Inglis, David - Macquarie University - Department of Engineering

个人简介

Dr Inglis received a Batchelor of Science in Engineering Physics from The University of Alberta in 2001 and a PhD in Electrical Engineering from Princeton University in 2007. He was an Australian Postdoctoral Fellow in the Physics Department of Macquarie University from 2008 to 2011 and a research associate there until 2013. He is now a lecturer in the Engineering Department at Macquarie University where he is the program coordinator for Mechatronics Engineering and the Engineering Learning and Teaching Representative.

研究领域

Microfluidics for cell separation High throughput bioparticle sorting Blood cell, stem cell and plasma separation devices Microbial and fungal separations/enrichments Rare cells in complex mixtures Microfluidic Fundamentals Simulations of flow in complex devices Effects of deformable particles and devices Deterministic lateral displacement physics Nanofluidics Nanofluidics for protein concentration and separation Fluorescene in Biology Autofluorescene profiling of stem cells Novel fluorescent particles

近期论文

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Characterization of the Interaction between Heterodimeric αvβ6 Integrin and Urokinase Plasminogen Activator Receptor (uPAR) Using Functional Proteomics, S. B. Ahn, A. Mohamedali, S. Anand, H. R. Cheruku, D. Birch, G. Sowmya, D. Cantor, S. Ranganathan, D. W. Inglis, R. Frank, M. Agrez, E. C. Nice, and M. S. Baker, Journal of Proteome Research, 13 (2014), 5956-5964. full text Isoelectric Focusing in a Silica Nanofluidic Channel: Effects of Electromigration and Electroosmosis, WL. Hsu, D. W. Inglis, M. A. Startsev, E. M. Goldys, M. R. Davidson, D. J. E. Harvie, Analytical Chemistry, 86 (2014), 8711-8718. full text Concentration gradient focusing and separation in a silica nanofluidic channel with a non-uniform electroosmotic flow, WL. Hsu, D. J. E. Harvie, M. R. Davidson, H. Jeong, E. M. Goldys and D. W. Inglis, Lab on a Chip, 14(2014), 3539-3549. full text Stationary Chemical Gradients for Concentration Gradient-Based Separation and Focusing in Nanofluidic Channels, WL. Hsu, D. W. Inglis, H. Jeong, D. Dunstan, M. R. Davidson, E. M. Goldys, D. J. Harvie, Langmuir, # (2014), in press. full text Manufacturing and wetting low-cost microfluidic cell separation devices, R. S. Pawell, D. W. Inglis, T. J. Barber and R. A. Taylor, Biomicrofluidics, 7 (2013), 056501. full text Nanochannel pH Gradient Electrofocusing of Proteins, M. A. Startsev, D. W. Inglis, M. S. Baker and E. M. Goldys, Analytical Chemistry, 85/15 (2013), 7133-7138. full text A Scalable Approach for High Throughput Branch Flow Filtration, D. W. Inglis and N. Herman, Lab on a Chip, 13 (2013), 1724-1731. full text Visible 532 nm laser irradiation of human adipose tissue-derived stem cells: effect on proliferation rates, mitochondria membrane potential and autofluorescence, A. G. Anwer, M. E. Gosnell, S. M. Perinchery, D. W. Inglis and E. M. Goldys Lasers in Surgery and Medicine, 44 (2012), 769-778. full text Simultaneous Concentration and Separation of Proteins in a Nanochannel, D. W. Inglis, E. M. Goldys and N. P. Calander Angewendte Chemie Int. Ed., 50/33 (2011), 7546-7550. full text Scaling deterministic lateral displacement arrays for high throughput and dilution-free enrichment of leukocytes, D. W. Inglis, M. Lord and R. E. Nordon J. Micromech. Microeng, 21 (2011), 054024. full text A method for reducing pressure-induced deformation in silicone microfluidics, D. W. Inglis Biomicrofluidics, 4 (2010), 026504. full text Highly accurate deterministic lateral displacement device and its application to purification of fungal spores, D. W. Inglis, N. Herman and G. Vesey. Biomicrofluidics, 4 (2010), 024109. full text Lighting up 5-nm monocrystalline nanodiamond with luminescent nitrogen-vacancy defect centers, B. R. Smith, D. Inglis, et al. Small, 5 (2009), 1649-1653. Efficient microfluidic particle separation arrays, D. W. Inglis. Applied Physics Letters, 94 (2009), 013510. full text Crossing microfluidic streamlines to lyse, label and wash cells, K. J. Morton, K. Loutherback, D. W. Inglis, et al. Lab on a Chip, 8 (2008), 1448-1453. full text Hydrodynamic Metamaterials: Microfabricated arrays to steer, refract, and focus streams of biomaterials, K. J. Morton, K. Loutherback, D. W. Inglis, et al. PNAS, 105, May 27, (2008), 7434-7438. full text Microfluidic Device for Label-Free Measurement of Platelet Activation, D. W. Inglis, et al. Lab on a Chip, 8 (2008), 925-931. full text Determining Blood Cell Size by Microfluidic Hydrodynamics, D. W. Inglis, et al. Journal of Immunological Methods, 329 (2008), 151-156. full text Deterministic Hydrodynamics: Taking Blood Apart, J. A. Davis, D. W. Inglis, et al. PNAS, 103, October 3, (2006), 14779-14784. full text Critical Particle Size for Fractionation by Deterministic Lateral Displacement, David W. Inglis, J. A. Davis, R. H. Austin, J. C. Sturm. Lab on a Chip, 6 (2006), 655-658. full text Microfluidic High Gradient Magnetic Cell Separation, David W. Inglis, R. Riehn, J. C. Sturm, R. H. Austin. Journal of Applied Physics 99 (2006) 08K101. full text Continuous Microfluidic Immunomagnetic Cell Separation, David W. Inglis, R. Riehn, R. H. Austin, J. C. Sturm. Applied Physics Letters, 85, Number 21 (2004), 5093-5095. full text