Tissue engineering to better understand senescence: Organotypics come of age

The recent advent of ‘organs in a dish’ has revolutionised the research landscape. These 3D culture systems have paved the way for translational, post genomics research by enabling scientists to model diseases in the laboratory, grow patient-derived organoids, and unite this technology with other cu...

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Veröffentlicht in:	Mechanisms of ageing and development 2020-09, Vol.190, p.111261-111261, Article 111261
Hauptverfasser:	Milligan, Deborah A., Tyler, Eleanor J., Bishop, Cleo L.
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Sprache:	eng
Schlagworte:	3D organotypic culture Drug discovery and development Living skin equivalent Original Remodelling the microenvironment Senescence Tissue engineering
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description	The recent advent of ‘organs in a dish’ has revolutionised the research landscape. These 3D culture systems have paved the way for translational, post genomics research by enabling scientists to model diseases in the laboratory, grow patient-derived organoids, and unite this technology with other cutting-edge methodologies such as drug discovery. Fields such as dermatology and neuroscience have revolutionised the development of robust 3D models, which faithfully recapitulate native physiology in vivo to provide important functional and mechanistic insights. These models have underpinned a rapid growth in the number of organs and myriad of human diseases that can be modelled in 3D, which currently includes breast, cerebral cortex, heart, intestine, kidney, liver, lung, neural tube, pancreas, prostate, skin and stomach, as well as patient derived tumours. However, so far, they have not yet been employed extensively in the study of fundamental cellular programmes such as senescence. Thus, tissue engineering and 3D culture offer an exciting opportunity to further understand the bright and dark sides of senescence in a more complex and physiologically relevant environment. Below, we will discuss previous approaches to investigating senescence and ageing using organotypic models, and some potential opportunities for future research.
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subjects	3D organotypic culture Drug discovery and development Living skin equivalent Original Remodelling the microenvironment Senescence Tissue engineering
title	Tissue engineering to better understand senescence: Organotypics come of age
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