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ref: -0 tags: bone marrow transplant chimera immune response to indwelling electrode implant capadona inflammation date: 02-02-2017 23:24 gmt revision:1 [0] [head]

PMID-24973296 The roles of blood-derived macrophages and resident microglia in the neuroinflammatory response to implanted intracortical microelectrodes.

  • Quite good introductory review on current understanding of immune / inflammatory / BBB breakdown response to indwelling neural implants.
  • Used chimera mice with marrow from CFP mice transplanted into irradiated hosts, so myeloid cells were labeled (including macrophages and monocytes).
    • Details of this process are properly fascinating ... there are clever ways of isolating and selecting the right marrow cells.
  • Implanted with a dummy Michigan style probe, 2mm x 123 um x 15um.
  • Histological processes and cell sorting / labeling also highly detailed.
  • 60% of the infiltrating cells (CFP+) are macrophages.
    • Within the total IBA1+ population (macrophages + microglia), we saw that only 20% of the total IBA1+ population was comprised of microglia at two weeks post implantation (Fig. 9G).
    • Additionally, at chronic time points (four, eight and sixteen weeks), we observed that less than 40% of the total IBA1+ population was comprised of microglia (Fig. 9G).
    • On the other hand, no significant differences were observed in microglia populations over time (Fig. 9G, Table 4). Together, our results suggest a predominant role of infiltrating macrophages surrounding implanted microelectrodes over time.
  • IBA1 = marker for ionized calcium binding adapter molecule, to label the total population of microglia/ macrophages (both resting and activated)
  • CD68 = activated microglia / macrophage.
    • Hard to discriminate microglia and infiltrating macrophages.
  • Interestingly, fluctuations in GFAP+ immunoreactivity correlated well with neuronal density and CFP+ immunoreactivty, suggesting a possible role of astrocytes in facilitating trafficking of blood-derived cells.
  • Contrary to what has been suggested by many intracortical microelectrode studies, a consistent connection was not found between activated microglia/macrophages and neuron density in our chimera models

{1204}
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ref: Linsmeier-2011.01 tags: histology lund electrodes immune response fine flexible review Thelin date: 12-08-2015 23:57 gmt revision:6 [5] [4] [3] [2] [1] [0] [head]

PMID-21867803[0] Can histology solve the riddle of the nonfunctioning electrode? Factors influencing the biocompatibility of brain machine interfaces.

  • We show results from an ultrathin multichannel wire electrode that has been implanted in the rat cerebral cortex for 1 year.
    • 12um Pt-Ir wires in a 200um bundle coated with gelatin. See PMID-20551508[1]
    • Electrode was left in the rat cortex for 354 days
    • no clear GFAP staining or ED1 positive cells at the electrode tips.
  • To improve biocompatibility of implanted electrodes, we would like to suggest that free-floating, very small, flexible, and, in time, wireless electrodes would elicit a diminished cell encapsulation.
  • Suggest standardized methods for the electrode design, the electrode implantation method, and the analyses of cell reactions after implantation
  • somewhat of a review -- Stice, Biran 2005 [2] 2007 [3].
  • 50um is the recording distance Purcell 2009.
  • See also [4]
  • Study of neuronal density and ED1 reactivity / GFAP:
    • Even at 12 weeks the correlation between NeuN density and GFAP / ED1 was small -- r 2=0.12
    • Note that DAPI labels many unknown cells in the vicinity of the electrode.

____References____

[0] Linsmeier CE, Thelin J, Danielsen N, Can histology solve the riddle of the nonfunctioning electrode? Factors influencing the biocompatibility of brain machine interfaces.Prog Brain Res 194no Issue 181-9 (2011)
[1] Lind G, Linsmeier CE, Thelin J, Schouenborg J, Gelatine-embedded electrodes--a novel biocompatible vehicle allowing implantation of highly flexible microelectrodes.J Neural Eng 7:4, 046005 (2010 Aug)
[2] Biran R, Martin DC, Tresco PA, Neuronal cell loss accompanies the brain tissue response to chronically implanted silicon microelectrode arrays.Exp Neurol 195:1, 115-26 (2005 Sep)
[3] Biran R, Martin DC, Tresco PA, The brain tissue response to implanted silicon microelectrode arrays is increased when the device is tethered to the skull.J Biomed Mater Res A 82:1, 169-78 (2007 Jul)
[4] Thelin J, Jörntell H, Psouni E, Garwicz M, Schouenborg J, Danielsen N, Linsmeier CE, Implant size and fixation mode strongly influence tissue reactions in the CNS.PLoS One 6:1, e16267 (2011 Jan 26)

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ref: -0 tags: histology immune response otto indiana electrodes gfap inflamation transparent clearing vimentin date: 04-19-2013 23:59 gmt revision:4 [3] [2] [1] [0] [head]

PMID-23428842 Chronic intracortical microelectrode arrays induce non-uniform, depth-related tissue responses.

