Observations on the transmissibility of bv
Early experiments conducted in the 1950s and 1960s are the only studies thus far that addressed the transmissibility of BV in a direct manner. In particular, Gardner and Dukes [
23] accomplished to induce BV in 11 of 15 female volunteers who were inoculated directly with vaginal secretions from patients with BV. Conversely, when they inoculated women with pure culture
Gardnerella vaginalis, BV occurred in only one in 13 volunteering women. However, Criswell
et al [
24], did manage to induce BV in 7 out of 29 volunteering women when using higher inocula of pure culture
Gardnerella. Hence, in these early experiments, the transmissible nature of BV had been clearly demonstrated.
The contention of BV as a transmissible disease then gained even more significance as epidemiological data pointed at concurrent carriage of
G. vaginalis by women with BV and their male partners. Gardner and Dukes isolated
G. vaginalis from the urethra in 45 of 47 male partners of women with BV and later on, Pheifer
et al detected
G. vaginalis in the urethra of 27 of 34 partners of BV patients [
23,
25]. Most recently, Swidsinski
et al assessed
G. vaginalis carriage in a large cross-sectional study [
26] involving different population groups. Building further on the discovery of the BV biofilm [
27,
28], Swidsinski
et al first described that the presence of
G. vaginalis can also reliably be assessed through fluorescence-in-situ-hybridisation (FISH) analysis on desquamated epithelial cells in urine in both women and men. In this study, the presence of
G. vaginalis was further referred to as "dispersed"
Gardnerella, consisting of loosely dispersed
Gardnerella cells, and as "cohesive"
Gardnerella, consisting of clustered
Gardnerella cells adhesive to the epithelium, the latter indicative of the presence of the
Gardnerella biofilm, previously shown an obligate finding in BV [
27]. The authors enrolled among others, 20 women with symptomatic BV and 10 of their partners and 72 consecutive married pregnant women and their 72 partners. It was shown that the 20 women with symptomatic BV consistently presented with cohesive
Gardnerella as did the 10 partners investigated. Among the 72 married pregnant women and their 72 partners, dispersed
Gardnerella was found in 14% and cohesive
Gardnerella in 17% of the females. Again, cohesive
Gardnerella was consistently found among the partners of the women with cohesive
Gardnerella, for whom the samples were analysable. No such concordance was observed for dispersed
Gardnerella. Hence, the previously known strong concordance of
G. vaginalis carriage by both partners when a woman has BV was herewith confirmed but further refined by the almost absolute concordance of cohesive
Gardnerella carriage, which might indicate that this biofilm mode of growth represents the infectious mode of
Gardnerella and/or BV.
Following the demonstration of transmissibility of G. vaginalis isolated from pure culture, the recognition of male carriage, and the concordance of
G. vaginalis carriage between couples, Piot
et al provided further evidence of sexual transmission by obtaining vaginal cultures from 12 women with BV and urethral cultures from their 12 male consorts within 24 hours [
29]. The
G. vaginalis biotypes isolated from both partners were the same for 11 of the couples (p = 0.005), strongly suggestive for sexual transmission of
G. vaginalis.
Observations that support male-to-female heterosexual transmission
Since male G. vaginalis carriage was first demonstrated, as mentioned above, among male partners of patients with BV, it has long been postulated that male carriage might indicate the presence of a male reservoir possibly leading to male-to-female transmission, although this assumption is not unequivocally supported by the literature. We herewith review the data on male carriage of G. vaginalis and on measures directed towards prevention of male-to-female transmission, including partner treatment with antibiotics, condom use and male circumcision.
The two largest cohort studies on male carriage of
G. vaginalis conducted until present - both involving male attendees of a sexually transmitted disease clinic - documented male urethral carriage of
G. vaginalis at a rate of 11.4% (49/430) in the UK [
30] and of 4.5% (10/309) in Sweden [
31]. As a matter of fact, male carriage of
G. vaginalis may even be higher than estimated from the aforementioned studies, as urethral sampling may not be the optimal approach to document it. Kinghorn
et al found a significantly higher rate of
G. vaginalis isolation from preputial than from urethral swabs [
32]. Swidsinski
et al recently made a similar observation, and found that desquamated epithelial cells loaded with
G. vaginalis could only reliably be recovered in a urine specimen if the praeputium was not pulled back during voiding [
26]. In this manner, it was shown that among 100 men admitted to a department of internal medicine, dispersed
Gardnerella occurred in 4% of males, while cohesive
Gardnerella was present in 7% [
26]. In addition, several culture-based studies have also documented the presence of
G. vaginalis in semen samples [
33‐
38] - possibly pointing at a seminal or prostatic reservoir - whereby in one study
G. vaginalis was recovered from semen in as much as 38% of 58 men attending an infertility clinic [
34]. Intriguingly, preceding the renowned description of
G. vaginalis as the causative agent in non-specific vaginitis by Gardner and Dukes [
23], the very first description of the species now known as
G. vaginalis was in association with prostatitis [
39].
