MASTER
- Richter, S. S., Otiso, J., Goje, O. J., Vogel, S., Aebly, J., Keller, G., Van Heule, H., Wehn, D., Stephens, A. L., Zanotti, S., Johnson, T., Leal, S. M., & Procop, G. W. (2019). Prospective Evaluation of Molecular Assays for Diagnosis of Vaginitis. J Clin Microbiol, 58(1). https://doi.org/10.1128/jcm.01264-19
- Schwebke, J. R., Gaydos, C. A., Nyirjesy, P., Paradis, S., Kodsi, S., & Cooper, C. K. (2018). Diagnostic Performance of a Molecular Test versus Clinician Assessment of Vaginitis. J Clin Microbiol, 56(6). https://doi.org/10.1128/jcm.00252-18
- Schwebke, J. R., Taylor, S. N., Ackerman, R., Schlaberg, R., Quigley, N. B., Gaydos, C. A., Chavoustie, S. E., Nyirjesy, P., Remillard, C. V., Estes, P., McKinney, B., Getman, D. K., & Clark, C. (2020). Clinical Validation of the Aptima Bacterial Vaginosis and Aptima Candida/Trichomonas Vaginitis Assays: Results from a Prospective Multicenter Clinical Study. J Clin Microbiol, 58(2). https://doi.org/10.1128/jcm.01643-19
- Sherrard, J. (2019). Evaluation of the BD MAX Vaginal Panel for the detection of vaginal infections in a sexual health service in the UK. Int J STD AIDS, 30(4), 411-414. https://doi.org/10.1177/0956462418815284
- Sobel, J. D. (1985). Epidemiology and pathogenesis of recurrent vulvovaginal candidiasis. Am J Obstet Gynecol, 152(7 Pt 2), 924-935.
- Sobel, J. D. (1999). Vulvovaginitis in healthy women. Compr Ther, 25(6-7), 335-346. http://dx.doi.org/
- Sobel, J. D. (2023a, 9/4/2020). Bacterial vaginosis: Clinical manifestations and diagnoses. Retrieved 1/29/2021 from https://www.uptodate.com/contents/bacterial-vaginosis-clinical-manifestations-and-diagnosis
- Sobel, J. D. (2023b, 02/09/2022). Candida vulvovaginitis: Clinical manifestations and diagnosis. Retrieved 02/09/2022 from https://www.uptodate.com/contents/candida-vulvovaginitis
- Sobel, J. D. (2023c, 05/16/2022). Vaginal discharge (vaginitis): Initial evaluation. https://www.uptodate.com/contents/vaginal-discharge-vaginitis-initial-evaluation
- Sobel, J. D., & Mitchell, C. (2023, 09/09/2022). Trichomoniasis. Retrieved 09/09/2022 from https://www.uptodate.com/contents/trichomoniasis
- Sobel, J. D., Subramanian, C., Foxman, B., Fairfax, M., & Gygax, S. E. (2013). Mixed vaginitis-more than coinfection and with therapeutic implications. Curr Infect Dis Rep, 15(2), 104-108. https://doi.org/10.1007/s11908-013-0325-5
- Spiegel, C. A. (1991). Bacterial vaginosis. Clin Microbiol Rev, 4(4), 485-502. http://dx.doi.org/
- Sumeksri, P., Koprasert, C., & Panichkul, S. (2005). BVBLUE test for diagnosis of bacterial vaginosis in pregnant women attending antenatal care at Phramongkutklao Hospital. J Med Assoc Thai, 88 Suppl 3, S7-13.
- Tabrizi, S. N., Pirotta, M. V., Rudland, E., & Garland, S. M. (2006). Detection of Candida species by PCR in self-collected vaginal swabs of women after taking antibiotics. In Mycoses (Vol. 49, pp. 523-524). https://doi.org/10.1111/j.1439-0507.2006.01312.x
- USPSTF. (2008). Screening for bacterial vaginosis in pregnancy to prevent preterm delivery: U.S. Preventive Services Task Force recommendation statement. Ann Intern Med, 148(3), 214-219.
- van Schalkwyk, J., & Yudin, M. H. (2015). Vulvovaginitis: screening for and management of trichomoniasis, vulvovaginal candidiasis, and bacterial vaginosis. J Obstet Gynaecol Can, 37(3), 266-274. https://doi.org/10.1016/s1701-2163(15)30316-9
- Weissenbacher, T., Witkin, S. S., Ledger, W. J., Tolbert, V., Gingelmaier, A., Scholz, C., Weissenbacher, E. R., Friese, K., & Mylonas, I. (2009). Relationship between clinical diagnosis of recurrent vulvovaginal candidiasis and detection of Candida species by culture and polymerase chain reaction. Arch Gynecol Obstet, 279(2), 125-129. https://doi.org/10.1007/s00404-008-0681-9
- Workowski, K. A., & Bolan, G. A. (2015). Sexually transmitted diseases treatment guidelines, 2015. MMWR Recomm Rep, 64(Rr-03), 1-137.
