Micropatterning and Alignment of Skeletal Muscle Myoblasts Using Microflowed Plasma Process

ObjectivesThe primary objective of the study was to optimize micropatterning environments using the microchannel flowed plasma process for controlling the orientation and behaviour of skeletal muscle cells. We have studied the cellular patterning and alignment of skeletal myoblast cells on the various micropattern widths developed on glass substrates.Materials and MethodsIn this method, we have utilized the microchannel flowed plasma process to create micropatterned self-assembled monolayers of octadecyltrichlorosilane and 3-aminopropyltrichlorosilane for creating cell adhesive widths of 20, 200 and 1000 microns on the glass substrates. The micropatterned substrates were characterized by using fluorescein 5(6)-isothiocyanate. Thereafter, the substrates were used to culture and pattern C2C12 and primary rat skeletal muscle cells. Further, we have studied the spatiotemporal variation in the orientation of the cells by using bright field and fluorescence microscopy. The microscopic images were analysed by using orientation order parameter and orientation distribution analysis.ResultsFITC based characterization of micropatterns reveals that the adopted process for micropatterning can effectively create cell adhesive widths with dimensions comparable to the diameter of myofiber. Microscopic observations and the orientation order parameter analysis reveal the precise alignment and specific orientation of myoblasts along the designated cell adhesive widths that closely mimics the physiological scenario. Both the cells showed immediate alignment within smaller cell adhesive widths of 20 and 200 μm. Actin cytoskeletal staining and its orientation distribution analysis of micropattrned C2C12 cells emphasises the influence of micropatterned environment on cytoskeletal actin orientation.ConclusionThis study corroborates the alignment of the myoblasts using surface cues facilitated by changing surface chemistry of the glass substrates. The study promotes the application of a simple micropatterning technique as a useful tool to regulate the orientation and behaviour of skeletal muscle cells. Also, the study emphasizes the role of spatial topography created by surface modification and its effect on cell adhesion and communication of alignment information across the micropatterns. The microchannel flowed plasma process could be applied to selectively pattern different adherent cell types, which could prove to be a useful platform for the exploration of various cellular processes.     

A micropatterning approach for imaging dynamic Cx43 trafficking to cell–cell borders

The precise expression and timely delivery of connexin 43 (Cx43) proteins to form gap junctions are essential for electrical coupling of cardiomyocytes. Growing evidence supports a cytoskeletal-based trafficking paradigm for Cx43 delivery directly to adherens junctions at the intercalated disc. A limitation of Cx43 localization assays in cultured cells, in which cell–cell contacts are essential, is the inability to control for cell geometry or reproducibly generate contact points. Here we present a micropatterned cell pairing system well suited for live microscopy to examine how the microtubule and actin cytoskeleton confer specificity to Cx43 trafficking to precisely defined cell–cell junctions. This system can be adapted for other cell types and used to study dynamic intracellular movements of other proteins important for cell–cell communication.     

Long‐Term Stability of Primary Rat Hepatocytes in Micropatterned Cocultures

Primary hepatocytes display functional and structural instability in standard monoculture systems. We have previously developed a model in which primary hepatocytes are organized in domains of empirically optimized dimensions and surrounded by murine embryonic fibroblasts (HepatoPac?). Here, we assess the long‐term phenotype of freshly isolated and cryopreserved rat hepatocytes in a 96‐well HepatoPac format. The viability, cell polarity (actin microfilaments, bile canaliculi), and functions (albumin, urea, Phase I/II enzymes, transporters) of fresh and cryopreserved rat hepatocytes were retained in HepatoPac at similar levels for at least 4 weeks as opposed to rapidly declining over 5 days in collagen/Matrigel? sandwich cultures. Pulse or continuous exposure of rat HepatoPac to GW‐7647, a selective agonist of PPARα, caused reproducible induction of CYP4A1 and 3‐hydroxy‐3‐methylglutaryl‐CoA synthase over 4 weeks. In conclusion, rat HepatoPac in a 96‐well format can be used for chronic dosing of highly functional hepatocytes and assessment of perturbed hepatocellular pathways. © 2013 Wiley Periodicals, Inc. J BiochemMol Toxicol 27:204‐212, 2013; View this article online at wileyonlinelibrary.com . DOI 10.1002/jbt.21469     

Bioactivation and Toxicity of Acetaminophen in a Rat Hepatocyte Micropatterned Coculture System

We have recently shown that primary rat hepatocytes organized in micropatterned cocultures with murine embryonic fibroblasts (HepatoPac?) maintain high levels of liver functions for at least 4 weeks. In this study, rat HepatoPac was assessed for its utility to study chemical bioactivation and associated hepatocellular toxicity. Treatment of HepatoPac cultures with acetaminophen (APAP) over a range of concentrations (0–15 mM) was initiated at 1, 2, 3, or 4 weeks followed by the assessment of morphological and functional endpoints. Consistent and reproducible concentration‐dependent effects on hepatocyte structure, viability, and basic functions were observed over the 4‐week period, and were exacerbated by depleting glutathione using buthionine sulfoximine or inducing CYP3A using dexamethasone, presumably due to increased reactive metabolite‐induced stress and adduct formation. In conclusion, the results from this study demonstrate that rat HepatoPac represents a structurally and functionally stable hepatic model system to assess the long‐term effects of bioactivated compounds. © 2013 Wiley Periodicals, Inc. J BiochemMol Toxicol 27:471‐478, 2013; View this article online at wileyonlinelibrary.com . DOI 10.1002/jbt.21512     

Transduction of cell and matrix geometric cues by the actin cytoskeleton

Engineered culture substrates have proven invaluable for investigating the role of cell and extracellular matrix geometry in governing cell behavior. While the mechanisms relating geometry to phenotype are complex, it is clear that the actin cytoskeleton plays a key role in integrating geometric inputs and transducing these cues into intracellular signals that drive downstream biology. Here, we review recent progress in elucidating the role of the cell and matrix geometry in regulating actin cytoskeletal architecture and mechanics. We address new developments in traditional two-dimensional culture paradigms and discuss efforts to extend these advances to three-dimensional systems, ranging from nanotextured surfaces to microtopographical systems (e.g. channels) to fully three-dimensional matrices.