about
Viscoelastic properties of differentiating blood cells are fate- and function-dependentOptical deformability as an inherent cell marker for testing malignant transformation and metastatic competenceThe F-actin modifier villin regulates insulin granule dynamics and exocytosis downstream of islet cell autoantigen 512.ODTbrain: a Python library for full-view, dense diffraction tomography.Muller cells are living optical fibers in the vertebrate retinaMyosin II Activity Softens Cells in Suspension.The regulatory role of cell mechanics for migration of differentiating myeloid cells.Separation of blood cells with differing deformability using deterministic lateral displacement(†).Dynamic operation of optical fibres beyond the single-mode regime facilitates the orientation of biological cells.Deformability-based flow cytometry.Actin stress fiber organization promotes cell stiffening and proliferation of pre-invasive breast cancer cells.Bone marrow niche-mimetics modulate HSPC function via integrin signaling.Mechanical deformation induces depolarization of neutrophils.Excitation beyond the monochromatic laser limit: simultaneous 3-D confocal and multiphoton microscopy with a tapered fiber as white-light laser source.Quantifying the contribution of actin networks to the elastic strength of fibroblasts.Reconfigurable microfluidic integration of a dual-beam laser trap with biomedical applications.High-throughput rheological measurements with an optical stretcher.The optical cell rotator.Fluorescence ratio thermometry in a microfluidic dual-beam laser trap.Interaction of Gaussian beam with near-spherical particle: an analytic-numerical approach for assessing scattering and stresses.Mechanical Strain Promotes Oligodendrocyte Differentiation by Global Changes of Gene ExpressionMonitoring of laser micromanipulated optically trapped cells by digital holographic microscopy.Mechanical difference between white and gray matter in the rat cerebellum measured by scanning force microscopy.Exact analytical expansion of an off-axis Gaussian laser beam using the translation theorems for the vector spherical harmonics.Quantifying cellular differentiation by physical phenotype using digital holographic microscopy.Mesenchymal stem cell mechanics from the attached to the suspended state.Changes in Ect2 localization couple actomyosin-dependent cell shape changes to mitotic progressionGrouped retinae and tapetal cups in some Teleostian fish: occurrence, structure, and function.SAMHD1 prevents autoimmunity by maintaining genome stability.Validation and perspectives of a femtosecond laser fabricated monolithic optical stretcherComparison of stresses on homogeneous spheroids in the optical stretcher computed with geometrical optics and generalized Lorenz-Mie theory.Nuclear architecture of rod photoreceptor cells adapts to vision in mammalian evolution.Impact of heating on passive and active biomechanics of suspended cells.Viscoelastic properties of individual glial cells and neurons in the CNS.A monolithic glass chip for active single-cell sorting based on mechanical phenotyping.Deformation of phospholipid vesicles in an optical stretcher.Brain tissue stiffness is a sensitive marker for acidosisChromatin decondensation and nuclear softening accompany Nanog downregulation in embryonic stem cells.A pH-driven transition of the cytoplasm from a fluid- to a solid-like state promotes entry into dormancy.Niche WNT5A regulates the actin cytoskeleton during regeneration of hematopoietic stem cells
P50
Q21134049-B849B3CF-2C47-440A-BCD6-1165E0FB1CC3Q24538594-AF9AC368-7A2F-4560-8161-3B274A4AAB91Q27308703-A40315D8-9D8C-4A33-82A8-530AA383DE5EQ27319819-6A78115A-D198-4781-A8EA-665C0757361FQ28301034-913FA597-763D-4DE9-AF13-C95E76360AF2Q30385390-1E49E7EB-1F20-4B3F-886B-E263EDADBC64Q30490345-7840DF73-1764-41DE-B50E-8DBA36BF54B8Q30596520-9C2E63D8-D5A4-47C9-87CD-D968F3C9336EQ30607436-30FDC742-3D89-4CFD-8383-83F5B448CA02Q30762735-72A2E56D-702A-49B4-886C-F4E8349B7164Q30852504-137CFE53-2A92-448E-8786-DE141EDE9B4FQ30854127-69204ea5-4a90-b23f-f588-70c76f23250fQ30855726-9B63A7C9-9490-4E5C-98CF-69E5234CA639Q33227380-D70A83A0-E748-46B7-9FED-83A2681751F4Q33244387-717C71BC-264C-429F-836D-FDE0A32FD92EQ33284775-AB2BCBF6-C575-4E92-BBE6-2014DE6C2422Q33290041-05A238CF-52B7-4CF7-916F-DBD78D61C8EBQ33375669-B849F0AC-44E5-40DB-BB66-DE81FA379253Q33473564-CCCCB648-F038-4E85-867C-2C67B40A89FEQ33489494-5A0016F1-6D5C-4207-9BDD-33B069A3EBF1Q33581205-96BB65ED-0229-42ED-ADA7-2DB2C86E7B28Q33599082-CC9FACAA-5AB7-4DB0-8078-02319D9A0CEAQ33639576-7F081F78-FA34-4879-BB69-EBACA43E63D0Q33833553-EBE36C91-9F6D-440D-AC91-BB6FCCB56D9AQ34133768-BD5F370A-C3E5-46EE-A20D-85A119D60332Q34201411-A6DAA55C-984A-4681-BF36-CEA94D95F4F1Q34294435-4F38C769-6FCC-43A3-9F72-1E405FF11BB7Q34380063-92EF04AB-270E-4EE7-86E2-93A235BE02D1Q34399058-CA694986-8348-4B79-8EE5-24E8281B2320Q34452420-1BFFD427-0B04-452C-9EC8-440C911832CEQ34498824-73EC8691-A5BA-428A-AABE-E552BF169297Q34976799-E8A6D229-E3C9-4C24-A287-F972D9DA0B0FQ35153301-7D427D97-456F-4D01-8557-6A8BFFDEA87FQ35215027-6D2BF90D-9DCA-48F0-89F1-50ECC6CBD4B3Q35533551-A6DAC7B4-AFA5-4F89-8A69-B92EF3BED5CEQ35681075-7AA04CBA-1251-4F55-BFC4-F691D8482FD2Q36067881-0438594E-B16F-4062-9A26-DA684842547FQ36439485-75347E3A-4867-4F5E-B8F4-D0794996AC50Q36851059-550C0E8A-4BB3-418B-A562-A7CFC6AB78D4Q37549702-5AC6444F-142D-4709-B2D1-7BA6C5F1C64D
P50
description
deutscher Biophysiker
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hulumtues
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wetenschapper
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հետազոտող
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name
Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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prefLabel
Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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Jochen Guck
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P1053
B-4412-2014
P106
P108
P1153
6602663898
P21
P2456
P31
P3829
P496
0000-0002-1453-6119
P569
1973-01-01T00:00:00Z