Implant size and fixation mode strongly influence tissue reactions in the CNS
about
Mechanical and Biological Interactions of Implants with the Brain and Their Impact on Implant DesignProgress towards biocompatible intracortical microelectrodes for neural interfacing applicationsMultiplexed, high density electrophysiology with nanofabricated neural probesAn array of highly flexible electrodes with a tailored configuration locked by gelatin during implantation-initial evaluation in cortex cerebri of awake rats.FEF inactivation with improved optogenetic methods.Characterization of Mechanically Matched Hydrogel Coatings to Improve the Biocompatibility of Neural Implants.Chronic intracortical microelectrode arrays induce non-uniform, depth-related tissue responses.Multiple implants do not aggravate the tissue reaction in rat brain.Three-Dimensional Flexible Electronics Enabled by Shape Memory Polymer Substrates for Responsive Neural InterfacesChronic tissue response to untethered microelectrode implants in the rat brain and spinal cord.A multi-channel, flex-rigid ECoG microelectrode array for visual cortical interfacingLong-term implanted cOFM probe causes minimal tissue reaction in the brainInfluence of probe flexibility and gelatin embedding on neuronal density and glial responses to brain implantsFlexible active electrode arrays with ASICs that fit inside the rat's spinal canal.Embedded Ultrathin Cluster Electrodes for Long-Term Recordings in Deep Brain Centers.Variability of acute extracellular action potential measurements with multisite silicon probes.Scanning electron microscopy of chronically implanted intracortical microelectrode arrays in non-human primatesHost response to microgel coatings on neural electrodes implanted in the brain.3D meshes of carbon nanotubes guide functional reconnection of segregated spinal explants.Impact of degradable nanowires on long-term brain tissue responses.The density difference between tissue and neural probes is a key factor for glial scarring.Bio-inspired hybrid microelectrodes: a hybrid solution to improve long-term performance of chronic intracortical implants.Materials approaches for modulating neural tissue responses to implanted microelectrodes through mechanical and biochemical means.Soft implantable microelectrodes for future medicine: prosthetics, neural signal recording and neuromodulation.Ultrasoft microwire neural electrodes improve chronic tissue integration.Complications of subdural and depth electrodes in 269 patients undergoing 317 procedures for invasive monitoring in epilepsy.Neural coding for effective rehabilitation.The sinusoidal probe: a new approach to improve electrode longevity.Sub-meninges implantation reduces immune response to neural implants.μ-Foil Polymer Electrode Array for Intracortical Neural Recordings.Rapid evaluation of the durability of cortical neural implants using accelerated aging with reactive oxygen species.Abiotic-biotic characterization of Pt/Ir microelectrode arrays in chronic implants.The effect of inflammatory cell-derived MCP-1 loss on neuronal survival during chronic neuroinflammation.A three dimensional in vitro glial scar model to investigate the local strain effects from micromotion around neural implants.Neural Interfaces for Intracortical Recording: Requirements, Fabrication Methods, and Characteristics.Safety and efficacy of explanting or replacing suprachoroidal electrode arrays in a feline model.Polyhydroxyalkanoate/carbon nanotube nanocomposites: flexible electrically conducting elastomers for neural applications.A Meta-Analysis of Intracortical Device Stiffness and Its Correlation with Histological OutcomesThiol-ene/acrylate substrates for softening intracortical electrodesSmart Polymers for Neural Interfaces
