Skin

Trauma to the skin can be caused by pressure necrosis due to inadequate padding between the skin and tourniquet or friction burns due to movement of a poorly applied tourniquet. Obese patients with redundant upper extremity skin folds are at increased risk for skin injury. Skin preparation solutions may soak into the padding under the tourniquet, resulting in full-thickness chemical burns.

Muscle

Myocytes are very sensitive to compression and ischemia. Injury is more severe with lengthy tourniquet inflation or high pressure. Usually, injury is greatest beneath the tourniquet. Associated ischemia, edema, and microvascular congestion cause the post-tourniquet syndrome. This includes stiffness, pallor, and weakness (not paralysis), with subjective extremity numbness. Rhabdomyolysis may occur if the tourniquet is inflated for a prolonged period of time under high pressure. Compartment syndrome may occur after tourniquet deflation as a result of edema and reperfusion hyperemia.

Peripheral Nerves

Mechanical pressure compresses nerves directly beneath the tourniquet cuff, and shear forces at the proximal and distal edges of the cuff also cause nerve injury ranging from paresthesia to complete paralysis. Distal ischemia plays a lesser role. The contribution of tourniquet time to the development of nerve injury is unclear, and paralysis has been reported with as little as 30 minutes of tourniquet inflation. Lower extremity nerve injury usually involves the sciatic nerve. The upper extremity appears to be more commonly associated with tourniquet related nerve injury than the lower extremity, with radial nerve injury more frequently observed than either ulnar or median nerve injury. When tourniquet-related nerve injury occurs in the lower extremity, the sciatic nerve is the most likely to be affected.

Localized nerve injuries tend to be neuropraxic injuries, with structural damage limited to the myelin sheath surrounding individual axons, without injury to the axon itself. Neuropraxic injuries tend to be self-limiting, with an excellent prognosis for complete recovery within a period of several days to weeks. In contrast, axonotmetic injuries involve damage to the axon itself, resulting in loss of signaling function once electrical excitability is lost and depolarization can no longer occur. These injuries take longer to recover as the axon must regenerate along the connective tissue highway, and some injuries may not completely recover. Rarely, a permanent nerve deficit occurs ( Table 55.1 ).

Vasculature

Arteries and veins, especially prosthetic grafts (e.g., arteriovenous fistulas, arterial bypass grafts), are susceptible to traumatic injury from mechanical compression. Although direct arterial injury is rare (0.03% to 0.14% incidence), fractured atherosclerotic plaque may cause localized thrombosis or embolize distally to cause ischemia. Although deep venous thrombosis (DVT) is a known and common complication of lower limb surgery, tourniquets bear no relation to deep venous stasis and thrombus formation. Rather, systemic hypercoagulability is due to catecholamine release and platelet aggregation caused by tourniquet-related or surgical pain. In contrast, active bleeding after tourniquet release may be aggravated by ischemia-caused tissue plasminogen activator release and fibrinolysis.

Autotransfusion

Limb exsanguination and rapid tourniquet inflation shunt blood into the central circulation (autotransfusion) and increase systemic vascular resistance. As much as 800 mL of blood is autotransfused with the simultaneous inflation of bilateral thigh tourniquets. This causes a transient increase in central venous pressure and systolic blood pressure, which gradually returns to baseline. In patients with compromised left ventricular function, congestive heart failure due to circulatory overload and cardiac arrest has been reported.

