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Characterization of perfusion decellularized whole animal body, isolated organs, and multi‐organ systems for tissue engineering applications

Doris A. Taylor, Stefan M. Kren, Katrina Rhett, Matthew J. Robertson, Jacquelynn Morrissey, Osman E. Rodriguez, Hassan Virk, Lourdes Chacon‐Alberty, Ernesto Curty da Costa, Fernanda Mesquita, Luiz C. Sampaio, Camila Hochman‐Mendez

2021Physiological Reports25 citationsDOIOpen Access PDF

Abstract

To expand the application of perfusion decellularization beyond isolated single organs, we used the native vasculature of adult and neonatal rats to systemically decellularize the organs of a whole animal in situ. Acellular scaffolds were generated from kidney, liver, lower limb, heart-lung system, and a whole animal body, demonstrating that perfusion decellularization technology is applicable to any perfusable tissue, independent of age. Biochemical and histological analyses demonstrated that organs and organ systems (heart-lung pair and lower limb) were successfully decellularized, retaining their extracellular matrix (ECM) structure and organ-specific composition, as evidenced by differences in organ-specific scaffold stiffness. Altogether, we demonstrated that organs, organ systems and whole animal bodies can be perfusion decellularized while retaining ECM components and biomechanics.

Topics & Concepts

DecellularizationPerfusionExtracellular matrixTissue engineeringBiomedical engineeringPathologyLungKidneyMedicineElastinAnatomyOrgan systemBiologyInternal medicineCell biologyDiseaseTissue Engineering and Regenerative MedicineElectrospun Nanofibers in Biomedical ApplicationsBone Tissue Engineering Materials
Characterization of perfusion decellularized whole animal body, isolated organs, and multi‐organ systems for tissue engineering applications | Litcius