Diagnosis of Vaginitis

Number: 0643

Table Of Contents

Policy
Applicable CPT / HCPCS / ICD-10 Codes
Background
References

Policy

Scope of Policy

This Clinical Policy Bulletin addresses the diagnosis of vaginitis.

  1. Medical Necessity

    Aetna considers the following medically necessary for the management of vaginitis:

    1. Direct DNA probe assays (e.g., Affirm VIP III) for trichomonas, Candida and Gardnerella for members with symptoms of vaginitis;
    2. Measurement of sialidase activity in vaginal fluid (e.g., the BVBlue test) for women with symptoms of vaginitis;
    3. Testing of pH, and testing for the presence of amines in vaginal fluids (e.g., FemExam) for women with symptoms of vaginitis;
    4. Nucleic acid amplification (PCR) tests for diagnosis of bacterial vaginosis (e.g., included in the BV 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)) and for the diagnosis of Candida vaginitis (Candida albicans, glabrata, krusei, parapsilosis and tropicalis) (e.g., included in the BD MAX vaginitis panel, GenPath GenPap, INFINITI Candida Vaginosis QUAD Assay, LabCorp NuSwab, MDL OneSwab and Quest's SureSwab test) in women with symptoms of vaginitis (see CPB 0650 - Polymerase Chain Reaction Testing: Selected Indications);
    5. Screening for Trichomonas vaginalis with nucleic acid amplification, direct probe, or antigen detection tests for women with the following risk factors (e.g., new or multiple partners; history of sexually transmitted diseases (STDs); exchange of sex for payment; or injection drug use).

  2. Experimental and Investigational

    The following procedures / tests are considered experimental and investigational because the effectiveness of these approaches has not been established (not an all-inclusive list):

    1. Pap smear for the diagnosis of Candida vulvo-vaginitis
    2. Routine screening for Candida and Gardnerella in asymptomatic women
    3. uBiome SmartJane screen
    4. Vaginal pathogen panel (identification of 27 organisms, Bridge Diagnostics) for vaginitis and for all other indications.

  3.  Related Policies

Table:

CPT Codes / HCPCS Codes / ICD-10 Codes
Code Code Description

CPT codes covered if selection criteria are met:
0353U Infectious agent detection by nucleic acid (DNA), Chlamydia trachomatis and Neisseria gonorrhoeae, multiplex amplified probe technique, urine, vaginal, pharyngeal, or rectal, each pathogen reported as detected or not detected
82120 Amines, vaginal fluid, qualitative
83986 pH, body fluid, except blood
87210 Smear, primary source with interpretation; wet mount for infectious agents (eg, saline, India ink, KOH preps)
87480 Infectious agent detection by nucleic acid (DNA or RNA); Candida species, direct probe technique
87491 Infectious agent detection by nucleic acid (DNA or RNA); Chlamydia trachomatis, amplified probe technique
87510 Infectious agent detection by nucleic acid (DNA or RNA); Gardnerella vaginalis, direct probe technique
87591 Infectious agent detection by nucleic acid (DNA or RNA); Neisseria gonorrhoeae, amplified probe technique
87660 Infectious agent detection by nucleic acid (DNA or RNA); Trichomonas vaginialis, direct probe technique
87661 Infectious agent detection by nucleic acid (DNA or RNA); Trichomonas vaginalis, amplified probe technique
87808 Infectious agent antigen detection by immunoassay with direct optical observation; Trichomonas vaginalis
87905 Infectious agent enzymatic activity other than virus (eg, sialidase activity in vaginal fluid) [BVBlue test]

CPT codes not covered for indications listed in the CPB:

uBiome SmartJane screen - no specific code:
88141 - 88155 Cytopathology, cervical or vaginal
88164 - 88167 Cytopathology, slides, cervical or vaginal
88174 - 88175 Cytopathology, cervical or vaginal

HCPCS codes not covered for indications listed in the CPB:
G0123 - G0124 Screening cytopathology, cervical or vaginal
G0141 - G0148 Screening cytopathology, smears, cervical or vaginal
P3000 - P3001 Screening papanicolaou smear, cervical or vaginal
Q0091 Screening papanicolaou smear, obtaining, preparing and conveyance of cervical or vaginal smear to laboratory

