Computational modeling of three-dimensional electrodiffusion in biological systems: application to the node of Ranvier. - Wikidata - awgldk - TriplyDB

Computational modeling of three-dimensional electrodiffusion in biological systems: application to the node of Ranvier.

Computational modeling of three-dimensional electrodiffusion in biological systems: application to the node of Ranvier.

http://www.wikidata.org/entity/Q36856372

about

Physiological Dynamics in Demyelinating Diseases: Unraveling Complex Relationships through Computer Modeling.Computational reconstruction of cell and tissue surfaces for modeling and data analysis.STEPS: Modeling and Simulating Complex Reaction-Diffusion Systems with Python.Electrodiffusive model for astrocytic and neuronal ion concentration dynamics.Efficacy of synaptic inhibition depends on multiple, dynamically interacting mechanisms implicated in chloride homeostasis.Anatomically Detailed and Large-Scale Simulations Studying Synapse Loss and Synchrony Using NeuroBox.Improved Simulation of Electrodiffusion in the Node of Ranvier by Mesh Adaptation.Effect of Ionic Diffusion on Extracellular Potentials in Neural Tissue.Hybrid finite element and Brownian dynamics method for charged particles.Mathematical Models of Blast-Induced TBI: Current Status, Challenges, and Prospects Electrostatics of non-neutral biological microdomains.Hybrid finite element and Brownian dynamics method for diffusion-controlled reactions Electrodiffusion models of neurons and extracellular space using the Poisson-Nernst-Planck equations--numerical simulation of the intra- and extracellular potential for an axon model.Role of connexin 32 hemichannels in the release of ATP from peripheral nerves.Computer modeling of mild axonal injury: implications for axonal signal transmission.Perinodal glial swelling mitigates axonal degradation in a model of axonal injury.On the Nernst-Planck equation.Primary paranode demyelination modulates slowly developing axonal depolarization in a model of axonal injury.Electrodiffusion phenomena in neuroscience: a neglected companion.Activity-dependent intracellular chloride accumulation and diffusion controls GABA(A) receptor-mediated synaptic transmission.Deconvolution of Voltage Sensor Time Series and Electro-diffusion Modeling Reveal the Role of Spine Geometry in Controlling Synaptic Strength.Asymptotic model of electrical stimulation of nerve fibers.Solutions to a reduced Poisson-Nernst-Planck system and determination of reaction rates.

P2860

Q26786977-251DD9EB-B184-47ED-B038-CAE3BF003E39 Q33470200-876E97C7-5FFD-4D95-8048-3FD1F7CF7A90 Q33485202-C6C9FE48-EE9C-4508-8546-D22F918A115A Q35075076-F9550EC2-F927-4D4F-B1E6-B7DCEB51223A Q35203892-46C349A1-5BF9-4489-BFDD-E5D7FF833CFF Q35931868-EAB8DC2D-DBCF-4F8B-AFFE-64FE9CDBA397 Q36109253-B5E69C55-B2D8-4989-A53F-8554D955E8FD Q36184330-C0D4A778-B43F-4B06-B85F-0E276258F2FC Q36853361-46CD6AF4-7834-48E5-A7E3-5C5D7965B9B8 Q36885898-AB9DF765-FD0F-4DE6-A995-ACD00B6E0383 Q41199488-43B5D0A9-0B63-4B6F-9B74-5A9C3EC1A4AE Q42158660-7BD25385-CC12-471D-A681-7763C06A179B Q43103239-86363A22-261F-4F29-BA4D-92958C5F1EA9 Q45952785-64E206C6-BA26-4902-91D2-001E55C6FA30 Q46170637-DD1A29C8-6666-4641-8F66-AA3BCEB53A16 Q46427894-EBB2540E-82E3-4DF8-A38C-3DE955A9BE01 Q47692129-2297203B-1E45-43A1-B251-122436C05B43 Q47848975-CA6235DB-6AB6-49FC-AD58-1BDEF1E1C55B Q48106924-85EC40EE-62C0-4721-B33B-4082926F70A3 Q48153979-98391781-4FC6-4400-901A-6BA1130E03BF Q50048416-22C246F4-A51E-4175-BBEE-24FBFE54255A Q51419664-8CD1059B-ACC8-45EE-A28E-609E6496D9EB Q55488520-E3A610CA-4C44-44D0-8A45-48758EB17B47

P2860

Computational modeling of three-dimensional electrodiffusion in biological systems: application to the node of Ranvier.

http://www.wikidata.org/entity/Q36856372

description

2008 nî lūn-bûn

@nan

2008年の論文

@ja

2008年論文

@yue

2008年論文

@zh-hant

2008年論文

@zh-hk

2008年論文

@zh-mo

2008年論文

@zh-tw

2008年论文

@wuu

2008年论文

@zh

2008年论文

@zh-cn

name

Computational modeling of thre ...... cation to the node of Ranvier.

