A prototype closed-loop brain–machine interface for the study and treatment of pain

Zhang, Qiaosheng; Hu, Sile; Talay, Robert; Xiao, Zhengdong; Rosenberg, David; Liu, Yaling; Sun, Guanghao; Li, Anna; Caravan, Bassir; Singh, Amrita; Gould, Jonathan Douglas; Chen, Zhe; Wang, Jing

doi:10.1038/s41551-021-00736-7

Cited by 46 publications

(33 citation statements)

References 93 publications

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“…In addition, significant progress has been made in translational application of combined optogenetics/electrophysiology techniques. For example, closed-loop BCIs based on combined optogenetics/electrophysiology can record neural activity and process it in real time for optogenetic stimulation of neural activity and has shown great promise for seizure control and peripheral neuromodulation ( Grosenick et al., 2015 ; Kuo et al., 2018 ; Mickle et al., 2019 ; Zhang et al., 2021 ). Wireless implantable devices have enabled long-lasting and high-fidelity interfaces for electrical recording and optogenetic stimulation in free-moving animals ( Gutruf and Rogers., 2018 ; Jeong et al., 2015 ; McCall et al., 2013 , 2017 ; Noh et al., 2018 ; Qazi et al., 2019 ; Shin et al., 2017 ; Zhang et al., 2019 ).…”

Section: Discussionmentioning

confidence: 99%

Multimodal neural probes for combined optogenetics and electrophysiology

Zou

Fang

2022

iScience

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Summary To understand how brain functions arise from interconnected neural networks, it is necessary to develop tools that can allow simultaneous manipulation and recording of neural activities. Multimodal neural probes, especially those that combine optogenetics with electrophysiology, provide a powerful tool for the dissection of neural circuit functions and understanding of brain diseases. In this review, we provide an overview of recent developments in multimodal neural probes. We will focus on materials and integration strategies of multimodal neural probes to achieve combined optogenetic stimulation and electrical recordings with high spatiotemporal precision and low invasiveness. In addition, we will also discuss future opportunities of multimodal neural interfaces in basic and translational neuroscience.

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Section: Discussionmentioning

confidence: 99%

Multimodal neural probes for combined optogenetics and electrophysiology

Zou

Fang

2022

iScience

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“…In addition, using a brain machine interface (BMI) can provide a quicker stimulation response. For example, in a chronic pain study that used BMI in mice to monitor and stimulate the brain, the time delay between characteristics detected and stimulation response was minimized; thus, the pain could be released even when recognizing acute pain signals ( Zhang et al, 2021 ).…”

Section: Closed Loop Transcranial Electrical Stimulationmentioning

confidence: 99%

Novel Non-invasive Transcranial Electrical Stimulation for Parkinson’s Disease

Yuan

et al. 2022

Front. Aging Neurosci.

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Conventional transcranial electrical stimulation (tES) is a non-invasive method to modulate brain activity and has been extensively used in the treatment of Parkinson’s disease (PD). Despite promising prospects, the efficacy of conventional tES in PD treatment is highly variable across different studies. Therefore, many have tried to optimize tES for an improved therapeutic efficacy by developing novel tES intervention strategies. Until now, these novel clinical interventions have not been discussed or reviewed in the context of PD therapy. In this review, we focused on the efficacy of these novel strategies in PD mitigation, classified them into three categories based on their distinct technical approach to circumvent conventional tES problems. The first category has novel stimulation modes to target different modulating mechanisms, expanding the rang of stimulation choices hence enabling the ability to modulate complex brain circuit or functional networks. The second category applies tES as a supplementary intervention for PD hence amplifies neurological or behavioral improvements. Lastly, the closed loop tES stimulation can provide self-adaptive individualized stimulation, which enables a more specialized intervention. In summary, these novel tES have validated potential in both alleviating PD symptoms and improving understanding of the pathophysiological mechanisms of PD. However, to assure wide clinical used of tES therapy for PD patients, further large-scale trials are required.

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“…operation of the interface. The BMI seeks to disrupt ongoing network excitation or inhibition (e.g., seizure control or optogenetic control; Bere ´nyi et al, 2012;Paz et al, 2013;Grosenick et al, 2015) and/or shape neural plasticity (e.g., mood regulation; Zhang et al, 2021;Shanechi, 2019). In contrast, user feedback BMIs (e.g., visual and motor prostheses) depend on how the user learns to use the interface (Carmena et al, 2003;Koralek et al, 2012;Shenoy and Carmena, 2014).…”

Section: Box 1 Correlation Matrix Estimationmentioning

confidence: 99%

“…Development of scalable methods for decoding arm or hand movement or assessing neural population dynamics can greatly advance the research field in motor control (Trautmann et al, 2019;Sussillo et al, 2016). The key component of BMIs is the feedback, as a form of neurostimulations (Bere ´nyi et al, 2012;Paz et al, 2013;Grosenick et al, 2015;Zhang et al, 2021), user-defined feedback control (Figure 2G; Carmena et al, 2003;Dangi et al, 2013;Shanechi et al, 2016), or the prediction error of neural responses (Figure 2H; Tafazoli et al, 2020), which can be further used to perturb the circuit or causally change the behavior. Finally, the time window of closed-loop feedback is critical, as it allows interaction with neurons and circuits differently.…”

Section: Speeding Up Neural Data Analysismentioning

confidence: 99%

“…In this perspective, we discuss how jointly scaling up data acquisition and data analysis in an active and adaptive manner can speed up the cycle and enable AACL experiments. We first review scalability in neurotechnology and instrumentation, (Lewi et al, 2009(Lewi et al, , 2011, adaptive stimulus optimization (Walker et al, 2019;Ponce et al, 2019), neurally defined stimulation (Bere ´nyi et al, 2012;Paz et al, 2013;Grosenick et al, 2015;Zhang et al, 2021), closed-loop decoder adaptation (Dangi et al, 2013), user-defined control or prosthetics (Carmena et al, 2003;Shanechi et al, 2016), or adaptive closed-loop neurostimulation (Tafazoli et al, 2020). (B) Schematic of adaptive stimulus optimization on the basis of BMI with neural decoder adaptation.…”

Section: Introductionmentioning

confidence: 99%

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