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ref: -0 tags: polyimide platinum electrodes Spain longitudinal intrafasicular adhesion delamination date: 10-05-2013 22:24 gmt revision:4 [3] [2] [1] [0] [head]

PMID-17278585 Assessment of biocompatibility of chronically implanted polyimide and platinum intrafascicular electrodes. 2007

  • Designed platinum/polyimide longitudinal intrafasicular electrodes (LIFEs)
    • 25um PT/Ir, insulated to 60-75um diameter. PT/IR has a young's modulus of 202 Gpa.
      • Plated with platinum black under sonication, as this forms a tougher surface than without sonication.
      • See also: PMID-20485478 Improving impedance of implantable microwire multi-electrode arrays by ultrasonic electroplating of durable platinum black. Desai SA, Rolston JD, Guo L, Potter SM. 2010
    • Polyimide PI2611, 10um thick, 50mm long, 220um wide in the electrode segment.
  • Implanted into rat sciatic nerve for 3 months.
  • These electrodes have been tested in people for two days:
    • Electrical stimulation through the implanted electrodes elicited graded sensations of touch, joint movement, and position, referring to the missing limb. This suggested that peripheral nerve interfaces could be used to provide amputees with prosthetic limbs with sensory feedback and volitional control that is more natural than what is possible with current myoelectric and body-powered prostheses.
  • CMAPs = compound muscle action potentials.
  • CNAPs = compound nerve action potentials.
  • Platinum wire LIFE performed very similarly to the thin-film polyimide LIFE in most all tests, with slightly higher potentials recorded by the larger polyimide probe.
  • 'Higher encapsulation with the polyimide probes! Geometry?
  • However, the polyimide LIFEs induced less functional decline than the wire LIFEs.
  • Other polyimide studies [14] [16] [24] -- one of which they observed a 70% reduction of tensile strength after 11 months of implantation.
    • [14] F. J. Rodríguez, D. Ceballos, M. Schüttler, E. Valderrama, T. Stieglitz, and X. Navarro, “Polyimide cuff electrodes for peripheral nerve stimulation,” J. Neurosci. Meth., vol. 98, pp. 105–118, 2000.
    • [16] N. Lago, D. Ceballos, F. J. Rodríguez, T. Stieglitz, and X. Navarro, “Long term assessment of axonal regeneration through polyimide regenerative electrodes to interface the peripheral nerve,” Biomaterials, vol. 26, pp. 2021–2031, 2005.
    • [24] M. Schuettler, K. P. Koch, and T. Stieglitz, “Investigations on explanted micromachined nerve electrodes,” in Proc. 8th Annu. Int. Conf. Int. Functional Electrical Stimulation Soc., Maroochydore, Australia, 2003, pp. 306–310.
      • The technology of sandwiching a metallization layer between two layers of polyimide seems to be suitable, because no delamination of the polyimide layers was observed even after 11 months. The right choice of metals for building the electrical conductive elements of the microelectrodes is crucial. Ti/Au/Ti/Pt layers tend to flake off from polyimide while delamination of Ti/Pt layers was not observed. However, adhesion of Ti/Pt layers was investigated after 2.5 months of implantation while Ti/Au/Ti/Pt layers were exposed after 11 months to the biological system. In previous research projects, surgeons also reported on delamination of Ti/Au layers from polyimide substrate after three months. Unfortunately, we had no possibility of inspecting these microelectrodes in our laboratory.
      • See also {1250}