Evidence for verbal memory enhancement with electrical brain stimulation in the lateral temporal cortex

Kucewicz, Michal T.; Berry, Brent M.; Miller, Laura R.; Khadjevand, Fatemeh; Ezzyat, Youssef; Stein, Joel M.; Kremen, Václav; Brinkmann, Benjamin H.; Wanda, Paul A.; Sperling, Michael R.; Gorniak, Richard; Davis, Kathryn A.; Jobst, Barbara C.; Gross, Robert E.; Lega, Bradley; Gompel, Jamie Van; Stead, Matt; Rizzuto, Daniel S.; Kahana, Michael J.; Worrell, Gregory A.

doi:10.1093/brain/awx373

Cited by 86 publications

(81 citation statements)

References 26 publications

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“…An open and important question is whether such stimulation can be used to enhance cognitive function, and if so, whether stimulation parameters (e.g., intensity and location) can be optimized and personalized based on individual brain anatomy and physiology. While some studies demonstrate enhancements in spatial learning [39] and memory [19,38,18,37,66] following direct electrical stimulation, others show decrements [30]. Such conflicting evidence is also present in the literature surrounding other types of stimulation, including transcranial magnetic stimulation.…”

Section: Introductionmentioning

confidence: 99%

White Matter Network Architecture Guides Direct Electrical Stimulation Through Optimal State Transitions

Stiso

Khambhati

Menara

et al. 2018

Preprint

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Electrical brain stimulation is currently being investigated as a potential therapy for neurological disease. However, opportunities to optimize and personalize such therapies are challenged by the fact that the beneficial impact (and potential side effects) of focal stimulation on both neighboring and distant regions is not well understood. Here, we use network control theory to build a formal model of brain network function that makes explicit predictions about how stimulation spreads through the brain's white matter network and influences large-scale dynamics. We test these predictions using combined electrocorticography (ECoG) and diffusion weighted imaging (DWI) data from patients with medically refractory epilepsy undergoing evaluation for resective surgery, and who volunteered to participate in an extensive stimulation regimen. We posit a specific model-based manner in which white matter tracts constrain stimulation, defining its capacity to drive the brain to new states, including states associated with successful memory encoding. In a first validation of our model, we find that the true pattern of white matter tracts can be used to more accurately predict the state transitions induced by direct electrical stimulation than the artificial patterns of a topological or spatial network null model. We then use a targeted optimal control framework to solve for the optimal energy required to drive the brain to a given state. We show that, intuitively, our model predicts larger energy requirements when starting from states that are farther away from a target memory state. We then suggest testable hypotheses about which structural properties will lead to efficient stimulation for improving memory based on energy requirements. We show that the strength and homogeneity of edges between controlled and uncontrolled nodes, as well as the persistent modal controllability of the stimulated region, predict energy requirements. Our work demonstrates that individual white matter architecture plays a vital role in guiding the dynamics of direct electrical stimulation, more generally offering empirical support for the utility of network control theoretic models of brain response to stimulation.

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Section: Introductionmentioning

confidence: 99%

White Matter Network Architecture Guides Direct Electrical Stimulation Through Optimal State Transitions

Stiso

Khambhati

Menara

et al. 2018

Preprint

Self Cite

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“…Second, our results suggest a means for biologically monitoring the tuning of therapeutic electrical stimulation in the treatment of several neurological disorders (28,29), such as epilepsy (17,(30)(31)(32), sleep and memory dysfunction (33)(34)(35), brain tumors (36) and Parkinson disease (37). It has been noted empirically that the frequency of electrical stimulation is a critical determinant of outcome in treating particular neurological diseases.…”

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confidence: 99%

Programmable Modulation for Extracellular Vesicles

Wang

Melvin

Bemis

et al. 2019

Preprint

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Every living cell releases extracellular vesicles (EVs) that are critical for cellular signaling and a wide range of biological functions. The potential diagnostic and therapeutic applications of EVs are well recognized, and rapidly expanding. While a complete understanding of the molecular mechanisms underpinning EVs release remains elusive, here we demonstrate a novel method for programmable control of the release of EVs and their cargo using external electric fields. As a proof of principle, we use cultured rat astrocytes to demonstrate how the frequency of external electrical stimulation selectively modulates EV release, their surface proteins, and microRNA profiles. This method could broadly impact biological science and medical applications. First, it raises an interesting question of how endogenous electrical activity could modulate EV production. Second, it provides a novel mechanism for tuning therapeutic electrical stimulation that may be useful for treating brain disorders. Third, it provides a new way to generate EVs carrying desired cargos by tuning electrical stimulation parameters. Unlike chemical methods for creating EVs, electrical stimulation is a clean physical method with adjustable parameters including stimulation frequency, field strength and waveform morphology.

