Repeated voltage biasing improves unit recordings by reducing resistive tissue impedances

Johnson, Matthew D.; Otto, Kevin J.; Kipke, Daryl R.

doi:10.1109/tnsre.2005.847373

Cited by 117 publications

(124 citation statements)

References 25 publications

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“…This effect only occurred in vivo, as they were unable to duplicate these results with an electrode in a saline bath. These results could be explained by work from Johnson et al (Johnson et al, 2005) who found that the most substantial and consistent impedance change came from protein adsorption and the cellular layers surrounding the electrode. In turn, stimulation through a given contact can modify the tissue microstructure of the local encapsulation, increasing conductivity and decreasing electrode impedance.…”

Section: Discussionmentioning

confidence: 89%

“…Encapsulation is the final stage of the foreign body reaction, wherein the body attempts to destroy or isolate any non-native substance. The tissue response includes both an early antiinflammatory response due to insertion trauma and a sustained response induced in part by the interplay among micromotion, tethering, and device biocompatibility (Johnson et al, 2005). Prior studies have indicated that encapsulation thickness around the DBS electrode lead is at least 25 μm and no greater than 1 mm (Haberler et al, 2000;Hemm et al, 2004).…”

Section: Discussionmentioning

confidence: 99%

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Sources and effects of electrode impedance during deep brain stimulation

Butson

Maks

McIntyre

2006

Clinical Neurophysiology

313

278

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Objective-Clinical impedance measurements for deep brain stimulation (DBS) electrodes in human patients are normally in the range 500-1500 Ω. DBS devices utilize voltage-controlled stimulation; therefore, the current delivered to the tissue is inversely proportional to the impedance. The goals of this study were to evaluate the effects of various electrical properties of the tissue medium and electrode-tissue interface on the impedance and to determine the impact of clinically relevant impedance variability on the volume of tissue activated (VTA) during DBS.Methods-Axisymmetric finite-element models (FEM) of the DBS system were constructed with explicit representation of encapsulation layers around the electrode and implanted pulse generator. Impedance was calculated by dividing the stimulation voltage by the integrated current density along the active electrode contact. The models utilized a Fourier FEM solver that accounted for the capacitive components of the electrode-tissue interface during voltagecontrolled stimulation. The resulting time-and space-dependent voltage waveforms generated in the tissue medium were superimposed onto cable model axons to calculate the VTA.Results-The primary determinants of electrode impedance were the thickness and conductivity of the encapsulation layer around the electrode contact and the conductivity of the bulk tissue medium. The difference in the VTA between our low (790 Ω) and high (1244 Ω) impedance models with typical DBS settings (−3 V, 90 μs, 130 Hz pulse train) was 121 mm 3 , representing a 52% volume reduction.Conclusions-Electrode impedance has a substantial effect on the VTA and accurate representation of electrode impedance should be an explicit component of computational models of voltage-controlled DBS.Significance-Impedance is often used to identify broken leads (for values >2000 Ω) or short circuits in the hardware (for values <50 Ω); however, clinical impedance values also represent an important parameter in defining the spread of stimulation during DBS.

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Section: Discussionmentioning

confidence: 89%

Section: Discussionmentioning

confidence: 99%

Sources and effects of electrode impedance during deep brain stimulation

Butson

Maks

McIntyre

2006

Clinical Neurophysiology

313

278

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“…These requirements would seem to suggest the use of a single microelectrode as a reference, instead of an unmatched larger electrode. Unfortunately, because of the small size of a microelectrode, coupled with fibrous encapsulation endemic to long-term cortical implants (Edell et al 1992;Johnson et al 2005;Ludwig et al 2006;Polikov et al 2005;Schmidt et al 1993;Szarowski et al 2003;Turner et al 1999;Vetter et al 2004;Williams et al 1999;Xindong et al 1999), the impedance of a microelectrode reference adds significant uncorrelated thermal noise to cortical recordings (Kovacs 1994;Schmidt and Humphrey 1990;Shoham and Nagarajan 2003;Webster 1998). Moreover, the microelectrode reference could potentially register neural signal as well as uncorrelated biological noise-adding both to neural recordings.…”

Section: Discussionmentioning

confidence: 99%

Using a Common Average Reference to Improve Cortical Neuron Recordings From Microelectrode Arrays

Ludwig

Miriani

Langhals³

et al. 2009

Journal of Neurophysiology

368

279

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“…Hence, several different approaches have been proposed, including chemical and physical modification of the surface sensing area [50,54], scaling of the sensor size to make the implant less invasive [55], development of more soft, flexible and conformable materials [27,56] and implementation of a rejuvenation protocol to prolong the implant life time [57,58].…”

Section: Long Term Stabilitymentioning

confidence: 99%

Flexible and Organic Neural Interfaces: A Review

Lago

Cester

2017

Applied Sciences

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Featured Application: Authors are encouraged to provide a concise description of the specific application or a potential application of the work. This section is not mandatory.Abstract: Neural interfaces are a fundamental tool to interact with neurons and to study neural networks by transducing cellular signals into electronics signals and vice versa. State-of-the-art technologies allow both in vivo and in vitro recording of neural activity. However, they are mainly made of stiff inorganic materials that can limit the long-term stability of the implant due to infection and/or glial scars formation. In the last decade, organic electronics is digging its way in the field of bioelectronics and researchers started to develop neural interfaces based on organic semiconductors, creating more flexible and conformable neural interfaces that can be intrinsically biocompatible. In this manuscript, we are going to review the latest achievements in flexible and organic neural interfaces for the recording of neuronal activity.

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Repeated voltage biasing improves unit recordings by reducing resistive tissue impedances

Cited by 117 publications

References 25 publications

Sources and effects of electrode impedance during deep brain stimulation

Sources and effects of electrode impedance during deep brain stimulation

Using a Common Average Reference to Improve Cortical Neuron Recordings From Microelectrode Arrays

Flexible and Organic Neural Interfaces: A Review

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