Mechanisms of Deep Brain Stimulation in Movement Disorders as Revealed by Changes in Stimulus Frequency

Birdno, Merrill J.; Grill, Warren M.

doi:10.1016/j.nurt.2007.10.067

Cited by 119 publications

(93 citation statements)

References 87 publications

(141 reference statements)

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“…Alternatively, the model indicated that there was increased synchronization of postsynaptic TC activity at 10 Hz, and this may have contributed to the additional phases and increase in magnitude and/or duration of existing ECAP phases. Clinical symptoms are suppressed only at high DBS frequencies and low frequencies are ineffective or may lead to exacerbation (Birdno and Grill 2008), and the extent of postsynaptic synchronization may contribute to this frequency dependence.…”

Section: Discussionmentioning

confidence: 99%

“…The signal energy takes into account changes in either the magnitude or the duration of ECAP phases and may be a more robust measure of neural activation than the ECAP magnitude alone. Similarly, the energy of secondary ECAP phases may enable identification of the critical DBS frequency above which pathological firing patterns are masked and symptoms are suppressed (Birdno and Grill 2008;Kuncel et al 2007). The ECAP could also be used to distinguish between activation of presynaptic inputs or postsynaptic cells that are associated with clinical benefit or side effects.…”

Section: Discussionmentioning

confidence: 99%

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Neural origin of evoked potentials during thalamic deep brain stimulation

Kent

Grill

2013

Journal of Neurophysiology

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Kent AR, Grill WM. Neural origin of evoked potentials during thalamic deep brain stimulation. J Neurophysiol 110: 826 -843, 2013. First published May 29, 2013 doi:10.1152/jn.00074.2013.-Closedloop deep brain stimulation (DBS) systems could provide automatic adjustment of stimulation parameters and improve outcomes in the treatment of Parkinson's disease and essential tremor. The evoked compound action potential (ECAP), generated by activated neurons near the DBS electrode, may provide a suitable feedback control signal for closed-loop DBS. The objectives of this work were to characterize the ECAP across stimulation parameters and determine the neural elements contributing to the signal. We recorded ECAPs during thalamic DBS in anesthetized cats and conducted computer simulations to calculate the ECAP of a population of thalamic neurons. The experimental and computational ECAPs were similar in shape and had characteristics that were correlated across stimulation parameters (R 2 ϭ 0.80 -0.95, P Ͻ 0.002). The ECAP signal energy increased with larger DBS amplitudes (P Ͻ 0.0001) and pulse widths (P Ͻ 0.002), and the signal energy of secondary ECAP phases was larger at 10-Hz than at 100-Hz DBS (P Ͻ 0.002). The computational model indicated that these changes resulted from a greater extent of neural activation and an increased synchronization of postsynaptic thalamocortical activity, respectively. Administration of tetrodotoxin, lidocaine, or isoflurane abolished or reduced the magnitude of the experimental and computational ECAPs, glutamate receptor antagonists 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) and D(Ϫ)-2-amino-5-phosphonopentanoic acid (APV) reduced secondary ECAP phases by decreasing postsynaptic excitation, and the GABA A receptor agonist muscimol increased the latency of the secondary phases by augmenting postsynaptic hyperpolarization. This study demonstrates that the ECAP provides information about the type and extent of neural activation generated during DBS, and the ECAP may serve as a feedback control signal for closed-loop DBS. evoked compound action potential; neural recording; computational model; thalamus

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Neural origin of evoked potentials during thalamic deep brain stimulation

Kent

Grill

2013

Journal of Neurophysiology

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“…Some models of STN DBS propose that high-frequency stimulation directly inhibits an overactive STN in PD, releasing the basal-ganglia motor circuitry from inhibition [9, 10], suggesting an optimal locus of stimulation within the STN. By contrast, other models propose that high-frequency stimulation of fibers of passage in the STN region replaces pathologic signal information flow in the basal ganglia, without direct STN inhibition [11-14]. …”

Section: Introductionmentioning

confidence: 99%

Atlas-Independent, Electrophysiological Mapping of the Optimal Locus of Subthalamic Deep Brain Stimulation for the Motor Symptoms of Parkinson Disease

Conrad

Mossner

Chou

et al. 2018

Stereotact Funct Neurosurg

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Background/Aims: Deep brain stimulation (DBS) of the subthalamic nucleus (STN) improves motor symptoms of Parkinson disease (PD). However, motor outcomes can be variable, perhaps due to inconsistent positioning of the active contact relative to an unknown optimal locus of stimulation. Here, we determine the optimal locus of STN stimulation in a geometrically unconstrained, mathematically precise, and atlas-independent manner, using Unified Parkinson Disease Rating Scale (UPDRS) motor outcomes and an electrophysiological neuronal stimulation model. Methods: In 20 patients with PD, we mapped motor improvement to active electrode location, relative to the individual, directly MRI-visualized STN. Our analysis included a novel, unconstrained and computational electrical-field model of neuronal activation to estimate the optimal locus of DBS. Results: We mapped the optimal locus to a tightly defined ovoid region 0.49 mm lateral, 0.88 mm posterior, and 2.63 mm dorsal to the anatomical midpoint of the STN. On average, this locus is 11.75 lateral, 1.84 mm posterior, and 1.08 mm ventral to the mid-commissural point. Conclusion: Our novel, atlas-independent method reveals a single, ovoid optimal locus of stimulation in STN DBS for PD. The methodology, here applied to UPDRS and PD, is generalizable to atlas-independent mapping of other motor and non-motor effects of DBS.

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“…Despite all the importance placed on mechanisms, the mechanisms by which DBS affects the signs of MDs are still unknown despite decades of research using animals [239][240][241]. This is an important element in our analysis of animal models and DBS as one of the reasons animal models in general have been heralded as important, indeed vital, is for the search for mechanisms.…”

Section: Epistemology and Mechanismsmentioning

confidence: 99%

The Development of Deep Brain Stimulation for Movement Disorders

Greek¹

2012

J Clinic Res Bioeth

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The development of deep brain stimulation has revolutionized care for patients with movement disorders like Parkinson's disease. Many areas of science contributed to this technology but one area, the use of animal models, has been cited as vital. We review these claims as well as the history of the discoveries that eventually led to deep brain stimulation in an attempt to ascertain: 1) the contributions of animal models; 2) the contributions from humanbased research and observation; and the role of advances in the engineering, physics, and computer science. We distinguish between advances and discoveries that were, or at least appear to be, dependent on animal models and those where animals were involved but that could have occurred, and/or were occurring simultaneously, with humanbased research. We conclude that animal-based research played a role in defining gross anatomy in the 19 th and early 20 th centuries, but that essentially all subsequent advances were human-based or secondary to advances in the physical and applied sciences. This has historical, funding, and ethical implications as the development of deep brain stimulation is cited as an example of the importance of animal-based research and a reason for continued social and financial support of animal models in general as opposed to clinical research, other human-based research modalities, and the various disciplines of the physical and applied sciences.

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Mechanisms of Deep Brain Stimulation in Movement Disorders as Revealed by Changes in Stimulus Frequency

Cited by 119 publications

References 87 publications

Neural origin of evoked potentials during thalamic deep brain stimulation

Neural origin of evoked potentials during thalamic deep brain stimulation

Atlas-Independent, Electrophysiological Mapping of the Optimal Locus of Subthalamic Deep Brain Stimulation for the Motor Symptoms of Parkinson Disease

The Development of Deep Brain Stimulation for Movement Disorders

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