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“…In the first study of its kind, applying an integrated IEEG-fMRI method, we have shown that established markers of memory encoding correspond to meaningful network differences captured by rsfMRI. In clinical terms, knowing a region is a hub, playing an important role in multi-regional and multi-functional connectivity, may inform technologies trying to identify the most effective targets to electrically or pharmacologically stimulate for cognitive enhancement in areas such as memory Ezzyat Y et al, 2018;Kucewicz MT et al, 2018), or perhaps be used to identify the areas with sufficient influence over targets to generate effective neuro-feedback loops (Hohenfeld C et al, 2017;Murphy AC et al, 2017).…”

Section: Discussionmentioning

confidence: 99%

Tonic resting-state hubness supports high-frequency activity defined verbal-memory encoding network in epilepsy

Chaitanya

Hinds

Kragel

et al. 2019

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High-frequency gamma activity of verbal-memory encoding using invasive-electroencephalogram coupled has laid the foundation for numerous studies testing the integrity of memory in diseased populations. Yet, the functional connectivity characteristics of networks subserving these HFAmemory linkages remains uncertain. By integrating this electrophysiological biomarker of memory encoding from IEEG with resting-state BOLD fluctuations, we estimated the segregation and hubness of HFA-memory regions in drug-resistant epilepsy patients and matched healthy controls. HFA-memory regions express distinctly different hubness compared to neighboring regions in health and in epilepsy, and this hubness was more relevant than segregation in predicting verbal memory encoding. The HFA-memory network comprised regions from both the cognitive control and primary processing networks, validating that effective verbal-memory encoding requires multiple functions, and is not dominated by a central cognitive core. Our results demonstrate a tonic intrinsic set of functional connectivity, which provides the necessary conditions for effective, phasic, task-dependent memory encoding. AbbreviationsHFA -High-frequency activity MEM -Brain regions showing HFA associated with verbal-memory encoding CN -Controls Nodes P.REC -Percentage of words recalled during IEEG memory testing CVLT -California Verbal Learning Test IEEG -Invasive Electroencephalography BC -Betweenness Centrality CC-Clustering Coefficient PC -Participation Coefficient Highlights 1. High frequency memory activity in IEEG corresponds to specific BOLD changes in resting-state data.2. HFA-memory regions had lower hubness relative to control brain nodes in both epilepsy patients and healthy controls.3. HFA-memory network displayed hubness and participation (interaction) values distinct from other cognitive networks.4. HFA-memory network shared regional membership and interacted with other cognitive networks for successful memory encoding. 5. HFA-memory network hubness predicted both concurrent task (phasic) and baseline (tonic) verbal-memory encoding success.resting-state fMRI (rsfMRI) data to characterize the network architecture of a task-defined HFAmemory network and understand its relationship to the functional connectivity of a broader set of intrinsic resting-state networks. Graph theory has been a useful tool for mapping functional networks and characterizing their properties during task and at rest. Three important graph indices that are essential in characterizing brain regions and their functionality include: (1) clustering coefficient (CC), which captures network segregation and local information processing and (2) betweenness centrality (BC), which captures hubness and the degree of importance held by a region that connects two or more modules and (3) participation coefficient (PC) which measures the extent to which regions within a network connect to networks other than its own, with a higher participation coefficient indicating that the regions connect with a variety of o...

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Evidence for verbal memory enhancement with electrical brain stimulation in the lateral temporal cortex

Cited by 86 publications

References 26 publications

White Matter Network Architecture Guides Direct Electrical Stimulation Through Optimal State Transitions

White Matter Network Architecture Guides Direct Electrical Stimulation Through Optimal State Transitions

Programmable Modulation for Extracellular Vesicles

Tonic resting-state hubness supports high-frequency activity defined verbal-memory encoding network in epilepsy

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