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{1396}
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ref: -0 tags: rogers thermal oxide barrier neural implants ECoG coating accelerated lifetime test date: 12-28-2017 02:29 gmt revision:0 [head]

PMID-27791052 Ultrathin, transferred layers of thermally grown silicon dioxide as biofluid barriers for biointegrated flexible electronic systems

  • Thermal oxide proved the superior -- by far -- water barrier for encapsulation.
    • What about the edges?
  • Many of the polymer barrier layers look like inward-rectifiers:
  • Extensive simulations showing that the failure mode is from gradual dissolution of the SiO2 -> Si(OH)4.
    • Even then a 100nm layer is expected to last years.
    • Perhaps the same principle could be applied with barrier metals. Anodization or thermal oxidation to create a thick, nonporous passivation layer.
    • Should be possible with Al, Ta...

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ref: Leung-2008.08 tags: biocompatibility alginate tissue response immunochemistry microglia insulation spin coating Tresco recording histology MEA date: 01-28-2013 21:19 gmt revision:4 [3] [2] [1] [0] [head]

PMID-18485471[0] Characterization of microglial attachment and cytokine release on biomaterials of differing surface chemistry

  • The important result is that materials with low protein-binding (e.g. alginate) have fewer bound microglia, hence better biocompatibility. It also seems to help if the material is highly hydrophilic.
    • Yes alginate is made from algae.
  • Used Michigan probes for implantation.
  • ED1 = pan-macrophage marker.
    • (quote:) Quantification of cells on the surface indicated that the number of adherent microglia appeared higher on the smooth side of the electrode compared to the grooved, recording site side (Fig. 2B), and declined with time. However, at no point were electrodes completely free of attached and activated microglial cells nor did these cells disappear from the interfacial zone along the electrode tract.
    • but these were not coated with anything new .. ???

____References____

[0] Leung BK, Biran R, Underwood CJ, Tresco PA, Characterization of microglial attachment and cytokine release on biomaterials of differing surface chemistry.Biomaterials 29:23, 3289-97 (2008 Aug)

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ref: -0 tags: histology review electrode response bioactive coatings date: 01-28-2013 20:16 gmt revision:0 [head]

PMID-20577634 Biocompatibility of intracortical microelectrodes: current status and future prospects.

  • ... but the most widely used method to enhance biocompatibility is the chemical modification of neural probe surfaces with anti-inflammatory compounds, adhesion proteins, or bioactive molecules (Heiduschka and Thanos, 1998; He et al., 2006; Ludwig et al., 2006; Moxon et al., 2007; Rennaker et al., 2007; Seymour and Kipke, 2007; Zhong and Bellamkonda, 2007; Leung et al., 2008; Williams, 2008; Grill et al., 2009)
    • Have any of these achieved success?
    • Many other polymers are basically biocompatible, provided they still insulate after equilibriating with the surrounding vapor pressure.
    • Personally I don't think biocoatings wil lmatter much if there is persistent shear at the interface.
  • Does make sense to have the electrode surface attractive to neurons (Kennedy..). For a later date.

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ref: -0 tags: mesh silk conformal coating date: 02-21-2012 20:03 gmt revision:0 [head]

PMID-20400953 Dissolvable films of silk fibroin for ultrathin conformal bio-integrated electronics.

  • Mounting such devices on tissue and then allowing the silk to dissolve and resorb initiates a spontaneous, conformal wrapping process driven by capillary forces at the biotic/abiotic interface.
  • Specialized mesh designs and ultrathin forms for the electronics ensure minimal stresses on the tissue and highly conformal coverage, even for complex curvilinear surfaces, as confirmed by experimental and theoretical studies.
    • Wow! cool!
  • polyimide electrode substrates 2.5 - 7.5 um thick. Electrodes were made of anisotropic conductive film.