P2860
Q26768238-D782516D-7189-4B9A-860D-3776A82BD31AQ27021648-FD2B1D43-D46A-46C3-B41A-B3EB29AC817EQ28743942-C9481EDC-FC2A-4214-B05E-1EC1443C6DCDQ30665695-D189B6F4-95A5-44F7-B8DF-B24EE3530514Q30830673-3C9730B6-A1E9-4688-B697-C6D80A0A9F9AQ33694798-2BC3DD83-DA3D-478D-BAA6-68DE62804AE6Q33894777-B7354043-7B28-4AF5-84AB-736C434F443BQ34455284-D3101BE5-E26E-47AD-BDA6-EF0201C10351Q34715424-90495CC0-288A-4FD1-9FBC-A6BAB6B14E9CQ35049784-C44763C5-46BC-4224-9556-7324E3ED5F2EQ35080936-20599C54-BBDF-4C02-8905-08616B944B5CQ35118715-8340DA04-A72E-4D78-B2B5-54C462335BD8Q35195861-2573E4FA-4B6D-4D42-8F78-987D248A340FQ35807139-BC16E30F-7D2A-4EDF-8538-AA4689EE939EQ36012165-019764A1-6B0E-4786-A312-921A69472ABBQ36322773-E60368BD-23FE-4A7C-A6B8-B5EC3A3C854AQ36862185-62AF8FF9-266C-497F-9F48-8CD1A5E85C07Q37033247-910441F9-B3E8-46B8-A76D-395B5BFEB266Q37115292-BE5D60AE-477A-44EF-989E-FC4C01B3BD32Q37163566-BF4E6254-E8C4-4758-9ED2-497A5CFA11F7Q37230019-419D69F4-8F09-4D00-BDC0-CE2A97571E34Q37707421-A8BC51C2-4317-40DF-B2C7-861492019210Q38296578-46172258-4CB3-409F-951B-D85599CD38D8Q38739413-AE4D55E4-EBC7-4E49-9DA5-FDB5705ED3D6Q38758984-5F6FF26B-EC12-4089-A515-4F2CC1984E6AQ38934282-3F1BCE1F-AB95-43CE-B204-C5D6FBFF9DE3Q39122735-4B3383A1-856E-4900-A033-31C29E65B91AQ39251687-86FA8848-133A-47C6-BD56-265399BBFDFEQ40392975-A72BECC6-8C3E-491F-B96A-26D450003517Q40723825-27933BBC-D4F8-4F1B-9F76-D9258DAA54ABQ41237403-AABD32C6-2631-4720-856A-E913BF4797B9Q41911330-3A1546CC-312C-4381-9678-0D8DBFE6ED15Q42544286-8FEB098B-5019-4D02-A715-7AF81D5F850EQ46249832-76A5A4EB-BAF4-49CC-B3AF-2021F7FBCE5EQ47104195-5E180B89-7B96-4381-A0BA-6F51E1EC7272Q48559282-02AED1C9-6B92-4769-BD1E-2653F27C288BQ50220016-A8C4585C-BA98-4A1D-BFEE-E86432163085Q58760554-CCB777EE-0736-4A30-ACAA-81256A682894Q58835316-F9E28437-7532-462E-98DB-50CFEF9F0DB6Q58835321-54F64FD3-C046-435B-A5EB-CBC861DBC38F
P2860
Implant size and fixation mode strongly influence tissue reactions in the CNS
description
2011 nî lūn-bûn
@nan
2011 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2011 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2011年の論文
@ja
2011年論文
@yue
2011年論文
@zh-hant
2011年論文
@zh-hk
2011年論文
@zh-mo
2011年論文
@zh-tw
2011年论文
@wuu
name
Implant size and fixation mode strongly influence tissue reactions in the CNS
@ast
Implant size and fixation mode strongly influence tissue reactions in the CNS
@en
type
label
Implant size and fixation mode strongly influence tissue reactions in the CNS
@ast
Implant size and fixation mode strongly influence tissue reactions in the CNS
@en
prefLabel
Implant size and fixation mode strongly influence tissue reactions in the CNS
@ast
Implant size and fixation mode strongly influence tissue reactions in the CNS
@en
P2093
P2860
P1433
P1476
Implant size and fixation mode strongly influence tissue reactions in the CNS
@en
P2093
Cecilia Eriksson Linsmeier
Elia Psouni
Henrik Jörntell
Martin Garwicz
Nils Danielsen
P2860
P304
P356
10.1371/JOURNAL.PONE.0016267
P407
P577
2011-01-26T00:00:00Z