ICD-10 codes covered if selection criteria are met:
A59.01 Trichomonal vulvovaginitis
B37.31, B37.32 Candidiasis of vulva and vagina
B96.89 Other specified bacterial agents as the cause of diseases classified elsewhere [Gardnerella vaginitis]
F11.10 - F11.19, F13.10 - F13.19, F14.10 - F14.19, F15.10 - F15.19, F16.10 - F16.19, F19.10 - F19.19 Nondependent abuse of drugs [injection drug use]
F11.20 - F11.229, F13.20 - F13.229, F14.20 - F14.29, F15.20 - F15.29, F16.20 - F16.29, F19.20 - F19.29 Drug dependence [injection drug use]
L29.2 Pruritus vulvae
L29.3 Anogenital pruritus, unspecified
N76.0 - N76.3 Vaginitis and vulvitis
N77.1 Vaginitis, vulvitis and vulvovaginitis in diseases classified elsewhere
N89.8 Other specified noninflammatory disorders of vagina
O23.00 - O23.93 Infections of genitourinary tract in pregnancy
Z72.51 - Z72.53 High risk sexual behavior [exchange of sex for payment, new or multiple partners]

ICD-10 codes not covered for indications listed in the CPB:
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
Z13.89 Encounter for screening for other disorder
Z33.1 Pregnant state, incidental
Z34.00 - Z34.93 Encounter for supervision of normal pregnancy
Z86.19 Personal history of other infectious and parasitic diseases

PCR testing for Symptomatic Vaginitis:

CPT codes covered if selection criteria are met:
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
81513 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 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
87481 Infectious agent detection by nucleic acid (DNA or RNA); Candida species, amplified probe technique
87511      Gardnerella vaginalis, amplified probe technique
87512      Gardnerella vaginalis, quantification
87798 Infectious agent detection by nucleic acid (DNA or RNA), not otherwise specified; amplified probe technique, each organism
87799      quantification, each organism
87801 Infectious agent detection by nucleic acid (DNA or RNA), multiple organisms; amplified probe(s) technique

CPT codes not covered for indications listed in the CPB:
0330U Infectious agent detection by nucleic acid (DNA or RNA), vaginal pathogen panel, identification of 27 organisms, amplified probe technique, vaginal swab

ICD-10 codes covered if selection criteria are met:
B37.31, B37.32 Candidiasis of vulva and vagina
L29.2 Pruritus vulvae
L29.3 Anogenital pruritus, unspecified
N76.0 Acute vaginitis
N76.1 Subacute and chronic vaginitis
N76.2 Acute vulvitis
N76.3 Subacute and chronic vulvitis
N77.1 Vaginitis, vulvitis and vulvovaginitis in diseases classified elsewhere
N89.8 Other specified noninflammatory disorders of vaginitis

Background

Vaginitis (infection of the vagina) is the most common gynecologic condition encountered by physicians in the office.  Patients with vaginitis almost always present with a chief complaint of abnormal vaginal discharge.  The most common causes of vaginitis are trichomoniasis (Trichomonas vaginalis infection), vaginal candidiasis (Candida vaginalis), and bacterial vaginosis (BV).

Bacterial vaginosis (BV) is the commonest cause of vaginal discharge in women of child-bearing age.  It is characterized by an overgrowth of anaerobic bacteria (Gardnerella vaginalis, Mycoplasma hominis; Mobiluncus species; anaerobic gram-negative rods of the genera Prevotella, Porphyromonas and Bacteriodes; and Peptostreptococcus species) leading to replacement of lactobacilli and an increase in vaginal pH from less than 4.5 up to 7.0.  The term vaginosis implies that infection is accompanied by little or no inflammation of the vagina.

Diagnosis of vaginitis is based on clinical symptoms, pH of the vaginal fluid and microscopic examination of the discharge.  Symptoms are not present in approximately 50 % of women with bacterial vaginosis infection.  Bacterial vaginosis is not associated with soreness, itching or irritation.  There may be an offensive and classically "fishy" smelling vaginal discharge.

