about
Cell-phone-based platform for biomedical device development and education applicationsIntegrated Raman- and angular-scattering microscopy.Construction of an integrated Raman- and angular-scattering microscope.Development of inexpensive blood imaging systems: where are we now?Development of a time-gated system for Raman spectroscopy of biological samples.Rejection of fluorescence background in resonance and spontaneous Raman microspectroscopyIntegrated Raman and angular scattering microscopy reveals chemical and morphological differences between activated and nonactivated CD8+ T lymphocytes.Nanometer-scale sizing accuracy of particle suspensions on an unmodified cell phone using elastic light scatteringCharacterization of femtosecond laser-induced breakdown spectroscopy (fsLIBS) and applications for biological samples.The effects of laser repetition rate on femtosecond laser ablation of dry bone: a thermal and LIBS study.Smart and Fast Blood Counting of Trace Volumes of Body Fluids from Various Mammalian Species Using a Compact, Custom-Built Microscope Cytometer.Single exosome study reveals subpopulations distributed among cell lines with variability related to membrane contentPreliminary fsLIBS study on bone tumors.Performance of a cost-effective and automated blood counting system for resource-limited settings operated by trained and untrained users.Single-step preparation and image-based counting of minute volumes of human blood.Raman Plus X: Biomedical Applications of Multimodal Raman Spectroscopy.Structured illumination microscopy with interleaved reconstruction (SIMILR).3D plasmonic nanobowl platform for the study of exosomes in solution.Single particle analysis: Methods for detection of platelet extracellular vesicles in suspension (excluding flow cytometry).Multispectral Optical Tweezers for Biochemical Fingerprinting of CD9-Positive Exosome Subpopulations.A new red cell index and portable RBC analyzer for screening of iron deficiency and Thalassemia minor in a Chinese population.Direct comparison of fatty acid ratios in single cellular lipid droplets as determined by comparative Raman spectroscopy and gas chromatography.Image reconstruction for structured-illumination microscopy with low signal level.In-plane rotation classification for coherent X-ray imaging of single biomolecules.Precise monitoring of chemical changes through localization analysis of dynamic spectra (LADS).Super-resolved spatial light interference microscopy.Surface-sensitive polarized Raman spectroscopy of biological tissue.Benchtop and animal validation of a portable fluorescence microscopic imaging system for potential use in cholecystectomy.Raman scattering in pathology.A modular, open-source, slide-scanning microscope for diagnostic applications in resource-constrained settings.Optical volumetric projection for fast 3D imaging through circularly symmetric pupil engineering.Subnanometer-resolved chemical imaging via multivariate analysis of tip-enhanced Raman mapsScreening of nutritional and genetic anemias using elastic light scatteringMorphology and structure of ZIF-8 during crystallisation measured by dynamic angle-resolved second harmonic scatteringAutomated morphometry toolbox for analysis of microscopic model organisms using simple bright-field imagingValidation of an integrated Raman- and angular-scattering microscopy system on heterogeneous bead mixtures and single human immune cellsSimple adaptive mobile phone screen illumination for dual phone differential phase contrast (DPDPC) microscopyImproving the limit of detection in portable luminescent assay readers through smart optical designDual-phone illumination-imaging system for high resolution and large field of view multi-modal microscopySimultaneous recovery of both bright and dim structures from noisy fluorescence microscopy images using a modified TV constraint
P50
Q31002987-DC9FBE6D-9A3A-42D8-8831-C544727BB2DDQ33326575-25E19048-F0C4-47F0-AE68-2673390F1E51Q33437014-8026CF46-12D1-4EB9-9C40-45709A4F774EQ33444853-8C638275-8665-4E03-A10B-53263CCDFAF6Q33716265-B1851AF9-1086-4695-A90D-2DFBC21B814AQ33919574-C8CAFBB5-BC75-4714-B884-F5DBA2041740Q33993307-4BB79C06-3225-4E84-A177-6B46BECAA1FCQ34441062-9B890273-2AAC-4D42-B58F-1DC1C3690E00Q35255397-691172CE-C164-4BE8-9D41-E088C0EC19FBQ35742046-5F638ADF-4503-44CC-B7B2-9CF63B868ECEQ35818859-B121F610-08F0-4C5D-B96E-8EFBEFB1B9DBQ35864064-91EDAF06-305A-46E7-B003-950D719255DFQ35880332-F1EFCEC6-794D-4EFB-B5E6-E0E97628817FQ38369871-E4A513D4-40CC-49EA-941E-129BD5094D1EQ38396953-8FEC5629-957B-4DF1-8DB6-33F4EBD487F8Q38661321-6BB2F722-8AC7-446C-AD52-8B9B089619B7Q38681275-5028762E-86AB-4F2A-81E8-E355C7BE1A4BQ38879263-714410D5-A72B-4050-989C-B9ED8135E918Q39062138-C27DFB45-7392-4B38-A7E7-5FD7B506DE69Q41340508-8FE09AFE-916F-4CAD-9A88-C121200A1B48Q41621252-2447B33E-62CE-40AE-8CFC-2028B7618CE3Q45003814-18CC98B3-6F06-49C5-9DCF-56868846D668Q45028731-B1F52ACA-A599-4AD6-9DC1-9050D69C9A63Q45388765-E21E6011-3016-453D-B406-B3F25BCF76FDQ45944455-5CA1A626-6FEA-42A2-821E-17EE70C304F6Q46101151-AACF275F-62CB-4FE3-949F-DC5B687E8D3FQ46569063-6E9EA4F9-1349-45CB-A5AA-E1FB09B861CEQ50145836-664EBC79-73EE-4F30-8C13-72700DF64DB1Q53678427-A86D365A-36F1-4FD1-90BB-CB3A03C79016Q53837223-3BF6B0A3-19D1-4E9F-A83A-4A3865B8A256Q55287023-68CE641D-7ACA-4B54-9F30-73CDF396EECBQ57149143-77BC66FC-B969-49D2-A559-D3F70B98D8F1Q57798452-7081A55A-7215-41AD-B8E8-D4049E0739B9Q58708316-12D025E4-B0F6-4066-9512-9BDB1196C495Q64093701-B156CBB9-3016-4D63-B821-3B0C4950A435Q83598399-F7555BFF-8E15-463B-B224-EB12E9CE56A2Q90357775-B00355FB-022D-4293-8CB7-A8D810900D9DQ90647098-50AA8415-CB05-4004-9B33-DE9683D52828Q91275875-47CD4DD7-5042-4496-B32A-0E6AC6068663Q91540709-8C6377EF-255A-4D13-B9EF-1DC14A78EABD
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Zachary J Smith
@ast
Zachary J Smith
@en
Zachary J Smith
@es
Zachary J Smith
@sl
type
label
Zachary J Smith
@ast
Zachary J Smith
@en
Zachary J Smith
@es
Zachary J Smith
@sl
prefLabel
Zachary J Smith
@ast
Zachary J Smith
@en
Zachary J Smith
@es
Zachary J Smith
@sl
P106
P21
P31
P496
0000-0002-7946-7863
P569
2000-01-01T00:00:00Z