What is the Nature of Pelvic Floor Muscle Involvement in Dyspareunia?

Overview

Dyspareunia, or pain experienced by women during penetrative sexual activities, affects the psychological and sexual health of more than one in five Canadian women [1], yet its pathophysiology is poorly understood [2-4] and evidence for management approaches is limited.[5] It is thought that pelvic floor muscle (PFM) dysfunction is implicated in many forms of dyspareunia, while the nature and aetiology of this involvement remain largely unknown. The goal of this study is to understand if and how PFM dysfunction contributes to the pain experienced by women with provoked vestibulodynia (PVD), the most common cause of dyspareunia. This goal will be achieved through implementing an innovative and comprehensive approach to measuring the neuromuscular function of the PFMs. Understanding the pathophysiology of PVD is essential to the development of effective interventions to improve the health and quality of life of the many Canadian women who suffer from dyspareunia.

Study Type

  • Study Type: Observational
  • Study Design
    • Time Perspective: Cross-Sectional
  • Study Primary Completion Date: January 15, 2023

Detailed Description

Despite its high prevalence, little is known about the aetiology of dyspareunia. Dyspareunia is often sub-classified by the location (generalized vs a specific region) and by the stimulus that induces pain (provoked vs spontaneous). As such, PVD is characterized by severe sharp and/or burning pain felt at the entrance to the vagina (i.e. the vulvar vestibule) when pressure is applied to this area (i.e. provoked). [2] PVD is considered to be the most common cause of dyspareunia in pre-menopausal women, with a prevalence of about 12% of women, [1] while it remains underreported due to stigma embarrassment and shame. [6] Among women who seek intervention for PVD, involuntary PFM activation is thought to play a significant role in the onset and/or maintenance of pain. [7-15] Indeed, PVD is sometimes accompanied by intense, involuntary contraction of the PFMs [3], termed vaginismus (VAG). Yet it is not known whether PVD and VAG are distinct entities, or whether VAG exists along some continuum of PVD severity; [8,16] a matter of much debate in the literature.[17,19] There is evidence to suggest that PFM dysfunction is a feature of PVD even in the absence of VAG.[7-15,20] When assessed through intravaginal palpation, women with PVD (without VAG) present with higher PFM tone (i.e., greater resistance to a passive manual stretch of the PFMs), difficulty relaxing their PFMs following a contraction, and lower PFM strength when compared to asymptomatic women.[7-9] Yet strength and tone graded by palpation are subjective, and studies were performed without assessor blinding. Some of these palpation findings have been corroborated using electromyography (EMG), including higher than normal tonic PFM activation,[14,21,22] poor ability to achieve a PFM contraction [10], impaired ability to relax the PFMs after activation [4], and/or poor ability to sustain a consistent activation level on voluntary PFM contraction,[10,15,23] yet the latter findings have been refuted by others.[9,20,24-26] While this more objective evidence exists, studies on PFM involvement in PVD using EMG have been small (n<12), have carried high risk of bias, [27] and authors have often failed to report whether women with PVD had concurrent VAG, perpetuating the lack of clarity around diagnosis. Indeed, it is often difficult to determine on clinical examination whether or not VAG is present in women with PVD [3] and the new Diagnostic and Statistical Manual of Mental Disorders (DSM-5) omits any distinction between PVD and VAG, referring to both as genito pelvic pain penetration disorder (GPPPD17,21). Yet PFM involvement in PVD that is accompanied by VAG (PVD+VAG) may be distinct from PFM dysfunction in PVD with no concurrent VAG. [4,27-31] While trying to understand the nature of PFM involvement in PVD, it remains prudent to evaluate the PFMs while distinguishing between those with PVD+VAG and those with PVD alone.[19] This study will contribute to our knowledge of the nature of PFM involvement in PVD, and will inform on differences in PFM involvement between those with PVD alone and those with PVD+VAG. Objectives and hypotheses: The overall goal of this project is to determine whether alterations in tonic, voluntary, reflex or behavioural responses of the superficial and/or the deep layer of the (PFMs) are implicated in PVD and/or PVD+VAG. There are four main aims with associated hypotheses: Aim 1: To measure and compare pressure pain threshold (PPT), Temporal Summation (TS) at the vulvar vestibule, pain reported during the tampon test, and sexual function. Hypothesis 1 (a): Compared to pain-free controls, women with PVD and PVD+VAG will demonstrate (a) greater self-reported pain during the tampon test. (b) lower PPT, (c) higher TS, and (d) lower sexual function. Aim 2: To measure corticomotor excitability of projections to the PFMs through motor evoked potentials (MEPs) and cortically mediated silent periods (cSPs). Hypothesis 2(a) Compared