In Vitro Perfusion of Engineered Heart Tissue Through Endothelialized Channels

Overview

Journal Tissue Eng Part A

Specialties Anatomy & Histology
Biomedical Engineering
Biotechnology

Date 2013 Oct 26

PMID 24156346

Citations 43

Authors

Ingra Vollert

Moritz Seiffert

Johanna Bachmair

Merle Sander

Alexandra Eder

Lenard Conradi

Alexander Vogelsang

Thomas Schulze

June Uebeler

Wolfgang Holnthoner

Heinz Redl

Hermann Reichenspurner

Arne Hansen

Thomas Eschenhagen

Affiliations

Soon will be listed here.

Abstract

In engineered heart tissues (EHT), oxygen and nutrient supply via mere diffusion is a likely factor limiting the thickness of cardiac muscle strands. Here, we report on a novel method to in vitro perfuse EHT through tubular channels. Adapting our previously published protocols, we expanded a miniaturized fibrin-based EHT-format to a larger six-well format with six flexible silicone posts holding each EHT (15×25×3 mm³). Thin dry alginate fibers (17×0.04×0.04 mm) were embedded into the cell-fibrin-thrombin mix and, after fibrin polymerization, dissolved by incubation in alginate lyase or sodium citrate. Oxygen concentrations were measured with a microsensor in 14-day-old EHTs (37°C, 21% oxygen) and ranged between 9% at the edges and 2% in the center of the tissue. Perfusion rapidly increased it to 10%-12% in the immediate vicinity of the microchannel. Continuous perfusion (20 μL/h, for 3 weeks) of the tubular lumina (100-500 μm) via hollow posts of the silicone rack increased mean dystrophin-positive cardiomyocyte density (36%±6% vs. 10%±3% of total cell number) and cross sectional area (73±2 vs. 48±1 μm²) in the central part of the tissue compared to nonperfused EHTs. The channels were populated by endothelial cells present in the reconstitution cell mix. In conclusion, we developed a novel approach to generate small tubular structures suitable for perfusion of spontaneously contracting and force-generating EHTs and showed that prolonged perfusion improved cardiac tissue structure.

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