In the area of drug discovery, high-speed synthesis has increased the number of drug candidates produced. These potential drugs need to be evaluated for their adsorption, distribution, metabolism, elimination, and toxicology (ADMET) properties as early in the drug development stage as possible. Previously, a potential drug's ADMET properties have been found out by using monolayer cell cultures and live animals. These methods can be costly, time-intensive, and impractical for screening the large amount of potential drugs created by combinatorial chemistry. A quick, small, inexpensive, and highly parallel device would be desirable to determine a drug candidate's properties (i.e., metabolism of the drug). Here we fabricate a microfluidic device entrapping human microsomes within poly(ethylene) glycol hydrogels thereby generating an in situ microreactor to assess a drug candidate's metabolic properties that can be coupled to analysis equipment. We show that microsomes can be entrapped without the loss of enzymatic activity during photopolymerization. Additionally, a microreactor utilizing hepatocytes was also created for comparison with the microsome microreactor.
In this study, a novel method for the one-step fabrication of stacked hydrogel microstructures using a microfluidic mold is presented. The fabrication of these structures takes advantage of the laminar flow regime in microfluidic devices, limiting the mixing of polymer precursor solutions. To create multilayered hydrogel structures, microfluidic devices were rotated 90 degrees from the traditional xy axes and sealed with a cover slip. Two discreet fluidic regions form in the channels, resulting in the multilayered hydrogel upon UV polymerization. Multilayered patterned poly(ethylene glycol) hydrogel arrays (60 mum tall, 250 mum wide) containing fluorescent dyes, fluorescein isothiocyanate, and tetramethylrhodamine isothiocyanate were created for imaging purposes. Additionally, this method was used to generate hydrogel layers containing murine fibroblasts and macrophages. The cell adhesion promoter, RGD, was added to hydrogel precursor solution to enhance fibroblast cell spreading within the hydrogel matrix in one layer, but not the other. We were able to successfully generate patterns of hydrogels containing multiple phenotypes by using this technique.
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