- Yudin, M. H., & Money, D. M. (2017). No. 211-Screening and Management of Bacterial Vaginosis in Pregnancy. J Obstet Gynaecol Can, 39(8), e184-e191. https://doi.org/10.1016/j.jogc.2017.04.018
Coding Section
Code | Number | Description |
CPT | 0352U (effective 10/01/2022) | Infectious disease (bacterial vaginosis and vaginitis), multiplex amplified probe technique, for detection of bacterial vaginosis-associated bacteria (BVAB-2, Atopobium vaginae, and Megasphera type 1), algorithm reported as detected or not detected and separate detection of Candida species (C. albicans, C. tropicalis, C. parapsilosis, C. dubliniensis), Candida glabrata/Candida krusei, and trichomonas vaginalis, vaginal-fluid specimen, each result reported as detected or not detected |
81513 (effective 01/01/2021) | Infectious disease, bacterial vaginosis, quantitative real-time amplification of RNA markers for Atopobium vaginae, Gardnerella vaginalis, and Lactobacillus species, utilizing vaginal-fluid specimens, algorithm reported as a positive or negative result for bacterial vaginosis |
|
81514 (effective 01/01/2021) | Infectious disease, bacterial vaginosis and vaginitis, quantitative real-time amplification of DNA markers for Gardnerella vaginalis, Atopobium vaginae, Megasphaera type 1, Bacterial Vaginosis Associated Bacteria-2 (BVAB-2), and Lactobacillus species (L. crispatus and L. jensenii), utilizing vaginal-fluid specimens, algorithm reported as a positive or negative for high likelihood of bacterial vaginosis, includes separate detection of Trichomonas vaginalis and/or Candida species (C. albicans, C. tropicalis, C. parapsilosis, C. dubliniensis), Candida glabrata, Candida krusei, when reported |
|
81515 (effective 01/01/2025) | Infectious disease, bacterial vaginosis and vaginitis, real-time PCR amplification of DNA markers for Atopobium vaginae, Atopobium species, Megasphaera type 1, and Bacterial Vaginosis Associated Bacteria-2 (BVAB-2), utilizing vaginal-fluid specimens, algorithm reported as positive or negative for high likelihood of bacterial vaginosis, includes separate detection of Trichomonas vaginalis and Candida species (C. albicans, C. tropicalis, C. parapsilosis, C. dubliniensis), Candida glabrata/Candida krusei, when reported | |
82120 | Amines, vaginal fluid, qualitative |
|
83986 | Ph; body fluid, not otherwise specified | |
87070 | Culture, bacterial; any other source except urine, blood or stool, aerobic, with isolation and presumptive identification of isolates | |
87149 | Culture, typing; identification by nucleic acid (DNA or RNA) probe, direct probe technique, per culture or isolate, each organism probed | |
87150 | Culture, typing; identification by nucleic acid (DNA or RNA) probe, amplified probe technique, per culture or isolate, each organism probed | |
87210 | Smear, primary source with interpretation; wet mount for infectious agents (e.g., saline, India ink, KOH preps) | |
87480 | Infectious agent detection by nucleic acid (dna or rna); candida species, direct probe technique | |
87481 | Infectious agent detection by nucleic acid (dna or rna); candida species, amplified probe technique | |
87482 | Infectious agent detection by nucleic acid (dna or rna); candida species, quantification technique | |
87510 | Infectious agent detection by nucleic acid (dna or rna); gardnerella vaginalis, direct probe technique | |
87511 | Infectious agent detection by nucleic acid (DNA or RNA); Gardnerella vaginalis, amplified probe technique |
|
87512 | Infectious agent detection by nucleic acid (DNA or RNA); Gardnerella vaginalis, quantification | |
87660 | Infectious agent detection by nucleic acid (dna or rna); trichomonas vaginalis, direct probe technique | |
87661 | Infectious agent detection by nucleic acid (dna or rna); trichomonas vaginalis, amplified probe technique | |
87797 | Infectious agent detection by nucleic acid (DNA or RNA), not otherwise specified; direct probe technique, each organism | |
87798 | Infectious agent detection by nucleic acid (DNA or RNA), not otherwise specified; amplified probe technique, each organism | |
87799 | Infectious agent detection by nucleic acid (DNA or RNA), not otherwise specified; quantification, each organism | |
87800 | Infectious agent detection by nucleic acid (dna or rna), multiple organisms; direct probe(s) technique | |
87801 | Infectious agent detection by nucleic acid (DNA or RNA), multiple organisms; amplified probe(s) technique | |
87808 | Infectious agent antigen detection by immunoassay with direct optical observation; trichomonas vaginalis | |
87905 | Infectious agent enzymatic activity other than virus (e.g., sialidase activity in vaginal fluid) | |
