about
Theoretical and experimental studies of distance dependent response of micro-ring resonator-based ultrasonic detectors for photoacoustic microscopy.Investigating femtosecond-laser-induced two-photon photoacoustic generation.A combined method to quantify the retinal metabolic rate of oxygen using photoacoustic ophthalmoscopy and optical coherence tomography.Laser-scanning Doppler photoacoustic microscopy based on temporal correlation.Image chorioretinal vasculature in albino rats using photoacoustic ophthalmoscopyIntegrated photoacoustic ophthalmoscopy and spectral-domain optical coherence tomography.Chemically Specific Imaging Through Stimulated Raman Photoexcitation and Ultrasound Detection: Minireview.Integrating photoacoustic ophthalmoscopy with scanning laser ophthalmoscopy, optical coherence tomography, and fluorescein angiography for a multimodal retinal imaging platform.Stimulated Raman scattering: old physics, new applications.Photoacoustic ophthalmoscopy for in vivo retinal imaging.Simultaneous imaging of a lacZ-marked tumor and microvasculature morphology in vivo by dual-wavelength photoacoustic microscopy.In vitro testing of a protease-sensitive contrast agent for optoacoustic imaging.Real-time full-field photoacoustic imaging using an ultrasonic camera.In vivo functional microangiography by visible-light optical coherence tomographyEffect of contact lens on optical coherence tomography imaging of rodent retinaFundus camera guided photoacoustic ophthalmoscopy.Absolute retinal blood flow measurement with a dual-beam Doppler optical coherence tomography.Directly measuring absolute flow speed by frequency-domain laser speckle imaging.Human retinal imaging using visible-light optical coherence tomography guided by scanning laser ophthalmoscopy.Measuring oxygen saturation in retinal and choroidal circulations in rats using visible light optical coherence tomography angiography.Measuring retinal blood flow in rats using Doppler optical coherence tomography without knowing eyeball axial length.Monte Carlo Investigation of Optical Coherence Tomography Retinal Oximetry.Accuracy of retinal oximetry: a Monte Carlo investigationIntroduction to the BIOMED 2014 feature issue.Visible light optical coherence tomography measures retinal oxygen metabolic response to systemic oxygenation.Automatic retinal vessel segmentation based on active contours method in Doppler spectral-domain optical coherence tomography.Optical fluence distribution study in tissue in dark-field confocal photoacoustic microscopy using a modified Monte Carlo convolution method.Effects of wavelength-dependent fluence attenuation on the noninvasive photoacoustic imaging of hemoglobin oxygen saturation in subcutaneous vasculature in vivoDisposable ultrasound-sensing chronic cranial window by soft nanoimprinting lithographyLongitudinal deep-brain imaging in mouse using visible-light optical coherence tomography through chronic microprism cranial windowSpeckle reduction in visible-light optical coherence tomography using scan modulationAccelerating multicolor spectroscopic single-molecule localization microscopy using deep learningSymmetrically dispersed spectroscopic single-molecule localization microscopy
P50
Q30401152-6A361264-A305-4C75-9110-0755E2929F54Q30405789-95BC9EA7-EEBE-4B80-B764-672C7AA7382CQ30428265-355BE5E2-18BD-4903-BA65-E386B2165345Q30438260-1EFD5109-1F9C-48FD-BFBC-48D94A1CECCCQ30440099-3D3C0BCD-E245-49D6-9DEF-E1BE243C08BFQ30442913-267178F0-02A0-490F-9B91-581EAC7D0C90Q30453167-CB8384B5-7CB7-4861-B4EE-CDE22AC874AFQ30454819-024897C9-9BD7-415C-88F6-2EAECE15DA0EQ30479374-9902F9EE-6158-4A6F-B7EA-93EBBC22F60AQ30481590-CA60E36E-C985-4C16-91E9-F1E14B0CD8B7Q30485160-53B484DF-E1A8-4540-BC17-7CA541E4B0EFQ33574760-2324490F-B816-4C8A-A7B1-67EFEB78CF50Q33574763-87331533-B91D-41AF-BBB8-5ECB3C354B1AQ34387631-0D2E4741-9ABB-40A4-9DEB-90B8E09BFB01Q34924994-26F3F712-BE3C-430D-B98B-DDFFB41CBD19Q35019078-C2106379-F8A5-4409-85A1-BC1C20B08235Q35039897-DF2ADC71-3046-41E3-886D-B2E28E6AA266Q35338173-B75E100E-5808-48DB-80A6-65FBF787574EQ35822428-45A9E381-B8CA-4AFA-AD8A-8314B5D470CAQ35970537-F36360CA-112A-4701-809F-71B0C9EC4B2BQ35983093-3837B85C-A480-46B3-BD86-2326F159ED6AQ36665546-BA3EFCD8-193A-4F24-B414-D53BB7D71E88Q36892845-301C8733-65D6-474A-AFA5-019161CFC597Q41889114-90D92CC1-5B73-4DFA-B613-E35E76214661Q41909255-3F0052C1-A638-4EB3-AE3C-E3D5983EDDC7Q42533781-FF7131A5-CAC5-45BA-BC02-FC9FF89AF87BQ51822269-101D0660-4592-4ABE-92A9-2AFA75336244Q53098393-EC8B527E-163C-406F-9EA0-73DBBC334318Q90183104-CD263F39-BE8B-47C5-BAE8-F479F99497D0Q90913222-E9B3C6CF-3D15-4C07-94F9-58FB7B12556BQ93089117-EBD0FAAD-A78B-4370-B9C9-E28C6D16E8A8Q96138392-18C3483D-3AA2-487C-A33F-4D2968781321Q96172383-9E8DA873-DE74-4529-9944-918EFF4FB1AA
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Hao F Zhang
@ast
Hao F Zhang
@en
Hao F Zhang
@es
Hao F Zhang
@nl
Hao F Zhang
@sl
type
label
Hao F Zhang
@ast
Hao F Zhang
@en
Hao F Zhang
@es
Hao F Zhang
@nl
Hao F Zhang
@sl
prefLabel
Hao F Zhang
@ast
Hao F Zhang
@en
Hao F Zhang
@es
Hao F Zhang
@nl
Hao F Zhang
@sl
P1053
C-2451-2015
P106
P31
P3829
P496
0000-0001-5089-1196