8 research outputs found
Bioartificial heart: a human-sized porcine model - the way ahead
BACKGROUND: A bioartificial heart is a theoretical alternative to transplantation or mechanical left ventricular support. Native hearts decellularized with preserved architecture and vasculature may provide an acellular tissue platform for organ regeneration. We sought to develop a tissue-engineered whole-heart neoscaffold in human-sized porcine hearts. METHODS: We decellularized porcine hearts (n = 10) by coronary perfusion with ionic detergents in a modified Langendorff circuit. We confirmed decellularization by histology, transmission electron microscopy and fluorescence microscopy, quantified residual DNA by spectrophotometry, and evaluated biomechanical stability with ex-vivo left-ventricular pressure/volume studies, all compared to controls. We then mounted the decellularized porcine hearts in a bioreactor and reseeded them with murine neonatal cardiac cells and human umbilical cord derived endothelial cells (HUVEC) under simulated physiological conditions. RESULTS: Decellularized hearts lacked intracellular components but retained specific collagen fibers, proteoglycan, elastin and mechanical integrity; quantitative DNA analysis demonstrated a significant reduction of DNA compared to controls (82.6+/-3.2 ng DNA/mg tissue vs. 473.2+/-13.4 ng DNA/mg tissue, p<0.05). Recellularized porcine whole-heart neoscaffolds demonstrated re-endothelialization of coronary vasculature and measurable intrinsic myocardial electrical activity at 10 days, with perfused organ culture maintained for up to 3 weeks. CONCLUSIONS: Human-sized decellularized porcine hearts provide a promising tissue-engineering platform that may lead to future clinical strategies in the treatment of heart failure
Whole-heart bioreactor: BIOSTAT B-DCU II and BioPAT DCU control tower (Sartorius Stedim Biotech GmbH, Germany).
<p>Whole-heart bioreactor: BIOSTAT B-DCU II and BioPAT DCU control tower (Sartorius Stedim Biotech GmbH, Germany).</p
Demonstration of multi-electrode array electric voltage undulations of up to 200 mV in a time scale from ca. 500–1000 ms (red arrows) as a measure of myocardial electrical activity.
<p>Demonstration of multi-electrode array electric voltage undulations of up to 200 mV in a time scale from ca. 500–1000 ms (red arrows) as a measure of myocardial electrical activity.</p
Results of Extracellular Matrix Analysis.
<p>All values are expressed as mean ± SEM and adjusted to 1 mg lyophilized tissue sample.</p><p>Results of Extracellular Matrix Analysis.</p
Results of biomechanical measurements.
<p>Left ventricular peak pressure vs. volume. Decellularized hearts showed similar mechanical stability as native hearts with no significant differences in biomechanical behavior. All values are expressed as mean ± SEM.</p
Photomicrographs of unstained tissue samples demonstrating intact coronary vasculature (A, B) with intact third- and fourth-level vessels (A, red arrows).
<p>The extracellular matrix composition of the aortic wall (<b>C</b>) and aortic valve leaflet (<b>D</b>) was preserved after decellularization and showed no remnant nuclear material as demonstrated by hematoxylin and eosin (HE) staining (C, D) and TEM analysis (<b>box in D</b>). Also the aortic valve remained competent after decellularization (<b>E, F</b>).</p
Representative images of a porcine heart before (A) and after (B) decellularization with sodium dodecyl sulfate (SDS).
<p>All structures including the coronary vasculature (B, red arrow) are preserved. Hematoxylin and eosin (HE) staining of ventricular tissue before (C) and after perfusion decellularization (D) showing no remnant nuclear structures after treatment with SDS, with maintained extracellular matrix and coronary vessels (D, black arrow). Scale bars, 200 µm.</p