John T. McDevitt, Ph.D.
Affiliations: | 1982-1987 | Physical Chemistry and Materials Science | Stanford University, Palo Alto, CA |
1987-1989 | Chemistry and Materials Science | University of North Carolina, Chapel Hill, Chapel Hill, NC | |
1989-2009 | Chemistry and Biochemistry | University of Texas at Austin, Austin, Texas, U.S.A. | |
2009-2015 | Bioengineering | Rice University, Houston, TX | |
2015- | Biomaterials | NYU Polytechnic Institute |
Area:
Analytical chemistry, materials science, biomedical engineering, biomaterialsWebsite:
http://engineering.nyu.edu/files/resume/5908/JTM_Full_CV_03_09_15.pdfGoogle:
"John McDevitt"Cross-listing: Chemistry Tree - Materials Tree
Parents
Sign in to add mentorJames Paddock Collman | grad student | 1982-1987 | Stanford (Chemistry Tree) |
Royce W. Murray | post-doc | 1987-1989 | UNC Chapel Hill (Chemistry Tree) |
Children
Sign in to add traineeSara J. Eames | grad student | 2000 | UT Austin |
Andrea D. Wells | grad student | 2001 | UT Austin |
Steen B. Schougaard | grad student | 2002 | UT Austin |
William R Murray | grad student | 1996-2003 | UT Austin (Chemistry Tree) |
Mehnaaz F. Ali | grad student | 2006 | UT Austin |
Alexandru C. Pavel | grad student | 2006 | UT Austin |
Michael J. Griffin | grad student | 2001-2007 | UT Austin |
Jie Chou | grad student | 2012 | Rice University |
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Publications
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Christodoulides N, McRae MP, Simmons GW, et al. (2019) Sensors that Learn: The Evolution from Taste Fingerprints to Patterns of Early Disease Detection. Micromachines. 10 |
McRae MP, Simmons G, Wong J, et al. (2016) Programmable Bio-nanochip Platform: A Point-of-Care Biosensor System with the Capacity To Learn. Accounts of Chemical Research |
McRae MP, Simmons GW, Wong J, et al. (2015) Programmable bio-nano-chip system: a flexible point-of-care platform for bioscience and clinical measurements. Lab On a Chip. 15: 4020-31 |
Kulla E, Chou J, Simmons G, et al. (2015) Enhancement of performance in porous bead-based microchip sensors: Effects of chip geometry on bio-agent capture. Rsc Advances. 5: 48194-48206 |
Chou J, Du N, Ou T, et al. (2013) Hot embossed polyethylene through-hole chips for bead-based microfluidicdevices Biosensors and Bioelectronics. 42: 653-660 |
Chou J, Wong J, Christodoulides N, et al. (2012) Porous bead-based diagnostic platforms: Bridging the gaps in healthcare Sensors (Switzerland). 12: 15467-15499 |
Chou J, Li LE, Kulla E, et al. (2012) Effects of sample delivery on analyte capture in porous bead sensors Lab On a Chip - Miniaturisation For Chemistry and Biology. 12: 5249-5256 |
Chou J, Lennart A, Wong J, et al. (2012) Modeling analyte transport and capture in porous bead sensors Analytical Chemistry. 84: 2569-2575 |
Du N, Chou J, Kulla E, et al. (2011) A disposable bio-nano-chip using agarose beads for high performance immunoassays Biosensors and Bioelectronics. 28: 251-256 |
Jokerst JV, Chou J, Camp JP, et al. (2011) Location of biomarkers and reagents within agarose beads of a programmable bio-nano-chip Small. 7: 613-624 |