Hypertension

Tourniquet-induced hypertension is common. Patients develop an increase in heart rate and systolic and diastolic blood pressures within 30 to 60 minutes of inflation, which persists until tourniquet deflation. This increase in mean arterial pressure has been attributed to (1) an acute increase in systemic vascular resistance with removal of a vascular bed; (2) limb exsanguination before tourniquet cuff inflation, which causes acute central blood volume expansion; and (3) pain associated with tourniquet compression and limb ischemia. The incidence of this constellation of vital signs is related to the type of anesthesia, and ranges from 2.5% of patients under brachial plexus anesthesia to 67% of patients under general anesthesia. A cutaneous mechanism is thought to be responsible, as demonstrated by the attenuation of tourniquet discomfort by topical eutectic mixture of local anesthetic agents (EMLA). A sympathetically mediated pathway may be unlikely given the lack of effectiveness of stellate ganglion block in reducing upper arm tourniquet discomfort in a limited size volunteer study. The leading hypothesis for the mechanism of tourniquet pain is the loss of inhibition of unmyelinated, slow-conducting C fibers. These fibers are usually inhibited by fast, myelinated A-delta fibers, which are blocked at the tourniquet site after approximately 30 minutes of tourniquet inflation and mechanical compression.

Hypotension

Tourniquet deflation results in reduced blood pressure and central venous pressure secondary to a shift of blood volume back into the extremity and postischemic reactive vasodilation. Also, with reperfusion, metabolites released from ischemic areas into the systemic circulation have the potential to cause myocardial depression and further reduce blood pressure. Hypotension is usually self-limited (≤15 minutes).

Hypercapnia

End-tidal carbon dioxide (ETCO ₂ ) increases after tourniquet release owing to the efflux of hypercapnic venous blood from the ischemic limb into the systemic circulation. The peak ETCO ₂ increase occurs within the first minute after deflation, and it returns to baseline approximately 10 to 13 minutes later. Spontaneously breathing patients compensate by increasing their respiratory rate. However, those with controlled ventilation require a transient increase in minute ventilation by 50% for about 5 minutes to maintain normocapnia. Hyperventilation can prevent the associated increase in cerebral blood volume and intracranial pressure that might otherwise be detrimental to a patient with intracranial hypertension.

Metabolic Acidosis

Elevated serum lactate and reduced pH are observed for approximately 30 minutes after reperfusion of the isolated extremity. The degree of change is proportional to the duration of tourniquet inflation.

Blood Oxygen Saturation

Arterial oxygen saturation usually remains normal. However, as large volumes of deoxygenated blood are returned to the central circulation after tourniquet release, mixed venous oxygen saturation is transiently decreased.

Impaired Antibiotic Penetration

Intravenously administered antibiotics may not penetrate to the operative site if the tourniquet is inflated before or while the antibiotics are still being administered. An interval of 5 minutes between antibiotic administration and tourniquet inflation is probably adequate to allow antibiotic penetration.

Core Body Temperature

Most patients remain normothermic during tourniquet use. Tourniquet inflation above arterial pressure transiently increases core body temperature, and tourniquet deflation transiently decreases it. The decline in core body temperature due to the return of hypothermic venous blood from the previously occluded limb into the systemic circulation is usually 0.7°C or less.

Deep Venous Thrombosis, Pulmonary or Systemic Thromboembolism

These potentially devastating complications may occur with lower limb trauma and surgery, but rarely intraoperatively. Although studies with transesophageal echocardiography have shown up to a 70% incidence of right atrial embolization following tourniquet release, most emboli are small and are unlikely to cause major morbidity. However, this risk is increased in patients with hypercoagulable states and thrombus due to trauma or prolonged immobilization. In this setting, it is believed that thrombus becomes dislodged during limb exsanguination or with tourniquet inflation. Catastrophic events such as DVT or pulmonary or systemic thromboembolism are more likely to occur postoperatively during rehabilitation. Use of enoxaparin for DVT prophylaxis has dramatically reduced the incidence of fatal pulmonary embolism. However, given that pulmonary and cerebral emboli have been reported during both inflation and deflation of tourniquets, anesthesiologists should be especially vigilant during these times. Attention should be focused on the patient’s neurologic status and any sudden, unexpected changes in arterial oxygen saturation and ETCO ₂ . Significant pulmonary emboli result in an acute reduction in ETCO ₂ , with tachycardia and hypotension, followed by hypoxemia and myocardial ischemia. Right ventricular dysfunction may also be observed (also see Chapter 65 , Chapter 142 ).