What does this research mean for the field?

Regional differences in myocardial oxygenation create an electrical current across the contact zone that causes electric instability and triggers ventricular fibrillation, whereas uniformly oxygenated or uniformly anoxic hearts remain electrically stable. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.NEUTRAL.

February 1, 1956Open Access

Electric Instability of the Heart

Structured PICO

Does a regional oxygen differential in the myocardium cause electric instability and ventricular fibrillation in dog hearts?

Population

Dog hearts (normally oxygenated and uniformly anoxic models)

Intervention

Creation of regional myocardial ischemia or regional perfusion with oxygenated blood in an anoxic heart (creating an oxygen differential)

Comparator

Uniformly oxygenated or uniformly anoxic myocardium

Outcome

Electric instability (resting electric potentials and spontaneous ventricular fibrillation)surrogate

Regional differences in myocardial oxygenation, rather than uniform anoxia, are the primary trigger for electrical instability and ventricular fibrillation.

Abstract

Normally oxygenated dog hearts and hearts rendered uniformly anoxic exhibit electric stability: there is no difference in resting electric potentials, and spontaneous ventricular fibrillation does not occur. When an area of myocardium is rendered ischemic, the resulting "trigger" may destroy the coordinated mechanism of the heart. A current of oxygen differential is produced across the zone of contact between red and blue myocardium resulting in "electric instability." In the electrically stable, uniformly anoxic heart, perfusion of an area with red blood produces a "reverse trigger" and electric instability. Application of these concepts and therapeutic implications to human coronary disease appears justified.

Electric Instability of the Heart

Structured PICO

Abstract

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