Up to date, six randomized controlled trials [
40‐
45] have addressed the effectiveness of male partner treatment in the treatment of BV. Five out of the six studies failed to document any benefit from male partner treatment with antibiotics [
40‐
42,
44,
45]. It may be acknowledged here, that most of these studies suffer from multiple methodological shortcomings [
46] including small sample sizes and large drop out rates. Moreover, the antibiotic regimens applied to male partners of women diagnosed with BV are mostly single doses or short courses with metronidazole or tinidazole, i.e. treatments that have been documented to be also poorly effective in women with BV and that are therefore not recommended by the CDC [
47]. In only one of the six RCTs, a CDC-recommended regimen for women was administered to the spouses of women with BV, consisting of a 7-day course of oral clindamycin [
45], though again without any noticeable effect. Finally, what one really wants to know is whether male treatment might prevent the recurrence of BV among their female partners, presuming that women might get re-infected from a male reservoir. This was addressed in two studies with a 3 month follow-up [
42,
45] whereby a recurrence rate of at least 50% among women is expected [
48]. Both these studies [
42,
45] failed to document any benefit of male sexual partner treatment on 3 month cure rates among their female partners.
It may be concluded that the evidence suggests that there is no benefit, i.e. reduction of BV occurrence in women, by treating the sexual partners of women with BV with the drug regimens tested [
46]. It may further be acknowledged that, when assuming a male-to-female route of transmission, the true effect of male treatment on the incidence of BV might at best be evaluated in a study in which male carriers would be treated prophylactically. Also, direct assessment of efficacy of antibiotic treatment for eradication of
G. vaginalis and other BV-associated micro-organisms in male partners would be essential, as the lack of effect of male treatment on recurrence of BV in female partners not necessarily excludes male-to-female reinfection, since male treatment may not eradicate biofilm-associated
G. vaginalis.
With regard to condom use as a means of preventing BV, six cross-sectional studies [
49‐
54] yielded contradicting results. Longitudinal and cohort studies on the other hand are more in line with each other towards a beneficial effect of condom use
vis-à-vis BV acquisition [
55‐
58], although the overall observed effect tends to be rather limited with an average relative risk reduction associated with condom use estimated at merely 20% in a recent meta-analysis [
59]. The two most recent studies also addressed recurrent BV [
58,
60]. Hutchinson
et al found a very strong overall protective effect of consistent condom use on the occurrence of both incident and recurrent BV in a three-year follow-up study (adjusted odds ratio 0.37, 95% CI 0.20-0.70) [
58]. Yotebieng
et al on the other hand found that consistent condom use in a 6-month follow-up study was protective against incident BV, but not against recurrent BV [
60]. Hence, the evidence on consistent condom use as a protective means for BV, overall, seems to suggest a rather moderate effect in the prevention of BV.
If the preputial space is suspected to act as the male reservoir of BV-associated micro-organisms - as was first suggested by Kinghorn
et al [
32] and recently reinforced by the findings by Swidsinski
et al [
26], who found more
G. vaginalis in men voiding without retracting the praeputium, then male circumcision is expected to have a protective effect on the occurrence of BV. However, results from a limited number of studies are contradictive again. In a US retrospective case-control study no difference was found in the prevalence of BV between women with circumcised partners compared to those with uncircumcised partners [
61]. In a large, very well-designed, randomised controlled trial involving a large cohort of young men in Rakai, Uganda however, male circumcision was associated with a significantly decreased risk (adjusted prevalence risk ratio 0.60, 95% CI 0.38-0.94) of BV at one year follow-up [
62].