Ideally, a diagnosis of BV is made if 3 out of 4 of "Amsel's criteria" are met:

  • A strong, fishy odor on adding alkali to vaginal fluid (positive amine test)
  • Clue cells (vaginal epithelial cells heavily coated with bacilli) on microscopy
  • Thin, white, homogenous discharge
  • Vaginal pH greater than 4.5.

Microscopic examination may also reveal motile trichomonads or candida hyphae.  The presence of Gardnerella vaginalis on culture can not be used to diagnose BV, since it is present in approximately 50 % of healthy women.  Culture of trichomonas and candida may be helpful if clinical symptoms are suggestive and microscopy is negative.  Mixed infections are also common, with trichomonas, candida or both coexisting with BV.

Physicians have become interested in alternative, office based methods of diagnosing vaginitis.  Office microscopy to detect either clue cells, trichomonas or candida may be perceived as cumbersome and inaccurate.  For example, the sensitivity of microscopy in diagnosing trichomonas is estimated as low as 38 % (see Table).  It is also estimated that only 50 % of practicing physicians can correctly diagnose routine cases of vaginal candidiasis.  While the presence of clue cells to diagnose BV is considered a sensitive test, many physicians may not be adequately trained in microscopic techniques.  Finally, several aspects of the diagnosis are subjective (e.g., the visual examination of the discharge, reading the pH paper, and evaluation of the odor as part of the whiff test).

DNA probes have been developed to directly detect the presence of candida, trichomonas and Gardnerella, thus providing a more objective diagnosis.  Since Gardnerella is a normal part of the vaginal flora, the DNA probe test is designed to be relatively insensitive, detecting only pathogenic levels of Gardnerella.  The Affirm VP III Microbial Identification System (Becton Dickinson) is a commercially available DNA probe office-based test kit that simultaneously detects the presence of Gardnerella, trichomonas and candida.  The Affirm VP III was cleared by the FDA based on a 510(k) application in June 1993.  The test's sensitivity for detecting trichomonas vaginalis is high, and it can provide results in as little as 45 mins.  Trichomonas can also be detected by by DNA probes amplified by polymerase chain reaction.  Sample is treated with enzymes that amplify specific regions of trichomonas vaginalis' DNA.  After amplification, the number of DNA fragments are quantified.  Polymerase chain reaction has proven to be the most accurate diagnostic method in recent studies.  Moreover, it is currently only used in research, not clinical settings.

Other options include the use of test cards that contain pH indicators and an amine test system that can be evaluated visually, as opposed to evaluating the presence of amines by odor.  The FemExam is an example of such a commercially available test system.  Also available is pH paper developed specifically for evaluating vaginal secretions.

Testing for amines and pH testing is a well-established practice.  In contrast, the use of DNA probe tests may be used as an alternative or a compliment to microscopic techniques.

The World Health Organization reviewed the literature on diagnostic tests for vaginitis, and found DNA techniques to be significantly more sensitive than standard wet mount microscopy, with comparable specificity for vaginal candidiasis and vaginal trichomoniasis, but somewhat less sensitive for bacterial vaginosis.

Table Characteristics of Detection Assays: Sensitivity/Specificity (%)

Organism

Microscopy (wet mount)

Culture

Antigen detection

DNA
Candidiasis 35-45% / 99% 67% / 66% 61-81 % / 97% 80% / 98%
Trichomoniasis 38-82% / 100% 98% / 100% 86% / 99% 88-91% / 100%
Bacterial vaginosis 81% / 94% 89% / 93% 93% / 93% 94% / 81%

