about
Impact of dimensionality and network disruption on microrheology of cancer cells in 3D environmentsMicromechanical architecture of the endothelial cell cortexOptical deformability as an inherent cell marker for testing malignant transformation and metastatic competenceBioengineering Models for Breast Cancer ResearchA Review of Cell Adhesion Studies for Biomedical and Biological Applications.The scanning ion conductance microscope for cellular physiologyA mechanical biomarker of cell state in medicineNanobiomechanics of living cells: a reviewThe Application of Micropipette Aspiration in Molecular Mechanics of Single CellsCellular Biomechanics in Drug Screening and Evaluation: MechanopharmacologyRheopathologic Consequence of Plasmodium vivax Rosette FormationArp2/3 inhibition induces amoeboid-like protrusions in MCF10A epithelial cells by reduced cytoskeletal-membrane coupling and focal adhesion assemblyHuman oocyte developmental potential is predicted by mechanical properties within hours after fertilizationA microfluidic pipette array for mechanophenotyping of cancer cells and mechanical gating of mechanosensitive channelsA serial micropipette microfluidic device with applications to cancer cell repeated deformation studies.Dynamic monitoring of cell mechanical properties using profile microindentation.Coupling intercellular molecular signalling with multicellular deformation for simulating three-dimensional tissue morphogenesisChanges in cellular mechanical properties during onset or progression of colorectal cancerRole of cortical tension in bleb growthBiomechanics of the sarcolemma and costameres in single skeletal muscle fibers from normal and dystrophin-null miceCell mechanics control rapid transitions between blebs and lamellipodia during migrationCell volume control in three dimensions: Water movement without solute movementMechanical dynamics in live cells and fluorescence-based force/tension sensorsMeasuring nanoscale viscoelastic parameters of cells directly from AFM force-displacement curves.Actomyosin Cortical Mechanical Properties in Nonadherent Cells Determined by Atomic Force Microscopy.Probing Cell Deformability via Acoustically Actuated Bubbles.Nanotechnology in Auditory Research: Membrane Electromechanics in Hearing.Biocompatible Optically Transparent MEMS for Micromechanical Stimulation and Multimodal Imaging of Living Cells.Myosin II Activity Softens Cells in Suspension.Entry effects of droplet in a micro confinement: Implications for deformation-based circulating tumor cell microfiltrationEffects of Stretching Speed on Mechanical Rupture of Phospholipid/Cholesterol Bilayers: Molecular Dynamics SimulationBiomechanical properties of red blood cells in health and disease towards microfluidics.Non-contact acoustic radiation force impulse microscopy via photoacoustic detection for probing breast cancer cell mechanics.Event-tracking model of adhesion identifies load-bearing bonds in rolling leukocytes.Controlled permeation of cell membrane by single bubble acoustic cavitation.Impact of a compound droplet on a flat surface: A model for single cell epitaxy.Electrical power free, low dead volume, pressure-driven pumping for microfluidic applicationsAnalysis of nematode mechanics by piezoresistive displacement clamp.Interactions between myosin and actin crosslinkers control cytokinesis contractility dynamics and mechanics.Noncontact measurement of the local mechanical properties of living cells using pressure applied via a pipette.
P2860
Q21145291-C069C8F3-1CF4-40A3-8736-4C9DBA2368EEQ24538048-EBF02378-E5FA-45CB-BCC9-285031AA57D8Q24538594-C6080921-B56F-453B-BCDC-7A7AF49E4C71Q26770495-8735F1B8-DAFD-499E-8E57-6DC16A2615D5Q26801184-0F31E509-004F-4AA6-B6A1-5D0D2EB7DDD9Q26825604-DD46E6B3-FB3F-44A2-9E8D-E63302EAC2C5Q26851354-1DB45EB8-E9D2-4B1A-B4B5-EBD2559225A8Q26999457-608ED0E7-E9F0-462D-8C09-9BD041C8C647Q27002348-66141FA7-049E-4804-B9C0-C826D243BB72Q27021118-EEAED320-D120-4FEA-9C3F-318AE2A920B3Q27303570-4FCEC7B5-1070-4A35-B6EE-5AA35AC01D36Q27321410-61155663-A21D-411E-87DF-18E4A11B6FBBQ27329726-6367419B-DA0E-4641-B077-02253DAE4D89Q27335311-ACED6771-D421-4D39-B3D5-C09C2A09D695Q27336373-4D53FFDA-50AD-4E33-8E88-61F3232C7946Q27346745-8E4C3787-F59F-4632-A2BA-18DE3A6B719FQ27347288-A47EA445-323F-4874-8039-815F7B03B824Q28079969-4AEB7F3C-9F5B-469D-98EA-4F9E39994218Q28262083-25B0AC85-14F1-49F6-A651-D3C135E9916CQ28305167-E6AE9700-8D82-4ACB-BD58-41F0CA94DF0DQ28581771-BCDDCE2D-F3DB-4D72-B783-5385DB618D2FQ28648373-46180E3F-2887-4EB9-887E-D7782639B03DQ28834419-4B9241C0-4938-480F-B0EA-DFC2EEA5C748Q29994746-B50E6760-529E-4229-990C-72D711819AB6Q30354714-E5A97B39-29F1-4408-B688-DA23DF74E2D9Q30363137-DC2C8DC1-4824-486D-94B2-B68D09B0F993Q30376438-3A72EBBA-7C8A-4200-93F1-FEAE9FF042EEQ30377465-99A87E44-DEF1-4FDD-B21B-F64FA305E878Q30385390-FD620F65-0E4B-44A4-B2E1-5D87103452A7Q30387411-E0243D21-F0CA-4665-854D-CBBBC8282993Q30400335-E6166783-258B-46DC-9670-A065B91E1F75Q30402763-97ED24EC-BA4B-450F-8F8A-1553E186E549Q30419329-27E4FF08-F67B-4380-8A7A-DDA8FF912814Q30437222-F4C87C9A-016C-4ADD-89CF-317F2DFD7F25Q30459198-004A0AC0-6A0D-4986-86A6-DEDC70656F05Q30474685-7A25618A-25A1-488D-9E89-2537808C8CDCQ30478768-976AEA6A-F434-474C-9701-F62699563DA3Q30480641-03D7D00F-11D3-420C-9FFE-BEA3A634BF4BQ30481813-A463A6D7-2A0F-4A05-8D1E-0A3397C89F5DQ30483305-E1680C2F-C5CC-4D00-BA9A-5882DEC85CAC
P2860
description
2000 nî lūn-bûn
@nan
2000 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2000 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2000年の論文
@ja
2000年論文
@yue
2000年論文
@zh-hant
2000年論文
@zh-hk
2000年論文
@zh-mo
2000年論文
@zh-tw
2000年论文
@wuu
name
Micropipette aspiration of living cells.
@ast
Micropipette aspiration of living cells.
@en
type
label
Micropipette aspiration of living cells.
@ast
Micropipette aspiration of living cells.
@en
prefLabel
Micropipette aspiration of living cells.
@ast
Micropipette aspiration of living cells.
@en
P1476
Micropipette aspiration of living cells.
@en
P2093
Hochmuth RM
P356
10.1016/S0021-9290(99)00175-X
P577
2000-01-01T00:00:00Z