Biomarkers and Stimulation Algorithms for Adaptive Brain Stimulation

Hoang, Kevin; Cassar, Isaac R.; Grill, Warren M.; Turner, Dennis A.

doi:10.3389/fnins.2017.00564

Cited by 69 publications

(89 citation statements)

References 154 publications

(239 reference statements)

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“…The electrical excitability of neural tissue around the electrode and the effects of stimulation are determined by several factors: (i) the proportion of gray and white matter structures (i.e., cell bodies or axons; Nowak & Bullier, ; Ranck, ; Dostrovsky & Lozano, ; Udupa & Chen, ); (ii) the type of ion channels on the cell membrane of a soma or axon (Hoang et al , ); (iii) the diameter and degree of myelination of axons (Ranck, ; Nowak & Bullier, ; Gubellini et al , ; Carron et al , ); (iv) the orientation of axons in relation to the electrode (Ranck, ; Gubellini et al , ); (v) the distance of the stimulated structure to the electrode (Deniau et al , ); and (vi) the microenvironment (astrocytes and microglia; Song et al , ; Reddy & Lozano, ).…”

Section: Electrical Effects At the Stimulation Targetmentioning

confidence: 99%

“…Thus, the current hypothesis of basal ganglia networks in PD is that the overall output to the thalamus and motor cortex is decreased and the circuit is caught in a hyper‐synchronized oscillatory state of entropy (Dorval et al , ; Anderson et al , ; Hoang et al , ). The efferent motor synapses of the STN during DBS are hypothesized to be depleted of their neurotransmitters and thereby filter low‐frequency oscillations (McIntyre & Anderson, ).…”

Section: Electrical Effects In the Neuronal Networkmentioning

confidence: 99%

“…The efferent motor synapses of the STN during DBS are hypothesized to be depleted of their neurotransmitters and thereby filter low‐frequency oscillations (McIntyre & Anderson, ). Low‐frequency DBS (20 Hz) appears to increase the amount of synchronization, whereas high‐frequency DBS (> 70 Hz) suppresses such activity in the GPi (Brown et al , ), similar to the administration of levodopa (Dorval et al , ; Hoang et al , ).…”

Section: Electrical Effects In the Neuronal Networkmentioning

confidence: 99%

See 2 more Smart Citations

Cellular, molecular, and clinical mechanisms of action of deep brain stimulation—a systematic review on established indications and outlook on future developments

et al. 2019

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Deep brain stimulation ( DBS ) has been successfully used to treat movement disorders, such as Parkinson's disease, for more than 25 years and heralded the advent of electrical neuromodulation to treat diseases with dysregulated neuronal circuits. DBS is now superseding ablative techniques, such as stereotactic radiofrequency lesions. While serendipity has played a role in developing DBS as a therapy, research during the past two decades has shown that electrical neuromodulation is far more than a functional lesion that can be switched on and off. This understanding broadens the field to enable new types of stimulation, clinical indications, and research. This review highlights the complex effects of DBS from the single cell to the neuronal network. Specifically, we examine the electrical, cellular, molecular, and neurochemical mechanisms of DBS as applied to Parkinson's disease and other emerging applications.

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Section: Electrical Effects At the Stimulation Targetmentioning

confidence: 99%

Section: Electrical Effects In the Neuronal Networkmentioning

confidence: 99%

Section: Electrical Effects In the Neuronal Networkmentioning

confidence: 99%

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Cellular, molecular, and clinical mechanisms of action of deep brain stimulation—a systematic review on established indications and outlook on future developments

et al. 2019

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“…Interestingly, not only parkinsonian bradykinesia/ rigidity but also dopaminergic side effects are reflected in subthalamic LFP patterns, where dyskinesia symptoms were associated with increased low frequency (4-8 Hz) and narrowband gamma (60-90 Hz) synchronization [90,91], very similar to the activity seen during normal movement [53,62,92,93]. Moreover, additional pathophysiological hallmarks have been identified in PD and recent research suggests that indeed these different biomarkers may signal different aspects of parkinsonian motor signs [50]. The second most prominent LFP biomarker associated with parkinsonism is the presence of so-called high-frequency oscillations (HFO) at~250 Hz, which are not generally attenuated by dopaminergic medication, but rather are shifted toward higher frequencies to3 50 Hz [61,94].…”

