Physiological aspects of cardiac tissue engineering

Eschenhagen, Thomas; Eder, Alexandra; Vollert, Ingra; Hansen, Arne

doi:10.1152/ajpheart.00007.2012

Cited by 90 publications

(55 citation statements)

References 112 publications

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“…Recent advances in stem cell biology and tissue engineering have provided unprecedented access to human heart tissue for basic biological studies, disease modeling, drug screening and regenerative medicine applications (Eder et al, 2016;Eschenhagen et al, 2012). Robust protocols have been developed to differentiate human pluripotent stem cells (hPSC), such as embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSCs), to produce cardiomyocytes (Hudson and Zimmermann, 2011).…”

Section: Introductionmentioning

confidence: 99%

Development of a human cardiac organoid injury model reveals innate regenerative potential

et al. 2017

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The adult human heart possesses a limited regenerative potential following an ischemic event, and undergoes a number of pathological changes in response to injury. While cardiac regeneration has been documented in zebrafish and neonatal mouse hearts, it is currently unknown whether the immature human heart is capable of undergoing complete regeneration. Combined progress in pluripotent stem cell differentiation and tissue engineering has facilitated the development of human cardiac organoids (hCO), which resemble fetal heart tissue and can be used to address this important knowledge gap. This study aimed to characterise the regenerative capacity of immature human heart tissue in response to injury. Following cryoinjury with a dry ice probe, hCO exhibited an endogenous regenerative response with full functional recovery by two weeks following acute injury. Cardiac functional recovery occurred in the absence of pathological fibrosis or cardiomyocyte hypertrophy. Consistent with regenerative organisms and neonatal human hearts, there was a high basal level of cardiomyocyte proliferation, which may be responsible for the regenerative capacity of the hCO. This study suggests that immature human heart tissue has an intrinsic capacity to regenerate.

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Section: Introductionmentioning

confidence: 99%

Development of a human cardiac organoid injury model reveals innate regenerative potential

et al. 2017

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“…75 The lower forces in engineered cardiac constructs are mainly explained by lower cardiac myocyte density, lower sarcomere volume fraction, and the overall lower level of cardiac myocyte differentiation. 74 Cardiac 3D constructs from chickens, rats, mice, and humans show a positive inotropic and chronotropic response to β-adrenergic stimulation, which is sensitive to the muscarinic agonist carbachol. 74 Furthermore, they increase force with ; in rat, 76 murine, 22 and mouse EHTs, 77 it was negative.…”

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confidence: 99%

“…74 Cardiac 3D constructs from chickens, rats, mice, and humans show a positive inotropic and chronotropic response to β-adrenergic stimulation, which is sensitive to the muscarinic agonist carbachol. 74 Furthermore, they increase force with ; in rat, 76 murine, 22 and mouse EHTs, 77 it was negative. Collectively, this demonstrates that 3D engineered tissues function qualitatively like native muscle.…”

