Fatma Zehra Erkoc-Biradli scite author profile

Corneal endothelial cells (CECs) have limited proliferation ability leading to corneal endothelium (CE) dysfunction and eventually vision loss when cell number decreases below a critical level. Although transplantation is the main treatment method, donor shortage problem is a major bottleneck. The transplantation of in vitro developed endothelial cells with desirable density is a promising idea. Designing cell substrates that mimic the native CE microenvironment is a substantial step to achieve this goal. In the presented study, we prepared polyacrylamide (PA) cell substrates that have a microfabricated topography inspired by the dimensions of CECs. Hydrogel surfaces were prepared via two different designs with small and large patterns. Small patterned hydrogels have physiologically relevant hexagon densities (∼2000 hexagons/mm2), whereas large patterned hydrogels have sparsely populated hexagons (∼400 hexagons/mm2). These substrates have similar elastic modulus of native Descemet's membrane (DM; ∼50 kPa) and were modified with Collagen IV (Col IV) to have biochemical content similar to native DM. The behavior of bovine corneal endothelial cells on these substrates was investigated and results show that cell proliferation on small patterned substrates was significantly (p = 0.0004) higher than the large patterned substrates. Small patterned substrates enabled a more densely populated cell monolayer compared to other groups (p = 0.001 vs. flat and p < 0.0001 vs. large patterned substrates). These results suggest that generating bioinspired surface topographies augments the formation of CE monolayers with the desired cell density, addressing the in vitro development of CE layers.

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Substrate stiffness effects on SH‐SY5Y: The dichotomy of morphology and neuronal behavior

Özgün

Erkoc-Biradli

Bulut

et al. 2020

J Biomed Mater Res

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Like many other cell types, neuroblastoma cells are also known to respond to mechanical cues in their microenvironment in vitro. They were shown to have mechanotransduction pathways, which result in enhanced neuronal morphology on stiff substrates. However, in previous studies, the differentiation process was monitored only by morphological parameters. Motivated by the lack of comprehensive studies that investigate the effects of mechanical cues on neuroblastoma differentiation, we used SH-SY5Y cells differentiated on polyacrylamide (PA) gels as a model. Cells differentiated on the surface of PA hydrogels with three different elastic moduli (0.1, 1, and 50 kPa) were morphologically evaluated and their electrophysiological responsiveness was probed using calcium imaging. Immunodetection of neural marker TUJ1 and p-FAK was used for biochemical characterization. Groups with defined stiffness that are matching and nonmatching to neural tissue extracellular matrix were used to distinguish biomimetic results from other effects. Results show that while cells display morphologies that do not resemble neurons on soft substrates, they are in fact electrophysiologically more responsive and abundant in neuronal marker TUJ1. Our findings suggest that while neuronal differentiation occurs more efficiently in microenvironments mechanically mimicking neural tissue, the SH-SY5Y model demonstrates morphologies that conflict with neuronal behavior under these conditions. These results are expected to contribute considerable input to researchers that use SH-SY5Y as a neuron model.

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Synthesis and characterization of stimuli-responsive hydrogels: evaluation of external stimuli influence on L929 fibroblast viability

Karasu¹,

Erkoc-Biradli²,

Öztürk-Öncel³

et al. 2022

Biomed. Phys. Eng. Express

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In this study, poly(2-hydroxyethyl methacrylate) [p(HEMA)] based hydrogels responsive to the pH, temperature and magnetic field were synthesized. The surface properties of p(HEMA) were improved by designing the stimuli-responsive hydrogels made of MAGA, NIPAAm and methacrylate-decorated magnetite nanoparticles as a function of pH-, thermo- and magnetic responsive cell culture surfaces. These materials were then modified an abundant extracellular matrix component, type I collagen, which has been considered as a biorecognition element to increase the applicability of hydrogels to cell viability. Based on results from scanning electron microscopy (SEM) and thermal gravimetric analysis (TGA), stimuli-responsive hydrogel demonstrated improved non-porous structures and thermal stability with a high degree of cross-linking. Mechanical analyses of the hydrogels also showed that stimuli-responsive hydrogels are more elastomeric due to the polymeric chains and heterogeneous amorphous segments compared to plain hydrogels. Furthermore, surface modification of hydrogels with collagen provided better biocompatibility, which was confirmed with L929 fibroblast cell adhesion. Produced stimuli-responsive hydrogels modulated cellular viability by changing pH and magnetic field.

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