to pain-free controls, women with PVD and PVD+VAG will have larger MEPs and shorter cSPs in the bulbocavernosus, pubovisceral, and external anal sphincter muscles in response to transcranial magnetic stimulation (TMS) of the cortical area corresponding to the PFMs. Hypothesis 2(b) Differences will be evident between women with PVD and PVD+VAG. Aim 3: To measure the amplitude and timing of EMG responses to pressure applied to the vulvar vestibule and the posterior thigh Hypothesis 3 (a): Compared to pain-free controls, women with PVD and PVD+VAG will have higher incidences of anticipatory responses (ie. responses recorded before pressure is applied) recorded from the PFMs (bulbocavernosus, pubovisceral, external anal sphincter) and remote (uppper trapezius, hip adductor) muscles when standardized pressure stimuli are applied to the posterior vaginal fourchette regardless of the intensity of the pressure (low vs moderate). Hypothesis 3 (b): Compared to pain-free controls, women with PVD and PVD+VAG will have higher muscle activation amplitude responses in the PFMs (bulbocavernosus, pubovisceral, external anal sphincter) and in more remote muscles (trapezius and hip adductor muscles) after standardized pressure stimuli (both low and moderate) are applied to the posterior vaginal fourchette. Hypothesis 3 (c): Compared to pain-free controls, women with PVD and PVD+VAG will demonstrate larger responses in the PFMs (bulbocavernosus, pubovisceral, external anal sphincter) and in more remote muscles (trapezius or hip adductors) in response to pressure that is applied to the posterior thigh. Aim 4: To measure the amplitude of PFM activation at rest (tonic), during maximum effort voluntary contraction of the PFMs and during a straining (Valsalva) maneuver Hypothesis 4: Compared to pain-free controls, women with PVD and PVD+VAG will demonstrate (a) higher tonic PFM activation, (b) more PFM activation during straining efforts (dyssynergia) and (c) lower PFM activation on maximum voluntary contraction. Novelty and Contributions to the advancement of knowledge: Through this study, a comprehensive picture of neuromuscular impairments in the PFMs that are associated with PVD will be generated. Through Aim 1 it is expected to find in women with PVD and PVD+VAG, greater self reported pain during tampon test, lower pressure pain threshold, higher temporal summation and lower sexual function comparing with the control group. No study has investigated corticomotor excitability of projections to the PFMs through TMS. Through Aim 2 differences in corticomotor excitability to the PFMs, evidenced through higher amplitude MEPs and shorter duration cSPs are expected to be found, between women with and without PVD as well as differences in the extent of enhanced corticomotor excitability to the PFMs between PVD and PVD+VAG. Also no study has evaluated whether differences seen in tonic or phasic responses of the PFMs between women with PVD and controls are present because of or in anticipation of pain. Studies by Van Lunsen & Ramakers [32], Reissing et al. [8] and van der Velde & Everaerd [33] suggest that the PFMs respond to generalized anxiety and in response to watching sexually threatening scenes. It is quite possible, and even probable, that anxiety or fear of pain may influence study outcomes [4,34]. Through Aim 3, the timing and magnitude of PFM activation will be evaluated to determine whether responses occur in anticipation of (i.e. before) and/or in response to pressure stimuli delivered at the vulvar vestibule. The hypotheses under Aims 2 and 3 have never before been tested and doing so will have a significant impact on our understanding of the pathophysiology of PVD. Through Aim 4, it we expect to corroborate previous findings in the literature: that women with PVD and PVD+VAG will demonstrate higher tonic PFM activation and PFM dyssynergia during straining – both being functionally related to increased corticomotor excitability. If women with PVD+VAG exhibit higher corticomotor excitability than women with PVD alone, this finding will be a major step toward understanding PVD and PVD+VAG as separate conditions, and will set the stage for improved diagnoses and targeted treatments such as repetitive TMS35 and neurotropic medications.[36] Further, interventions that have shown some evidence for effectiveness [37] including stretching, [9,38,39] acupuncture, [40] Botox injection, [41,42] and cognitive behavioural therapy [39] may be enhanced by combining them with new interventions that focus on corticomotor inhibition. The impact of any new as well as existing interventions on corticomotor excitability can, in turn, be evaluated using the innovative yet accessible assessment approaches developed through this work. For descriptive purposes, five on-line questionnaires will be applied to assess sexual function [43,44], pain [45] pain catastrophising [46], depression/anxiety [47,48], and central sensitization [49]. Assessment will be scheduled within the week following the start of women's last menstrual cycle to account for cyclic variations in motor and sensory thresholds [50] , and at a time that is convenient.

