Pharmacological and Simulated Exercise Cardiac Stress Tests Produce Different Ischemic Signatures in High-resolution Experimental Mapping Studies

Overview

Journal J Electrocardiol

Specialty Cardiology & Vascular Diseases

Date 2021 Aug 2

PMID 34339897

Citations 2

Authors

Brian Zenger

Wilson W Good

Jake A Bergquist

Lindsay C Rupp

Maura Perez

Gregory J Stoddard

Vikas Sharma

Rob S MacLeod

Affiliations

Soon will be listed here.

Abstract

Objective: Test the hypothesis that exercise and pharmacological cardiac stressors create different electrical ischemic signatures.

Introduction: Current clinical stress tests for detecting ischemia lack sensitivity and specificity. One unexplored source of the poor detection is whether pharmacological stimulation and regulated exercise produce identical cardiac stress.

Methods: We used a porcine model of acute myocardial ischemia in which animals were instrumented with transmural plunge-needle electrodes, an epicardial sock array, and torso arrays to simultaneously measure cardiac electrical signals within the heart wall, the epicardial surface, and the torso surface, respectively. Ischemic stress via simulated exercise and pharmacological stimulation were created with rapid electrical pacing and dobutamine infusion, respectively, and mimicked clinical stress tests of five 3-minute stages. Perfusion to the myocardium was regulated by a hydraulic occluder around the left anterior descending coronary artery. Ischemia was measured as deflections to the ST-segment on ECGs and electrograms.

Results: Across eight experiments with 30 (14 simulated exercise and 16 dobutamine) ischemic interventions, the spatial correlations between exercise and pharmacological stress diverged at stage three or four during interventions (p<0.05). We found more detectable ST-segment changes on the epicardial surface during simulated exercise than with dobutamine (p<0.05). The intramyocardial ischemia formed during simulated exercise had larger ST40 potential gradient magnitudes (p<0.05).

Conclusion: We found significant differences on the epicardium between cardiac stress types using our experimental model, which became more pronounced at the end stages of each test. A possible mechanism for these differences was the larger ST40 potential gradient magnitudes within the myocardium during exercise. The presence of microvascular dysfunction during exercise and its absence during dobutamine stress may explain these differences.

Citing Articles

Tipping the scales of understanding: An engineering approach to design and implement whole-body cardiac electrophysiology experimental models.

Zenger B, Bergquist J, Busatto A, Good W, Rupp L, Sharma V Front Physiol. 2023; 14:1100471.

PMID: 36744034 PMC: 9893785. DOI: 10.3389/fphys.2023.1100471.

Body Surface Potential Mapping: Contemporary Applications and Future Perspectives.

Bergquist J, Rupp L, Zenger B, Brundage J, Busatto A, MacLeod R Hearts (Basel). 2022; 2(4):514-542.

PMID: 35665072 PMC: 9164986. DOI: 10.3390/hearts2040040.

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