posted on 2021-05-21, 16:38authored byG. Janani, Biman B. Mandal
Mimicking nativelike metabolic zonation
is indispensable to develop
an efficient bioartificial liver model, as it facilitates physiological
cues, hepatocyte polarity, and phenotypic functions. The present study
shows the first evidence of hepatocyte metabolic heterogeneity in
an in vitro liver model encompassing liver extracellular
matrix (ECM)-functionalized silk scaffolds (LECM-SF) by altering ECM
proportion. Upon static culture, individual LECM-SF scaffold supports
differential synthetic and metabolic functions of cultured primary
neonatal rat hepatocytes (PNRHs), owing to discrete biophysical attributes.
A single in vitro liver system comprising PNRHs seeded
LECM-SF scaffolds assisting periportal to pericentral gradient functions
is stacked and matured in a perfusion bioreactor to simulate oxygen
gradient. The scaffold with high ECM supports periportal-specific
albumin synthesis, urea secretion, and bile duct formation, albeit
scaffold with low ECM supports pericentral-specific cytochrome P450
activity. Extensive physicochemical characterizations confirmed the
stability and interconnected porous network of scaffolds, signifying
cellular infiltration and bidirectional nutrient diffusion. Furthermore,
scaffolds demonstrate minimal thrombogenicity, reduced foreign-body
response, and enhanced pro-remodeling macrophage activation, supporting
constructive tissue remodeling. The developed liver model with zone-specific
functions would be a promising avenue in bioartificial liver and drug
screening.