about
The role of the cytoskeleton in sensing changes in gravity by nonspecialized cellsZebrafish Bone and General Physiology Are Differently Affected by Hormones or Changes in GravityThe effect of combined hypergravity and micro-grooved surface topography on the behaviour of fibroblasts.The effect of combined simulated microgravity and microgrooved surface topography on fibroblasts.Plant cell proliferation and growth are altered by microgravity conditions in spaceflight.An atomic force microscope operating at hypergravity for in situ measurement of cellular mechano-response.The impact of simulated and real microgravity on bone cells and mesenchymal stem cellsShort-term weightlessness produced by parabolic flight maneuvers altered gene expression patterns in human endothelial cells.Gravitational and magnetic field variations synergize to cause subtle variations in the global transcriptional state of Arabidopsis in vitro callus culturesPlanarians sense simulated microgravity and hypergravityTransient Intervals of Hyper-Gravity Enhance Endothelial Barrier Integrity: Impact of Mechanical and Gravitational Forces Measured ElectricallyGrowing tissues in real and simulated microgravity: new methods for tissue engineering.The threshold at which substrate nanogroove dimensions may influence fibroblast alignment and adhesion.Invited review article: Advanced light microscopy for biological space research.Microgravity and bone cell mechanosensitivity.Ground-based facilities for simulation of microgravity: organism-specific recommendations for their use, and recommended terminology.Spaceflight-related suboptimal conditions can accentuate the altered gravity response of Drosophila transcriptome.A Comparison of Torque Forces Used to Apply Intermaxillary Fixation Screws.Differential gene regulation under altered gravity conditions in follicular thyroid cancer cells: relationship between the extracellular matrix and the cytoskeleton.Release of nitric oxide, but not prostaglandin E2, by bone cells depends on fluid flow frequency.Effects of hypergravity on the angiogenic potential of endothelial cells.Bone cell responses to high-frequency vibration stress: does the nucleus oscillate within the cytoplasm?How microgravity affects the biology of living systems.Decreased mineralization and increased calcium release in isolated fetal mouse long bones under near weightlessness.Plastid position in Arabidopsis columella cells is similar in microgravity and on a random-positioning machine.Towards human exploration of space: the THESEUS review series on muscle and bone research priorities.Novel, Moon and Mars, partial gravity simulation paradigms and their effects on the balance between cell growth and cell proliferation during early plant development.Hypergravity prevents seed production in Arabidopsis by disrupting pollen tube growth.Simulated microgravity, Mars gravity, and 2g hypergravity affect cell cycle regulation, ribosome biogenesis, and epigenetics in Arabidopsis cell cultures.Continuous Exposure to Simulated Hypergravity-Induced Changes in Proliferation, Morphology, and Gene Expression of Human Tendon Cells.Effects of microgravity simulation on zebrafish transcriptomes and bone physiology-exposure starting at 5 days post fertilization.Transcriptomic Analysis of Planarians under Simulated Microgravity or 8 g Demonstrates That Alteration of Gravity Induces Genomic and Cellular Alterations That Could Facilitate Tumoral TransformationNitric oxide production by bone cells is fluid shear stress rate dependentDynamic shear stress in parallel-plate flow chambersThe effect of combined cyclic mechanical stretching and microgrooved surface topography on the behavior of fibroblastsSimulated microgravity activates MAPK pathways in fibroblasts cultured on microgrooved surface topographyNoise enhances the rapid nitric oxide production by bone cells in response to fluid shear stressGravity control of growth form in Brassica rapa and Arabidopsis thaliana (Brassicaceae): Consequences for secondary metabolismThe interaction between nanoscale surface features and mechanical loading and its effect on osteoblast-like cells behaviorProteomic signature of Arabidopsis cell cultures exposed to magnetically induced hyper- and microgravity environments
P50
Q26851541-61D47E4A-8020-45D3-881C-AEA01EBA6C65Q27307063-2A24ACD8-9DEB-4BCA-BEC3-71102D958588Q33239560-5DDF0A4F-2C11-42DD-AF26-4F8048869DBBQ33269773-B966852C-9BFE-4134-B3CE-1E22E939DD4BQ33348102-D3A509B1-EC0A-4B46-9FD6-62719ACF034BQ33409694-D3CC7F13-6488-4104-9028-4D50C640BDF2Q33993217-438B17F7-B19D-4A7E-AD10-05643263670EQ34056957-7C457A3C-3991-4C27-9888-8D828E8D5368Q34204664-CCADA8B3-457B-4C3F-B183-C9ED0A908FABQ34278102-19E6D0C3-F7AE-4964-A2D8-015367EDA172Q34504125-E34BDAD7-B3A6-4734-8E23-78DB8D1F964EQ34563701-EFC3B6A4-FAFD-48CD-BE08-F5EE880135B0Q34638587-8067A72C-489D-4283-9F2A-1714C778C053Q35384864-9E3D7BB1-77FB-4A63-AE38-3E8F2A48664BQ35682084-1204D8A0-1B2B-42B9-9995-6CA03E25767AQ36547447-4D0A6116-11CE-4C02-AA3C-150F460CF209Q38505206-CDAA6ACE-F27E-4C3C-9617-93DA1DB2807CQ38957639-35651F22-A9C4-4461-8FAC-7DAF8D5E3F8BQ39484894-57C4AE24-F50B-4887-B301-F6BED672B244Q40279073-3EF6B0F7-DAD3-43A8-B697-A7FAF6511C0FQ42790943-167033A3-A8AA-4A08-B274-6112AFDE957CQ42802509-0CD7A0A1-C654-44F5-80B0-02A3A99E5906Q43125290-3A9DC354-E6C0-437B-B174-E89809102F88Q46294605-3E1FD6EF-5B4C-48DC-B5B5-193824509AE9Q47229628-B230BBD7-6D4D-4043-BD0F-22DE95343B81Q51811279-4F67AD31-D8A2-4B8A-8FE3-259F9A0F009CQ52592687-CEB93DB4-5803-49A2-ACB8-1088D379BB57Q52594937-67058977-713B-47AD-BB2E-DE1D938CA3D8Q52717233-73E3DAF3-404E-49E6-B46C-63A4EBB925F1Q52719797-B870D54D-CA0F-493D-9100-2D8CD86C3A9BQ55404719-8CC39AE7-1C8D-479A-AF61-8ABA8069C4C8Q64273522-0B1A305E-E7C0-4A28-A9FB-1422C68AEAA3Q76383251-AF05DBB9-F277-4963-8AC5-83AEF48A6AD5Q80943639-9503B017-E21D-46DC-B45A-1C33B868E483Q81085957-73CEAF45-C0E9-491C-88A0-AA3E90E8CE87Q81563180-C48BE093-E663-4FF1-8886-28D04F57B382Q83941475-184CFBBD-9404-43DD-AA2B-CBF6473D3E5AQ84235143-E6028FAF-9D4A-4305-86D9-4634A5AF6263Q84582607-F8AE55F1-5F3D-477A-8986-C67FF44F34E5Q86427968-7C35644C-8085-4428-9414-54096AE34BA5
P50
description
researcher ORCID ID = 0000-0001-9051-6016
@en
wetenschapper
@nl
name
Jack van Loon
@ast
Jack van Loon
@en
Jack van Loon
@es
Jack van Loon
@nl
type
label
Jack van Loon
@ast
Jack van Loon
@en
Jack van Loon
@es
Jack van Loon
@nl
prefLabel
Jack van Loon
@ast
Jack van Loon
@en
Jack van Loon
@es
Jack van Loon
@nl
P106
P31
P496
0000-0001-9051-6016