Observations that support female-to-male heterosexual transmission
One of the earliest observations casting doubt over the purportedly male-to-female sexual transmission route comes from a large cohort study on urethral carriage of
G. vaginalis among men [
30]. In this study, Dawson
et al isolated
G. vaginalis from 11.4% of urethral samples from 430 consecutive male patients attending a clinic for sexually transmitted disease [
30]. Interestingly, the authors documented that the recovery rate of urethral
G. vaginalis was significantly higher in heterosexual men (14.5%) than among homosexual men (4.5%) (p < 0.001). This finding suggests that, somehow, heterosexual contact enhances male carriage of
G. vaginalis, as if female-to-male transmission rather than the opposite route is at stake. Ten years later, Holst conducted an elegant experiment that corroborates this hypothesis [
63]. Holst first documented that several BV-associated organisms, including
Mobiluncus mulieris,
M. curtisii and
G. vaginalis, could be isolated from the urethras and/or coronal sulci of 10 in 44 male consorts (22.7%) of women with BV. However, after two weeks of consistent condom use during regular sexual intercourse, these BV index species disappeared from all men [
63], suggesting that transient carriage of BV-associated micro-organisms by men actually may ensue from (continued) female-to-male contamination during intercourse. A very recent study by Schwebke
et al [
64] corroborates this. In this study, Schwebke
et al [
64] investigated male carriage of
G. vaginalis through species-specific PCR in urine, on a urethral swab, and on a swab obtained from the coronal sulcus from 47 men, of whom 23 were partners of women with BV and 24 were partners of women without BV. Overall,
G. vaginalis was detected in 12 males. The authors observed that the 11 participants who did use a condom at the last sexual encounter were all negative for
G. vaginalis, whereas one in three men (12/36) who did not use a condom at the last sexual encounter was positive for
Gardnerella. Moreover, none of the 5 participants who stated that they always used a condom for the past 3 months had
G. vaginalis, whereas 12/42 of those who did not always use a condom in the past 3 months were positive for
G. vaginalis [
64]. Thus, Schwebke
et al found that
G. vaginalis carriage by men is closely linked to condom use, and hence this is suggestive for a female-to-male transmission-like route of infection, as had been suggested by Holst [
63] two decades ago.
These findings may at least in part explain the high concordance rates between women with BV and their male consorts as mentioned above and may further explain the low success rate of BV eradication in women by condom use by their partners [
59].
In addition, a female-to-male route of transmission may further be consistent with the observation that
G. vaginalis is not present in prepubertal boys, as apparent from one study involving 99 boys with negative cultures for
G. vaginalis from the urethra, glans, and rectum [
65]. In accordance, in a study comprising 50 adolescent males who had not engaged yet in sexual activity/who were sexually inexperienced,
G. vaginalis was isolated from the urethra in only one [
66] and in a study by the same authors, involving 50 recently married, young men in monogamous relationships with no history of STDs,
G. vaginalis was isolated from none of them [
66].
Observations on bacterial vagiginosis resulting from non-coital sexual acts in heterosexuals
Among heterosexual women, non-coital sexual behaviours, including receptive oral sex, receptive anal sex, and non-penetrative digito-genital contact have also been identified to confer an increased risk of BV acquisition.
Nandwani
et al and Tchamouroff and Panja reported on a prospective cohort study, including 256 heterosexual female patients, attending a genito-urinary medicine clinic, and found a highly significant difference in the rate of BV among women who reported receptive oral sex in the previous four weeks (41/111 or 37%) as compared to women who did not experience cunnilingus in the past four weeks (14/145 or 10%, p < 0.001) [
67,
68]. Schwebke
et al also found that an unstable microflora - as defined by the number of episodes of vaginal microflora shifting away from a
Lactobacillus-dominated microbiota to a bacterial vaginosis-like profile - was significantly associated with more frequent episodes of receptive oral sex [
69]. Interestingly, a similar observation has been repeatedly made with regard to cunnilingus and vaginal
Candida infection [
70,
71,
54] and this was not explained by differences in extragenital carriage of
Candida by the women nor by differences in extragenital and genital carriage of
Candida by their partners [
70].
Unprotected receptive anal sex [
72,
73] and unprotected receptive anal sex before vaginal intercourse [
74] have also been associated with BV.
In a study involving 44 self-reported virginal women, of which 27 provided detailed information regarding sexual practices by a self-administered questionnaire, self-collected tampons were tested for
G. vaginalis and
A. vaginae through species-specific PCRs [
75]. Surprisingly, it was found that
G. vaginalis carriage in these virginal women was very strongly associated with oral sex and non-penetrative digito-genital contact [
75]. Similarly, Fethers
et al very recently documented an association among 17-21-year-old females between noncoital sexual practices (oral sex and non-penetrative digito-genital contact) and the occurrence of BV [
76].
