about
Noninvasive high-speed photoacoustic tomography of cerebral hemodynamics in awake-moving ratsWhole-body multispectral photoacoustic imaging of adult zebrafishPhotoacoustic and fluorescence image-guided surgery using a multifunctional targeted nanoprobe.Molecular photoacoustic tomography of breast cancer using receptor targeted magnetic iron oxide nanoparticles as contrast agents.HER-2/neu targeted delivery of a nanoprobe enables dual photoacoustic and fluorescence tomography of ovarian cancer.Development of an anti-angiogenic therapeutic model combining scAAV2-delivered siRNAs and noninvasive photoacoustic imaging of tumor vasculature developmentPhotoacoustic computed microscopyHandheld miniature probe integrating diffuse optical tomography with photoacoustic imaging through a MEMS scanning mirror.Design and evaluation of a compound acoustic lens for photoacoustic computed tomography.Label-free photoacoustic imaging of the cardio-cerebrovascular development in the embryonic zebrafish.Microelectromechanical systems scanning-mirror-based handheld probe for fluorescence molecular tomography.Image-guided surgery using multimodality strategy and molecular probes.High resolution functional photoacoustic tomography of breast cancer.Discovery of structure-based small molecular inhibitor of αB-crystallin against basal-like/triple-negative breast cancer development in vitro and in vivo.Miniature probe integrating optical-resolution photoacoustic microscopy, optical coherence tomography, and ultrasound imaging: proof-of-concept.Liquid acoustic lens for photoacoustic tomography.Portable optical-resolution photoacoustic microscopy for volumetric imaging of multiscale organisms.Hybrid photoacoustic and electrophysiological recording of neurovascular communications in freely-moving rats.Evaluation of breast tumor margins in vivo with intraoperative photoacoustic imaging.Curved-array-based multispectral photoacoustic imaging of human finger joints.Photoacoustic endomicroscopy based on a MEMS scanning mirror.Portable optical resolution photoacoustic microscopy (pORPAM) for human oral imaging.Integrated photoacoustic and diffuse optical tomography system for imaging of human finger joints in vivo.Inverted multiscale optical resolution photoacoustic microscopy.Confocal photoacoustic microscopy using a single multifunctional lens.Opto-acousto-fluidic microscopy for three-dimensional label-free detection of droplets and cells in microchannels.Large-field-of-view optical resolution photoacoustic microscopy.In vivo study of rat cortical hemodynamics using a stereotaxic-apparatus-compatible photoacoustic microscope.A handheld microscope integrating photoacoustic microscopy and optical coherence tomography.Acoustic lens with variable focal length for photoacoustic microscopyUltracompact high-resolution photoacoustic microscopyAssessing hemorrhagic shock: Feasibility of using an ultracompact photoacoustic microscopeMiniaturized Optical Resolution Photoacoustic Microscope Based on a Microelectromechanical Systems Scanning MirrorWearable optical resolution photoacoustic microscopy
P50
Q27321506-27D73D49-512E-48FF-9EF8-90C0F1642EAEQ30372981-DB692525-CBF1-4316-8234-BDAAB71A56FDQ30381349-E2479B97-6ED7-44EE-8E6D-2A0124ED98D7Q30410360-2EBA74DA-7874-49FC-A2BA-8F7BF1580962Q30415480-E5A7A138-DA46-4701-B3F8-69CB5B1B3167Q30434991-BD5D18D1-6B8C-4A5C-BBD0-036AA7D638B2Q30438495-874A8D0D-8DF4-4F33-8D09-84FF4C7EED84Q30456261-85FE98B4-7DC7-4AF3-8A14-FA1512FB76CCQ33824655-022D3392-525B-4B1A-9575-683CBB5485AAQ33917727-32ECA5B1-AC51-4988-A314-EC46B35F9B64Q37049670-BBC833E8-3CF1-4002-91BC-2ED9889A21E6Q38520183-E59506B6-D93D-4DE3-BDC6-7FF6C62CD23CQ38578344-3B869C55-B14A-41EE-A6D5-E3383C35472BQ39006758-8D3FA341-CD6B-4449-A7A7-AF4A4DBAA73FQ40834088-288BDFB1-C97E-44CF-A24E-48A766CBEB84Q44632224-7B8AC933-1806-4E8F-8066-1FE5568ADA94Q47416712-78F60092-528B-4888-81A0-EAF71900D52AQ47783071-35B46AC0-497C-423D-9177-AAD2A9F2255DQ48561840-96C83771-745C-473E-8249-3D69F0DB7EE0Q48639939-D5916ABE-8ECB-45C1-B347-688D1E809262Q50001171-938FA919-9993-48E2-93EF-14216A378913Q50222615-A4FD012C-A57C-47C8-B835-85C00FD34D95Q50800144-3FF8D8F4-6882-4211-9C3B-AE54C2A15469Q51027190-BA1E0832-F4F7-4892-87B5-D515F5A13CDBQ51731684-D9261C81-69DF-47AD-95B5-412DE5089481Q52605802-5A0FE0DB-2277-440D-AE18-B664B984607FQ52687988-0CBD28E9-2BBF-4B60-B287-8E4811BA0528Q53781472-89594B89-BA12-4518-8F6A-B4B488CB308EQ55104779-797B952B-E73B-417A-ACB8-4B89E6973094Q59901315-FD79FC9B-4BB4-4EC7-AF9A-BC0DA2F1DB03Q88224554-90753D38-2ED8-461D-A9F2-450193FDFC69Q93025333-B9F7AE04-57E6-4AB5-AE03-A1F4DDD71A31Q93044638-94DB9712-547B-41F4-AA78-5E91C1AADA20Q93120809-FC67300C-9595-4DE7-904C-DAC05CC93F83
P50
description
researcher ORCID ID = 0000-0002-2598-6801
@en
wetenschapper
@nl
name
Lei Xi
@ast
Lei Xi
@en
Lei Xi
@nl
type
label
Lei Xi
@ast
Lei Xi
@en
Lei Xi
@nl
prefLabel
Lei Xi
@ast
Lei Xi
@en
Lei Xi
@nl
P108
P106
P108
P31
P496
0000-0002-2598-6801