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(Circulation. 1999;100:41-47.)
© 1999 American Heart Association, Inc.

Clinical Investigation and Reports

In Vivo Human Brachial Artery Elastic Mechanics

Effects of Smooth Muscle Relaxation

Alan J. Bank, MD; Daniel R. Kaiser, MS; Scott Rajala, BS; Anthony Cheng, MD

From the Cardiovascular Division, Department of Medicine, and the Graduate Program in Biophysical Sciences and Medical Physics, Department of Radiology, University of Minnesota, Minneapolis.

Correspondence to Alan J. Bank, MD, Cardiovascular Division, Department of Medicine, University of Minnesota Medical School, Box 508 FUMC, 420 Delaware Street, SE, Minneapolis, MN 55455. E-mail bankx001{at}tc.umn.edu

Background—–The effects of smooth muscle relaxation on arterial wall mechanics are controversial. We used a new, in vivo, noninvasive technique to measure brachial artery wall mechanics under baseline conditions and following smooth muscle relaxation with nitroglycerin (NTG).

Methods and Results—Eight healthy, normal subjects (6 male, 2 female; age 30±3.1 years) participated in the study. The nondominant brachial artery was imaged through a water-filled blood pressure cuff using an external ultrasound wall-tracking system at baseline and following 0.4 mg sublingual NTG. Simultaneous radial artery pressure waveforms were recorded by tonometry. Transmural pressure (TP) was reduced by increasing water pressure in the cuff. Brachial artery area, unstressed area, compliance, stress, strain, incremental elastic modulus (E_inc), and pulse wave velocity (PWV) were measured over a TP range from 0 to 100 mm Hg. Baseline area versus TP curves generated 30 minutes apart were not significantly different. NTG significantly shifted area versus TP (P<0.0001) and compliance versus TP (P<0.001) curves upward, whereas the E_inc versus TP (P<0.05) and PWV versus TP (P<0.01) curves were shifted downward. NTG also significantly shifted stress versus strain (P<0.01) and E_inc versus strain (P<0.01) curves to the right.

Conclusions—We conclude that brachial artery elastic mechanics can be reproducibly measured over a wide range of TP and smooth muscle tone using a new noninvasive ultrasound technique. Smooth muscle relaxation with NTG increases isobaric compliance and decreases isobaric E_inc and PWV in the human brachial artery.

Key Words: arteries • elasticity • nitroglycerin • muscle, smooth • ultrasonics • vasodilation

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