Biased random walk by stochastic fluctuations of chemoattractant-receptor interactions at the lower limit of detection.
about
An excitable cortex and memory model successfully predicts new pseudopod dynamicsChemotaxis of Dictyostelium discoideum: collective oscillation of cellular contactsActivated membrane patches guide chemotactic cell motilityNavigation of chemotactic cells by parallel signaling to pseudopod persistence and orientationPredicting chemical environments of bacteria from receptor signalingNatural search algorithms as a bridge between organisms, evolution, and ecologyMigrating fibroblasts reorient directionality by a metastable, PI3K-dependent mechanismFour key signaling pathways mediating chemotaxis in Dictyostelium discoideum.Bayesian model predicts the response of axons to molecular gradients.Cell speed, persistence and information transmission during signal relay and collective migration.Self-organization of the phosphatidylinositol lipids signaling system for random cell migrationChemotactic cell trapping in controlled alternating gradient fieldsDelineating the core regulatory elements crucial for directed cell migration by examining folic-acid-mediated responsesDistinct cell shapes determine accurate chemotaxisDeciphering chemokine properties by a hybrid agent-based model of Aspergillus fumigatus infection in human alveoli.Coupled excitable Ras and F-actin activation mediates spontaneous pseudopod formation and directed cell movementStochastic Dynamics of Membrane Protrusion Mediated by the DOCK180/Rac Pathway in Migrating CellsBimodal analysis reveals a general scaling law governing nondirected and chemotactic cell motility.External and internal constraints on eukaryotic chemotaxis.Noise filtering tradeoffs in spatial gradient sensing and cell polarization response.Modeling and measuring signal relay in noisy directed migration of cell groups.In chemotaxing fibroblasts, both high-fidelity and weakly biased cell movements track the localization of PI3K signaling.Microfluidic technologies for temporal perturbations of chemotaxis.The stochastic dynamics of filopodial growth.3'-phosphoinositides regulate the coordination of speed and accuracy during chemotaxisAccuracy of direct gradient sensing by single cells.Receptor noise limitations on chemotactic sensing.High fidelity information processing in folic acid chemotaxis of Dictyostelium amoebaeAdaptive-control model for neutrophil orientation in the direction of chemical gradients.Experimental evidence for UNC-6 (netrin) axon guidance by stochastic fluctuations of intracellular UNC-40 (DCC) outgrowth activity.How cells use pseudopods for persistent movement and navigation.The local cell curvature guides pseudopodia towards chemoattractants.Tracking shallow chemical gradients by actin-driven wandering of the polarization site.Statistical analysis of lateral diffusion and multistate kinetics in single-molecule imaging.Phenomenological approach to eukaryotic chemotactic efficiency.Quantifying information transmission in eukaryotic gradient sensing and chemotactic response.A stochastic model for chemotaxis based on the ordered extension of pseudopodsRac signal adaptation controls neutrophil mobilization from the bone marrow.Memory improves precision of cell sensing in fluctuating environments.How geometry and internal bias affect the accuracy of eukaryotic gradient sensing.
P2860
Q27306786-9E438FF3-001A-4AEF-981F-1FC6CE845D22Q27320107-EBA13FC3-82A8-4B98-AB4C-70E0257E07A9Q27333557-43A56F9D-8372-4022-822D-7C2B32B08447Q27342689-C25F26F1-19D8-4D1B-AB26-5C232723D1E6Q28544010-756D2DEE-2F70-410E-92FB-88894BC38D21Q30362796-A2DE1CDD-BC03-45F9-9CBB-64619E1A4BBCQ30424658-1C95101F-D03F-4634-A0F2-D7A37DA7E095Q30481433-4E7A87D2-60E3-4993-A68A-AA6E8C6562C3Q30488359-DDFAA70B-B158-4221-8D74-A97A3D11C703Q30494348-46FB4BCF-EE81-440F-B046-D9B7169337BAQ30495403-1A747B5C-6BCD-4753-9B90-FF95085E74E5Q30502473-6A1A0833-B906-4351-8066-0EB621EB0CA9Q30537866-AC420ADA-1D32-48B1-92A0-9293DDC69ED9Q30544146-851FE1C7-0464-40E1-9453-E5A281D6BEFDQ30651977-4B864825-B18D-43E4-A33F-FDB02BA07A1AQ30844726-C20A9838-811F-4B8C-8057-BC6815365F9FQ33847640-8D7A3FCF-BD4F-49E1-85CF-FB08CC9729C1Q33999590-4CB87ABC-6393-419F-BEEF-E90EB390614BQ34006769-6240AC41-B93F-43BE-8871-29FC0019F990Q34099885-C0002DD9-284B-45CC-83D5-666278153F48Q34711760-D53161A6-4C19-46AF-B77D-225073ADF55EQ34800896-E4A43006-F185-4F45-95DC-66FDE825BD55Q35157430-33F65E81-1917-4877-B824-455242F009B0Q36632087-90FA6FAC-B0C0-4310-A499-05D821DA55FEQ36908334-B52C70BF-7C77-4B12-B75E-C09241384B11Q36948985-8707FB80-C6F7-4F26-A12B-1119EAFE5263Q37039512-8797147E-EC92-42D6-BA64-D3F1EACAAFD8Q37204209-90D27028-FDA5-4AAB-98B4-30D80572BD0DQ37265574-510F6C08-315D-4C00-B71A-59C39574A25CQ37392791-E74743CA-61C3-43AD-BD39-ED77466BCBC8Q39595796-50031C31-D95F-4479-A0FF-9B5C967A66A0Q41819745-5F70E1E3-9D90-4B22-8AC0-CC6D355012F8Q41842230-F41E758C-D551-4DA7-9EC1-39EDC1347967Q41873665-C92A3B52-2BC8-4E4B-905E-A8D7CE37A3C1Q42063751-A339ADBC-78CB-488B-A564-8040B112EB09Q42129474-71B38242-D1C6-4913-8186-D3760BD91A3FQ42364808-0CEEA290-8CAF-4A93-8E8C-D79304DA7DC5Q42503313-922994E5-66FF-407A-AB66-ED1A860F30DBQ42735327-6E0444D4-69F5-40D4-BCBA-C4059AED2704Q42767837-3715D507-7B42-4614-9823-BE577B6ED124
P2860
Biased random walk by stochastic fluctuations of chemoattractant-receptor interactions at the lower limit of detection.
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Biased random walk by stochast ...... the lower limit of detection.
@en
Biased random walk by stochast ...... the lower limit of detection.
@nl
type
label
Biased random walk by stochast ...... the lower limit of detection.
@en
Biased random walk by stochast ...... the lower limit of detection.
@nl
prefLabel
Biased random walk by stochast ...... the lower limit of detection.
@en
Biased random walk by stochast ...... the lower limit of detection.
@nl
P2860
P1433
P1476
Biased random walk by stochast ...... the lower limit of detection.
@en
P2093
Marten Postma
Peter J M van Haastert
P2860
P304
P356
10.1529/BIOPHYSJ.107.104356
P407
P577
2007-05-18T00:00:00Z