  • Woolley AJ, Desai HA, Otto KJ.
  • One timepoint, 4 weeks.
  • Laser confocal microscopy
    • after tissue clearing (optical index of refraction matching) in a 60% sucrose solution.
  • Single-shank iridium contact silicon substrate MEA.
    • Device cut level with surface of brain after insertion.
  • Intact MEAs via device-capture histology, DHhist (Woolley et al 2011)
    • 350-450um tissue explanted with device.
    • They promote their technique.
  • Tissue surrounding microdevices exhibited two major depth-related phenomena:
    • a non-uniform microglial coating along the device length and
    • a dense mass of cells surrounding the implant in cerebral cortical layers I and II.
      • The dense mass of cells contained vimentin, a protein not typically expressed highly in CNS cells, evidence that non-CNS cells likely descended down the face of the penetrating devices from the pial surface.
        • But no Iba1 (activated microglia) per se in the tissue mass.
    • Hoe342 -- cell marker.
    • This mass was apparently consistent across animals!
    • Cells in the mass were VIM positive -- fibroblasts -- meninges?
  • low GFAP = not an astrocytic scar.
  • This study provides further evidence that a progressive invasion of non-CNS cells contributes substantially to the chronic phase of the tissue response around intracortical MEAs.
    • Again, might be from BBB distruption {1237}


This result is supported by previous papers:
  • {1193} -- microglia response not correlated to electrode failure, but correlated to ferritin immunoresponse
  • {781} -- also note that menigeal fibroblasts migrate down electrode tracts.
  • {1028} -- measured vimentin, GFAP, and ED1 (not Iba1). Found Vim+ and GFAP+, suggesting reactive astrocytes and not meningeal cells. ED1 aka CD68 is specific to macrophages and not microglia, so these may be blood-derived cells.
  • {1200} -- chronic contact with the meninges v.s intraparenchymal correlated with Vim+ encapsulation.
  • {1210} -- old paper showing the same result near surface of implant.
  • {1196} -- more against GFAP & pro BBB disruption
  • {1204} -- GFAP uncorrelated (!) with NeuN intensity
  • {307} -- all initial tests of utah arrays showed fibrous encapsulation; one array was completely explanted. This is why now they put gore-tex over the implant -- to prevent fibroblast migration (i guess).

{1237}
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ref: -0 tags: winslow Tresco 2010 BBB histology immune response microelectrodes date: 04-19-2013 23:25 gmt revision:0 [head]

PMID-19963267 Quantitative analysis of the tissue response to chronically implanted microwire electrodes in rat cortex.

  • Winslow BD, Tresco PA.
  • The spatial distribution of biomarkers associated with the foreign body response to insulated microwires placed in rat cerebral cortex was analyzed 2, 4, and 12 weeks after implantation using quantitative methods.
  • We found no evidence that reactive gliosis increases over time or that neuronal loss is progressive, we did find evidence of persistent inflammation and enhanced BBB permeability at the electrode brain tissue interface that extended over the 3 month indwelling period and that exhibited more animal to animal variability at 3 months than at 2 and 4 weeks.

{781}
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ref: Polikov-2005.1 tags: neural response glia histology immune electrodes recording 2005 Tresco Michigan microglia date: 01-29-2013 00:34 gmt revision:10 [9] [8] [7] [6] [5] [4] [head]

PMID-16198003[0] Response of brain tissue to chronically implanted neural electrodes

