Generating an In Vitro 3D Cell Culture Model from Zebrafish Larvae for Heart Research.

Bianka Grunow; Lisa Mohamet; Holly A Shiels

doi:10.1242/jeb.118224

Generating an In Vitro 3D Cell Culture Model from Zebrafish Larvae for Heart Research.

Bianka Grunow, Lisa Mohamet, Holly A Shiels

Research output: Contribution to journal › Article › peer-review

Abstract

We describe here a novel, fast and inexpensive method for producing a 3D 'heart' structure that forms spontaneously, in vitro, from larval zebrafish (ZF). We have named these 3D 'heart' structures 'zebrafish heart aggregate(s)' (ZFHAs) and have characterised their basic morphology and structural composition using histology, immunohistochemistry, electron microscopy and mass spectrometry. After 2 days in culture the ZFHA spontaneously form and become a stable contractile syncytium consisting of cardiac tissue derived by in vitro maturation, which beats rhythmically and consistently for more than 8 days. We propose this model as a platform technology, which can be developed further to study in vitro cardiac maturation, regeneration, tissue engineering and safety pharmacological/toxicology testing.

Original language	English
Journal	The Journal of Experimental Biology
DOIs	https://doi.org/10.1242/jeb.118224
Publication status	Published - 24 Feb 2015

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title = "Generating an In Vitro 3D Cell Culture Model from Zebrafish Larvae for Heart Research.",

abstract = "We describe here a novel, fast and inexpensive method for producing a 3D 'heart' structure that forms spontaneously, in vitro, from larval zebrafish (ZF). We have named these 3D 'heart' structures 'zebrafish heart aggregate(s)' (ZFHAs) and have characterised their basic morphology and structural composition using histology, immunohistochemistry, electron microscopy and mass spectrometry. After 2 days in culture the ZFHA spontaneously form and become a stable contractile syncytium consisting of cardiac tissue derived by in vitro maturation, which beats rhythmically and consistently for more than 8 days. We propose this model as a platform technology, which can be developed further to study in vitro cardiac maturation, regeneration, tissue engineering and safety pharmacological/toxicology testing.",

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AU - Shiels, Holly A

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AB - We describe here a novel, fast and inexpensive method for producing a 3D 'heart' structure that forms spontaneously, in vitro, from larval zebrafish (ZF). We have named these 3D 'heart' structures 'zebrafish heart aggregate(s)' (ZFHAs) and have characterised their basic morphology and structural composition using histology, immunohistochemistry, electron microscopy and mass spectrometry. After 2 days in culture the ZFHA spontaneously form and become a stable contractile syncytium consisting of cardiac tissue derived by in vitro maturation, which beats rhythmically and consistently for more than 8 days. We propose this model as a platform technology, which can be developed further to study in vitro cardiac maturation, regeneration, tissue engineering and safety pharmacological/toxicology testing.

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JO - The Journal of Experimental Biology

JF - The Journal of Experimental Biology

SN - 1477-9145

ER -

Generating an In Vitro 3D Cell Culture Model from Zebrafish Larvae for Heart Research.

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