Section: Beyond Beta Activity In Parkinson's Diseasementioning

confidence: 92%

“…Similarly, subthalamic DBS was demonstrated to suppress beta activity locally [43][44][45][46] and, again, the amount of suppression of local beta activity was correlated with improvement in parkinsonian motor signs [43,47]. The finding that a biomarker of concurrent parkinsonian motor sign severity can be recorded in real-time through the same electrodes that deliver the therapeutic stimulation has inspired the concept of a demand-dependent adaptive DBS paradigm [48], where the stimulation parameters are adapted directly according to the recorded electrophysiological parkinsonian symptom correlate, closing the loop from recording to stimulation [49,50]. Importantly, the presence of beta synchronization in the basal ganglia should not be mistaken as PD specific or pathological per se, as studies from other DBS patient groups, such as dystonia [51][52][53] and OCD [54][55][56], have reported peaks of beta activity in the basal ganglia.…”

Section: Pathophysiological Neural Activity In Dbs Patients With Parkmentioning

confidence: 99%

Toward Electrophysiology-Based Intelligent Adaptive Deep Brain Stimulation for Movement Disorders

et al. 2019

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Deep brain stimulation (DBS) represents one of the major clinical breakthroughs in the age of translational neuroscience. In 1987, Benabid and colleagues demonstrated that high-frequency stimulation can mimic the effects of ablative neurosurgery in Parkinson's disease (PD), while offering two key advantages to previous procedures: adjustability and reversibility. Deep brain stimulation is now an established therapeutic approach that robustly alleviates symptoms in patients with movement disorders, such as Parkinson's disease, essential tremor, and dystonia, who present with inadequate or adverse responses to medication. Currently, stimulation electrodes are implanted in specific target regions of the basal ganglia-thalamic circuit and stimulation pulses are delivered chronically. To achieve optimal therapeutic effect, stimulation frequency, amplitude, and pulse width must be adjusted on a patient-specific basis by a movement disorders specialist. The finding that pathological neural activity can be sampled directly from the target region using the DBS electrode has inspired a novel DBS paradigm: closed-loop adaptive DBS (aDBS). The goal of this strategy is to identify pathological and physiologically normal patterns of neuronal activity that can be used to adapt stimulation parameters to the concurrent therapeutic demand. This review will give detailed insight into potential biomarkers and discuss next-generation strategies, implementing advances in artificial intelligence, to further elevate the therapeutic potential of DBS by capitalizing on its modifiable nature. Development of intelligent aDBS, with an ability to deliver highly personalized treatment regimens and to create symptom-specific therapeutic strategies in real-time, could allow for significant further improvements in the quality of life for movement disorders patients with DBS that ultimately could outperform traditional drug treatment.

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Monitoring stimulus‐evoked hemodynamic response during deep brain stimulation with single fiber spectroscopy

Noor

Kiss

et al. 2022

Journal of Biophotonics

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Deep brain stimulation (DBS) is a revolutionary treatment for movement disorders. Measuring DBSinduced hemodynamic responses may be useful for surgical guidance of DBS electrode implantation as well as to study the mechanism and assess therapeutic effects of DBS.In this study, we evaluated the performance of a single fiber spectroscopic (SFS) system for measuring hemodynamic response in different cortical layers in a DBS animal model. We showed that SFS is capable of measuring minute relative changes in oxygen saturation and blood volume fraction in-vivo at a sampling rate of 22-33 Hz. During stimulation, blood volume fraction increased, while oxygen saturation showed both increases and decreases at different cortical depths across animals. In addition, we showed the potential of using SFS for measuring other physiological parameters, for example, heart rate, and respiratory rate.

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Biomarkers and Stimulation Algorithms for Adaptive Brain Stimulation

Cited by 69 publications

References 154 publications

Cellular, molecular, and clinical mechanisms of action of deep brain stimulation—a systematic review on established indications and outlook on future developments

Cellular, molecular, and clinical mechanisms of action of deep brain stimulation—a systematic review on established indications and outlook on future developments

Toward Electrophysiology-Based Intelligent Adaptive Deep Brain Stimulation for Movement Disorders

Monitoring stimulus‐evoked hemodynamic response during deep brain stimulation with single fiber spectroscopy

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