Similarly, recurrent vaginal candidiasis has also been associated with a history of recent masturbating with saliva by both the patient as her partner, while this was not explained by oral
Candida carriage [
70]. Recurrent urinary tract infection has also been associated with frequent masturbation [
77].
Observations on the occurrence of bacterial vaginosis in sexually inexperienced women
Clearly, there is ample evidence that BV is not confined to women who are or were ever engaged in a heterosexual relationship, much in contrast to traditional STDs, indicating that heterosexual penetrative contact is definitely not a necessary prerequisite to the acquisition of BV.
Swidsinski
et al investigated
G. vaginalis carriage in 50 premenarchal girls and found that, dispersed
Gardnerella occurred in 10%, whereas none of the 50 girls showed cohesive, i.e. biofilm-associated,
Gardnerella [
26]. It has to be acknowledged here, that higher prevalence rates of
G. vaginalis have been found in sexually abused girls as compared to non-abused girls in most [
78‐
80] though not all studies [
81]. Apart from
G. vaginalis carriage, bacterial vaginosis in children is however rare. Anecdotically, Papanikolaou
et al reported one case of recurrent BV in a 17-year old adolescent with an intact hymen [
82].
In contrast, once beyond the menarche, BV also occurs among sexually inexperienced adolescents and virginal women according to several studies [
83‐
85], albeit at lower rates on average as compared to sexually active reproductive aged-women. This contention was recently challenged however by an Australian study comprising 528 young women of which 25 women had BV [
76] The largest sample up to date involved US women, entering the military, with a mean age of 19.1 years. In this study, BV in women reporting to never have had vaginal intercourse occurred at a rate of 18%, whereas their sexually experienced counterparts had BV at a rate of 28% [
84]. The findings on BV prevalence in the large cohort of US women entering the military are in line with those on
G. vaginalis epidemiology with a limited number of studies also documenting higher rates of
G. vaginalis carriage among sexually active adolescents. Shafer
et al reported that up to one third of non-sexually active adolescents harboured
G. vaginalis, which was significantly less than in sexually active adolescents (60%) [
86]. Another culture-based study of 120 asymptomatic 14- to 17-year-old females found a twofold lower prevalence of
G. vaginalis (17%) in women who reported no penetrative sexual activity compared with sexually active females (34%), albeit a non-statistically significant difference [
87]. So, overall, several lines of evidence corroborate that the BV incidence is increased by sexual activity, but clearly also contradict exclusive heterosexual transmission.
We reviewed the literature on BV epidemiology and extracted published data on BV in relation to sexual behaviour and thereby covered published studies and congress proceedings going back for more than half a century. We did not accomplish to unravel BV epidemiology, or to present a definite understanding of disease acquisition. A potential pitfall to our review, is that a considerable number of data reviewed relate to a single pathogen, in particular G. vaginalis, involved in a polymicrobial overgrowth condition. Though G. vaginalis is a key pathogen to BV, also numerically dominant in the biofilm mode of overgrowth in BV, it is not necessarily the BV initiating or causative agent.
Nonetheless, several conclusions, even if partially supported by circumstantial evidence, can be put forward.
First of all, it is clear that BV differs from established STDs in as much that BV is not confined to women who are, or were, ever engaged in a heterosexual relationship, indicating that, if anything, heterosexual penetrative contact is definitely not a necessary prerequisite to the acquisition of BV.
Among children and prepubertal girls, BV is rather rare, except in case of sexual abuse, even though vaginal carriage of
G. vaginalis identified through FISH is not uncommon in young girls according to one recent study [
26]. Similarly, based on culture-dependent study,
G. vaginalis seems to be virtually absent in prepubertal boys.
Once beyond the menarche however, BV is observed even among adolescent girls and sexually inexperienced girls, and young women in general, at an appreciable frequency, though on average at significantly lower rates as compared to sexually active adolescents and young women These findings do actually correlate well on what has been observed on the epidemiology of
G. vaginalis carriage among sexually active versus non-sexually active adolescents [
86,
87].
Girls and young women who have never engaged in penetrative sexual contact are likely to have practised non-penetrative heterosexual behaviours however, and Tabrizi
et al documented that among virginal women
G. vaginalis carriage was very strongly associated with oral sex and non-penetrative digito-genital contact [
75]. Similarly, Fethers
et al very recently documented an association among 17-21-year-old females between noncoital sexual practices (oral sex and non-penetrative digito-genital contact) and the occurrence of BV [
76].
