A canine model was developed to simulate use of a pneumatic tourniquet in the clinical setting in order to study the acute and delayed effects of transient ischemia on limb and tissue blood flow, using radioactive microspheres and electromagnetic flow probes. Experimental femoral artery flow rose markedly after tourniquet ischemia, and remained significantly elevated for 24 hours (p less than 0.01). Blood flow to the rectus femoris and anterior tibial muscles rose significantly (p less than 0.05) immediately after tourniquet ischemia, and the latter remained significantly elevated at 24 hours (p less than 0.05). Blood flow to the skin of the experimental limbs was elevated significantly (p less than 0.05), immediately ater tourniquet ischemia, and at no other time. Blood flow to the nerves did not increase to its maximum until 15 minutes after tourniquet deflation, and by 24 hours was normal. Tibial and femoral marrow blood flow remained significantly lower in the experimental limb throughout the 24-hour period. Ater tourniquet ischemia (300 mmhg; 2 hours), greatly increased femoral artery flow was related to reactive hyperemia in skin, muscle, and nerve. Twenty-four hours after tourniquet deflation, there was a significant increase in femoral artery and anterior tibial muscle blood flow, and significant arteriovenous shunting from the experimental limb. These data suggest that the hemodynamic response to a transient ischemic injury is more prolonged and of greater magnitude than previously believed.