Large and persistent electrical currents enter the transected lamprey spinal cord.
about
Electrical Stimulation Elicits Neural Stem Cells Activation: New Perspectives in CNS RepairElucidating the Role of Injury-Induced Electric Fields (EFs) in Regulating the Astrocytic Response to Injury in the Mammalian Central Nervous SystemPI3K mediated electrotaxis of embryonic and adult neural progenitor cells in the presence of growth factors.Physiological electrical signals promote chain migration of neuroblasts by up-regulating P2Y1 purinergic receptors and enhancing cell adhesion.Effects of sodium and chloride on neuronal survival after neurite transection.Consequences of neurite transection in vitro.Electrical stimulation modulates injury potentials in rats after spinal cord injury.Cellular engineering: molecular repair of membranes to rescue cells of the damaged nervous system.Controlling cell behavior electrically: current views and future potential.Electrical implications of corrosion for osseointegration of titanium implantsTransient electric changes immediately after surgical trauma.Affinity for, and localization of, PEG-functionalized silica nanoparticles to sites of damage in an ex vivo spinal cord injury model.Airway epithelial wounds in rhesus monkey generate ionic currents that guide cell migration to promote healingThe critical role of voltage-dependent calcium channel in axonal repair following mechanical trauma.Spontaneous high-frequency action potential.Non-invasive tools for measuring metabolism and biophysical analyte transport: self-referencing physiological sensing.Polyethylene glycol repairs membrane damage and enhances functional recovery: a tissue engineering approach to spinal cord injury.In vitro and in vivo neuronal electrotaxis: a potential mechanism for restoration?Graphite Oxide to Graphene. Biomaterials to Bionics.Cellular responses of identified lamprey central neurons to axonal and dendritic injury. An in situ model for studying cellular injury on the single cell level in the vertebrate CNS.Electric field-controlled directed migration of neural progenitor cells in 2D and 3D environments.Large naturally-produced electric currents and voltage traverse damaged mammalian spinal cord.Polyethylene glycol immediately repairs neuronal membranes and inhibits free radical production after acute spinal cord injury.Neuronal responses to an asymmetrical alternating current field can mimic those produced by an imposed direct current field in vitro.Understanding the response of pulsed electric field on osteoblast functions in three-dimensional mesh structures.Electrical stimulation of the motor cortex enhances progenitor cell migration in the adult rat brain.Electrical characterization of a single cell electroporation biochip with the 2-D scanning vibrating electrode technology.Calculated spinal cord electric fields and current densities for possible neurite regrowth from quasi-DC electrical stimulation.Electric field-mediated growth of osteoblasts - the significant impact of dynamic flow of medium.A time-lapse and quantitative modelling analysis of neural stem cell motion in the absence of directional cues and in electric fields.Early cytoskeletal changes following injury of giant spinal axons in the lamprey.Effects of electric fields on human mesenchymal stem cell behaviour and morphology using a novel multichannel device.Macrophage Biocompatibility of CoCr Wear Particles Produced under Polarization in Hyaluronic Acid Aqueous Solution.Percutaneous direct current stimulation - a new electroceutical solution for severe neurological pain and soft tissue injuries.
P2860
Q26779694-A685B92C-2651-4583-8924-1AE543A229C5Q27344252-D16D31E5-A2FE-4DDA-8F5B-7025545ED042Q30557078-86358678-D1E7-4664-B9D9-2A82E5167374Q30620739-66DB2A7C-1BA8-4A4B-B670-176B795B9872Q30980561-2C9A314B-F19D-4E74-8CF9-2F63EB35805EQ33528078-F92F8790-FBFD-43DF-98C1-8FF147867E2DQ34094657-A2FEF743-BABF-4544-B9C3-366924E82928Q34336446-816E16C7-CCA6-4AEF-A463-FAF6FCABF14CQ34650760-3E5E0E74-E50C-4441-A330-24036386C379Q35549010-A3EB3337-D5CB-4F43-AD9C-7949BD88B8FEQ36274654-C7729F55-8CB1-4BD1-AE05-12F592A449B9Q36547886-A55244C1-3D62-43D1-9D4F-AE3166D0EB87Q37174574-00317A54-B1CC-4CA5-BEAD-408215E339B8Q37239428-1064CB8A-B4D3-4684-BD11-3AC0EF1D6AA6Q37867552-EE3B1867-5B36-4FE2-AD62-2CB8927F04D9Q37901403-3495CFDD-5B07-43E8-8F21-D3200522FD76Q38124780-DCF71A17-DC95-433B-94FD-C6AED0C47867Q38163472-0A9DA2E7-4A59-4F6D-8510-528E2E256715Q39013935-97B388F3-A872-4CE3-B03C-C334986427E4Q40917201-8D016C65-B18C-4CD5-BD0F-72E18946BFB6Q41879508-DA21FE7B-18F5-4E62-A6CB-599E864E1765Q43174080-67CA3131-4473-4972-B49D-9A032C2B5942Q44210294-20561E50-717F-4615-81D0-6FF31E16C530Q47903389-3F6D33D2-7400-4DC0-A8B6-B917B9B5078DQ48636552-437161F1-22C7-4D0E-9918-EE1E683EFF02Q49078378-2CBFCC34-AFBD-4EEB-A17B-4EB772420C9BQ51564543-056FFFE9-4D0A-4570-BB4B-C1824194F325Q51662170-1CBEBF7F-2367-415F-A2CB-2610A99CB8EAQ51686605-D14F42F6-7A47-4F03-89DC-F148C8732A06Q51898571-07D667C2-D6E9-4194-BC86-7F2B1E09ACA1Q52509772-E2980C76-3560-4DB9-BC76-1BBA9282FFACQ53008584-58BA8B0C-D97F-4519-9BFA-CD7333F0C585Q54974223-DFA8250F-CAB1-46DC-9C9F-2637934D3A51Q55444881-ABD2CABC-B1E4-4E95-8883-A0C2FF612899
P2860
Large and persistent electrical currents enter the transected lamprey spinal cord.
description
1980 nî lūn-bûn
@nan
1980年の論文
@ja
1980年学术文章
@wuu
1980年学术文章
@zh-cn
1980年学术文章
@zh-hans
1980年学术文章
@zh-my
1980年学术文章
@zh-sg
1980年學術文章
@yue
1980年學術文章
@zh
1980年學術文章
@zh-hant
name
Large and persistent electrical currents enter the transected lamprey spinal cord.
@ast
Large and persistent electrical currents enter the transected lamprey spinal cord.
@en
type
label
Large and persistent electrical currents enter the transected lamprey spinal cord.
@ast
Large and persistent electrical currents enter the transected lamprey spinal cord.
@en
prefLabel
Large and persistent electrical currents enter the transected lamprey spinal cord.
@ast
Large and persistent electrical currents enter the transected lamprey spinal cord.
@en
P2093
P2860
P356
P1476
Large and persistent electrical currents enter the transected lamprey spinal cord.
@en
P2093
P2860
P304
P356
10.1073/PNAS.77.2.1209
P407
P577
1980-02-01T00:00:00Z