DNA probe tests may be especially useful for primary care physicians who may be less skilled in office laboratory diagnostic techniques for vaginitis than obstetricians and gynecologists.  Ferris and colleagues (1995) reported the results of a study that compared the performance of routine primary care physician-performed office laboratory diagnostic techniques for women with abnormal vaginal symptoms to the results obtained by a DNA probe test for Trichomonas vaginalis, Gardnerella vaginalis, and Candida species (Affirm VIP III).  The investigators found that primary care physicians were not as accurate as the DNA probe test in diagnosing vaginal infections.  Of 499 symptomatic women, vulvo-vaginal candidiasis was diagnosed in 20 %, vaginal trichomoniasis in 7.4 %, and bacterial vaginosis in 52.1 %.  Fourteen percent of subjects had multiple vaginal infections.  The sensitivity and specificity of clinician microscopically diagnosed vulvovaginal candidiasis was 39.6 % and 94 %, vaginal trichomoniasis was 75.0 % and 96.6 %, and bacterial vaginosis was 76.5 % and 70.8 %, using independent clinical examination by a medical technician as the gold standard.  By comparison, the sensitivity and specificity of the DNA probe test for vulvo-vaginal candidiasis was 75.0 % and 95.7 %, vaginal trichomoniasis was 86.5 % and 98.5 %, and bacterial vaginosis was 95.4 % and 60.7 %.  The DNA probe test was especially more accurate for diagnosing multiple vaginal infections.  When only women with multiple vaginal infections were considered, the percentages of correct clinician diagnosis for vulvovaginal candidiasis, trichomoniasis, and bacterial vaginosis were 49.3 %, 83.6 %, and 59.7 %.  For the DNA probe test, the percentages of correct diagnoses were 72.9 %, 92.9 % and 90.0 %, respectively.  The authors concluded that primary care physicians demonstrated a high specificity but low sensitivity when identifying vaginal trichomoniasis and vulvo-vaginal candidiasis by microscopic techniques, and that the primary care physicians were not as accurate as the DNA probe test.

The screening of asymptomatic pregnant women for bacterial vaginosis to reduce the likelihood of pre-term birth is considered experimental and investigational and is not covered.  The American College of Obstetricians and Gynecologists (2001) has concluded that "[t]here are no current data to support the use of … BV screening as strategies to identify or prevent pre-term birth.… Screening for risk of pre-term labor by means other than historic risk factors is not beneficial in the general obstetric population."  ACOG guidelines on risk factors for pre-term birth state: 

Although some trials have shown an association with the presence of BV and pre-term birth, most large trials designed to determine whether treatment of BV can prevent pre-term birth have failed.  Currently, there are insufficient data to suggest screening and treating women at either low or high risk will reduce the overall rate of pre-term birth.

Porter and colleagues (2004) stated that treating asymptomatic, low-risk women with BV does not always prevent pre-term delivery.  These authors further noted that, in general, there was no benefit to routine screening and treatment of BV.  Leitich (2005) stated that BV, elevated levels of interleukin (IL)-6, IL-8, ferritin and granulocyte colony-stimulating factor are some of the secondary predictors that confirm the role of intra-uterine infection in the pathogenesis of pre-term birth.  Apart from BV, inflammatory markers are still not routinely used.  The sensitivity of single markers in predicting pre-term birth is only moderate and serial examinations of markers, combinations of different markers and multiple marker tests have been studied, with limited results.  Studies of interventions in order to prevent pre-term birth have also yielded mixed benefits, as a consequence of which the use of these markers to screen low-risk pregnancies is generally not recommended.  Currently, secondary predictors of pre-term birth are used mainly to design new intervention studies tailored to specific high-risk populations and to avoid unnecessary interventions in the management of high-risk women.

The U.S. Preventive Services Task Force (USPSTF, 2008) does not recommend screening for bacterial vaginosis in pregnant women at low-risk for pre-term delivery.  The USPSTF also states that current evidence is insufficient to evaluate the balance of benefits and harms of screening for bacterial vaginosis in pregnant women at high-risk for pre-term delivery.  The USPSTF weighed the benefits and harms of screening for bacterial vaginosis in pregnancy by identifying new evidence addressing previously identified gaps from the 2001 USPSTF recommendation.  Published literature on this topic was identified by using MEDLINE, Cochrane Library databases, the Database of Abstracts of Reviews of Effects, reference lists, and consultation with experts and was systematically reviewed.  When data allowed, a series of meta-analyses (using new and 2001 report data) was done to estimate the pooled effect of treatment on pre-term delivery (less than 37 weeks, less than 34 weeks, or less than 32 weeks) and on low birth-weight and pre-term, premature rupture of membranes.

