Biowire Model of Interstitial and Focal Cardiac Fibrosis

Overview

Journal ACS Cent Sci

Specialty Chemistry

Date 2019 Aug 13

PMID 31403068

Citations 56

Authors

Erika Yan Wang

Naimeh Rafatian

Yimu Zhao

Angela Lee

Benjamin Fook Lun Lai

Rick Xingze Lu

Danica Jekic

Locke Davenport Huyer

Ericka J Knee-Walden

Shoumo Bhattacharya

Peter H Backx

Milica Radisic

Affiliations

Soon will be listed here.

Abstract

Myocardial fibrosis is a severe global health problem due to its prevalence in all forms of cardiac diseases and direct role in causing heart failure. The discovery of efficient antifibrotic compounds has been hampered due to the lack of a physiologically relevant disease model. Herein, we present a disease model of human myocardial fibrosis and use it to establish a compound screening system. In the Biowire II platform, cardiac tissues are suspended between a pair of poly(octamethylene maleate (anhydride) citrate) (POMaC) wires. Noninvasive functional readouts are realized on the basis of the deflection of the intrinsically fluorescent polymer. The disease model is constructed to recapitulate contractile, biomechanical, and electrophysiological complexities of fibrotic myocardium. Additionally, we constructed a heteropolar integrated model with fibrotic and healthy cardiac tissues coupled together. The integrated model captures the regional heterogeneity of scar lesion, border zone, and adjacent healthy myocardium. Finally, we demonstrate the utility of the system for the evaluation of antifibrotic compounds. The high-fidelity model system combined with convenient functional readouts could potentially facilitate the development of precision medicine strategies for cardiac fibrosis modeling and establish a pipeline for preclinical compound screening.

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