about
Noninvasive real-time characterization of non-melanoma skin cancers with handheld optoacoustic probes.Optical methods for blood perfusion measurement--theoretical comparison among four different modalities.Hemodynamic monitoring of Chlorin e6-mediated photodynamic therapy using diffuse optical measurements.Multi-channel deep tissue flowmetry based on temporal diffuse speckle contrast analysis.Diffuse correlation spectroscopy with a fast Fourier transform-based software autocorrelator.Generating Localized Plasmonic Fields on an Integrated Photonic Platform using Tapered Couplers for Biosensing Applications.Photoacoustic microscopy for evaluating combretastatin A4 phosphate induced vascular disruption in orthotopic glioma.Optical resolution photoacoustic microscopy based on multimode fibers.Quantitative in vivo detection of adipose tissue browning using diffuse reflectance spectroscopy in near-infrared II windowHandheld confocal Raman spectroscopy (CRS) for objective assessment of skin barrier function and stratification of severity in atopic dermatitis (AD) patientsOptoacoustic mesoscopy analysis and quantitative estimation of specific imaging metrics in Fitzpatrick skin phototypes II to VInvestigation of morphological, vascular and biochemical changes in the skin of an atopic dermatitis (AD) patient in response to dupilumab using raster scanning optoacoustic mesoscopy (RSOM) and handheld confocal Raman spectroscopy (CRS)Acoustic resolution photoacoustic microscopy based on microelectromechanical systems scannerA review of clinical photoacoustic imaging: Current and future trendsIn vivo label-free functional photoacoustic monitoring of ischemic reperfusionHigh-speed simultaneous multiscale photoacoustic microscopyFast pulsatile blood flow measurement in deep tissue through a multimode detection fiber
P50
Q33806935-2E5709F2-827C-4BF9-AA04-7C8889952C21Q35772461-3E302241-930C-4438-9333-8EF677B48967Q38963837-8FA62577-E494-4708-ADF4-E5492AEAF7BFQ43473434-2C0F97ED-90DC-4886-92A7-90B917497B86Q45907711-4DC9E182-3C21-4FD0-B6C0-F96074720619Q47152871-B3CD9458-AB90-4D8B-B458-8BD690477C93Q50116866-50595BED-59E5-4B43-A18C-179A19B6BB03Q52654988-426EBF28-0ED8-4D54-8D64-C28089C026A4Q89441650-7408AF64-4DA8-4C20-A9E4-F216D74FEF95Q89734738-9E034B9A-AC4D-42DD-8E29-A43DDF848DCAQ90223043-13E1E172-6FC1-436B-ACC9-5D0B62069FC8Q90313983-A73BAD9E-0FC3-47DF-B25A-B87EF7509703Q91087432-54567BFE-4E18-44D7-9E17-7727156051FAQ92222376-01BCAB7D-7105-45DE-AADB-F47302FF1630Q92326949-BDA880CB-D8E4-411C-A201-6519D26BD4C3Q92719783-E8D75D4E-DC29-4B1A-BB17-FF193102C67FQ94675782-8E96C193-2F12-4B37-A81E-013E92099B62
P50
description
investigador
@es
researcher
@en
wetenschapper
@nl
name
Renzhe Bi
@en
Renzhe Bi
@nl
type
label
Renzhe Bi
@en
Renzhe Bi
@nl
prefLabel
Renzhe Bi
@en
Renzhe Bi
@nl
P31
P496
0000-0001-7173-064X