Carlos Escobedo
Carlos Escobedo
Associate Professor of Chemical Engineering, Queen's University
Verified email at - Homepage
Cited by
Cited by
Nanoholes as nanochannels: flow-through plasmonic sensing
F Eftekhari, C Escobedo, J Ferreira, X Duan, EM Girotto, AG Brolo, ...
Analytical chemistry 81 (11), 4308-4311, 2009
On-chip nanohole array based sensing: a review
C Escobedo
Lab on a Chip 13 (13), 2445-2463, 2013
Microfluidics for sperm analysis and selection
R Nosrati, PJ Graham, B Zhang, J Riordon, A Lagunov, TG Hannam, ...
Nature Reviews Urology 14 (12), 707-730, 2017
Optofluidic concentration: plasmonic nanostructure as concentrator and sensor
C Escobedo, AG Brolo, R Gordon, D Sinton
Nano letters 12 (3), 1592-1596, 2012
Flow-through vs flow-over: analysis of transport and binding in nanohole array plasmonic biosensors
C Escobedo, AG Brolo, R Gordon, D Sinton
Analytical chemistry 82 (24), 10015-10020, 2010
Polycaprolactone-and polycaprolactone/ceramic-based 3D-bioplotted porous scaffolds for bone regeneration: A comparative study
KK Gómez-Lizárraga, C Flores-Morales, ML Del Prado-Audelo, ...
Materials Science and Engineering: C 79, 326-335, 2017
Direct and indirect electroosmotic flow velocity measurements in microchannels
D Sinton, C Escobedo-Canseco, L Ren, D Li
Journal of Colloid and Interface Science 254 (1), 184-189, 2002
On-chip electroporation and impedance spectroscopy of single-cells
SC Bürgel, C Escobedo, N Haandbæk, A Hierlemann
Sensors and Actuators B: Chemical 210, 82-90, 2015
Structure of a 1.5-MDa adhesin that binds its Antarctic bacterium to diatoms and ice
S Guo, CA Stevens, TDR Vance, LLC Olijve, LA Graham, RL Campbell, ...
Science advances 3 (8), e1701440, 2017
Mitotic cells contract actomyosin cortex and generate pressure to round against or escape epithelial confinement
B Sorce, C Escobedo, Y Toyoda, MP Stewart, CJ Cattin, R Newton, ...
Nature communications 6 (1), 8872, 2015
A new method of evaluating the average electro-osmotic velocity in microchannels
L Ren, C Escobedo-Canseco, D Li
Journal of Colloid and Interface Science 250 (1), 238-242, 2002
Quantification of ovarian cancer markers with integrated microfluidic concentration gradient and imaging nanohole surface plasmon resonance
C Escobedo, YW Chou, M Rahman, X Duan, R Gordon, D Sinton, ...
Analyst 138 (5), 1450-1458, 2013
Rapid identification and quantification of illicit drugs on nanodendritic surface-enhanced Raman scattering substrates
H Dies, J Raveendran, C Escobedo, A Docoslis
Sensors and Actuators B: Chemical 257, 382-388, 2018
Cost-effective flow-through nanohole array-based biosensing platform for the label-free detection of uropathogenic E. coli in real time
J Gomez-Cruz, S Nair, A Manjarrez-Hernandez, S Gavilanes-Parra, ...
Biosensors and Bioelectronics 106, 105-110, 2018
Crossed surface relief gratings as nanoplasmonic biosensors
S Nair, C Escobedo, RG Sabat
ACS sensors 2 (3), 379-385, 2017
Integrated nanohole array surface plasmon resonance sensing device using a dual-wavelength source
C Escobedo, S Vincent, AIK Choudhury, J Campbell, AG Brolo, D Sinton, ...
Journal of Micromechanics and Microengineering 21 (11), 115001, 2011
Surface-enhanced Raman scattering (SERS) optrodes for multiplexed on-chip sensing of nile blue A and oxazine 720
M Fan, P Wang, C Escobedo, D Sinton, AG Brolo
Lab on a Chip 12 (8), 1554-1560, 2012
Electroosmotic flow in a microcapillary with one solution displacing another solution
L Ren, C Escobedo, D Li
Journal of colloid and interface science 242 (1), 264-271, 2001
Magnetotaxis enables magnetotactic bacteria to navigate in flow
S Rismani Yazdi, R Nosrati, CA Stevens, D Vogel, PL Davies, ...
Small 14 (5), 1702982, 2018
In situ assembly of active surface-enhanced Raman scattering substrates via electric field-guided growth of dendritic nanoparticle structures
H Dies, J Raveendran, C Escobedo, A Docoslis
Nanoscale 9 (23), 7847-7857, 2017
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