Interventions

  • Diagnostic Test: Corticomotor excitability to the pelvic floor muscles
    • Transcranial magenetic stimulation will be used to probe the excitability of cortical projections to the pelvic floor muscles. The outcomes of interest will include motor evoked potential amplitude and silent period.
  • Diagnostic Test: Pelvic floor muscle response to pressure applied at the vulvar vestibule
    • Electromyography will be used to determine whether the pelvic floor muscles (PFMs) respond to pressure applied to the vulvar vestibule as anticipatory (i.e. PFMs are active before the pressure is applied) and as behavioural (i.e. PFMs are active after the pressure is applied) responses. The amplitude of the EMG responses will also be recorded.
  • Diagnostic Test: Pressure pain threshold (PPS)
    • A custom vulvalgesiometer will be used to determine the mean pressure at which participants first report pain at the posterior vaginal fourchette.
  • Diagnostic Test: Temporal summation of pain
    • A custom vulvalgesiometer will be used to apply the same pressure (rated as 4/10 duiring PPS testing as described above) to the vulvar vestibule across 10 repetitions. The difference in pain rated on the tenth application and that rated on the first application will be the outcome.
  • Diagnostic Test: Tonic, phasic and reflex activation of the pelvic floor muscles (PFMs)
    • Electromyography will be used to measure the mean smoothed, rectified activation amplitude across 1 second of complete rest, across three maximal effort PFM contractions, and across three attempts at a bearing down maneuver.

Arms, Groups and Cohorts

  • Provoked vestibulodynia (PVD)
    • Provoked vestibulodynia (PVD) is characterized by severe sharp and/or burning pain felt at the entrance to the vagina (i.e. the vulvar vestibule) when pressure is applied to this area or during attempts at vaginal insertional activities (i.e. provoked).
  • Provoked vestibulodynia (PVD) + Vaginismus (VAG)
    • PVD is sometimes accompanied by intense, involuntary contraction of the PFMs3, termed vaginismus (VAG).
  • Control
    • Participants matched by age (within 2 years), parity (parous vs nulliparous) and use of oral contraceptive medications (yes vs no) to women in the PVD group, with no signs and symptoms of PVD.

Clinical Trial Outcome Measures

Primary Measures

  • Motor evoked potential (MEP) peak to peak amplitude (µV)
    • Time Frame: 1 day
    • Transcranial magnetic stimulation outcome (i.e. Motor evoked potential peak to peak amplitude – µV) will be determined for all participants and compared among groups. A Magstim® 200 system coupled with a double cone coil (96 mm loops, P/N 9902) [57] will be used to probe the corticospinal projections to PFMs. MEPs will be ensemble averaged to generate estimates of MEP peak to peak amplitude (µV).
  • Cortical silent period duration (ms)
    • Time Frame: 1 day
    • Transcranial magnetic stimulation outcome (i.e. cortical silent period duration – ms) will be determined for all participants and compared among groups. A Magstim® 200 system coupled with a double cone coil (96 mm loops, P/N 9902) [57] will be used to probe the corticospinal projections to PFMs. MEP cortical silent period (cSP) will be measured from individual trials and then averaged.
  • Anticipatory responses (ms)
    • Time Frame: 1 day
    • The proportion of women in each group who demonstrate anticipatory responses of the PFMs to impending pressure applied at the vulvar vestibule will be determined for each group. Participants will be deemed to have anticipatory responses if electromyographic signals recorded from the PFMs precede the application of pressure. A vulvalgesiometer [58] will be employed using a response-dependent methodology. [59,60] The vulvalgesiometer will be used to apply low (25 g) and moderate (232 g) pressures to the posterior vaginal fourchette or to the posterior thigh, the moderate value having been generated through the team’s previous research. [9]
  • Behavioural responses (µV)
    • Time Frame: 1 day
    • The proportion of women in each group who demonstrate behavioral responses of the PFMs to pressure applied at the vulvar vestibule will be determined for each group. Participants will be deemed to have behavioural if the activation of the PFMs (or other muscles) occurs after the pressure is applied. A vulvalgesiometer [58] will be employed using a response-dependent methodology. [59,60] The vulvalgesiometer will be used to apply low (25 g) and moderate (232 g) pressures to the posterior vaginal fourchette or to the posterior thigh, the moderate value having been generated through the team’s previous research. [9]
  • Tonic, phasic and reflex activation of the pelvic floor muscles
    • Time Frame: 1 day
    • Surface Electromyography (EMG) recorded using differential suction electrodes (DSEs, developed by Dr. McLean) [54-56] will be used to measure tonic, voluntary and reflex activation of the superficial and deep PFMs. Smoothed peak EMG amplitudes (µV) will be computed as outcomes while women keep their PFMs as relaxed as possible (tonic), contract as strongly as possible (phasic) and perform a straining maneuver (reflex activation).

