Muscle PO2 in the initial phase of increased local oxygen demand (rhythmical muscle contraction) in rats with portacaval shunt (PCA).

The influence of a hyperdynamic syndrome caused by PCA on PO2 distribution in skeletal muscle of rats during the initial phase of muscle activity was examined. Rhythmical muscle contraction of the m. biceps femoris was induced by direct electrical stimulation. Tissue PO2 of the contracting muscle was recorded continuously from the start of the 210 s-long activity period up to 140 s after the last contraction using a multiwire surface electrode. In comparison with controls no different behaviour of mean muscle PO2 in the initial phase of contraction was found. After muscle activity mean PO2 decreased to a lower level in rats with PCA than in controls. This might be a further indication of the disturbing influence of a hyperdynamic syndrome on the regulating mechanisms of the microcirculation.

Circadian course of PO2-oscillations in skeletal muscle of intact and portacaval shunted (PCA) rats.

In rats several circadian rhythms such as heart rate, body temperature, and locomotor activity are known. Several authors found a loss of day-night-rhythm (locomotor activity, EEG) after portacaval shunting (PCA). The aim of this study was to evaluate whether muscle PO2 oscillations are circadian and whether they are altered after time-limited hypercirculation caused by PCA. 126 days after operation tissue PO2 of m. rectus abdominis of 9 rats with PCA and 10 controls was measured with a multi-wire surface electrode. All animals were kept under constant conditions and each animal was measured 6 times at intervals of 4 hours in order to get a circadian PO2 course. In controls the circadian course of mean muscle PO2 resembled a sine oscillation with high values at night and low values in the afternoon. In PCA-rats the time course of mean muscle PO2 showed 3 oscillations with different amplitudes, each with a period length of 24 hours. Our results indicate that oscillations of muscle PO2 are determined principal by circadian locomotor activity and that time-limited hypercirculation influences the circadian course of mean muscle PO2.