Collagen-I and fibronectin modified three-dimensional electrospun PLGA scaffolds for long-term in vitro maintenance of functional hepatocytes.

Extracellular matrix (ECM) proteins are important regulators of cellular behaviour in the native environment. It has been established that ECM proteins - collagen-I and fibronectin - are present in liver extracellular matrix and regulate specific functions of primary hepatocytes. While scaffolds grafted with the individual ECM protein have shown support for hepatocyte functional properties in vitro, the synergistic effects of both ECM proteins remain to be explored. Such studies are even more limited when three-dimensional (3D) scaffolds are involved. In the current work, the fabrication of a series of highly porous poly(lactic-co-glycolic acid) (PLGA) 3D electrospun scaffolds, simultaneously modified with both collagen-I and fibronectin, has been demonstrated. Different ratios of collagen-I to fibronectin were optimized to study the synergistic effects of the proteins in supporting the viability and functional properties of Huh-7.5 cells. The ratio of collagen-I to fibronectin at 3:1 was found to provide the most efficient chemisorption on the 3D scaffolds. At this ratio, the total protein content that can be grafted on the scaffolds was the highest and the most homogeous. This led to remarkable enhancement of cell seeding efficiency as well as proliferation. Most importantly, liver specific genes such as albumin and cytochrome P450 enzymes i.e. CYP3A4 and CYP3A7 were significantly upregulated by ~12.5, 7 and 4.5 fold respectively, as compared to unmodified PLGA scaffolds after 28 days of culture. Compared to single-protein modified scaffolds, scaffolds modified with 3:1 collagen to fibronectin result in a rise of the albumin gene expression of cultured cells by ~8 to 10 fold, whereas CYP3A4 gene expression improved by ~5 to 7 fold and CYP3A7 gene expression improved by ~4 to 4.5 fold after a long culture period of 28 days. Albumin secretion was improved by ~4 fold compared to unmodified PLGA scaffolds, ~3 fold compared to collagen-I modified culture groups and ~2 fold compared to fibronectin modified culture groups. The multi-protein modified scaffolds, at the optimum ratio, were able to significantly enhance functional properties of the liver cells. This simple yet highly functioning platform would be useful for in vitro culture of liver cells for both drug screening as well as translational purposes.

Nanofibrous PLGA electrospun scaffolds modified with type I collagen influence hepatocyte function and support viability in vitro.

A major challenge of maintaining primary hepatocytes in vitro is progressive loss of hepatocyte-specific functions, such as protein synthesis and cytochrome P450 (CYP450) catalytic activity. We developed a three-dimensional (3D) nanofibrous scaffold made from poly(l-lactide-co-glycolide) (PLGA) polymer using a newly optimized wet electrospinning technique that resulted in a highly porous structure that accommodated inclusion of primary human hepatocytes. Extracellular matrix (ECM) proteins (type I collagen or fibronectin) at varying concentrations were chemically linked to electrospun PLGA using amine coupling to develop an in vitro culture system containing the minimal essential ECM components of the liver micro-environment that preserve hepatocyte function in vitro. Cell-laden nanofiber scaffolds were tested in vitro to maintain hepatocyte function over a two-week period. Incorporation of type I collagen onto PLGA scaffolds (PLGA-Chigh: 100 µg/mL) led to 10-fold greater albumin secretion, 4-fold higher urea synthesis, and elevated transcription of hepatocyte-specific CYP450 genes (CYP3A4, 3.5-fold increase and CYP2C9, 3-fold increase) in primary human hepatocytes compared to the same cells grown within unmodified PLGA scaffolds over two weeks. These indices, measured using collagen-bonded scaffolds, were also higher than scaffolds coupled to fibronectin or an ECM control sandwich culture composed of type I collagen and Matrigel. Induction of CYP2C9 activity was also higher in these same type I collagen PLGA scaffolds compared to other ECM-modified or unmodified PLGA constructs and was equivalent to the ECM control at 7 days. Together, we demonstrate a minimalist ECM-based 3D synthetic scaffold that accommodates primary human hepatocyte inclusion into the matrix, maintains long-term in vitro survival and stimulates function, which can be attributed to coupling of type I collagen. STATEMENT OF SIGNIFICANCE: Culturing primary hepatocytes within a three-dimensional (3D) structure that mimics the natural liver environment is a promising strategy for extending the function and viability of hepatocytes in vitro. In the present study we generate porous PLGA nanofibers, that are chemically modified with extracellular matrix proteins, to serve as 3D scaffolds for the in vitro culture of primary human hepatocytes. Our findings demonstrate that the use of ECM proteins, especially type I collagen, in a porous 3D environment helps to improve the synthetic function of primary hepatocytes over time. We believe the work presented within will provide insights to readers for drug toxicity and tissue engineering applications.