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. 1981 Jan;193(1):89–98. doi: 10.1097/00000658-198101000-00015

Temporary Incomplete Ischemia of the Legs Induced by Aortic Clamping in Man: Effects on Central Hemodynamics and Skeletal Muscle Metabolism by Adrenergic Block

B Eklöf, P Neglén, D Thomson
PMCID: PMC1345008  PMID: 7458455

Abstract

The hemodynamic changes which occur when clamping and unclamping the aorta during reconstructive surgery might be a threat to the elderly patient with concomitant cardiac disease. In addition, the cross-clamping induces a temporary ischemia of the legs, with severe metabolic derangement after the release of the aortic clamp. We have studied the effect of a intraoperative adrenergic block (phenoxybenzamine plus metoprolol) on the central circulation and the skeletal metabolism in 14 patients undergoing aortic reconstruction to treat occlusive arteriosclerotic disease. Cardiac output, heart rate, arterial and pulmonary artery pressures, and cardiac filling pressures, as well as femoral venous blood flow were studied. Biopsy specimens of the lateral vastus muscle and blood samples from the radial artery and iliac vein were taken before aortic clamping, and before, 30 minutes, four and 16 hours after the aorta was unclamped, as well as five days postoperatively. In addition, intramuscular temperature and pH were measured. Glycogen, glucose, lactate, pyruvate, ATP, ADP, AMP, phosphocreatine (PCr) and creatine (Cr) contents of the muscle and lactate and pyruvate concentrations in iliac venous and radial arterial blood were determined using enzymatic fluorometric techniques. Mean arterial blood pressure (MAP) averaged 80 mmHg before clamping, chiefly because of the low systemic vascular resistance (SVR), and left ventricular stroke work (LVSW) was normal. At clamping MAP, SVR, LVSW, remained unchanged. MAP and LVSW were unaffected even though SVR decreased slightly after the aorta was unclamped and resulted in an increased cardiac output, mainly due to a higher stroke volume. No major change in the pulmonary circulation was observed. During clamping the muscle lactate/pyruvate ratio increased, intramuscular pH and femoral venous blood flow decreased indicating insufficient tissue perfusion. Energy charge (EC), the adenylate (ATP + ADP + AMP) and creatine (PCr + Cr) pools were, however, unchanged. In spite of a restored blood flow to the legs, a severe metabolic derangement of the muscle was observed after declamping, with lowered EC, ATP + ADP + AMP and PCr + Cr indicating cellular damage. No improvement in the condition of the cells was observed 16 hours after operation. In conclusion, we found that by using neurolept anesthesia and an intraoperative adrenergic block in combination with a differentiated fluid therapy the central circulation stabilized and was largely unaffected by the clamping and unclamping procedures. In spite of the improved central hemodynamics no favorable effect on the skeletal muscle metabolism was observed.

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Selected References

These references are in PubMed. This may not be the complete list of references from this article.

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