Engineered heart tissue grafts improve systolic and diastolic function in infarcted rat hearts

Zimmermann, Wolfram‐Hubertus; Melnychenko, Ivan; Wasmeier, Gerald; Didié, Michael; Naito, Hiroshi; Nixdorff, Uwe; Heß, Andreas; Budinský, Luboš; Brune, Kay; Michaelis, Bjela; Dhein, Stefan; Schwoerer, Alexander Peter; Ehmke, Heimo; Eschenhagen, Thomas

doi:10.1038/nm1394

Cited by 897 publications

(788 citation statements)

References 27 publications

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“…The constructs appeared to delay the ventricular thinning and led to a reduced increase in the diastolic volume and pressure compared to the sham groups [25]. The constructs were about ~ 400 µm thick and showed vessel formation by the donor cells that supported the construct beyond the 100 µm mark of diffusion limit [26].…”

Section: Engineered Heart Tissues (Ehts)mentioning

confidence: 94%

Endothelial cells guided by immobilized gradients of vascular endothelial growth factor on porous collagen scaffolds

et al. 2011

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A key challenge in tissue engineering is overcoming cell death in the scaffold interior due to the limited diffusion of oxygen and nutrients therein. We hypothesized here that immobilizing a gradient of vascular endothelial growth factor would guide endothelial cells into the interior of the scaffold thereby enhancing angiogenesis. The protein was immobilized onto a collagen scaffold through carbodiimide chemistry by one of the three methods experimented: placing 5 µl of the solution at the center of the scaffold to create a ~2 ng/ml/mm gradient in a radial direction. D4T endothelial cells were observed to be guided by this VEGF-165 gradient deep into the center of the scaffold compared to both uniformly immobilized VEGF-165 and VEGFfree controls. We concluded that the VEGF-165 gradient scaffolds promoted the migration, and not proliferation, of cells deep into the scaffold. These gradient scaffolds provide the foundation for future in vivo tissue engineering studies.iii

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Section: Engineered Heart Tissues (Ehts)mentioning

confidence: 94%

Endothelial cells guided by immobilized gradients of vascular endothelial growth factor on porous collagen scaffolds

et al. 2011

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“…This has been shown to improve ECT twitch force production. 26 ECTs formed as hiPSC-CMcontaining fibrin gels were able to displace the microspherecontaining PDMS, which allowed for indirect quantification of the twitch force. While not reported, contraction and relaxation rates can be directly quantified and compared.…”

Section: Discussionmentioning

confidence: 99%

Tissue Contraction Force Microscopy for Optimization of Engineered Cardiac Tissue

Schaefer

Tranquillo

2016

Tissue Engineering Part C: Methods

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We developed a high-throughput screening assay that allows for relative comparison of the twitch force of millimeter-scale gel-based cardiac tissues. This assay is based on principles taken from traction force microscopy and uses fluorescent microspheres embedded in a soft polydimethylsiloxane (PDMS) substrate. A gelforming cell suspension is simply pipetted onto the PDMS to form hemispherical cardiac tissue samples. Recordings of the fluorescent bead movement during tissue pacing are used to determine the maximum distance that the tissue can displace the elastic PDMS substrate. In this study, fibrin gel hemispheres containing human induced pluripotent stem cell-derived cardiomyocytes were formed on the PDMS and allowed to culture for 9 days. Bead displacement values were measured and compared to direct force measurements to validate the utility of the system. The amplitude of bead displacement correlated with direct force measurements, and the twitch force generated by the tissues was the same in 2 and 4 mg/mL fibrin gels, even though the 2 mg/mL samples visually appear more contractile if the assessment were made on free-floating samples. These results demonstrate the usefulness of this assay as a screening tool that allows for rapid sample preparation, data collection, and analysis in a simple and cost-effective platform.

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“…Furthermore, these EHTs can be stacked together in various geometries to increase graft size and then stitch the graft to an infarcted heart. Epicardial mapping has shown that paced EHTs propagate electrical signals to the surrounding myocardium, and that these grafts do not lead to arrhythmia [74]. Moreover, echocardiograph and MRI indicated reduced left ventricular dilation and end diastolic volume.…”

Section: Engineered Tissue Constructsmentioning

confidence: 99%

“…1c, d), and then use it to surgically repair the diseased myocardium. Several laboratories are successfully moving toward this goal [48,66,[73][74][75][76]. For example, engineered heart tissue grafts (EHTs) have been developed by seeding neonatal cardiomyocytes in circular molds with collagen and Matrigel, and then culturing the formed rings in a mechanical stretch device [73].…”

Section: Engineered Tissue Constructsmentioning

confidence: 99%

“…Recent modifications to EHT generation, using a mixed cell population with fibroblasts, smooth muscle cells, and endothelial cells, have resulted in superior contractile performance over cardiomyocyte samples alone [66]. Moreover, the creation of EHT from ESC and successful engraftment of these ESC-EHT into the working myocardium has also been reported [74].…”

Section: Engineered Tissue Constructsmentioning

confidence: 99%

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Adhesion Proteins, Stem Cells, and Arrhythmogenesis

Gillum

Sarvazyan

2008

Cardiovasc Toxicol

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Cell-transplantation therapy is a promising treatment option that is being actively explored as a way to repair cardiac muscle. The ultimate goal is to reconstitute the architecture of the cardiac muscle and to reestablish electrical propagation, while avoiding hypertrophy and scar formation. In this review, we focus on recent advances in the field as well as the difficulties encountered when the engraftment of cells into the host tissue is to be confirmed and functionally characterized. This is critical since incomplete or partial engraftment of transplanted cells within the host cardiac network exacerbates the heterogeneity already present in the injured myocardium and increases its propensity to arrhythmia. We conclude with a brief discussion of how the modulation of cell adhesion via modification of coupling proteins within transplanted cells may facilitate engraftment and alleviate the arrhythmogenic potential of cardiac grafts.

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Engineered heart tissue grafts improve systolic and diastolic function in infarcted rat hearts

Cited by 897 publications

References 27 publications

Endothelial cells guided by immobilized gradients of vascular endothelial growth factor on porous collagen scaffolds

Endothelial cells guided by immobilized gradients of vascular endothelial growth factor on porous collagen scaffolds

Tissue Contraction Force Microscopy for Optimization of Engineered Cardiac Tissue

Adhesion Proteins, Stem Cells, and Arrhythmogenesis

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