  • Good review (the kind where figures are taken from other papers). Nothing terribly new (upon a very cursory inspection)
  • When CNS damage severs blood vessels, microglia are indistinguishable from the blood borne, monocyte-derived macrophages that are recruited by the degranulation of platelets and the cellular release of cytokines.
  • Furthermore, microglia are known to secrete, either constitutively, or in response to pathological stimuli, neurotrophic factors that aid in neuronal survival and growth.
    • Also release cytotoxic and neurotoxic factors that can lead to neuronal death in vitro.
    • It has been suggested that the presence of insoluble materials in the brain may lead to a state of 'frustrated phagocytosis' or inability of the macrophages to remove the foreign body, resulting in persistent release of neurotoxic substances.
  • When a 10x10 array of silicon probes was implanted in feline cortex, 60% of the needle tracks showed evidence of hemorrhage and 25% showed edema upon explantation of the probes after one day (Schmidt et al 1993) {1163}
    • Although a large number of the tracks were affected, only 3-5% of the area was actually covered by hemorrhages and edema, suggesting the actual damage to blood vessels may have been relatively minor. (!!)
  • Excess fluid and cellular debris diminishes 6-8 days due to the action of activated microglia and re-absorption.
  • As testament to the transitory nature of this mechanically induced wound healing response, electrode tracks could not be found in animals after several months when the electrode was inerted and quickly removed (Yuen and Agnew 1995, Rousche et al 2001; Csicsvari et al 2003, Biran et al 2005).
  • Biran et al 2005: observed persistent ED-1 immunoreactivity around silicon microelectrode arrays implanted in rat cortex at 2 and 4 weeks following implantation; not seen in microelectrode stab wound controls.
  • On the glial scar:
    • observed in the CNS of all vertebrates, presumably to isolate damaged parts of the nervous system and maintain the integrity of the blood-brain barrier.
    • mostly composed of reactive astrocytes.
    • presumably the glial scar insulates electrodes from nearby neurons, hindering diffusion and increasing impedance.
  • On the meninges:
    • Meningeal fibroblasts, which also stain for vimentin, but not for GFAP, may migrate down the electrode shaft from the brain surface and form the early basis for the glial scar.
  • On recording quality:
    • Histological examination upon explantation revealed that every electrode with stable unit recordings had at least one large neuron near the electrode tip, while every electrode that was not able to record resolvable action potentials was explanted from a site with no large neurons nearby.
  • Perhaps the clearest example of this variability was observed in the in vivo response to plastic “mock electrodes” implanted in rabbit brain by Stensaas and Stensaas (1976) {1210} and explanted over the course of 2 years. They separated the response into three types: Type 1 was characterized by little to no gliosis with neurons adjacent to the implant, Type 2 had a reactive astrocyte zone, and Type 3 exhibited a layer of connective tissue between the reactive astrocyte layer and the implant, with neurons pushed more than 100 um away. All three responses are well documented in the literature; however this study found that the model electrodes produced all three types of reactions simultaneously,depending on where along the electrode one looked.

____References____

[0] Polikov VS, Tresco PA, Reichert WM, Response of brain tissue to chronically implanted neural electrodes.J Neurosci Methods 148:1, 1-18 (2005 Oct 15)

{1200}
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ref: Kim-2004.05 tags: histology electrode immune response Tresco hollow fiber membranes GFAP vimentin ED1 date: 01-28-2013 03:08 gmt revision:7 [6] [5] [4] [3] [2] [1] [head]

PMID-14741588[0] Chronic response of adult rat brain tissue to implants anchored to the skull.

  • The increase in tissue reactivity observed with transcranially implanted HFMs may be influenced by several mechanisms including chronic contact with the meninges and possibly motion of the device within brain tissue.
  • Broadly speaking, our results suggest that any biomaterial, biosensor or device that is anchored to the skull and in chronic contact with meningeal tissue will have a higher level of tissue reactivity than the same material completely implanted within brain tissue.
  • See also [1]
  • Could slice through the hollow fiber membrane for histology. (as we shall).
  • Good list of references.

____References____

[0] Kim YT, Hitchcock RW, Bridge MJ, Tresco PA, Chronic response of adult rat brain tissue to implants anchored to the skull.Biomaterials 25:12, 2229-37 (2004 May)
[1] Biran R, Martin DC, Tresco PA, The brain tissue response to implanted silicon microelectrode arrays is increased when the device is tethered to the skull.J Biomed Mater Res A 82:1, 169-78 (2007 Jul)

{898}
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ref: Ward-2009.07 tags: microelectrode arrays immune response recording MEA Purdue date: 01-28-2013 01:52 gmt revision:8 [7] [6] [5] [4] [3] [2] [head]

PMID-19486899[0] Toward a comparison of microelectrodes for acute and chronic recordings.

