The investigation is focused on the development of a compartmentalized microfluidic device for coculturing the cells of crucial retinal cellular layers and assessing cell‐to‐cell interactions. A perfusion‐based microfluidic co‐culture device… Click to show full abstract
The investigation is focused on the development of a compartmentalized microfluidic device for coculturing the cells of crucial retinal cellular layers and assessing cell‐to‐cell interactions. A perfusion‐based microfluidic co‐culture device was employed and computationally validated for determining the pressure drop and fluid flow rate within the device microchannels. Fabrication was performed using PDMS polymer and coating of fibronectin and collagen facilitated adherence of the cells over the glass surface. Microfluidic device successfully supported cell proliferation, under continuous perfusion of 1 μl min‐1 flow rate. The barrier integrity of this coculture was confirmed by evaluating the permeability of fluorescently labeled molecules. The coculture expressed characteristic phenotypic protein markers like recoverin, PAX6, for retinal precursor cells, and RPE65 for retinal epithelial cells. The coculture also exhibited basal expression of TNF‐α under normal conditions. Differentiated photoreceptor cells positively expressed rhod inherently possess sensitivity toward violet/blue light, which was validated in R28 cells by exposure to light having a wavelength of 405 nm, which significantly decreased cell viability via increased TNF‐α production and reduced rhodopsin expression. This proof‐of‐concept investigation proved the functionality of the retinal coculture, which may be used as an appropriate perfusion‐based, preclinical tool for the evaluation of novel retinal drugs and delivery systems.
               
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