0330U | Infectious agent detection by nucleic acid (DNA or RNA), vaginal pathogen panel, identification of 27 organisms, amplified probe technique, vaginal swab Proprietary test: Bridge Women's Health Infectious Disease Detection Test Lab/Manufacturer: Bridge Diagnostics/ThermoFisher and Hologic Test Kit on Panther Instrument |
|
0352U | Infectious disease (bacterial vaginosis and vaginitis), multiplex amplified probe technique, for detection of bacterial vaginosis–associated bacteria (BVAB-2, Atopobium vaginae, and Megasphera type 1), algorithm reported as detected or not detected and separate detection of Candida species (C. albicans, C. tropicalis, C. parapsilosis, C. dubliniensis), Candida glabrata/Candida krusei, and trichomonas vaginalis, vaginal-fluid specimen, each result reported as detected or not detected Protietary test: Xpert® Xpress MVP Lab/Manufacturer: Cepheid® |
|
0505U (effective 10/01/2024) | Infectious disease (vaginal infection), identification of 32 pathogenic organisms, swab, real-time PCR, reported as positive or negative for each organism | |
Q0111 | Wet mounts, including preparations of vaginal, cervical or skin specimens | |
ICD-10-CM | A56.11 | Chlamydial female pelvic inflammatory disease |
A59 | Trichomoniasis | |
A59.0 | Urogenital trichomoniasis | |
A59.00 | Urogenital trichomoniasis, unspecified | |
A59.01 | Trichomonal vulvovaginitis | |
B37.3 | Candidiasis of vulva and vagina | |
B96.89 | Other specified bacterial agents as the cause of diseases classified elsewhere [Gardnerella vaginitis] | |
F11.10-F11.99 | Opioid related disorders [injecting drug users] | |
F13.10-F13.99 | Sedative, hypnotic, or anxiolytic related disorders [injecting drug users] | |
F14.10-F14.99 | Cocaine related disorders [injecting drug users] | |
F15.10-F15.99 | Other stimulant related disorders [injecting drug users] | |
L29.0 | Pruritus ani | |
L29.2 | Pruritus vulvae | |
L29.8 | Other pruritus | |
L29.9 | Pruritus, unspecified | |
N72 | Inflammatory disease of cervix uteri | |
N73 | Other female pelvic inflammatory diseases | |
N73.9 | Female pelvic inflammatory disease, unspecified | |
N76 | Other inflammation of vagina and vulva | |
N76.0 | Acute vaginitis | |
N76.1 | Subacute and chronic vaginitis | |
N76.2 | Acute vulvitis | |
N76.3 | Subacute and chronic vulvitis | |
N76.89 | Other specified inflammation of vagina and vulva | |
N77.1 | Vaginitis, vulvitis and vulvovaginitis in diseases classified elsewhere | |
N89.0 | Mild vaginal dysplasia | |
N89.1 | Moderate vagina dysplasia | |
N89.8 | Other specified noninflammatory disorders of vagina | |
N90.89 | Other specified noninflammatory disorders of vulva and perineum | |
N93 | Other abnormal uterine and vaginal bleeding | |
N94.11 | Superficial (introital) dyspareunia | |
N94.89 | Other specified conditions associated with female genital organs and menstrual cycle | |
O09.211 | Suprvsn of preg w history of pre-term labor, first trimester | |
O09.212 | Suprvsn of preg w history of pre-term labor, second tri | |
O09.213 | Suprvsn of preg w history of pre-term labor, third trimester | |
O09.219 | Suprvsn of preg w history of pre-term labor, unsp trimester | |
R10.2 | Pelvic and perineal pain | |
Z01.411 | Encounter for gynecological examination (general) (routine) with abnormal findings | |
Z11.2 | Encounter for screening for other bacterial diseases | |
Z11.3 | Encounter for screening for infections with a predominantly sexual mode of transmission | |
Z11.8 | Encounter for screening for other infectious and parasitic diseases [High risk screening for Trichomonas only] | |
Z13.89 | Encounter for screening for genitourinary disorders | |
Z20.2 | Contact with and (suspected) exposure to infections with a predominantly sexual mode of transmission | |
Z20.9 | Contact with and (suspected) exposure to unspecified communicable disease | |
Z33.1 | Pregnant state, incidental | |
Z72.5 | High risk sexual behavior | |
Z86.19 | Personal history of other infectious and parasitic diseases |
Procedure and diagnosis codes on medical policy documents are included only as a general reference tool for each policy. They may not be all-inclusive.
This medical policy was developed through consideration of peer-reviewed medical literature generally recognized by the relevant medical community, U.S. FDA approval status, nationally accepted standards of medical practice and accepted standards of medical practice in this community, Blue Cross Blue Shield Association technology assessment program (TEC) and other nonaffiliated technology evaluation centers, reference to federal regulations, other plan medical policies, and accredited national guidelines.
"Current Procedural Terminology © American Medical Association. All Rights Reserved"
History From 2024 Forward