Pelvic organ prolapse is characterized as the descent of the pelvic organs into the vaginal canal. In the USA, there is a 12% lifetime risk for requiring surgical intervention. Although vaginal childbirth is a well-established risk factor for prolapse, the underlying mechanisms are not fully understood. Decreased smooth muscle organization, composition and maximum muscle tone are characteristics of prolapsed vaginal tissue. Maximum muscle tone of the vaginal wall was previously investigated in the circumferential or axial direction under uniaxial loading; however, the vaginal wall is subjected to multiaxial loads. Further, the contribution of vaginal smooth muscle basal (resting) tone to mechanical function remains undetermined. The objectives of this study were to determine the contribution of smooth muscle basal and maximum tone to the regional biaxial mechanical behaviour of the murine vagina. Vaginal tissue from C57BL/6 mice was subjected to extension–inflation protocols ( n = 10) with and without basal smooth muscle tone. Maximum tone was induced with KCl under various circumferential ( n = 5) and axial ( n = 5) loading conditions. The microstructure was visualized with multiphoton microscopy ( n = 1), multiaxial histology ( n = 4) and multiaxial immunohistochemistry ( n = 4). Smooth muscle basal tone decreased material stiffness and increased anisotropy. In addition, maximum vaginal tone was decreased with increasing intraluminal pressures. This study demonstrated that vaginal muscle tone contributed to the biaxial mechanical response of murine vaginal tissue. This may be important in further elucidating the underlying mechanisms of prolapse, in order to improve current preventative and treatment strategies.
Preeclampsia is a pregnancy-related hypertensive disorder accounting for 14% of global maternal deaths annually. Preeclampsia — maternal hypertension and proteinuria — is promoted by placental ischemia resulting from reduced uteroplacental perfusion. Here, we assess longitudinal changes in placental oxygenation during preeclampsia using spectral photoacoustic imaging. Spectral photoacoustic images were acquired of the placenta of normal pregnant (NP) and preeclamptic reduced uterine perfusion pressure (RUPP) Sprague Dawley rats on gestational days (GD) 14, 16, and 18, corresponding to mid- to late gestation (n = 10 per cohort). Two days after implementation of the RUPP surgical model, placental oxygen saturation decreased 12% in comparison with NP. Proteinuria was determined from a 24-hour urine collection prior to imaging on GD18. Blood pressure measurements were obtained on GD18 after imaging. Placental hypoxia in the RUPP was confirmed with histological staining for hypoxia-inducible factor (HIF)-1α, a cellular transcription regulator which responds to local oxygen levels. Using in vivo, longitudinal imaging methods we determined that the placenta in the reduced uterine perfusion pressure rat model of preeclampsia is hypoxic, and that this hypoxia is maintained through late gestation. Future work will utilize these methods to assess the impact of novel therapeutics on placental ischemia and the progression of preeclampsia.
Because arterial stiffness increases following menopause, estrogen may be a protective factor. Our previous work indicates that the GPER (G protein–coupled estrogen receptor) mediates estrogen’s vascular actions. In the current study, we assessed arterial stiffening using pulse wave velocity (PWV), a clinically relevant measurement that independently predicts cardiovascular mortality. We hypothesized that genetic deletion of GPER would attenuate sex differences in PWV and would be associated with changes in passive vascular mechanics. Control and Ang II (angiotensin II)–infused male and female wild-type and GPER knockout mice were assessed for blood pressure, intracarotid PWV, cardiac function, passive biaxial mechanics, constitutive modeling, and histology. Sex differences in PWV and left ventricular mass were detected in wild-type mice but absent in GPER knockout and Ang II–infused mice, regardless of genotype. Despite lower PWV, the material stiffness of female wild-type carotids was greater than males in control conditions and was maintained in response to Ang II due to increased wall thickness. PWV positively correlated with unloaded thickness as well as circumferential and axial stiffness only in females. In contrast, blood pressure positively associated with circumferential and axial stiffness in males. Taken together, we found that female wild-type mice were unique in their vascular adaptation to hypertension by increasing wall thickness to maintain stiffness. Given that carotid arteries are easily accessible clinically, systematic assessment of intracarotid PWV in women may provide insight into vascular damage that cannot be assumed from blood pressure measurements alone.
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