Skeletal muscle contractions attenuate the norepinephrine-related reduction in interstitial oxygen pressures in the rat spinotrapezius

Abstract

Increased sympathetic nerve activity with exercise plays a key role in the control of arterial blood pressure and redistribution of blood flow. Within the microcirculation, elevated sympathetic outflow promotes the release of norepinephrine and smooth muscle contraction. Exercise-induced attenuation of sympathetic vasoconstriction (i.e., functional sympatholysis) is thus critical for active muscle oxygen delivery-utilization matching. However, the extent to which muscle contractions impact noradrenergic regulation of interstitial oxygen pressures (PO2is) is unknown. This is important because, as dictated by Fick’s law, PO2is provides the sole driving force for oxygen diffusion into the myocyte thereby supporting oxidative phosphorylation. PURPOSE: To determine the effects of norepinephrine administration on resting and contracting rat skeletal muscle PO2is. We tested the hypothesis that topical application (superfusion) of norepinephrine would result in blunted decreases in skeletal muscle PO2is during contractions compared to rest. METHODS: PO2is was determined via phosphorescence quenching in the exposed spinotrapezius muscle of anesthetized male Sprague-Dawley rats (n=7, 2-3 months old) at rest and during electrically-induced submaximal contractions (0.5 Hz, 3-6 V) for 6 minutes in response to norepinephrine superfusion (5x10−4 M). Functional sympatholysis was determined as the difference between the norepinephrine-induced changes in PO2is at rest and during the contraction steady-state (i.e., 2 min following the onset of muscle contractions) using (i) the absolute PO2is fall with norepinephrine (ΔPO2is), and (ii) the area under the PO2is curve plotted as a function of time (AUC). The tail (caudal) artery was cannulated for measurements of mean arterial pressure (MAP) and heart rate (HR). RESULTS: Consistent with our hypothesis, skeletal muscle contractions attenuated norepinephrine-evoked reductions in spinotrapezius interstitial oxygenation as evaluated by ΔPO2is (rest: -8.7±1.4, contractions: -4.3±1.1 mmHg, p<0.05) and AUC (rest: 2246±368, contractions: 1066±273 mmHg·s, p<0.05). Although MAP increased significantly with norepinephrine both at rest (+5±1%, p<0.05) and during contractions (+8±1%, p<0.05), this mild hypertensive response to norepinephrine was not different between conditions (p>0.05). Norepinephrine superfusion did not affect HR at rest or during contractions (p>0.05). CONCLUSIONS: That muscle contractions blunted the decrease in spinotrapezius PO2is with norepinephrine compared to the resting condition is consistent with functional sympatholysis. The latter serves to match active muscle O2 delivery-utilization in the face of elevated sympathetic nerve activity during exercise. The current results indicate that a novel combination of phosphorescence quenching (interstitial oxygenation, PO2is) and superfusion techniques may be used to evaluate functional sympatholysis in the intact rat spinotrapezius muscle. Showalter Research Trust, Purdue University. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.