  • Good research, paper well written.
  • Results suggest significant variability within and between microelectrode types with no clearly superior array (from the abstract).
  • As Miguel mantains, "Much of the new technology, however, does not supersede traditional microwire technology in its ability to evade a host immune response".
  • Initial implantation wound initiates a cascade of immune responses which culminates in a sheath of microglia, astrocytes, various ectracellular matrix constituents, and macrophages.
    • Decent citation list -- many people have been working on MEAs.
  • Fibrous encapusulation of the electrode is much less conductive than healthy nervous tissue, hence impedance measurements can be used to track tissue response.
  • Used Osort to sort the recorded neurons.
  • "Despite differing implant locations, and thus potentially differing levels of background neural activity, and differing scarring responses, which relates to the level of thermal noise in the observed signal (Ludwig et al., 2006), no significant SNR differences were observed among the MEA types for the duration of the study."
  • SNR trends did not seem to relate to site impedance trends over the 31-day period, and by inference, the extent of tissue encapsulation and neuronal density loss.
    • SNR is likely controlled by background neural noise, not thermal noise (which would be linked to impedance).
  • Electrodes with lower impedance generally recorded units from more sites than arrays with higher impedance.

____References____

[0] Ward MP, Rajdev P, Ellison C, Irazoqui PP, Toward a comparison of microelectrodes for acute and chronic recordings.Brain Res 1282no Issue 183-200 (2009 Jul 28)

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ref: Sanders-2000.1 tags: polymer fiber immune reaction biocompatibility rats polycaprolactone recording electrodes histology MEA date: 01-28-2013 00:01 gmt revision:11 [10] [9] [8] [7] [6] [5] [head]

PMID-10906696[0] Tissue response to single-polymer fibers of varying diameters: evaluation of fibrous encapsulation and macrophage density.

  • Fibers smaller than 6μm show reduced immune response.
    • Fibers implanted in the subcutaneous dorsum (below the skin in the back of rats).
    • Polypropylene. (like rope).
    • Wish the result extended to small beads & small electrodes. 7μm is tiny, but possible with insulated Au wires.
      • Beads: try PMID-1913150 -- shows that the 600um - 50um beads ('microspheres') are well tolerated.
      • Also {750}.
  • Macrophage density in tissue with fiber diameters 2.1-5.9um comparable to that of unoperated contralateral control.

"

fiber diametercapsule thickness
2.1-5.90.6
6.5-10.611.7
11.1-15.820.3
16.7-26.725.5

____References____

[0] Sanders JE, Stiles CE, Hayes CL, Tissue response to single-polymer fibers of varying diameters: evaluation of fibrous encapsulation and macrophage density.J Biomed Mater Res 52:1, 231-7 (2000 Oct)

{897}
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ref: Harris-2011.08 tags: microelectrodes nanocomposite immune response glia recording MEA date: 01-27-2013 22:19 gmt revision:5 [4] [3] [2] [1] [0] [head]

PMID-21654037[0] In vivo deployment of mechanically adaptive nanocomposites for intracortical microelectrodes

  • J P Harris, A E Hess, S J Rowan, C Weder, C A Zorman, D J Tyler and J R Capadona Case Western University.
  • Simple idea: electrodes should be rigid enough to penetrate the brain, yet soft enough to not damage it once implanted.
  • Many studies have shown that shear stress around a microelectrode shaft causes neural die-off and glial response.
  • You can only record from neurons if they are < 100um from the electrode tip.
  • Nanocomposite material is inspired by sea cucumber skin.
    • Our materials exhibit this behaviour by mimicking the architecture and proposed switching mechanism at play in the sea cucumber dermis by utilizing a polymer NC consisting of a controllable structural scaffold of rigid cellulose nanofibres embedded within a soft polymeric matrix. When the nanofibres percolate, they interact with each other through hydrogen bonding and form a nanofibre network that becomes the load-bearing element, leading to a high overall stiffness of the NC. When combined with a polymer system which additionally undergoes a phase transition at physiologically relevant temperatures, a contrast of over two orders of magnitude for the tensile elastic modulus is exhibited.
  • Probes were 200um wide, 100um thick, and had a point sharpened to 45deg.
  • Buckle force testing was done on 53um thick, 125um wide probes sharpened to a 30deg point.
  • Penetration stress through the rat pia is 1.2e7 dynes/cm^2 for a Si probe 40um thick and 80um wide.
  • See also {1198}

____References____

[0] Harris JP, Hess AE, Rowan SJ, Weder C, Zorman CA, Tyler DJ, Capadona JR, In vivo deployment of mechanically adaptive nanocomposites for intracortical microelectrodes.J Neural Eng 8:4, 046010 (2011 Aug)

{1210}
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ref: Stensaas-1976.01 tags: histology implant electrodes immune response date: 01-25-2013 02:52 gmt revision:1 [0] [head]

PMID-782142[0] The reaction of the cerebral cortex to chronically implanted plastic needles.

