about
Selective plane illumination microscopy techniques in developmental biology.Endothelial cell self-fusion during vascular pruningGenetic and physiologic dissection of the vertebrate cardiac conduction systemMechanical Coupling between Endoderm Invagination and Axis Extension in DrosophilaOptical sectioning deep inside live embryos by selective plane illumination microscopyZebrafish model for human long QT syndromeA dual role for ErbB2 signaling in cardiac trabeculation.The Popeye domain containing 2 (popdc2) gene in zebrafish is required for heart and skeletal muscle development.High-speed panoramic light-sheet microscopy reveals global endodermal cell dynamicsSingle continuous lumen formation in the zebrafish gut is mediated by smoothened-dependent tissue remodeling.Multiple imaging axis microscopy improves resolution for thick-sample applications.Optical levitation of absorbing particles with a nominally Gaussian laser beam.Optogenetic control of cardiac function.Even fluorescence excitation by multidirectional selective plane illumination microscopy (mSPIM).Multilayer mounting for long-term light sheet microscopy of zebrafish.Slicing embryos gently with laser light sheets.Multilayer mounting enables long-term imaging of zebrafish development in a light sheet microscope.Rapid 3D light-sheet microscopy with a tunable lens.Real-time multi-view deconvolutionThe smart and gentle microscope.Hyperspectral light sheet microscopy.eduSPIM: Light Sheet Microscopy in the MuseumMultiple roles for Med12 in vertebrate endoderm development.Light sheet microscopy for real-time developmental biology.Fast Fluorescence Microscopy with Light Sheets.In vivo imaging of cardiac development and function in zebrafish using light sheet microscopy.A guide to light-sheet fluorescence microscopy for multiscale imaging.Transgenic zebrafish illuminate the dynamics of thyroid morphogenesis and its relationship to cardiovascular development.Cse1l is a negative regulator of CFTR-dependent fluid secretion.The extracellular domain of Smoothened regulates ciliary localization and is required for high-level Hh signalingGenetic evidence for a noncanonical function of seryl-tRNA synthetase in vascular development.Regulation of neurocoel morphogenesis by Pard6 gamma b.Light sheet microscopy.Genome-wide RNA Tomography in the zebrafish embryo.Fibrillin-2b regulates endocardial morphogenesis in zebrafish.High-resolution reconstruction of the beating zebrafish heart.High-speed imaging of developing heart valves reveals interplay of morphogenesis and function.Cell-accurate optical mapping across the entire developing heart.Guide to light-sheet microscopy for adventurous biologists.Multi-view image fusion improves resolution in three-dimensional microscopy.
P50
Q24657143-8905E39E-0833-41BE-8220-D7405294EBC8Q27312235-A6781572-C847-419A-8844-08EBB41A5A5CQ27333494-EEFD8D7F-448D-421A-B3F5-92B1BFDAF01CQ27346459-BFAF4FBE-DBEC-4D4F-825B-33015ACFFF7AQ29619782-DD9F7B7A-56DE-4A40-8040-C35CD927F63EQ30480271-0C141D76-C930-4EF6-A595-30C3D494D7AAQ30498335-4FD3C7B5-36EC-4DD4-AA56-DF533EDDB0D7Q30540461-AD56205C-D043-4D65-BAB8-9C36EC3DB7A6Q30542048-8C66E6A1-9C84-49AF-9AE6-E43610B2C86FQ30572292-BF818714-D095-45E1-86B7-AE62249CC18EQ30987979-A9BEC570-13BF-4130-9784-8207FD16A564Q30987979-E05BCFE9-3888-4333-B1C7-F08EC16844B0Q33306439-B287AC49-9A13-4C52-A2F4-978908B63B79Q33744875-192BBC94-A31E-49E3-B1A9-9E06B341B79BQ34006277-804248EA-3EE5-4597-9D12-6AE05C4F893DQ34074805-E4D5D309-A5A2-45CE-B3EE-146B06C54538Q34186831-C041D4F9-0112-4BB1-A214-0DC33B9BB056Q34370398-62CFD749-AAC3-4768-826D-BA9C021736C2Q35011396-B21205D9-E031-4D91-9B68-D894B7FE252EQ35674897-BD472F73-0178-4CE7-BA6A-F989BCD2A747Q35739642-0FD715E2-A4BC-483F-8662-06ABDE854F98Q36059287-5F23D423-4042-4907-81E8-81DEC39D29E6Q36112759-593E87B8-9C56-4422-A44B-D763EAFF5989Q36730975-7EDFE882-8563-4E1F-9F8A-9DB6837D6C59Q37941362-37735FC0-36F5-4718-B79A-3D80C47419B2Q38225136-AB0238B9-AABE-47D2-8038-A9CA6AEAB5EAQ38678209-B8024807-1CF4-474E-8B65-D590756F8DF9Q38864885-D994E59A-AC64-4119-8D95-F497199C1915Q39545095-3E347CAE-C195-4FDB-8E89-03447166F476Q39646452-646ECCAC-6E6E-4D46-920E-C69AD54CB654Q41461407-238E8C50-BBEE-4535-9E07-CD77D6F54908Q41883687-B7507796-5766-44D7-8AFB-70C118BC39CBQ43198871-8F372BB7-E4C0-4538-B276-147CD995E02BQ44207825-7C990C08-E95C-4977-99F0-FD5B793CA507Q44623633-EC5BDBF4-1D4D-449C-81BF-871F398F1CF7Q44951653-52807FE5-BF98-40BC-BF87-CC8D39822C8DQ46058311-8377E06A-40C4-475F-BB54-3C0C6BC878FEQ46219006-BE94DAF3-899D-4DDD-B80E-EF6938B6BA57Q47134002-2A8A8A57-E851-4064-817B-CD3F9FE5F453Q48239702-F1F19133-E60E-4626-B817-00CD41A226FD
P50
description
deutscher Physiker
@de
hulumtues
@sq
onderzoeker
@nl
researcher
@en
ricercatore
@it
taighdeoir
@ga
հետազոտող
@hy
name
Jan Huisken
@aa
Jan Huisken
@af
Jan Huisken
@ak
Jan Huisken
@aln
Jan Huisken
@an
Jan Huisken
@ang
Jan Huisken
@arn
Jan Huisken
@ast
Jan Huisken
@ay
Jan Huisken
@az
type
label
Jan Huisken
@aa
Jan Huisken
@af
Jan Huisken
@ak
Jan Huisken
@aln
Jan Huisken
@an
Jan Huisken
@ang
Jan Huisken
@arn
Jan Huisken
@ast
Jan Huisken
@ay
Jan Huisken
@az
prefLabel
Jan Huisken
@aa
Jan Huisken
@af
Jan Huisken
@ak
Jan Huisken
@aln
Jan Huisken
@an
Jan Huisken
@ang
Jan Huisken
@arn
Jan Huisken
@ast
Jan Huisken
@ay
Jan Huisken
@az
P227
P1053
B-2472-2009
P106
P19
P21
P214
2146635452641981483
P227
1103600052
P31
P3829
P496
0000-0001-7250-3756
P569
1974-11-26T00:00:00Z
P734
P7859
viaf-2146635452641981483