Publications

• Saichon Sumantakul, Vincent T. Remcho 2023. Selective laser ablation for in situ fabrication of enclosed channel porous-media microfluidic analytical devices https://pubs.rsc.org/en/content/articlepdf/2023/lc/d3lc00208j
• Gayan C. Bandara, Linus J. Unitan, Matthew H. Kremer, Owen T. Shellhammer, Shay Bracha, and Vincent T. Remcho 2021. Wicking microfluidic approach to separate blood plasma from whole blood to facilitate downstream assays https://link.springer.com/content/pdf/10.1007/s00216-021-03420-6.pdf
• Rachel M. Roller, Saichon Sumantakul, Michelle Tran, Andrea Van Wyk, Jessica Zinna, Destiny A. Donelson, Sarah G. Finnegan, Gregory Foley, Olivia R. Frechette, Jessica Gaetgens, Jiani Jiang, Katheryn C. Rinaolo, Renée S. Cole, Marya Lieberman, Vincent T. Remcho, and Kimberley A. Frederick 2021. Inquiry-Based Laboratories Using Paper Microfluidic Devices https://pubs.acs.org/doi/epdf/10.1021/acs.jchemed.1c00214
• Gayan C. Bandara, Vincent T. Remcho 2019. Oxygen radical‐driven surface modification of polycaprolactone‐filled glass microfiber media: Probing the surface chemistry of wicking microfluidic devices https://analyticalsciencejournals.onlinelibrary.wiley.com/doi/epdf/10.1002/sia.6658
• Sumate Pengpumkiat, Yuanyuan Wu, Saichon Sumantakul, Vincent T. Remcho 2019. A Membrane-based Disposable Well-Plate for Cyanide Detection Incorporating a Fluorescent Chitosan-CdTe Quantum Dot https://www.jstage.jst.go.jp/article/analsci/36/2/36_19P267/_pdf
• Siraprapa Boobphahoma, Nipapan Ruechab, Nadnudda Rodthongkumb, Orawon Chailapakulc, Vincent T. Remcho 2019. A copper oxide-ionic liquid/reduced graphene oxide composite sensor enabled by digital dispensing: Non-enzymatic paper-based microfluidic determination of creatinine in human blood serum https://pdf.sciencedirectassets.com/271374/1-s2.0-S0003267019X00355/1-s2.0-S0003267019308372/main.pdf?X-Amz-Security-Token=IQoJb3JpZ2luX2VjEM7%2F%2F%2F%2F%2F%2F%2F%2F%2F%2FwEaCXVzLWVhc3QtMSJHMEUCIEFDUGpPpXeF0HtqOdVhlINjLHnx10D2VRjND26JJfNHAiEAwbX%2Bgl75l9jgBMFs%2FNe3hXA9BvBVnlbtPmUXXJsTErcquwUIxv%2F%2F%2F%2F%2F%2F%2F%2F%2F%2FARAFGgwwNTkwMDM1NDY4NjUiDMDwqnaQgtEdc85BzCqPBVYVq%2FLB4lC0KDJIw6IaJDvNeE%2BcKtiLjS5xpzyhQk6tm2RHhfIVfKdUxrod0oY9w08Rvoq%2BhGcey%2FGMDfaPpEWWJNT1RZ08Ftn11nBSiyFSD6m6beh8WIwn0QU%2FavFwvZyGjAQAGvrTc01lOU9nrE0R5s6qBBZj9NwzjkKohWR0xjvyFHVRjmVmqgCMjN%2Bsr%2FvYdT%2BE5OyCFVIjymfaGUNfxsCO4VEV6zequFxIdKTXH36ee9ovqJW1vJGf3aUOJjVPmGejk%2FVAsWHNSqgTSmLi8KtSLZvLGGftDbJVQ50bAHcVix%2B1tPKbvEUCdcA97