Abstract
Recently, microdevices made of resins have been strongly supporting cell analysis in a range of fields, from fundamental life science research to medical applications. Many microdevices are fabricated by molding resin to a mold made precisely from rigid materials. However, because dimensional errors in the mold are also accurately printed to the products, the accuracy of the product is limited to less than the accuracy of the rigid mold. Therefore, we hypothesized that if dimensional errors could be self-corrected by elastic molds, microdevices could be facilely fabricated with precision beyond that of molds. In this paper, we report a novel processing strategy in which an elastic mold made of polymethylsiloxane (PDMS) deforms to compensate for the dimensional error on the products. By heat-press molding a polycarbonate plate using a mold that has 384 PDMS convexes with a large dimensional error of height of ± 15.6 µm in standard deviation, a 384-round-well plate with a bottom thickness 13.3 ± 2.3 µm (n = 384) was easily fabricated. Finally, single-cell observation and polymerase chain reactions (PCRs) demonstrated the application of the products made by elastic PDMS molds. Therefore, this processing method is a promising strategy for facile, low-cost, and higher precision microfabrication.
Highlights
Resin processing technologies based on rigid molds are some of the most essential technologies to supply tools that support life sciences and healthcare
Resin products finer and more precise than conventional ones are contributing to the development of fundamental life science research and pharmaceutical and medical applications, such as cell analysis devices
These so-called microdevices, such as microwell arrays for single-cell manipulation [4,5], microfluidic channels for rapid and high-throughput polymerase chain reaction (PCR) [6,7], and drug testing [8,9], and point-of-care testing (POCT) devices for blood cell analysis [10], have been studied extensively
Summary
Resin processing technologies based on rigid molds are some of the most essential technologies to supply tools that support life sciences and healthcare. Resin products finer and more precise than conventional ones are contributing to the development of fundamental life science research and pharmaceutical and medical applications, such as cell analysis devices These so-called microdevices, such as microwell arrays for single-cell manipulation [4,5], microfluidic channels for rapid and high-throughput polymerase chain reaction (PCR) [6,7], and drug testing [8,9], and point-of-care testing (POCT) devices for blood cell analysis [10], have been studied extensively. Microfabricated chips have become essential resin products for controlling droplets and cells for advanced gene analysis technologies, such as digital PCR [13,14] and single-cell PCR [15,16]
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