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Understanding the cellular dynamics, engineering perspectives and translation prospects in bioprinting epithelial tissues

İrem Deniz Derman, Joseph Christakiran Moses, Taino Rivera, İbrahim T. Özbolat

2024Bioactive Materials13 citationsDOIOpen Access PDF

Abstract

The epithelium is one of the important tissues in the body as it plays a crucial barrier role serving as a gateway into and out of the body. Most organs in the body contain an epithelial tissue component, where the tightly connected, organ-specific epithelial cells organize into cysts, invaginations, or tubules, thereby performing distinct to endocrine or exocrine secretory functions. Despite the significance of epithelium, engineering functional epithelium in vitro has remained a challenge due to it is special architecture, heterotypic composition of epithelial tissues, and most importantly, difficulty in attaining the apico-basal and planar polarity of epithelial cells. Bioprinting has brought a paradigm shift in fabricating such apico-basal polarized tissues. In this review, we provide an overview of epithelial tissues and provide insights on recapitulating their cellular arrangement and polarization to achieve epithelial function. We describe the different bioprinting techniques that have been successful in engineering polarized epithelium, which can serve as in vitro models for understanding homeostasis and studying diseased conditions. We also discuss the different attempts that have been investigated to study these 3D bioprinted engineered epithelium for preclinical use. Finally, we highlight the challenges and the opportunities that need to be addressed for translation of 3D bioprinted epithelial tissues towards paving way for personalized healthcare in the future. • In-depth analysis of epithelial tissues with emphasis on different bioprinting strategies. • Perspectives involved in engineering polarized epithelium that serve as in vitro models for studying diseased conditions. • Highlights of different bioprinted epithelial models in preclinical stages and their translational prospects.

Topics & Concepts

Translation (biology)Dynamics (music)Tissue engineeringCell biologyChemistryNanotechnologyMaterials scienceComputer scienceBiophysicsEngineeringBiomedical engineeringBiologyPhysicsBiochemistryMessenger RNAGeneAcoustics3D Printing in Biomedical ResearchInnovative Microfluidic and Catalytic Techniques InnovationCancer Cells and Metastasis
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