Matrix decoded – A pancreatic extracellular matrix with organ specific cues guiding human iPSC differentiation

The extracellular matrix represents a dynamic microenvironment regulating essential cell functions in vivo. Tissue engineering approaches aim to recreate the native niche in vitro using biological scaffolds generated by organ decellularization. So far, the organ specific origin of such scaffolds was...

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Veröffentlicht in:	Biomaterials 2020-06, Vol.244, p.119766-119766, Article 119766
Hauptverfasser:	Berger, Constantin, Bjørlykke, Yngvild, Hahn, Lukas, Mühlemann, Markus, Kress, Sebastian, Walles, Heike, Luxenhofer, Robert, Ræder, Helge, Metzger, Marco, Zdzieblo, Daniela
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Sprache:	eng
Schlagworte:	Cell Differentiation Cues Decellularization Engineering Engineering, Biomedical Extracellular Matrix Human induced pluripotent stem cells Humans Induced Pluripotent Stem Cells Intestine Lung Materials Science Materials Science, Biomaterials Organ specificity Pancreas Proteomics Science & Technology Technology Tissue Engineering Tissue Scaffolds
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container_title	Biomaterials
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creator	Berger, Constantin Bjørlykke, Yngvild Hahn, Lukas Mühlemann, Markus Kress, Sebastian Walles, Heike Luxenhofer, Robert Ræder, Helge Metzger, Marco Zdzieblo, Daniela
description	The extracellular matrix represents a dynamic microenvironment regulating essential cell functions in vivo. Tissue engineering approaches aim to recreate the native niche in vitro using biological scaffolds generated by organ decellularization. So far, the organ specific origin of such scaffolds was less considered and potential consequences for in vitro cell culture remain largely elusive. Here, we show that organ specific cues of biological scaffolds affect cellular behavior. In detail, we report on the generation of a well-preserved pancreatic bioscaffold and introduce a scoring system allowing standardized inter-study quality assessment. Using multiple analysis tools for in-depth-characterization of the biological scaffold, we reveal unique compositional, physico-structural, and biophysical properties. Finally, we prove the functional relevance of the biological origin by demonstrating a regulatory effect of the matrix on multi-lineage differentiation of human induced pluripotent stem cells emphasizing the significance of matrix specificity for cellular behavior in artificial microenvironments. [Display omitted]
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Tissue engineering approaches aim to recreate the native niche in vitro using biological scaffolds generated by organ decellularization. So far, the organ specific origin of such scaffolds was less considered and potential consequences for in vitro cell culture remain largely elusive. Here, we show that organ specific cues of biological scaffolds affect cellular behavior. In detail, we report on the generation of a well-preserved pancreatic bioscaffold and introduce a scoring system allowing standardized inter-study quality assessment. Using multiple analysis tools for in-depth-characterization of the biological scaffold, we reveal unique compositional, physico-structural, and biophysical properties. Finally, we prove the functional relevance of the biological origin by demonstrating a regulatory effect of the matrix on multi-lineage differentiation of human induced pluripotent stem cells emphasizing the significance of matrix specificity for cellular behavior in artificial microenvironments. 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Tissue engineering approaches aim to recreate the native niche in vitro using biological scaffolds generated by organ decellularization. So far, the organ specific origin of such scaffolds was less considered and potential consequences for in vitro cell culture remain largely elusive. Here, we show that organ specific cues of biological scaffolds affect cellular behavior. In detail, we report on the generation of a well-preserved pancreatic bioscaffold and introduce a scoring system allowing standardized inter-study quality assessment. Using multiple analysis tools for in-depth-characterization of the biological scaffold, we reveal unique compositional, physico-structural, and biophysical properties. 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Tissue engineering approaches aim to recreate the native niche in vitro using biological scaffolds generated by organ decellularization. So far, the organ specific origin of such scaffolds was less considered and potential consequences for in vitro cell culture remain largely elusive. Here, we show that organ specific cues of biological scaffolds affect cellular behavior. In detail, we report on the generation of a well-preserved pancreatic bioscaffold and introduce a scoring system allowing standardized inter-study quality assessment. Using multiple analysis tools for in-depth-characterization of the biological scaffold, we reveal unique compositional, physico-structural, and biophysical properties. 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subjects	Cell Differentiation Cues Decellularization Engineering Engineering, Biomedical Extracellular Matrix Human induced pluripotent stem cells Humans Induced Pluripotent Stem Cells Intestine Lung Materials Science Materials Science, Biomaterials Organ specificity Pancreas Proteomics Science & Technology Technology Tissue Engineering Tissue Scaffolds
title	Matrix decoded – A pancreatic extracellular matrix with organ specific cues guiding human iPSC differentiation
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