AI Article Synopsis
- A microfluidic protein aggregation device (microPAD) allows simultaneous testing of proteins in 64 incubation chambers with varying concentrations of two reagents.
- It was tested using bovine insulin to analyze how insulin and sodium chloride affect fibril formation, using a fluorescent marker for observation.
- The device offers insights into protein aggregation processes, potentially aiding in the study of misfolding diseases related to amyloid growth.
Article Abstract
A microfluidic protein aggregation device (microPAD) that allows the user to perform a series of protein incubations with various concentrations of two reagents is demonstrated. The microfluidic device consists of 64 incubation chambers to perform individual incubations of the protein at 64 specific conditions. Parallel processes of metering reagents, stepwise concentration gradient generation, and mixing are achieved simultaneously by pneumatic valves. Fibrillation of bovine insulin was selected to test the device. The effect of insulin and sodium chloride (NaCl) concentration on the formation of fibrillar structures was studied by observing the growth rate of partially folded protein, using the fluorescent marker Thioflavin-T. Moreover, dual gradients of different NaCl and hydrochloric acid (HCl) concentrations were formed, to investigate their interactive roles in the formation of insulin fibrils and spherulites. The chip-system provides a bird's eye view on protein aggregation, including an overview of the factors that affect the process and their interactions. This microfluidic platform is potentially useful for rapid analysis of the fibrillation of proteins associated with many misfolding-based diseases, such as quantitative and qualitative studies on amyloid growth.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7144930 | PMC |
| http://dx.doi.org/10.3390/molecules25061380 | DOI Listing |
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