YCub8h9Bq1Fq63p%2F0iOj3iNF%2BtIPLz93QHKhHS8TmE1mhTBpUmYPg7O%2BwMYQnyGxmfy%2FnNuac%2FmdEtaLFf%2F6pY63OcaOZdhIUTQNKQ5btlo8HrvOUu%2Br9Va1MYCgGbfcEvdZ%2F%2BIeWiBroDljX8XqK5djiiGhwdQZcPrEIbCFAbBdMR77gZ5NG5h8wZcnjgi9exNdZ5ysIuPgZ5TL9QX%2FlGhEKouD2YTpelFvHw9P0JtEW7l4xc%2FIop0MN7R8%2B7AiUCb5toGutYe%2BEay%2B6OMzPAeLpr1KHrfMernIvrNINmccAX5FNaGxY2VYNBniS4JTEr8maHmrzGwcYsccq%2FZ0pPZm%2FR5lotCdLOY1MgxwaGbjgo2JkJSg44PmEgu4dwztLDT%2FUG76i9vguozIDmkqxbC3XFl7L%2BT%2BtBcr8aDuyWPJK%2FHzhzMwGaDNIhMtIEc16x4u4vkcsI5WjqjgjRFac6dTQol90%2BW5TyTa%2FfWOA0k8PsH5kr2EpkUxhUT0lvz51f8A46ptVCDnP5dJHcXR%2F%2BLuJS%2FS9cRAgN4AWk49vkw69%2BorwY6sQHgOVNMTstfJRuhxAORw2ht1hbxw%2FT3AbK8IbywGTM9ZJcagzcb2egCzP5uQzSoK1wRNQ6NlpixPIS6g9rEugBGRNSBBa9nxqxCXLr53MuwXMmrcI6t80TpUCtFeRa%2FH7IkLkICj63MbpyCHopFSeCRCC9hhNGkASe%2FvwwZOv0l1tl8%2B8K6dB1oBB5oOyhDXIRrlC0qUjPZsRWzUFG24t6GX5eCYvBeEcre9FXhc5Yt9WY%3D&X-Amz-Algorithm=AWS4-HMAC-SHA256&X-Amz-Date=20240307T222245Z&X-Amz-SignedHeaders=host&X-Amz-Expires=300&X-Amz-Credential=ASIAQ3PHCVTYZ673KMQZ%2F20240307%2Fus-east-1%2Fs3%2Faws4_request&X-Amz-Signature=a5b9236d11795a47f716b41aabd4eab7778250fa9a053c0f30d0ac134b679b5a&hash=0b69cce175411dba520acb51bf0c1128db0a6dc514f6b80be3da935b9e027b34&host=68042c943591013ac2b2430a89b270f6af2c76d8dfd086a07176afe7c76c2c61&pii=S0003267019308372&tid=spdf-373e216f-66b0-44f2-81ee-559baa65e1a0&sid=78c4d75498a8d4430c5b685781825dbaf1ecgxrqa&type=client&tsoh=d3d3LnNjaWVuY2VkaXJlY3QuY29t&ua=0f115a525f0405005006&rr=860dfc6aefa9ef98&cc=us
• Christopher A. Heist; Gayan C. Bandara; David J. Bemis; Joel C. Pommerenck; Vincent T. Remcho 2018. New paper-based microfluidic tools for the analysis of blood serum protein and creatinine built via aerosolized deposition of polycaprolactone https://pubs.rsc.org/en/content/articlepdf/2018/ay/c8ay00981c
• Gayan C. Bandara, Christopher A. Heist, Vincent T. Remcho 2018. Chromatographic Separation and Visual Detection on Wicking Microfluidic Devices: Quantitation of Cu2+ in Surface, Ground, and Drinking Water https://pubs.acs.org/doi/pdf/10.1021/acs.analchem.7b04087
• Gayan C. Bandara, Christopher A. Heist, Vincent T. Remcho 2018. Patterned polycaprolactone-filled glass microfiber microfluidic devices for total protein content analysis