The USPSTF (Nygren et al, 2008) examined new evidence on the benefits and harms of screening and treating bacterial vaginosis in asymptomatic pregnant women.  Study and patient characteristics, treatment variables, adverse pregnancy outcomes, and internal validity quality criteria from the U.S. Preventive Services Task Force (USPSTF) and Jadad scale were abstracted.  A total of 7 new randomized, controlled treatment trials and 2001 report data were combined in a series of meta-analyses to estimate the pooled effect of treatment on pre-term delivery (less than 37, less than 34, and  less than 32 weeks); low birth-weight; and pre-term, premature rupture of membranes.  No screening studies that compared a screened population with a non-screened population were found.  Significant heterogeneity was found among the high-risk treatment trials (p < 0.001).  It is not clear from the detailed description of the studies which factors explain the differences in pre-term delivery rates and potentially the association of treatment effect; however, both raise concern for the unintended potential for harm.  The authors concluded that no benefit was found in treating women with low- or average-risk pregnancies for asymptomatic bacterial vaginosis.  They stated that more research is needed to better understand these groups and the conditions under which treatment can be harmful or helpful, and to explore the relevance of bacterial vaginosis to other adverse pregnancy outcomes, such as delivery before 34 weeks.

The BVBlue test (Genzyme Diagnostics, Cambridge, MA) is used to aid in the diagnosis of BV.  It detects elevated activity of vaginal-fluid sialidase, an enzyme produced by bacterial pathogens, such as gardnerella, mobiluncus, bacteroides, and prevotella.  With less than 1 min of hands-on time, the test provides objective results.  The solution turns blue or green if positive, yellow if negative, and is 92.8 % sensitive and 98 % specific versus gram stain.  Studies have shown that BV may increase the risk of preterm delivery, low-birth-weight infants, endometritis, pelvic inflammatory disease, and miscarriage; and may increase the susceptibility to HIV and other STDs.  While there are studies that reported the clinical value of the BVBlue test in diagnosing BV, available guidelines have not recommended its use.

Sumeksri et al (2005) compared the sensitivity of the BVBlue test for diagnosis of BV with Gram stain by using Nugent score as a gold standard.  The speculum for this examination, used in the process of collecting vaginal secretions, must not be lubricated with any lubricants.  The vaginal discharge was collected from the lower 1/3 of the vaginal wall.  Gram stain score and the BVBlue test were conducted and compared.  A total of 173 patients were enrolled in the present study.  The BVBlue test was compared to the standard method for the diagnosis of BV by Gram stain using Nugent score as a gold standard.  The sensitivity, specificity, accuracy, positive and negative predictive value of the BVBlue test versus the Gram stain score for diagnosis of bacterial vaginosis were 94 %, 96 %, 96 % 86 %, and 98 %, respectively.  The authors concluded that the BVBlue test for diagnosis of BV had high sensitivity, specificity, accuracy, positive- and negative-predictive value (94 %, 96 %, 96 %, 86 %, and 98 %, respectively).

On the other hand, Yen and colleagues (2003) noted that traditionally, BV diagnosis is defined clinically by the presence of 3 of the 4 Amsel criteria.  The authors stated that additional laboratory-based methods of BV diagnosis have included culture for G. vaginalis, biochemical tests for metabolic by-products of vaginal bacteria (gas chromatography), and colorimetric tests for enzymes produced by BV organisms (sialidase).  The authors stated, however, that these methods remain research tools and are not widely available in clinical settings.

Furthermore, the American Academy of Pediatrics Committee on Infectious Diseases (Red Book, 2012) as well as the U.S. Preventive Services Task Force's statement on screening for BV in pregnancy to prevent preterm delivery (2008) did not mention the use of the BVBlue system (sialidase activity). 

Guidelines on bacterial vaginosis from the British Association for Sexual Health and HIV (Hay, et al., 2012) stated that 2 approaches to diagnosis are available:

  • Amsel’s criteria. At least 3 of the four criteria are present for the diagnosis of bacterial vaginosis to be confirmed

    • Thin, white, homogeneous discharge; 
    • Clue cells on microscopy of wet mount;
    • pH of vaginal fluid greater than 4.5; and
    • Release of a fishy odor on adding alkali (10 % KOH)
      .

  • A Gram stained vaginal smear, evaluated with the Hay/Ison criteria or the Nugent criteria. 

    • The Hay/Ison criteria are defined as follows:

      • Grade 1 (normal)Lactobacillus morphotypes predominate;
      • Grade 2 (intermediate)mixed flora with some Lactobacilli present, but Gardnerella or Mobiluncus morphotypes also present;
      • Grade 3 (BV)predominantly Gardnerella and/or Mobiluncus morphotypes; few or absent Lactobacilli.

