This case confirms the importance of the FSHR in female pubertal development and reproduction, and supports a relationship between phenotype and function for FSHR mutations.
Objectives
This study sought to determine whether salt‐induced ANG II suppression contributes to impaired CBF autoregulation.
Methods
Cerebral autoregulation was evaluated with LDF during graded reductions of blood pressure. Autoregulatory responses in rats fed HS (4% NaCl) diet vs LS (0.4% NaCl) diet were analyzed using linear regression analysis, model‐free analysis, and a mechanistic theoretical model of blood flow through cerebral arterioles.
Results
Autoregulation was intact in LS‐fed animals as MAP was reduced via graded hemorrhage to approximately 50 mm Hg. Short‐term (3 days) and chronic (4 weeks) HS diet impaired CBF autoregulation, as evidenced by progressive reductions of laser Doppler flux with arterial pressure reduction. Chronic low dose ANG II infusion (5 mg/kg/min, i.v.) restored CBF autoregulation between the pre‐hemorrhage MAP and 50 mm Hg in rats fed short‐term HS diet. Mechanistic‐based model analysis showed a reduced myogenic response and reduced baseline VSM tone with short‐term HS diet, which was restored by ANG II infusion.
Conclusions
Short‐term and chronic HS diet lead to impaired autoregulation in the cerebral circulation, with salt‐induced ANG II suppression as a major factor in the initiation of impaired CBF regulation.
The present study assessed the effect of nearby construction activity on the responses of rat middle cerebral arteries (MCA)to the endothelium-dependent vasodilator acetylcholine and the NO donor sodium nitroprusside (SNP) and the activity of MaxiK potassium channels in MCA smooth muscle cells from male Sprague–Dawley rats. Two monitoring systems were used to assess vibrations in the animal rooms during and immediately after construction activities near the research building where the animal facility is located. One was a commercially available system; the other was a Raspberry-Pi (RPi)–based vibration monitoring system designed in our laboratory that included a small computing unit attached to a rolling sensor (low sensitivity) and a piezoelectric film sensor (high sensitivity). Both systems recorded increased levels of vibration during construction activity outside the building. During the construction period, vasodilator responses to acetylcholine and SNP were abolished, and MaxiK single-channel current opening frequency and open-state probability in cell-attached patches of isolated MCA myocytes were dramatically decreased. Recovery of acetylcholine- and SNP-induced dilation was minimal in MCA from rats studied after completion of construction but housed in the animal facility during construction, whereas responses to acetylcholine and SNP were intact in rats purchased, housed, and studied after construction. Baseline levels of vibration returned after the completion of construction, concomitant with the recovery of normal endothelium-dependent vasodilation to acetylcholine and of NO sensitivity assessed by using SNP in MCA from animals obtained after construction. The results of this study indicate that the vibration associated with nearby construction can have highly disruptive effects on crucial physiologic phenotypes.
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