https://pdf.sciencedirectassets.com/271360/1-s2.0-S0039914017X00118/1-s2.0-S0039914017308500/main.pdf?X-Amz-Security-Token=IQoJb3JpZ2luX2VjEM7%2F%2F%2F%2F%2F%2F%2F%2F%2F%2FwEaCXVzLWVhc3QtMSJHMEUCIACtJtYFVS9%2BNPhwxTzxDwV0Iwer0QulmWZRY30UA6jXAiEAwPZM3nrQwf3BfLpVeYcjv0udLQJvSptVmoVXJ0Ky4%2FIqvAUIx%2F%2F%2F%2F%2F%2F%2F%2F%2F%2F%2FARAFGgwwNTkwMDM1NDY4NjUiDNSOp6wfiwsBOEV%2B3CqQBYmHgNJ1fEz8x7R3Ncozoj6bv1TF%2BwCi1LlxThZms%2Bo%2Bk7Qaac%2BNx%2FRXtbvqhnekupv%2BQvzpawQh4pBK%2BlaucobhX%2B%2FVOSyrGMWjmQ2bSEbpjqVecp429vwN1epYMiQDXqw3mla8JGXQ60FY%2FpdhswdahcVFcO7ExK%2Fq0KF8Dx8QVz0B2Figt7ajUmqmWybZK%2B07zhuoqvaISI2qdQR1hzGZN7EDnNtTQ5Cb1y3NX4ePZ6CO1oSNFU8HwxTc9k2cz33jxgazFTnhKgU71nDwmW4y2hDmYVMfyejUoik7wWGX3E6zZpJnVFcaf8CFciGKBQ4eVPAd3Um8P%2FusHeJuAoWob3%2F2djR07GaK%2B7X4p5FPLJu8MRuTZZlFvVNpgZ3JtMZo5syY0U5dze5uIW8xH2BTEK0wXb2KWcGBwTkMTB6suwMG0cEXLwC9CjdcqTgxaC65HaT8%2B5thkG8QQWGy5dlOdC43t3I7iGBvnrWt%2BZgB7sr2fZWlP9r%2Bs%2FpbB7rjmz5SNaV96ZQA7OksMGeh9xZlMn4ciK5CnROttlrtbH5ng6ev18xoWxBUvCcFsQ7gTRCCET3NSK6Qk7ekFECy6JKPHGFsOD9qLBaNR4ZgZ%2BRSzMIgz%2B4xyF%2F%2B%2F0bigQhYQRgk1%2BJTQQi8LKvVm2iHDGxyGyHXbV%2Faqo4mffb7XhqJTKXDI1Xbcy2MAVym%2FRNP%2FIiJICsOR5Q9m1EOeZ2fG1VdC8ZZpstnUaMRrcafiit2BjgP7uWEHBo4Myw3BtxEHwJlcMTJdQ5%2BLct%2B4amgS%2BIl56xHrXHmfleVoU01Ae67U1EEBbpUPnVi9zJbmWMoV2RbOHmZknEURgQpcmN%2B3RMc7TW%2FvqYvnWNCyVbCMsTLMLrhqK8GOrEB8AEPCGdpRbhFQq39rHw0kiPBLkJNywIya8cLOehtttMD3fQ9qXxlmlhx2tybVI9EfaB%2F%2FfDaNMTndM8HEdOc4qRHGW5OFaVhS2TZO6eHWEWdNN0v8wKGgyvXhTfIWP0hMeFL14hsUvCZur2nL7I9%2Bueeg4Z6%2BvC8Fy9NHkxKRuaOKJGMqDh%2BZ3tjq6P7TDlXgcywgpcufWpAg3W877GgjGh%2FqaQUXyBZqR2BMTPJu%2BIh&X-Amz-Algorithm=AWS4-HMAC-SHA256&X-Amz-Date=20240307T223339Z&X-Amz-SignedHeaders=host&X-Amz-Expires=300&X-Amz-Credential=ASIAQ3PHCVTY25PXFXV7%2F20240307%2Fus-east-1%2Fs3%2Faws4_request&X-Amz-Signature=e2aedfda3f8d8f981e62dac232f377fd98c2f6cf6d9198e157d8769624bc0741&hash=1b658de227bf9e59ea32d5fef4f1806d60cf781c0f126a56b3a0f5591c9389f5&host=68042c943591013ac2b2430a89b270f6af2c76d8dfd086a07176afe7c76c2c61&pii=S0039914017308500&tid=spdf-a0942984-0711-455d-94df-bdf645d5cb17&sid=78c4d75498a8d4430c5b685781825dbaf1ecgxrqa&type=client&tsoh=d3d3LnNjaWVuY2VkaXJlY3QuY29t&ua=0f115a525f0553005055&rr=860e0c623e9c5ec8&cc=us
• Gayan C. Bandara; Christopher A. Heist; Vincent T. Remcho 2018. Chromatographic Separation and Visual Detection on Wicking Microfluidic Devices: Quantitation of Cu2+ in Surface, Ground, and Drinking Water https://pubs.acs.org/doi/epdf/10.1021/acs.analchem.7b04087
• Sumate Pengpumkiat, Yuanyuan Wu, Anukul Boonloed, Gayan C. Bandara, Vincent T. Remcho 2017. A microfluidic detection system for quantitation of copper incorporating a wavelength-ratiometric fluorescent quantum dot pair https://pubs.rsc.org/en/content/articlepdf/2017/ay/c6ay02718k

WORK IN PROGRESS