Controlled activation of hepatocyte aggregation is critical to three‐dimensional (3D) multicellular morphogenesis during native regeneration of liver as well as tissue reconstruction therapies. In this work, we quantify the stimulatory effects of two model hepatotrophic activators, epidermal growth factor (EGF) and hepatocyte growth factor (HGF), on the aggregation kinetics and liver‐specific function of hepatocytes cultured on organotypic substrates with differing mechanical resistivity. Substrate‐specific morphogenesis of cultured hepatocytes is induced on a tissue basement membrane extract, Matrigel, formulated at two distinct levels of mechanical compliance (storage modulus G′, at oscillatory shear rate 1 rad/s, was 34 Pa for basal Matrigel and 118 Pa for crosslinked Matrigel). Overall, we report that growth factor stimulation selectively promotes the kinetics of aggregation in the form of two‐dimensional corded aggregates on basal Matrigel and three‐dimensional spheroidal aggregates on crosslinked Matrigel. Our analysis also indicates that costimulation with EGF and HGF (20 ng/mL each) cooperatively maximizes the kinetics of aggregation in a substrate‐specific manner. In addition, we show that the role of growth factor stimulation on hepatocyte function is sensitively governed by the mechanical compliance of the substrate. In particular, on matrices with high compliance, costimulatory aggregation is shown to elicit a marked increase in albumin secretion rate, whereas on matrices with low compliance aggregation results in effective functional repression to basal, unstimulated levels. Thus, our studies highlight a novel interplay of physicochemical parameters of the culture microenvironment, leading to selective enhancement or repression of differentiated functions of hepatocytes, in concert with the activation of cellular morphogenesis. © 2000 John Wiley & Sons, Inc. Biotechnol Bioeng 69: 359–369, 2000.
In order to evaluate the sensitivity of hepatocellular cultures to variations in both substrate stiffness and bioactive ligand presentation, hepatocytes were cultured on differentially compliant polyacrylamide gel discs functionalized with varying amounts of the ECM ligand, fibronectin (FN). Subconfluent cell cultures were established in a multiwell plate format enabling the systematic evaluation of cellular response to both underlying substrate rigidity and substrate ligand concentration. Hepatocellular morphogenesis, regulated by a combination of both ligand density and substrate compliance, resulted in a broad spectrum of patterns of cellular reorganization and assembly ranging from highly two-dimensionally spread cells to highly compact, three-dimensional spheroids. Cell compaction was promoted by increasing levels of substrate mechanical compliance and generally inhibited by increasing concentrations of substrate-bound FN. We identified regimes of substrate compliance in which cells are highly responsive or relatively insensitive to the level of substrate-based ligands. For example, while FN presentation did not have a large impact on cell morphogenesis for cultures on highly compliant gels (G' = 1.9 kPa), hepatocytes on "firm" substrates of intermediate compliance (G' = 5.6 kPa) exhibited approximately a 2-fold increase in cell area between the highest and lowest FN concentrations used in this study. Further, we show that increasing substrate compliance at constant ligand concentration results in increased levels of liver-specific albumin secretion while increasing levels of FN at constant substrate rigidity yield reduced liver-specific functional activity. These substrate-elicited differences in cell function also coincided with analogous changes in the transcript levels of metabolic, growth-related, and liver-specific gene markers. Notably, these results also demonstrated that "firm" gel substrates elicit the most hepatocyte functional sensitivity to substrate-based FN presentation. Overall, our findings indicate that hepatocellular responsiveness to ligand concentration can be acutely regulated by gradation of substrate compliance, suggesting that concerted biochemical and biophysical design strategies may be critical toward the fabrication of hepatospecific biomaterials that effectively support desired levels of liver-specific function.
Objective To assess collagen network alterations occurring with flow and other abnormalities of articular cartilage at medial femoral condyle (MFC) sites repaired with osteochondral autograft (OATS) after 6 and 12 months, using quantitative polarized light microscopy (qPLM) and other histopathological methods Design The collagen network structure of articular cartilage of OATS-repaired defects and non-operated contralateral control sites were compared by qPLM analysis of parallelism index (PI), orientation angle (α) relative to the local tissue axes, and retardance (Γ) as a function of depth. qPLM parameter maps were also compared to ICRS and Modified O’Driscoll grades, and cell and matrix sub-scores, for sections stained with H&E and Safranin-O, and for Collagen-I and II Results Relative to non-operated normal cartilage, OATS-repaired regions exhibited structural deterioration, with low PI and more horizontal α, and unique structural alteration in adjacent host cartilage: more aligned superficial zone, and reoriented deep zone lateral to the graft, and matrix disorganization in cartilage overhanging the graft. Shifts in α and PI from normal site-specific values were correlated with histochemical abnormalities and co-localized with changes in cell organization/orientation, cloning, or loss, indicative of cartilage flow, remodeling, and deterioration, respectively Conclusions qPLM reveals a number of unique localized alterations of the collagen network in both adjacent host and implanted cartilage in OATS-repaired defects, associated with abnormal chondrocyte organization. These alterations are consistent with mechanobiological processes and the direction and magnitude of cartilage strain.
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