Cristina S. Saleme

Intensive supervised versus unsupervised pelvic floor muscle training for the treatment of stress urinary incontinence: a randomized comparative trial

Introduction and hypothesisPelvic floor muscle training (PFMT) is considered to be the first-line treatment for female stress urinary incontinence (SUI). There are few studies that have tested the efficacy of unsupervised PFMT. The aim of this study was to compare the effectiveness of intensive supervised PFMT to unsupervised PFMT in the treatment of female SUI.MethodsSixty-two women with SUI were randomized to either supervised or unsupervised PFMT after undergoing supervised training sessions. They were evaluated before and after the treatment with the Oxford grading system, pad test, quality of life questionnaire, subjective evaluation, and exercise compliance.ResultsAfter treatment, there were no differences between the two groups regarding PFM strength (p = 0.20), International Consultation on Incontinence Questionnaire-Short Form score (p = 0.76), pad test (p = 0.78), weekly exercise compliance (p = 0.079), and subjective evaluation of urinary loss (p = 0.145).ConclusionsBoth intensive supervised PFMT and unsupervised PFMT are effective to treat female SUI if training session is provided.

An approach on determining the displacements of the pelvic floor during voluntary contraction using numerical simulation and MRI.

The present study was conducted in order to establish a methodology based on the finite element method to simulate the contraction of the pelvic floor (PF) muscles. In the generated finite element model, a downward pressure of 90 cm H2O was applied, while actively contracting the PF muscles with different degrees of muscular activation (10, 50 and 100%). The finite element methodology of the active contraction behaviour proposed in this study is adequate to simulate PF muscle contraction with different degrees of muscular activation. In this case, in particular, for an activation of 100%, the numerical model was able to displace the pubovisceral muscle in a range of values very similar to the displacement found in the magnetic resonance imaging data. In the analysed case study, it would be possible to conclude that an intensity contraction of 50% would be necessary to produce enough stiffness to avoid possible urine loss.

Translation of biomechanics research to urogynecology

IntroductionPelvic floor (PF) dysfunctions represent a frequent and complex problem for women. The interaction between the vagina and its supportive structures, that are designed to support increases in abdominal pressure, can be considered a biomechanical system. Recent advances in imaging technology have improved the assessment of PF structures. The aim of this paper is to review the applications of biomechanics in urogynecology.MethodsThe available literature on biomechanics research in urogynecology was reviewed.ResultsComputational models have been demonstrated to be an effective tool to investigate the effects of vaginal delivery and PF dysfunctions. Biomechanical analysis of PF tissues provides a better understanding on PF dysfunctions etiology. These studies are also important for the development of synthetic prostheses utilized in PF surgery.ConclusionAn interdisciplinary and multidisciplinary collaborative research, involving bioengineers and clinicians, is crucial to improve clinical outcomes in patients with PF dysfunctions.

Multidirectional Pelvic Floor Muscle Strength Measurement

Pelvic floor muscle (PFM) strength measurement provides useful information for the study of pelvic floor dysfunctions. Vaginal digital palpation, intravaginal pressure measurements, and the use of a dynamometric speculum represent currently available clinical methods for evaluating PFM strength. However, none of these methods provide a dynamic measurement of pelvic floor strength in multiple directions simultaneously. The aim of the present paper is to report the development and first measurement trial of a device that follows the vaginal canal morphology and is able to measure pelvic floor strength multidirectionally.

Vaginal Tissue Properties versus Increased Intra-Abdominal Pressure: A Preliminary Biomechanical Study

Background/Aims: This study aims to evaluate the pelvic floor (PF) tension response during simulated increased intra-abdominal pressure (IAP) and the vaginal biomechanical properties. Methods: A 3-dimensional computational finite element model for PF was developed based on magnetic resonance imaging from a nulliparous healthy volunteer. The model was used to simulate an IAP of 90 cm H2O and to evaluate the PF stresses in the longitudinal and transversal axes. The vaginal samples were obtained from 15 non-prolapsed female cadavers. A uniaxial tensile test to obtain stiffness and maximum stress of vaginal tissue in the longitudinal and transversal axes was performed. Results: The simulated IAP was associated with a similar PF stress state in the longitudinal and transversal axes. The stiffness and maximum stress in vaginal tissues presented a great variability between subjects. There was no difference in the vaginal tissue elasticity (6.2 ± 1.5 vs. 5.4 ± 1.1 MPa; p = 0.592) and maximum stress (2.3 ± 0.5 vs. 2.6 ± 0.9 MPa; p = 0.692) regarding the measurements in the longitudinal and transversal axes. Conclusion: The isotropic biomechanical behavior of vagina is in agreement with the PF stress state response during increased IAP.