  • Three different classes of result:
    • Type I is characterized by little or no gliosis and synapses within 1-5mu of the implant;
    • type II contains a pronounced zone of reactive astrocytes;
    • type III is typified by a zone of connective tissue near the implant surface
      • One implant can evince all 3 different types!
  • Already were thinking of neuroprosthetic devices.

____References____

[0] Stensaas SS, Stensaas LJ, The reaction of the cerebral cortex to chronically implanted plastic needles.Acta Neuropathol 35:3, 187-203 (1976)

{1196}
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ref: Skousen-2011.01 tags: electrodes immune response Tresco Wise Michigan histology GFAP atrocyte surface area foreign body response date: 01-25-2013 01:44 gmt revision:5 [4] [3] [2] [1] [0] [head]

PMID-21867802[0] Reducing surface area while maintaining implant penetrating profile lowers the brain foreign body response to chronically implanted planar silicon microelectrode arrays.

  • We studied the chronic brain foreign body response to planar solid silicon microelectrode arrays and planar lattice arrays with identical penetrating profiles but with reduced surface area in rats after an 8-week indwelling period.
  • Using quantitative immunohistochemistry, we found that presenting less surface area after equivalent iatrogenic injury is accompanied by significantly less
    • persistent macrophage activation,
    • decreased blood brain barrier leakiness,
    • and reduced neuronal cell loss.
  • Could be a factor of micromotion, too -- the lattice array has more anchoring points (?)
  • They propose it's a factor of TNF- α concentration around the implants. This, and other proinflammatory and cytoxic cytokines, is released by macrophages.
  • "Recent studies from our lab have described disruption of BBB integrity, indicated by the presence of autologous IgG in the brain parenchyma, surrounding both microwire and planar silicon recording devices ([1][2]. Under normal conditions, autologous IgG is excluded from the brain parenchyma (Azzi et al., 1990; Seitz et al., 1985) but has been observed following BBB disruption (Aihara et al., 1994).
    • E.g. the presence of IgG proves that the BBB was compromised.
      • Less so with the lattice implants.
  • Previous work from our lab using single microwires and single shaft, planar silicon microelectrode arrays indicated that the spatial distribution of GFAP does not increase with time over the indwelling period and did not support the “increase in astrogliosis over time hypothesis” as a dominant or general biologically related failure mechanism for this type of microelectrode recording device {1197}.

____References____

[0] Skousen JL, Merriam SM, Srivannavit O, Perlin G, Wise KD, Tresco PA, Reducing surface area while maintaining implant penetrating profile lowers the brain foreign body response to chronically implanted planar silicon microelectrode arrays.Prog Brain Res 194no Issue 167-80 (2011)
[1] Winslow BD, Christensen MB, Yang WK, Solzbacher F, Tresco PA, A comparison of the tissue response to chronically implanted Parylene-C-coated and uncoated planar silicon microelectrode arrays in rat cortex.Biomaterials 31:35, 9163-72 (2010 Dec)
[2] Winslow BD, Tresco PA, Quantitative analysis of the tissue response to chronically implanted microwire electrodes in rat cortex.Biomaterials 31:7, 1558-67 (2010 Mar)

{737}
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ref: Biran-2005.09 tags: microelectrode Michigan probe glia tissue response electrode immune histology MEA Biran date: 01-24-2013 20:49 gmt revision:5 [4] [3] [2] [1] [0] [head]

PMID-16045910[0] Neuronal cell loss accompanies the brain tissue response to chronically implanted silicon microelectrode arrays.

