Bioengineered 3D electrospun nanofibrous scaffold with human liver cells to study alcoholic liver disease in vitro.

Alcohol injury induces hepatic fibrosis which gradually progresses to cirrhosis, sometimes may lead to liver cancer. Animal models are less efficient in mimicking responses of human liver cells, whereas in vitro models discussed so far are majorly based on rodent cells. In this work, a coculture of primary human hepatocytes (PHHs) with LX-2 cells was established on the unmodified (C:F_0:0), collagen-I modified (C:F_1:0), fibronectin modified (C:F_0:1) and 3:1 collagen-I to fibronectin modified (C:F_3:1) 3D electrospun fibrous scaffolds. The effect of alcohol injury was evaluated on this cell-scaffold model at 0-40 µl/ml alcohol concentrations over 14 days of culture period by using the gold standard sandwich culture as the control. Among all the culture groups, C:F_3:1 scaffold was able to maintain translational and transcriptional properties of human liver cells at all concentrations of alcohol treatment. The study reveals that, PHHs on C:F_3:1 were able to maintain ~4-fold and ~1.6-fold higher secretion of albumin than the gold standard sandwich culture on Day 3 and Day 7, respectively. When treated with alcohol, at concentrations of 20 and 40 µl/ml, albumin secretion was also observed to be higher (~2-fold) when compared to the gold standard sandwich culture. Again as expected, in C:F_3:1 culture group on 40 µl/ml alcohol treatment, albumin gene expression decreased by ~2-fold due to alcohol toxicity, whereas CYP2C9, CYP3A4, CYP2E1 and CYP1A2 gene expressions upregulated by ~3.5, ~~4, ~5 and ~15-fold, respectively in response to the alcohol injury. LX-2 cells also acquire more quiescent phenotype on C:F_3:1 scaffolds when compared to the gold standard sandwich culture upon alcohol treatment. Thus, C:F_3:1 scaffold with human liver cells was established as the potential platform to scan alcohol toxicity at varied alcohol concentrations. Thus, it can pave a promising path not only to support functional healthy human liver cells for liver tissue engineering but also to examine potential drugs to study the progression or inhibition of alcoholic liver fibrosis in vitro.

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.

Essential design considerations for the resazurin reduction assay to noninvasively quantify cell expansion within perfused extracellular matrix scaffolds.

Precise measurement of cellularity within bioartificial tissues and extracellular matrix (ECM) scaffolds is necessary to augment rigorous characterization of cellular behavior, as accurate benchmarking of tissue function to cell number allows for comparison of data across experiments and between laboratories. Resazurin, a soluble dye that is reduced to highly fluorescent resorufin in proportion to the metabolic activity of a cell population, is a valuable, noninvasive tool to measure cell number. We investigated experimental conditions in which resazurin reduction is a reliable indicator of cellularity within three-dimensional (3D) ECM scaffolds. Using three renal cell populations, we demonstrate that correlation of viable cell numbers with the rate of resorufin generation may deviate from linearity at higher cell densities, lower resazurin working volumes, or longer incubation times that all contribute to depleting the pool of resazurin. In conclusion, while the resazurin reduction assay provides a powerful, noninvasive readout of metrics enumerating cellularity and growth within ECM scaffolds, assay conditions may strongly influence its applicability for accurate quantification of cell number. The approach and methodological recommendations presented herein may be used as a guide for application-specific optimization of this assay to obtain rigorous and accurate measurement of cellular content in bioengineered tissues.

Inducing cells to disperse nickel nanowires via integrin-mediated responses.

We present non-cytotoxic, magnetic, Arg-Gly-Asp (RGD)-functionalized nickel nanowires (RGD-nanowires) that trigger specific cellular responses via integrin transmembrane receptors, resulting in dispersal of the nanowires. Time-lapse fluorescence and phase contrast microscopy showed that dispersal of 3 µm long nanowire increased by a factor of 1.54 with functionalization by RGD, compared to polyethylene glycol (PEG), through integrin-specific binding, internalization and proliferation in osteosarcoma cells. Further, a 35.5% increase in cell density was observed in the presence of RGD-nanowires, compared to an increase of only 15.6% with PEG-nanowires. These results promise to advance applications of magnetic nanoparticles in drug delivery, hyperthermia, and cell separation where uniformity and high efficiency in cell targeting is desirable.

In vitro collagen fibril alignment via incorporation of nanocrystalline cellulose.

This study demonstrates a method for producing ordered collagen fibrils on a similar length scale to those in the cornea, using a one-pot liquid-phase synthesis. The alignment persists throughout samples on the mm scale. The addition of nanocrystalline cellulose (NCC), a biocompatible and widely available material, to collagen prior to gelation causes the fibrils to align and achieve a narrow size distribution (36±8nm). The effects of NCC loading in the composites on microstructure, transparency and biocompatibility are studied by scanning electron microscopy, ultraviolet-visible spectroscopy and cell growth experiments. A 2% loading of NCC increases the transparency of collagen while producing an ordered microstructure. A mechanism is proposed for the ordering behavior on the basis of enhanced hydrogen bonding during collagen gel formation.

Silica hybrid for corneal replacement: optical, biomechanical, and ex vivo biocompatibility studies.

PURPOSE: To investigate compositions of silica-collagen hybrid materials as potential artificial corneal substitutes, how these components affect the optical and biomechanical properties of the hybrids, and their biocompatibility in an organ culture model. METHODS: Hybrid materials were created from different proportions of collagen and silica precursors and manufactured to specific dimensions. The microstructure of the materials was determined by electron microscopy and mechanical strength was measured by using suture pullout tests. The refractive index and transmittance were measured by using an Abbe refractometer and a spectrophotometer. Materials were implanted into rabbit corneas to determine their epithelialization in organ culture. RESULTS: Scanning electron microscopy demonstrated that the hybrid material consisted of silica-encapsulating collagen fibrils. The refractive index ranged from 1.332 to 1.403 depending upon the composition and manufacturing characteristics. The rupture strength of a 3:1 (silica:collagen ratio by weight) rehydrated xerogel was 0.161 ± 0.073 N/mm (n = 12), while the hydrogels and 9:1 xerogel were too fragile for suturing. Re-epithelialization of 5- to 6-mm-wide rabbit corneal epithelial defects was complete in 5.5 ± 2.4 days (n = 6), with evidence of epithelial stratification. CONCLUSIONS: Silica-collagen hybrid materials can be manufactured to specific dimensions to serve as a possible artificial corneal substitute. In preliminary studies, the materials had favorable optical, biomechanical, and biocompatibility properties necessary for replacing the corneal stroma.