Complex impedance spectroscopy for monitoring tissue responses to inserted neural implants

Williams, Justin; Hippensteel, Joseph A.; Dilgen, J.; Shain, William; Kipke, Daryl R.

doi:10.1088/1741-2560/4/4/007

Cited by 358 publications

(388 citation statements)

References 41 publications

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“…Impedance spectroscopy in a frequency range of 10 Hz-10 kHz (Figure 4, and Supplementary Fig. S3) showed that PC/COC/CPE fiber probes exhibit slightly decreasing impedance values of 1.3-2.8 ± 0.4 MΩ (for 10 mm) and 2-6 ± 2 MΩ (for 50 mm) at 10-1000 Hz (the frequency range most useful for recording of neuronal activity), which lies within the range commonly cited for neural probes [29,39,40] .…”

Section: Resultssupporting

confidence: 63%

Polymer Fiber Probes Enable Optical Control of Spinal Cord and Muscle Function In Vivo

Froriep

Koppes

et al. 2014

Adv Funct Materials

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Restoration of motor and sensory functions in paralyzed patients requires the development of tools for simultaneous recording and stimulation of neural activity in the spinal cord. In addition to its complex neurophysiology, the spinal cord presents technical challenges stemming from its flexible fibrous structure and repeated elastic deformation during normal motion. To address these engineering constraints, we developed highly flexible fiber probes, consisting entirely of polymers, for combined optical stimulation and recording of neural activity. The fabricated fiber probes exhibit low-loss light transmission even under repeated extreme bending deformations.Using our fiber probes, we demonstrate simultaneous recording and optogenetic stimulation of neural activity in the spinal cord of transgenic mice expressing the light sensitive protein channelrhodopsin 2 (ChR2). Furthermore, optical stimulation of the spinal cord with the polymer fiber probes induces on-demand limb movements that correlate with electromyographical (EMG) activity.

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Section: Resultssupporting

confidence: 63%

Polymer Fiber Probes Enable Optical Control of Spinal Cord and Muscle Function In Vivo

Froriep

Koppes

et al. 2014

Adv Funct Materials

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“…They are fabricated with silicon or titanium. They may comprise a single needle bearing multiple contacts on its shaft [20,39] or a 10 9 10 matrix of single contact electrodes [19,36]. Successful penetrating electrodes are already available to humans, e.g., cochlear implants [40] and deep brain stimulator [10,17].…”

Section: Introductionmentioning

confidence: 99%

Flexible and stretchable micro-electrodes for in vitro and in vivo neural interfaces

Lacour

Benmerah

Tarte

et al. 2010

Med Biol Eng Comput

234

174

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Microelectrode arrays (MEAs) are designed to monitor and/or stimulate extracellularly neuronal activity. However, the biomechanical and structural mismatch between current MEAs and neural tissues remains a challenge for neural interfaces. This article describes a material strategy to prepare neural electrodes with improved mechanical compliance that relies on thin metal film electrodes embedded in polymeric substrates. The electrode impedance of micro-electrodes on polymer is comparable to that of MEA on glass substrates. Furthermore, MEAs on plastic can be flexed and rolled offering improved structural interface with brain and nerves in vivo.MEAs on elastomer can be stretched reversibly and provide in vitro unique platforms to simultaneously investigate the electrophysiological of neural cells and tissues to mechanical stimulation. Adding mechanical compliance to MEAs is a promising vehicle for robust and reliable neural interfaces.

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“…Once an electrode is implanted it will be treated as a foreign material by the body, but the material should not impact the immune system dramatically (Polikov et al, 2005). This kind of response would reduce the electrode charge delivery capacity and recording sensitivity (Williams et al, 2007). Biocompatibility of CNTs is highly dependent on their mode of production, size, purification chemical functionalization, dose, and type of administration (systemic etc) (Ciofani et al, 2010;Nayagam et al, 2011).…”

Section: Biocompatibiltymentioning

confidence: 99%

Implantable Electrodes with Carbon Nanotube Coatings

Minnikanti¹,

Peixoto²

2011

Carbon Nanotubes Applications on Electron Devices

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Complex impedance spectroscopy for monitoring tissue responses to inserted neural implants

Cited by 358 publications

References 41 publications

Polymer Fiber Probes Enable Optical Control of Spinal Cord and Muscle Function In Vivo

Polymer Fiber Probes Enable Optical Control of Spinal Cord and Muscle Function In Vivo

Flexible and stretchable micro-electrodes for in vitro and in vivo neural interfaces

Implantable Electrodes with Carbon Nanotube Coatings

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