    • The Nugent score is derived from estimating the relative proportions of bacterial morphotypes to give a score between 0 and 10. A score of less than 4 is normal, 4 to 6 is intermediate, and greater than 6 is bacterial vaginosis.

The Bacterial Special Interest Group of the British Association of Sexual Health and HIV (Hay et al, 2012) recommend using the Hay/Ison criteria in genitourinary medicine clinics.  The guidelines note that commercially available tests are available such as the BVBlue, the Affirm VIP III, and a prolineaminopeptidase test card (Pip Activity TestCard, Quidel, San Diego, CA) "perform adequately" when assessed against Amsel and Gram stain criteria; however, the guidelines include no recommendation for their use.  The guidelines state that isolation of Gardnerella vaginalis cannot be used to diagnose bacterial vaginosis because it can be cultured from the vagina of more than half of normal women.  The guidelines stated that detection of combinations of bacterial vaginosis associated bacteria by polymerase chain reaction (PCR) may offer highly sensitive and specific diagnosis in the future but is not yet available.

The Centers for Disease Control and Prevention (2010) also recommended the gram stain as the gold standard for diagnosis of bacterial vaginosis, and recommend use of Amsel's criteria if a gram stain is not available.  Similar to the BASHH guidelines, the CDC states that the BVBlue, the Affirm VIP, and the Pip Activity TestCard "have acceptable performance characteristics" compared to the gram stain, but make no recommendation for their use.  The CDC stated that a card test is available for the detection of elevated pH and trimethylamine, but it has low sensitivity and specificity and therefore is not recommended.  The CDC also stated that PCR also has been used in research settings for the detection of a variety of organisms associated with bacterial vaginosis, but evaluation of its clinical utility is uncertain.  The CDC stated that culture of G. vaginalis is not recommended as a diagnostic tool because it is not specific, and that cervical Pap tests have no clinical utility for the diagnosis of bacterial vaginosis because of their low sensitivity.

Guidelines on bacterial vaginosis from the New York State Department of Health (2009) recommend Amsel's criteria for diagnosis of bacterial vaginosis.  The guidelines state that several commercially available tests have been developed recently and may be clinically useful; however, few published data exist on their performance.  The guidelines state that PCR is not the standard for evaluation, and that culture of G. vaginalis is too nonspecific to be used for diagnosis of bacterial vaginosis.

Guidelines from the World Heatlh Organization (Sherrard, et al., 2018) state that the current best method to diagnose bacterial vaginosis, Candida, and aerobic vaginitis is microscopy.  The guidelines state that PCR testing is the preferred method of diagnosing trichomonas vaginitis.

Guidelines from the Centers for Disease Control and Prevention (CDC) (Workowski et al, 2010) stated that screening for T. vaginalis in women can be considered in those at high risk for infection (i.e., women who have new or multiple partners, have a history of STDs, exchange sex for payment, and use injection drugs).

An UpToDate review on "Approach to women with symptoms of vaginitis" (Sobel, 2015a) does not mention PCR testing of Prevotella bivia as a tool of diagnostic evaluation.

An UpToDate review on "Candida vulvovaginitis" (Sobel, 2015b) states that "Pap smear is positive in 25 % of patients with culture positive, symptomatic vulvovaginal candidiasis.  It is insensitive because the cells are derived from the cervix, which is not affected by Candida vaginitis.  Treatment of Candida on a Pap smear of an asymptomatic woman is not indicated".