@en

type

label

Computational modeling of thre ...... cation to the node of Ranvier.

@en

prefLabel

Computational modeling of thre ...... cation to the node of Ranvier.

@en

P1433

Q36856372-5065D2C6-EE6B-46C7-9322-6E70457FFF18

P1476

Q36856372-B001ADA3-0ABE-4208-8B04-735DCA7A4457

P2093

Q36856372-177ABBEC-2946-4868-BED8-C50902E2D432

Q36856372-34303846-F8AB-48D5-8337-C9957B734059

Q36856372-ADD9F26A-8578-432C-8755-28CAA4E9CD2A

Q36856372-BCC48FC8-25AA-41E8-84C8-2A1F0E04089F

Q36856372-ED6AB4B3-C33E-4561-ADB1-8B824EE61961

P2860

Q36856372-0B34B965-D33F-4921-91C9-9218EEC4B739

Q36856372-0D2832B0-5328-4ECC-90A5-9A0D177A22A8

Q36856372-604993D6-1352-4852-9E9E-6B49C8FDC427

Q36856372-6E4BBF38-5D00-45EE-AF27-B44E37CDF043

Q36856372-7ECEEBB1-EF4F-43DD-A7A5-4E6A6BF92467

Q36856372-958836CB-B600-4E1F-B275-99F2B084B7AD

Q36856372-9BF69235-328F-4125-864A-51BA296BD72E

Q36856372-BB1171E1-2398-479A-9493-2EBAE1F862D7

Q36856372-C8976EF4-D5B8-42A1-AD54-FA303B4E0C1C

Q36856372-C95CAD95-3FA1-4096-A01D-D694996C0455

P304

Q36856372-0D7E110F-1448-4027-9EAB-298C0AF72B21

P31

Q36856372-1FFD5880-9453-4F2F-8659-EA0917595C0B

P356

Q36856372-9C4858C3-4364-48C6-8ACC-428C7ADEE1A8

P407

Q36856372-ACB235AE-9200-4872-AF98-D1D5BA4F69CB

P433

Q36856372-7D6447EC-CB83-4279-B74E-2DBAD939C028

P478

Q36856372-CB18BB12-6561-4273-BB7B-31DFC0D38967

P50

Q36856372-A933ABD9-F6FD-4D23-ADC4-A295E3DB72E0

Q36856372-B5B2BE80-0E79-46A0-9452-838CDA8483ED

P577

Q36856372-E6A1409F-0F48-4459-8A28-EE0BD8E33ECD

P5875

Q36856372-158A765C-664E-45D6-BA97-EC00FDD8A6B8

P698

Q36856372-58222156-8E3E-45CE-8693-D41446E9A083

P932

Q36856372-DFE4487E-1721-41A1-B311-5D9F8340427D

P356

BIOPHYSJ.108.132167

P1433

Biophysical Journal

P1476

Computational modeling of thre ...... cation to the node of Ranvier.

@en

P2093

Courtney L Lopreore

http://www.w3.org/2001/XMLSchema#string

Daniel X Keller

http://www.w3.org/2001/XMLSchema#string

Gina E Sosinsky

http://www.w3.org/2001/XMLSchema#string

Mark H Ellisman

http://www.w3.org/2001/XMLSchema#string

Thomas M Bartol

http://www.w3.org/2001/XMLSchema#string

P2860

A quantitative description of membrane current and its application to conduction and excitation in nerve

THE ACTION POTENTIAL IN THE MYELINATED NERVE FIBER OF XENOPUS LAEVIS AS COMPUTED ON THE BASIS OF VOLTAGE CLAMP DATA.

Cooperative 4Pi excitation and detection yields sevenfold sharper optical sections in live-cell microscopy.

A model for axonal propagation incorporating both radial and axial ionic transport.

NEURON: a tool for neuroscientists.

Time constants and electrotonic length of membrane cylinders and neurons.

Three fluorescent protein voltage sensors exhibit low plasma membrane expression in mammalian cells.

Immunocytochemical localization of sodium channel distributions in the excitable membranes of Electrophorus electricus

Synthesis of models for excitable membranes, synaptic transmission and neuromodulation using a common kinetic formalism.

The NEURON simulation environment.

P304

2624-2635

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1529/BIOPHYSJ.108.132167

http://www.w3.org/2001/XMLSchema#string

P407

P433

6

http://www.w3.org/2001/XMLSchema#string

P478

95

http://www.w3.org/2001/XMLSchema#string

P50

Terrence J. Sejnowski

P577

2008-06-13T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

5299512

http://www.w3.org/2001/XMLSchema#string

P698

18556758

http://www.w3.org/2001/XMLSchema#string

P932

2527256

http://www.w3.org/2001/XMLSchema#string