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(Circulation. 1999;100:497-502.)
© 1999 American Heart Association, Inc.

Clinical Investigation and Reports

Cocaine Stimulates the Human Cardiovascular System via a Central Mechanism of Action

Wanpen Vongpatanasin, MD; Yasser Mansour, MD; Bahman Chavoshan, MD; Debbie Arbique, RN; Ronald G. Victor, MD

From the Divisions of Hypertension and Cardiology, Department of Internal Medicine, University of Texas Southwestern Medical Center, Dallas, Tex.

Correspondence to Dr Ronald G. Victor, Division of Hypertension, Department of Internal Medicine, University of Texas Southwestern Medical Center, 5323 Harry Hines Blvd, J4.134, Dallas, TX 75235-8586.

Background—Cocaine is thought to stimulate the cardiovascular system by blocking peripheral norepinephrine reuptake. This study was designed to test the novel hypotheses that cocaine also stimulates the human cardiovascular system by (1) increasing central sympathetic outflow, or (2) decreasing parasympathetic control of heart rate.

Methods and Results—In 14 healthy cocaine-naive humans, we measured blood pressure, heart rate, and skin sympathetic nerve activity (SNA) with intraneural microelectrodes before, during, and for 90 minutes after intranasal cocaine (2 mg/kg, n=7) or lidocaine (2 mg/kg, n=7). Intranasal cocaine caused an initial but transient 3.3-fold increase in skin SNA during the period of intranasal administration followed by a sustained 2.4-fold increase lasting for up to 90 minutes after cocaine. Unlike cocaine, intranasal lidocaine caused only a small transient increase in skin SNA due to local nasal irritation. The cocaine-induced increase in SNA was accompanied by decreased skin blood flow, increased skin vascular resistance, and increased heart rate. In 11 additional subjects, we showed that the cocaine-induced increase in heart rate was eliminated by ß-adrenergic receptor blockade (propranolol) but unaffected by muscarinic receptor blockade (atropine), indicating sympathetic mediation.

Conclusions—These studies provide direct microneurographic evidence in humans that intranasal cocaine stimulates central sympathetic outflow. This central sympathetic activation appears to be targeted not only to the cutaneous circulation promoting peripheral vasoconstriction but also to the heart promoting tachycardia.

Key Words: cocaine • nervous system, sympathetic • microneurography

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