Fishing for Insights from Single-Lead and Multi-Lead ECG of Live Adult Zebrafish

Events and Times

Introduction

In this webinar, Dr. Thao Nguyen discusses the exciting discoveries that her research team has made, debunks some common myths, and shares best-practices for data acquisition, analysis, and interpretation. Her in vivo studies of adult zebrafish cardiac electrophysiology rely on single-lead and multi-lead surface ECG in live anesthetized adult zebrafish.

Join us for the live webinar:

DATE: TUESDAY MAY 4 2021
START TIME: 11am PT | 2pm ET | 8pm CET
DURATION: 60 MINUTES

Click here to register

Key topics will include:

Describing the four major steps in recording in vivo surface ECG for adult zebrafish
Defining single-lead vs dual-lead electrode positions
Critiquing ECG recording quality
Performing basic interpretation of adult zebrafish cardiac depolarization, repolarization, and heart rate variability from single-lead ECG
Performing basic interpretation of adult zebrafish Einthoven triangle and cardiac axis from dual-lead ECG
Diagnosing arrhythmias, conduction blocks, and drug effects/toxicities by distinguishing pathologic deviations from normal ECG patterns

Abstract:

Zebrafish is a popular high-throughput vertebrate model to study human cardiac electrophysiology, arrhythmias, and myopathies. One reason for this popularity is the purported striking similarities between zebrafish and human electrocardiograms (ECGs). While human ECG, discovered 120 years ago, remains a standard technique in routine clinical practice, establishing similar standards for routine adult zebrafish cardiac research faces unique challenges. Yet, in vivo surface ECG offers the single most practical, economical, if not unique, solution to study adult zebrafish in vivo cardiac electrophysiology and arrhythmias.

About the speaker:

Thao P. Nguyen, MD, PhD
Associate Professor of Medicine
The Cardiovascular Research Laboratory Department of Medicine, Division of Cardiology
David Geffen School of Medicine
Dr. Nguyen is a cardiologist-biophysicist and the Principal Investigator of an NIH-funded research laboratory. Her diverse portfolio of scientific expertise in the fields of neuroscience, cardiology, ion channelopathies, system biology, biophysics, and electrophysiology provides her with a unique research perspective for multidisciplinary research in cardiac arrhythmias.