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(Circulation. 1995;92:756-766.)
© 1995 American Heart Association, Inc.

Articles

Incremental Doses of Dobutamine Induce a Biphasic Response in Dysfunctional Left Ventricular Regions Subtending Coronary Stenoses

Presented in part at the 66th Scientific Sessions of the American Heart Association, Atlanta, Ga, November 8-11, 1993.

Chunguang Chen, MD; Li Li, MD; Liang Long Chen, MD; Jose V. Prada, MD; Ming Hui Chen, MD; John T. Fallon, MD, PhD; Arthur E. Weyman, MD; David Waters, MD; Linda Gillam, MD

From the Division of Cardiology, Hartford Hospital, University of Connecticut, Hartford, and the Cardiac Unit, Massachusetts General Hospital, Harvard Medical School, Boston (J.V.P., M.H.C., J.T.F., A.E.W.).

Correspondence to Chunguang Chen, MD, Division of Cardiology, Hartford Hospital, 80 Seymour St, Hartford, CT 06102.

Background Dobutamine stress echocardiography has been proposed as a diagnostic tool to identify viable myocardium. How regional wall thickening responds to dobutamine in the ischemic or short-term hibernating myocardium has not been adequately defined. We hypothesized that regional wall thickening would improve initially and subsequently deteriorate with incremental doses of dobutamine in viable myocardial regions supplied by a stenotic coronary artery. This study was undertaken to determine whether this biphasic pattern of regional function characterizes the response of ischemic or hibernating myocardium to dobutamine and to explore the factors and mechanisms that determine this response.

Methods and Results Twenty-six pigs in four groups were studied: a control group (n=5) to assess the response of myocardium perfused by nonstenotic coronary artery to incremental doses of dobutamine, and three experimental groups with a left anterior descending coronary artery stenosis producing acute myocardial ischemia (n=7), short-term myocardial hibernation for 90 minutes (n=7), and short-term hibernation for 24 hours (n=7) to determine the functional and metabolic response to dobutamine under these conditions. Regional coronary flow was reduced to 40% to 60% of baseline, with significant reductions of regional wall thickening as measured by two-dimensional echocardiography and sonomicrometers. An incremental dobutamine infusion from 2.5 to 25 µg · kg^-1 · min^-1 increased wall thickening and coronary flow without lactate production in the control group. In the other three groups, during the incremental dobutamine infusion, regional wall thickening improved initially, from 11.4±7.5% to 19.8±11.4%, P<.01, at dobutamine doses of 2.5 to 10 (4.5±2.2) µg · min^-1 · kg^-1 but deteriorated subsequently to 5.0±5.8% at the maximal dose of dobutamine of 12.6±4.1 µg · min^-1 · kg^-1. The initial improvement of regional wall thickening was associated with a small increase in regional coronary flow (from 0.53±0.18 to 0.68±0.25 mL · min^-1 · g^-1 myocardium, P<.05) and with regional lactate production. High doses of dobutamine did not further increase regional coronary flow but markedly increased lactate production and induced regional myocardial acidosis (pH 7.26±0.07). The biphasic pattern of response to dobutamine was observed in each of the three experimental groups. Both peak improvement and peak deterioration occurred earlier and at lower dobutamine dose levels in the group with acute ischemia compared with the group with short-term hibernation for 24 hours (P<.05).

Conclusions A biphasic response of wall thickening to incremental dobutamine with initial improvement and subsequent deterioration is characteristic of ischemic or short-term hibernating myocardium. The initial low-dose dobutamine infusion improved wall thickening in the ischemic or hibernating myocardial region to a modest level. This initial modest improvement was transient and at the expense of metabolic deterioration of myocardial ischemia, so that at higher doses during prolonged dobutamine infusion, wall thickening deteriorated, lactate accumulated, and myocardial acidosis developed.

Key Words: dobutamine • echocardiography • myocardium • ischemia

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