We describe a novel technique, low surface energy Gas Expansion Molding (GEM), to fabricate microbubble arrays in polydimethylsiloxane (PDMS) which are incorporated into parallel plate flow chambers and tested in ...We describe a novel technique, low surface energy Gas Expansion Molding (GEM), to fabricate microbubble arrays in polydimethylsiloxane (PDMS) which are incorporated into parallel plate flow chambers and tested in cell sorting and microcell cuTture applications. This architecture confers several operational advantages that distinguish this technology approach from currently used methods. Herein we describe the GEM process and the parameters that are used to control microbubble formation and a Vacuum-Assisted Coating (VAC) process developed to selectively and spatially alter the PDMS surface chemistry in the wells and on the microchannel surface. We describe results from microflow image visualization studies conducted to investigate fluid streams above and within microbubble wells and conclude with a discussion of cell culture studies in PDMS.展开更多
基金supported by grants fromthe NIH/NIAID 5K25AI060884 to Lisa A.
文摘We describe a novel technique, low surface energy Gas Expansion Molding (GEM), to fabricate microbubble arrays in polydimethylsiloxane (PDMS) which are incorporated into parallel plate flow chambers and tested in cell sorting and microcell cuTture applications. This architecture confers several operational advantages that distinguish this technology approach from currently used methods. Herein we describe the GEM process and the parameters that are used to control microbubble formation and a Vacuum-Assisted Coating (VAC) process developed to selectively and spatially alter the PDMS surface chemistry in the wells and on the microchannel surface. We describe results from microflow image visualization studies conducted to investigate fluid streams above and within microbubble wells and conclude with a discussion of cell culture studies in PDMS.