These studies are further in line with several other studies that have identified oral receptive sex as a risk factor for BV [
67‐
69]. An obvious critique would be that these studies suffer from confounding, however Schwebke
et al for instance performed a thorough multivariable analysis, thereby controlling for a number of factors, and found that only receptive oral sex retained significance as a risk factor to unstable vaginal microflora, indicating microflora shifting away from
Lactobacillus dominance to a BV-like profile [
69].
So overall, epidemiological data obtained from adolescent girls and young women, point at an alternative pathogenesis model, not observed with traditionally defined STDs, this is, while the evidence corroborates on the one hand the sexual nature of BV, it clearly also contradicts at least to some extent a traditional infectious disease-like route of disease acquisition.
Furthermore, there is convincing evidence ensuing from condom studies [
63,
64], from studies among heterosexual versus homosexual men [
30], and from studies among young, monogamous men [
65,
66], that transmission of BV-associated micro-organisms may occur, however that female-to-male transmission may be a far more common route than male-to-female transmission. This sheds a completely different light on the high concordance rates of
G. vaginalis carriage among couples of whom the female partner has BV, which has been a longstanding argument in favour of BV as an STD.
Data on BV epidemiology among WSW in turn support both aforementioned pathogenetic pathways, i.e. the high rates of BV among WSW may point either at female-to-female route of transmission, either at sexual enhancement of BV occurrence through non-coital sexual behaviours, similar to what is observed among heterosexual couples. Indeed, it has been observed that WSW not only present rather consistently with very high prevalence rates of
G. vaginalis and bacterial vaginosis, but also that monogamous lesbian couples present with high concordance rates of vaginal microflora characteristics in general. This was recently confirmed by Marrazzo
et al in terms of concordance between
Lactobacillus species shared by monogamous lesbian couples [
92]. It remains elusive how this concordance is established, though likely to be sexually related. Marrazzo
et al thereby also pointed at a putative disease mechanism. In particular, recent receptive digital-vaginal sex apparently affected the vaginal
Lactobacillus community composition and specifically, receptive digital-vaginal sex was associated with the presence of
L. gasseri, whereas the presence of
L. gasseri in turn was associated with an increased BV risk [
92]. The presence of
L. gasseri (and
L. iners) was recently also found among heterosexual pregnant women to confer an increased BV risk [
93].
So as a first set of conclusions, it appears as if (1) women with BV may transmit BV-associated micro-organisms to their male or female sexual partners and (2) that non-coital sexual behaviours may enhance the occurrence of BV, which may relate to an effect of such non-penetrative heterosexual and homosexual behaviours on the Lactobacillus composition of the vaginal niche, or by the introduction of G. vaginalis and/or other BV-related anaerobes in the vagina, or by both.
Finally, while there is ample evidence that both protected and unprotected penetrative sexual behaviour is at the very least a risk marker if not a causal factor to BV, it remains to be answered for how sexual contact is related to BV occurrence and whether this involves sexual transmission of BV-related micro-organisms from a male to a female host. Two alternative explanations emerge from the literature however.
Firstly, an interesting observation was published in 1971 by Leppäluoto [
94]. Leppäluoto concluded - based on the study of a large series of Papanicolaou smears taken before and after unprotected coitus - that, lactobacilli-dominated precoital smears were replaced by
G. vaginalis dominant microflora in postcoital smears [
94]. Hence, coitus seems to be associated with a temporary disbalance in the delicate vaginal microflora equilibrium in favour of BV-related micro-organisms. Leppäluoto further launched the idea that the temporary imbalance of the vaginal microflora towards a BV-like profile serves sperm survival and transport, and further speculated that this imbalance is actually physiological in nature, if the microflora is allowed enough time to recover following a coital act [
94]. This in turn might concur with the observation made by Vallor
et al, that loss of hydrogen peroxide producing lactobacilli is primarily explained by the frequency of intercourse [
95], while a lack or loss of hydrogen peroxide producing lactobacilli is a strong risk factor to the occurrence of BV [
55,
96‐
99].