Next-Generation Sequencing for the Diagnosis of Vaginitis

Hong and colleagues (2016) stated that next-generation sequencing (NGS) can detect many more microorganisms of a microbiome than traditional methods.  These researchers analyzed the vaginal microbiomes of Korean women by using NGS that included bacteria and other microorganisms.  The NGS results were compared with the results of other assays, and NGS was evaluated for its feasibility for predicting vaginitis.  A total of 89 vaginal swab specimens were collected.  Microscopic examinations of Gram staining and microbiological cultures were conducted on 67 specimens; NGS was performed with GS junior system on all of the vaginal specimens for the 16S rRNA, internal transcribed spacer (ITS), and Tvk genes to detect bacteria, fungi, and Trichomonas vaginalis.  In addition, DNA probe assays of the Candida spp., Gardnerella vaginalis, and Trichomonas vaginalis were performed.  Various predictors of diversity that were obtained from the NGS data were analyzed to predict vaginitis; ITS sequences were obtained in most of the specimens (56.2 %).  The compositions of the intermediate and vaginitis Nugent score groups were similar to each other, but differed from the composition of the normal score group.  The fraction of the Lactobacillus spp. showed the highest area under the curve value (0.8559) in ROC curve analysis.  The NGS and DNA probe assay results showed good agreement (range of 86.2 to 89.7 %).  The authors concluded that fungi as well as bacteria should be considered for the investigation of vaginal microbiome.  The intermediate and vaginitis Nugent score groups were indistinguishable in NGS.  They stated that NGS is a promising diagnostic tool of the vaginal microbiome and vaginitis, although some problems need to be resolved.

This study had several drawbacks
  1. these investigators could not evaluate the various analytical performance parameters, but they examined the possibility of the use of NGS as a clinical diagnostic tool.  They evaluated the accuracy of the NGS assay by comparison with the culture and DNA probe assay results,
  2. the NGS results and microbiological culture results were indirectly compared,
  3. although the cost of NGS is decreasing rapidly, it is still too high for use as a clinical test, and
  4. the interpretation of the NGS data is complicated, and few recognizable standards for NGS interpretation exist.

PCR Testing (e.g., BD MAX Vaginal Panel)

Schwebke and colleagues (2018) determined the characteristics of an investigational test (BD MAX vaginal panel, a molecular test for vaginitis), compared to reference, for detection of bacterial vaginosis, Candida spp., and Trichomonas vaginalis.  Vaginal specimens from a cross-sectional study were obtained from 1,740 women (greater than or equal to 18 years old), with vaginitis symptoms, during routine clinic visits (across 10 sites in the United States).  Specimens were analyzed using a commercial PCR/fluorogenic probe-based investigational test that detects bacterial vaginosis, candida spp., and trichomonas vaginalis.  Clinician diagnosis and in-clinic testing (Amsel's test, potassium hydroxide preparation, and wet mount) were also employed to detect the 3 vaginitis causes.  All testing methods were compared to the respective reference methods (Nugent Gram stain for bacterial vaginosis, detection of the candida gene its2, and trichomonas vaginalis culture).  The investigational test, clinician diagnosis, and in-clinic testing were compared to reference methods for bacterial vaginosis, candida spp., and trichomonas vaginalis.  The investigational test resulted in significantly higher sensitivity and negative predictive value than clinician diagnosis or in-clinic testing.  In addition, the investigational test showed a statistically higher overall percent agreement with each of the 3 reference methods than did clinician diagnosis or in-clinic testing.  The investigational test showed significantly higher sensitivity for detecting vaginitis, involving more than one cause, than did clinician diagnosis.  Taken together, these results suggested that a molecular investigational test can facilitate accurate detection of vaginitis.  The authors concluded that findings from the current study supported the potential utility of the investigational test in the differential diagnosis of vaginitis.  While some laboratory tests take 2 to 7 days to provide results, the investigational test results were generally available within 24 hours.  Moreover, they stated that although future work is needed to establish the cost/benefit ratio regarding the application of this investigational test in a practical setting, its high sensitivity, specificity, and accuracy (across a large spectrum of disease prevalence) should impart benefits and decrease the chance of needless treatment of patients that are negative for the disease.  This may prove especially important with cases of vaginitis that involve multiple causes, where the sensitivity of clinician diagnosis may be limited.

