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Formation of spatially and geometrically controlled three-dimensional tissues in soft gels by sacrificial micromolding.


ABSTRACT: Patterned three-dimensional (3D) cell culture models aim to more accurately represent the in vivo architecture of a tissue for the purposes of testing drugs, studying multicellular biology, or engineering functional tissues. However, patterning 3D multicellular structures within very soft hydrogels (<500 Pa) that mimic the physicochemical environment of many tissues remains a challenge for existing methods. To overcome this challenge, we use a Sacrificial Micromolding technique to temporarily form spatially and geometrically defined 3D cell aggregates in degradable scaffolds before transferring and culturing them in a reconstituted extracellular matrix. Herein, we demonstrate that Sacrificial Micromolding (1) promotes cyst formation and proper polarization of established epithelial cell lines, (2) allows reconstitution of heterotypic cell-cell interactions in multicomponent epithelia, and (3) can be used to control the lumenization-state of epithelial cysts as a function of tissue size. In addition, we discuss the potential of Sacrificial Micromolding as a cell-patterning tool for future studies.

SUBMITTER: Cerchiari A 

PROVIDER: S-EPMC4442595 | biostudies-literature | 2015 Jun

REPOSITORIES: biostudies-literature

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Formation of spatially and geometrically controlled three-dimensional tissues in soft gels by sacrificial micromolding.

Cerchiari Alec A   Garbe James C JC   Todhunter Michael E ME   Jee Noel Y NY   Pinney James R JR   LaBarge Mark A MA   Desai Tejal A TA   Gartner Zev J ZJ  

Tissue engineering. Part C, Methods 20141211 6


Patterned three-dimensional (3D) cell culture models aim to more accurately represent the in vivo architecture of a tissue for the purposes of testing drugs, studying multicellular biology, or engineering functional tissues. However, patterning 3D multicellular structures within very soft hydrogels (<500 Pa) that mimic the physicochemical environment of many tissues remains a challenge for existing methods. To overcome this challenge, we use a Sacrificial Micromolding technique to temporarily fo  ...[more]

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