Journal
ANNUAL REVIEW OF BIOMEDICAL ENGINEERING, VOL 12
Volume 12, Issue -, Pages 233-258Publisher
ANNUAL REVIEWS
DOI: 10.1146/annurev-bioeng-070909-105305
Keywords
ventricular fibrillation; electrical shock; resuscitation; cardiac mapping; transmembrane potential
Categories
Funding
- NHLBI NIH HHS [R01 HL085370, HL67748, K99HL091138, K99 HL091138-01A1, K99 HL091138-02, L30 HL082315-01, R00 HL091138-04, R01 HL042760, R01 HL067748, HL42760, HL85370, K99 HL091138, L30 HL082315, R00 HL091138-03, R00 HL091138] Funding Source: Medline
- NATIONAL HEART, LUNG, AND BLOOD INSTITUTE [R01HL067748, R01HL042760, R01HL085370, K99HL091138, R00HL091138] Funding Source: NIH RePORTER
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Electrical shock has been the one effective treatment for ventricular fibrillation for several decades. With the advancement of electrical and optical mapping techniques, histology, and computer modeling, the mechanisms responsible for defibrillation are now coming to light. In this review, we discuss recent work that demonstrates the various mechanisms responsible for defibrillation. On the cellular level, membrane depolarization and electroporation affect defibrillation outcome. Cell bundles and collagenous septae are secondary sources and cause virtual electrodes at sites far from shocking electrodes. On the whole-heart level, shock field gradient and critical points determine whether a shock is successful or whether reentry causes initiation and continuation of fibrillation.
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