about
Multiphoton microscopy for structure identification in human prostate and periprostatic tissue: implications in prostate cancer surgeryLive tissue intrinsic emission microscopy using multiphoton-excited native fluorescence and second harmonic generationMolecular Mechanism of a Green-Shifted, pH-Dependent Red Fluorescent Protein mKate VariantExchange of protein molecules through connections between higher plant plastidsBlinking and nonradiant dark fraction of water-soluble quantum dots in aqueous solution.Multiphoton imaging can be used for microscopic examination of intact human gastrointestinal mucosa ex vivo.A microRNA miR-34a-regulated bimodal switch targets Notch in colon cancer stem cells.Measurement of molecular diffusion in solution by multiphoton fluorescence photobleaching recoveryKinetic and mechanical analysis of live tube morphogenesis.Feasibility of using multiphoton excited tissue autofluorescence for in vivo human histopathology.Identification of cartilage injury using quantitative multiphoton microscopy.Diffusion of nerve growth factor in rat striatum as determined by multiphoton microscopy.Water-soluble quantum dots for multiphoton fluorescence imaging in vivo.Multiphoton microscopy in biological research.Multiphoton fluorescence excitation: new spectral windows for biological nonlinear microscopy.A multiphoton objective design with incorporated beam splitter for enhanced fluorescence collection.Layer 6 cortical neurons require Reelin-Dab1 signaling for cellular orientation, Golgi deployment, and directed neurite growth into the marginal zoneConformational changes of calmodulin upon Ca2+ binding studied with a microfluidic mixer.Multiphoton microscopy in the evaluation of human bladder biopsies.The green fluorescent protein as a marker to visualize plant mitochondria in vivo.Kinetics of promoter Pol II on Hsp70 reveal stable pausing and key insights into its regulation.Quantifying translational mobility in neurons: comparison between current optical techniques.Core-shell silica nanoparticles as fluorescent labels for nanomedicine.Regulation of the type III InsP(3) receptor by InsP(3) and calcium.Self-assembly of aligned tissue-engineered annulus fibrosus and intervertebral disc composite via collagen gel contraction.Regulation of calcium signals in the nucleus by a nucleoplasmic reticulum.Recruitment timing and dynamics of transcription factors at the Hsp70 loci in living cells.Spatial profiles of store-dependent calcium release in motoneurones of the nucleus hypoglossus from newborn mouse.Liver fatty acid-binding protein gene ablation inhibits branched-chain fatty acid metabolism in cultured primary hepatocytes.Neural activity triggers neuronal oxidative metabolism followed by astrocytic glycolysis.Calcium signaling in response to fluid flow by chondrocytes in 3D alginate culture.Translocation and utilization of fungal storage lipid in the arbuscular mycorrhizal symbiosis.BAC transgenic mice express enhanced green fluorescent protein in central and peripheral cholinergic neurons.Use of multiphoton imaging for studying cell migration in the mouse.Achieving uniform mixing in a microfluidic device: hydrodynamic focusing prior to mixing.Focal volume confinement by submicrometer-sized fluidic channels.Heterogeneous effects of dopamine on highly localized, voltage-induced Ca2+ accumulation in identified motoneurons.Toxicity and biomedical imaging of layered nanohybrids in the mouseDNA fragment sizing by single molecule detection in submicrometer-sized closed fluidic channelsMacromolecular impurities and disorder in protein crystals
P50
Q24609385-E664237A-676C-42EA-B38C-6001356B990BQ24680802-FC033836-859B-4CC5-AA46-66DEE186D7EFQ27672852-144E41BB-FAE0-4634-84D2-3E13808DFF6CQ28241867-5F390CF2-BE7D-4D6B-90B2-A14EB1B0385FQ30476241-A4E9992A-EC86-4CA6-BB6E-0070C6DB37D5Q30481333-84EFD87D-FD86-4491-900E-C4552920A236Q30539598-26FF1C0C-F204-4944-9B62-BB9D2DBB61B8Q30805046-0A14D6FC-C23D-467D-9944-BC4648B57682Q33371897-96B467C8-91D0-4233-8F5F-552AE02BD60AQ33801039-86AA3E80-BDBC-4BE8-AAE4-C303CE98C224Q33981340-4826E44C-9473-44C6-8B21-45DC4991ECA6Q34181998-ECC8B1B6-6663-49A1-9204-9410204376F2Q34201368-F137BDC8-D37B-436E-BABB-64BF2A3782B8Q34386316-B3FBB8B7-D54C-4598-B1CD-95C5F13462ACQ34401453-6D3A8D59-33AC-44AB-A688-D46A1CE881E6Q36042907-18565861-8356-4CFF-BB47-4906098C4C14Q36303889-0EA3FF86-2303-42B4-98D6-98FF703CD024Q36392915-BF38E20F-C55E-4A9F-B8C2-8E063E9252BCQ36807220-C288F8D7-E140-4419-876A-BFA3F77481CDQ36854532-3F2A7541-F0D3-4D79-ADF6-F7671EC36929Q37488718-DA0DE417-0240-4619-BFF6-CC08FB912062Q37819483-D577CEC9-3819-45FB-B8BA-DC961D17CBD1Q40029726-29FC780B-24CB-4E97-AA2C-8A6D8F242B49Q40726251-FBEC5C59-EF01-4128-9A2A-64CFD484904FQ41886124-E9127C9F-8CA2-4D3F-8A0C-35B320D65E72Q42017116-AB97455D-1B77-466C-A931-64288748F4EBQ42573475-069CC9A6-D114-44AE-A859-7714D8E5AD85Q44300140-40D32EE6-455C-4FBC-B441-28FFEE869069Q44904775-F4085318-AB12-4E10-BD1C-305DE71E44D4Q44962228-DAD5498D-CFE7-48DE-BA45-D3A55111C161Q46805448-E9C4C6E1-50DE-4ECE-B3DA-A07539CA0800Q48324241-C9DB0738-E2E0-463F-A738-268ACE0D0E35Q48434307-080ABB43-4D3F-492D-93C9-D970A1A84257Q48822392-A326CD90-BB40-4B7C-8B7A-7D6292D7A803Q51170888-2943F89E-294D-453D-B85C-2D11855EBC04Q51702123-5017F849-E79F-4BE3-A019-05450B49187DQ54113725-BEA29CCE-6191-4069-A9D0-5CA565540E1CQ57186817-EEA1D9BF-3531-4702-89AB-C4961F1BDEF8Q77844338-F1CD6656-66ED-4B4C-A2B6-4E72ACD88801Q78010849-ECA186AC-2320-4A3C-AD35-F7BBB6C5F295
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Warren R Zipfel
@nl
Warren R Zipfel
@sl
Warren R. Zipfel
@en
Warren R. Zipfel
@es
type
label
Warren R Zipfel
@nl
Warren R Zipfel
@sl
Warren R. Zipfel
@en
Warren R. Zipfel
@es
prefLabel
Warren R Zipfel
@nl
Warren R Zipfel
@sl
Warren R. Zipfel
@en
Warren R. Zipfel
@es
P1053
B-4059-2016
P106
P1153
6701713249
P21
P31
P3829
P496
0000-0003-2640-329X