The most straightforward explanation to this coital effect on the vaginal microflora is that unprotected sexual intercourse alters the physico-chemical vaginal environment thereby also affecting the vaginal microflora. In particular, it has been shown that the alkaline prostatic content of the ejaculate raises the vaginal pH, which remains elevated up to eight hours following coitus [
100]. The alkaline ejaculate neutralizes the vaginal pH and the reacidificiation rate of the vagina is estimated (based on
in vitro experiments) to proceed at about 0.75 pH units per hour in the presence of log8 lactobacilli [
101]. Anaerobes grow preferably at a higher pH. The optimum pH for
G. vaginalis is 6 to 6.5 [
102] and it is 5 for
P. bivia [
103]. Hence, unprotected coitus most likely induces an imbalance at the level of the vaginal growth conditions and epithelial binding sites in favour of BV-associated micro-organisms as consistently shown in a large series of postcoital smears by Leppäluoto [
94]. Hence, increased coital activity may be one of the reasons why lactobacilli are losing the plot [
104].
However, if this were the only mechanism involved than condom use would be expected to act as a very effective means of prevention - which it is not - and hence the proposed mechanism involving a pH-increase does not quite explain why BV acquisition is almost equally enhanced by protected intercourse, as outlined above. Possibly, condom use might be protective against incident BV, but this effect may be obscured in epidemiological studies due to recurrent BV in a substantial number of women, not prevented by condom use.
As a second alternative mechanism, apart from the coital pH-mediated effect on the vaginal microflora, another conceivable mechanism that may be considered is that vaginal penetration somehow promotes the transfer of perianal, perineal, and perivulvar bacteria to the vagina, thereby possibly inducing BV in some women. A similar mechanism has been observed for urinary tract infections in women, and in particular, a significantly elevated risk for urinary tract infection with
E. coli associated with condom use has been observed [
105], presumably involving a rectal-vestibular-urethral pathway. A most important piece of evidence to this postulate with regard to BV, comes from a study by Eschenbach
et al in which they aimed to document the effects of a single episode of intercourse on the vaginal microflora in subjects randomly assigned to groups that used no condom or lubricated (nonspermicide) condoms [
106]. It was found that the 22 subjects who used no condoms had significantly more
E. coli at a high concentration (> 10
5 cfu/mL) in the vagina following unprotected intercourse. However, among the 20 subjects who did use condoms there was also a marginally significant trend towards more vaginal
E. coli (p = 0.06) and a highly significant increase in other enteric gram-negative rods (p = 0.001) after protected intercourse [
106]. It is therefore conceivable that also other, non-coital sexual acts such as oral sex endanger the vaginal microflora through the transfer of BV-associated bacteria from the rectal and perineal regions to the vulvar region and the vagina in analogy to what has been observed for urinary tract infections [
107].
Taken together, the abovementioned data suggest that unprotected intercourse may affect the vaginal microflora status through a suppressive effect on lactobacillary colonisation, on the colonisation resistance of the H
2O
2-producing lactobacilli, and through the introduction of enteric gram-negative bacteria, but equally, that even protected intercourse is associated with a significant increase of enteric bacteria in the vagina. These mechanisms therefore suggest that BV may behave as a
sexually enhanced disease rather than an (exclusively)
sexually transmitted infection. A critical factor - as outlined above - thereby presumably is the frequency of intercourse as has been shown for BV [
95] and for urinary tract infection [
108,
109], possibly by not granting the vaginal ecosystem to restore after a coital act.
Finally, it may be concluded that at present, there is little evidence in support of some kind of male-to-female sexual transmission of BV-associated pathogens. It may be acknowledged however that this transmission route cannot be ruled out based on the available evidence. First, with the surge of molecular studies of the vaginal microflora, a whole new series of previously unknown bacteria has been identified with bacterial vaginosis [
110,
111] and it is not known whether these species might be transferred through sexual contact and whether these may act as BV-inducing micro-organisms. Secondly, there are some epidemiological data that cannot be explained solely by the sexually enhanced disease model, in particular the observation in the Rakai study [
62] that male circumcision is strongly protective against BV acquisition, possibly pointing at the presence of BV-associated bacteria on the prepuce, as recently corroborated by Swidsinski
et al [
26].
In summary, while there is inconclusive evidence in support of male-to-female sexual transmission, we propose that the strong association between sexual behaviour - and level of sexual activity in particular - may be explained by an alternative pathogenetic model, which implies that BV might behave as a sexually enhanced disease rather than a sexually transmitted infection. This model is in principle consistent with most epidemiological observations cited in this review.