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confidence: 99%

Cardiac Tissue Engineering

2014

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Abstract:The engineering of 3-dimensional (3D) heart muscles has undergone exciting progress for the past decade.Profound advances in human stem cell biology and technology, tissue engineering and material sciences, as well as prevascularization and in vitro assay technologies make the first clinical application of engineered cardiac tissues a realistic option and predict that cardiac tissue engineering techniques will find widespread use in the preclinical research and drug development in the near future. Tasks that need to be solved for this purpose include standardization of human myocyte production protocols, establishment of simple methods for the in vitro vascularization of 3D constructs and better maturation of myocytes, and, finally, thorough definition of the predictive value of these methods for preclinical safety pharmacology. The present article gives an overview of the present state of the art, bottlenecks, and perspectives of cardiac tissue engineering for cardiac repair and in vitro testing. ( Jeffrey Robbins, EditorOriginal received May 24, 2013; revision received July 12, 2013; accepted July 15, 2013. In November 2013, the average time from submission to first decision for all original research papers submitted to Circulation Research was 14.6 days.From the Department of Experimental Pharmacology and Toxicology, University Medical Center Hamburg-Eppendorf, Hamburg, Germany; and DZHK (German Centre for Cardiovascular Research), partner site Hamburg/Kiel/Lübeck, Hamburg, Germany.Correspondence to Thomas Eschenhagen, Department of Experimental Pharmacology and Toxicology, University Medical Center Hamburg-Eppendorf, Martinistraße 52, 20246 Hamburg, Germany. E-mail t.eschenhagen@uke.de by guest on May 9, 2018 http://circres.ahajournals.org/ Downloaded from Hirt et al Cardiac Tissue Engineering 355gyratory shaking of embryonic chicken cardiac myocytes in an Erlenmeyer flask induced the formation of spontaneously beating spheroids with improved functionality when compared with standard 2D-cultured myocytes. This selfassembly is still used in variations to generate cardiac microspheres. 5 Current cardiac tissue engineering methods embark on this endogenous capacity and use engineering techniques to make 3D constructs of the desired size, geometry, and orientation (Table). Hydrogel TechniqueThe hydrogel method has been pioneered in the 1980s as an advanced culture method for fibroblasts and skeletal muscle cells 6 and gave rise to the first successful cardiac tissue.7 It needs 3 factors: solutions of gelling natural products, such as collagen I, matrigel, fibrin, or mixtures of them; casting molds; and anchoring constructs. The hydrogel entraps cells in a 3D space during gelling, the mold gives the 3D form, and the anchors allow the growing tissue to fix and to develop mechanical tension between ≥2 anchor points. Important aspects of this technique are that the naturally occurring hydrogels stimulate cells to spread and form intercellular connections and that the cells compress the gel, reduce the w...

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“…Since lentivirus randomly integrate into the host genome and may thereby activate or inactivate genes, many researchers worked on improving this method by using non-integrating viral transduction such as Sendai virus [43•], direct transfer of mRNA [44] or proteins [45], or replacing some of the pluripotency factors by small molecules [46,47]. Given the relative ease and robustness and the lack of ethical concerns in their generation, human iPSC (hiPSC) are becoming increasingly important not only in the field of regeneration [48] but also as an unlimited source of patient/ disease-specific differentiated cells with great economic potential (e.g., Axiogenesis AG, Cellular Dynamics International, Pluriomics).…”

Section: Induced Pluripotent Stem Cellsmentioning

confidence: 99%

“…Various systems have been developed to fix the remodeling tissue and provide the mechanical strain necessary for cell orientation between the fixation points. The setup ranges from Velcro-coated glass tubes [94], rings [95], Flexcell chambers [97], and mesoscopic micropost arrays [98] to newer systems in which the fixation posts serve as means to measure contractile force [99,100] (overview in [48]). For cardiac repair, the hydrogel systems can be upscaled, either by employing larger casting molds [101] or assembling of several smaller elements [102].…”

Section: Approaches For the Use Of Pluripotent Stem Cell Products In mentioning

confidence: 99%

Engineering Cardiovascular Regeneration

et al. 2015

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The human heart has very limited regenerative capacity, making the loss of heart muscle tissue during myocardial infarction essentially irreversible. Regenerative medicine aims at promoting the formation of new functional heart muscle in an injured heart, either by stimulating myocyte proliferation, formation of myocytes from preexisting stem cells, direct reprogramming of fibroblasts into myocytes, or adding new muscle tissue from exogenous stem cell sources. Recent advances in stem cell research make these goals more realistic. This review provides a short overview about different approaches for cardiovascular regeneration, stem cell sources, and modes of application, focusing on current cardiac tissue engineering techniques and their way towards clinical application.

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Physiological aspects of cardiac tissue engineering

Cited by 90 publications

References 112 publications

Development of a human cardiac organoid injury model reveals innate regenerative potential

Development of a human cardiac organoid injury model reveals innate regenerative potential

Cardiac Tissue Engineering

Engineering Cardiovascular Regeneration

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