The authors stated that this study had several drawbacks that prevented an exact interpretation of the findings.  Several analyses involved observations for each type of infection that were excluded due to non-compliance or inability to report.  It was possible, for example, that listing these types of observations as "not compliant" or "not reportable" for the investigational test, in lieu of "failure to correctly diagnose", may have artificially improved its operating characteristics.  Other drawbacks included the fact that the investigational assay may have resulted in an over-diagnosis of vaginitis, as it could not distinguish non-pathogenic colonization from pathogenic growth; this would be considered for clinician diagnosis.  However, the clinical cut-off for the investigational test was set by the current reference standard for diagnosing candida spp. (positive fungal culture report), and therefore, the results were consistent with everyday practice. Moreover, bacterial vaginosis may be detected by the Nugent score (7 to 10) but also be asymptomatic.  The investigational test showed the best agreement with the Nugent score, which is the gold standard, but may have included asymptomatic bacterial vaginosis.  The bacterial vaginosis algorithm for the investigational test was set by the composite reference method of concordant positive and negative Nugent and Amsel's criteria.  Thus, only unambiguous specimens for bacterial vaginosis status were used to develop the algorithm.  Additionally, this study employed a cross-sectional design that did not evaluate clinical outcomes for patients with discordant reference method results and clinician diagnosis.  Only clinics with expertise and resource availability for detection of the 4 Amsel's criteria and wet mount procedures were chosen as study sites.  Therefore, clinician diagnosis benefited from reliability of in-clinic results in a way that might not occur under real-life conditions.  Thus, the actual difference in clinician diagnosis versus the investigational test may likely be greater than that observed in this study.  Finally, in this study these investigators omitted the intermediate values for Nugent scoring (4 to 6), whereas Gaydos et al (2017) used the composite reference method of Nugent score combined with the modified Amsel 2/3 criteria without discharge to discriminate intermediate Nugent scoring (4 to 6).  These researchers may have missed some cases of bacterial vaginosis, the exclusion of which could have led to either an over- or under-estimation of performance in the investigational test.  However, the prevalence of bacterial vaginosis in this study (58% ) was very close to that reported by Gaydos et al (55.8 %).

Guidelines from the American College of Obstetricians and Gynecologists on vaginitis in nonpregnant patients (ACOG, 2020) address the use of PCR testing for the diagnosis of bacterial vaginosis, stating: "Polymerase chain reaction (PCR) has been used in research settings for the detection of G vaginalis as well as a variety of organisms associated with bacterial vaginosis; however, until recently, its use as a clinical diagnostic test for bacterial vaginosis was still investigational. . . . . Although the clinical utility of PCR testing for the diagnosis of bacterial vaginosis is still being evaluated, this single-swab multiplex test may be a promising alternative to microscopy."  Regarding the use of PCR testing for diagnosis of vulvovaginal Candidiasis, the ACOG guidelines state: "Polymerase chain reaction testing for Candida species offers results within a few hours compared with culture and has comparable sensitivity and specificity (97.7% and 93.2%, respectively). However, these PCR tests often are considerably more expensive than fungal culture and have not been FDA approved for the detection of yeast despite their frequent use in clinical practice."

Guidelines from the Centers for Disease Control and Prevention (Workowski, et al., 2021) state that, "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."  The guidelines also state 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." Regarding the use of PCR testing for diagnosis of vulvovaginal Candidiasis, the CDC guidelines state: "The majority of PCR tests for yeast are not FDA cleared, and providers who use these tests should be familiar with the performance characteristics of the specific test used."

Vaginal Pathogen Panel (Bridge Diagnostics)

Women's Health by Molecular Assay (Bridge Diagnostics) is a custom OpenArray assay vaginal pathogen panel, obtained via vaginal swab, used for the detection of 27 microorganisms (Atopobium vaginae, BVAB2, Chlamydia trachomatis, Enterococcus faecalis, Escherichia coli, Gardnerella vaginalis, Haemophilus ducreyi, Lactobacillus crispatus, Lactobacillus jensenii, Megasphaera Species (Type 1), Mobiluncus curtisii, Mobiluncus mulieris, Mycoplasma genitalium, Mycoplasma hominis, Neisseria gonorrhoeae, Staphylococcus aureus, Streptococcus agalactiae (GBS), Treponema pallidum (Syphilis), Candida albicans, Candida glabrata, Candida krusei, Candida parapsilosis Candida tropicalis, Trichomonas vaginalis, Herpes Simplex Virus type 1 (HSV-1), Herpes Simplex Virus type 2 (HSV-2)) involved in bacterial vaginosis (BV), aerobic vaginitis (AV), vaginal candidiasis, and sexually transmitted infections (STIs) using Real-Time PCR technology on the OpenArray platform.

References

The above policy is based on the following references:

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