  • See also {1190} (wow, I'm redundant!)
  • Important point: ED1 up-regulation and neuronal loss were not observed in microelectrode stab controls, indicating that the phenotype did not result from the initial mechanical trauma of electrode implantation, but was associated with the foreign body response.
    • CD68 = ED1 is a marker for microglia and other macrophages. (wikipedia article is informative).
    • GFAP = glial fibrillary acidic protein, marker for astrocytes.
  • Recording failure is caused by chronic inflammation (mostly activated microglia) at the microelectrode brain tissue interface.
  • Only tested response 2 and 4 weeks after implantation. Makes sense for stab wound, but didn't the want to see a longer term response? Or do their electrodes just not last that long?
  • What did they coat the silicon probes in?
  • Used silastic to shock-mount their floating electrodes, but this apparently made no difference compared to conventional dental cement and bone screw mounting.
  • Suggest that chronic inflammatory response may be related to the absorption of fibrogen and complement to the surface of the device (device should not be porous?), the subsequent release of pro-inflammatory and cytotoxic cytokines by activated microphages, and the persistence of activated macrophages around materials which cannot be broken down.
    • Well then, how do you make the electrodes biochemically / biologically 'invisible'?
    • Persistently activated microglia are found around insoluble plaques in AD (plaques that cannot be / are not removed from the brain via proteolysis. Microglia form 'glitter cells' when they engulf undigestible stubstances). This has been termed 'frustrated phagocytosis', which results in increased secretion of proinflamatory cytokines that directly or indirectly cause neuronal death.
  • Significant reductions in neurofiliament reactivity was seen up to 230um from the microelectrode interface; this was not seen for stab wounds. Maximum recording distance is about 130um; 100um more reasonable in normal conditions.
  • Accumulating evidence from postmortem analysis of patients implanted with DBS electrodes reveals that chronic neuroinflamation is part of the response to such (duller, larger) implants as well. They have seen cell loss up to 1mm fromt the electrode surface here.

____References____

[0] Biran R, Martin DC, Tresco PA, Neuronal cell loss accompanies the brain tissue response to chronically implanted silicon microelectrode arrays.Exp Neurol 195:1, 115-26 (2005 Sep)

{1199}
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ref: -0 tags: histology atryocytes immune response electrode arrays lund multiple exacerbate date: 01-24-2013 19:56 gmt revision:1 [0] [head]

PMID-23091629 Multiple implants do not aggravate the tissue reaction in rat brain.

  • After six weeks, the astrocytic scar surrounding the middle out of five implants was significantly smaller compared to the single contralateral implant, suggesting that an intrahemispheric interaction might be taking place, reducing the astrocytic response around the central implant.
  • Weak (?) staining for ED1 in this study?
  • -- after 6 weeks.
  • Thought: every paper has a different method for quantify immune response, GFAP staining in this case.

{923}
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ref: Freire-2011.01 tags: Nicolelis BMI electrodes immune respones immunohistochemistry chronic arrays rats 2011 MEA histology date: 06-29-2012 01:20 gmt revision:5 [4] [3] [2] [1] [0] [head]

PMID-22096594[0] Comprehensive analysis of tissue preservation and recording quality from chronic multielectrode implants.

  • Says what might be expected: tungsten microelectrode arrays work, though the quality gradually declines over 6 months.
  • Histological markers correlated well with recording performance.
  • Shows persistent glial activation around electrode sites + cell body hypertropy.
    • Suggest that loss in recording quality may be due to glial encapsulation.
  • References
    • Szarowski et al 2003 {1028}
    • Ward et al 2009
  • Histology:
    • NADPH-d: nicotinamide adenine dinucleotide phosphate-diaphorase, via beta-NADP
    • CO: cytochrome oxidase, via diamnibenzidine DAB, cytochrome c and catalase.
      • both good for staining cortical layers; applied in a standard buffered solution and monitored to prevent overstaining.
  • Immunohistochemistry:
    • Activated microglia with ED-1 antibody.
    • Astrocytes labeled with glial fibrillary acid protein.
    • IEG with an antibody against EGR-1, 'a well-known marker of calcium dependent neuronal activity'
    • Neurofilament revealed using a monoclonal NF-M antibody.
    • Caspace-3 with the associated antibody
    • Details the steps for immunostaining -- wash, blocknig buffer, addition of the antibody in diluted blocking solution (skim milk) overnight, wash again, incubate in biotinylated secondary antibody, wash again, incubate in avidin-biotin-peroxidase solution.
    • Flourescent immunohistochemistry had biotynlation replaced with alexa Fluor 488-conjugated horse anti-mouse and Alexa Fluor 594-conjugated goat anti-rabbit overnight.

____References____

[0] Freire MA, Morya E, Faber J, Santos JR, Guimaraes JS, Lemos NA, Sameshima K, Pereira A, Ribeiro S, Nicolelis MA, Comprehensive analysis of tissue preservation and recording quality from chronic multielectrode implants.PLoS One 6:11, e27554 (2011)