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Über die Auswirkung mechanische Last auf die Entwicklung von künstlichem Herzgewebe / The influence of mechanical stress on artificial heart tissueBaltzer, Anne 15 December 2014 (has links)
No description available.
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Fibroblast-Cardiomyocyte Cross-Talk in Heart Muscle Formation and FunctionSchlick, Susanne 19 December 2018 (has links)
No description available.
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Development of a Rhesus macaque engineered heart muscle model from pluripotent stem cellsGolat, Brian 15 May 2017 (has links)
No description available.
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Development of a novel technology to engineer heart muscle for contractile and paracrine support in heart failureSoong, Poh Loong 23 October 2012 (has links)
The human heart has poor endogenous regeneration. If myocytes are lost due
to injury, the myocardium is unable to restore its myocyte content and instead
undergoes compensatory hypertrophy and remodeling. Cardiac tissue
engineering aims to recreate and provide functional myocardium that replaces
the injured myocardium. In this study, human engineered heart muscle (EHM)
from cardiomyogenically differentiated human embryonic stem cells was
generated. EHMs consisted of elongated, anisotropically organized
cardiomyocyte bundles and responded “physiologically” to increasing calcium
concentrations. To generate large myocardium capable of encompassing the
ventricles, a novel process to systematically upscale the dimensions of
engineered myocardium to a humanized Biological Ventricular Assisted Device
(hBioVAD) was introduced. The hBioVADs formed a “pouch-like” myocardium at
rabbit heart dimensions and were beating spontaneously. Further enhancement
by biomimetic pulsatile loading generated “more mature” myocardium.
Additional paracrine functionality was integrated by generating insulin-like
growth factor-1 (IGF-1) secreting fibroblasts for tissue engineering applications.
IGF-1 release induced higher levels of Akt phosphorylation and hypertrophy in
cardiomyocytes resulting in increased force generation of EHM. Finally,
feasibility of “paraBioVAD” (IGF-1 cell line and cardiomyocytes) implantation
was demonstrated in a healthy rat model. Histological observations
demonstrated engraftment on the heart and the presence of vascular structures.
In conclusion, a humanized “paraBioVAD” technology for mechanic and
paracrine heart support was developed. Future studies will assess its
therapeutic utility in heart failure
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