Secondary Measures

  • Tampon test
    • Time Frame: 1 day
    • Women will be instructed to insert and then remove the tampon and they will be instructed to record the degree of pain during the entire insertion/ removal experience on a 0-10 pain numeric rating scale, with 0 meaning no pain, and 10 meaning the worst possible pain.
  • Pressure pain threshold (PPT)
    • Time Frame: 1 day
    • The pressure at which women report pain on pressure applied through a cotton swab to the region of the posterior vaginal fourchette. Pressure pain threshold (PPT) will be determined using a custom vulvalgesiometer. PPT will be defined as the average pressure at which women first report pain when the cotton swab tip of the vulvalgesiometer is applied at 6 o’ clock of the vaginal introitus [51].
  • Temporal summation (TS) of pain
    • Time Frame: 1 day
    • The difference in pain rating (scale 1-10) between the tenth and first application of a pressure applied to the posterior vaginal fourchette through a custom vulvalgesiometer. The PPT determined at the 6-o-clock position, will be applied ten times at a rate of approximately one per second at the 6 o’clock location on the vestibule. Participants will rate their pain level on the initial and final application of this pressure using a Numeric Rating Scale (0-10). TS will be defined as the difference in pain rating between the final and first application of the pressure [52,53]

Participating in This Clinical Trial

Inclusion Criteria

  • Premenopausal women over the age of 18 – Biologically born female – Signs and symptoms consistent with Provoked Vestibulodynia (PVD) alone or PVD+ Vaginismus (VAG) (i.e. evidence of a vaginal muscle spasm in response to palpation) or no history of pain during sexual activities or tampon insertion to serve as a comparison group – Not currently pregnant, or pregnant in the past six months. Exclusion Criteria:

  • Neurological condition such as stroke, multiple sclerosis, spinal cord injury, epilepsy, or history of epilepsy in the family, etc – Metal implants (cochlear, pacemaker, etc.) – Tendency to faint – in Peri- or post-menopause – express high levels of anxiety about the assessment protocol

Gender Eligibility: Female

Minimum Age: 18 Years

Maximum Age: 45 Years

Are Healthy Volunteers Accepted: Accepts Healthy Volunteers

Investigator Details

  • Lead Sponsor
    • University of Ottawa
  • Provider of Information About this Clinical Study
    • Principal Investigator: Dr. Linda McLean, Professor in the School of Rehabilitation Sciences at the University of Ottawa. – University of Ottawa
  • Overall Official(s)
    • Linda McLean, Principal Investigator, University of Ottawa

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Petersen KK, Arendt-Nielsen L, Simonsen O, Wilder-Smith O, Laursen MB. Presurgical assessment of temporal summation of pain predicts the development of chronic postoperative pain 12 months after total knee replacement. Pain. 2015 Jan;156(1):55-61. doi: 10.1016/j.pain.0000000000000022.

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Keshwani N, McLean L. A differential suction electrode for recording electromyographic activity from the pelvic floor muscles: crosstalk evaluation. J Electromyogr Kinesiol. 2013 Apr;23(2):311-8. doi: 10.1016/j.jelekin.2012.10.016. Epub 2012 Dec 5.

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Tracy LM, Gibson SJ, Georgiou-Karistianis N, Giummarra MJ. Effects of explicit cueing and ambiguity on the anticipation and experience of a painful thermal stimulus. PLoS One. 2017 Aug 23;12(8):e0183650. doi: 10.1371/journal.pone.0183650. eCollection 2017.

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