Transcranial direct current stimulation with functional magnetic resonance imaging: a detailed validation and operational guide

Nardo, Davide; Creasey, Megan; Negus, C. R.; Pappa, Katerina; Reid, Alphonso; Josephs, Oliver; Callaghan, Martina F.; Crinion, Jenny

doi:10.12688/wellcomeopenres.16679.1

Cited by 6 publications

(24 citation statements)

References 24 publications

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“…The poles and the damping parameters associated with the linearized models of the four tES perturbation pathways are listed in Table S1 in the supplementary materials. S1 in the supplementary materials show the electrical field distribution for 2mA tDCS with FC5 (anodal electrode) and FP2 (cathodal electrode) computed with the ROAST package [14] for the opensource tES-fMRI dataset [10]. Figure 5(a) shows the functional sensitivity metrics calculated using the open-source code and data from the tES-fMRI dataset [10], where anodal tDCS (figure legend: anodal) led to a shift to a higher t-score (first row of Figure 5 We also applied HRF estimation using the rsHRF toolbox [13] that elucidated the effects of anodal tDCS at four ROIs in the grey matter.…”

Section: Resultsmentioning

confidence: 99%

“…S1 in the supplementary materials show the electrical field distribution for 2mA tDCS with FC5 (anodal electrode) and FP2 (cathodal electrode) computed with the ROAST package [14] for the opensource tES-fMRI dataset [10]. Figure 5(a) shows the functional sensitivity metrics calculated using the open-source code and data from the tES-fMRI dataset [10], where anodal tDCS (figure legend: anodal) led to a shift to a higher t-score (first row of Figure 5 We also applied HRF estimation using the rsHRF toolbox [13] that elucidated the effects of anodal tDCS at four ROIs in the grey matter. Figure 5(b) shows that the canonical HRF with time & dispersion derivatives primarily captured the tES effects on the magnitude of the main response and the magnitude of undershoot.…”

Section: Resultsmentioning

confidence: 99%

“…In this study, we used the modal analysis approach to analyze the physiologically detailed NVU model for evaluating neurovascular coupling modes that may be perturbed with tACS. We also used a nonparametric impulse response estimation of the HRF from an open-source fMRI-tDCS dataset [10] and compared that with the canonical HRF to elucidate tES effects on the temporal profile of the HRF.…”

Section: Introductionmentioning

confidence: 99%

“…In contrast, in transcranial alternating current stimulation (tACS), the oscillating current reverses the flow rhythmically at a specific frequency. For example, tACS differs from tDCS in that it provides a mechanism for manipulating intrinsic oscillations through the injection of sinusoidal currents [8][9][10]. Then, the other methods are transcranial oscillating current stimulation (tOCS) which uses tDCS to set a baseline to the tACS oscillations, and transcranial random noise stimulation (tRNS) that injects 'noisy' current with bounded stochasticity [7,8].…”

Section: Introductionmentioning

confidence: 99%

“…FigureS1in the supplementary materials show the electrical field distribution for 2mA tDCS with FC5 (anodal electrode) and FP2 (cathodal electrode) computed with the ROAST package[14] for the opensource tES-fMRI dataset[10]. Figure5(a) shows the functional sensitivity metrics calculated using the open-source code and data from the tES-fMRI dataset[10], where anodal tDCS (figure legend: anodal) led to a shift to a higher t-score (first row of Figure5(a)). Here, the No-tDCS and the Sham-tDCS conditions resulted in a similar HRF temporal profile different from the anodal tDCS condition based on the canonical HRF model.…”

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confidence: 99%

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Transcranial electrical stimulation effects on neurovascular coupling

Arora

Dutta

2022

Preprint

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Transcranial electrical stimulation (tES) can exert cerebrovascular effects, but the mechanisms are unclear. Long-term (≥3min) transcranial direct current stimulation (tDCS) can also change the extracellular ion concentrations that can modulate neuronal excitability. An increase in interstitial K+ can modulate the neurovascular system's sensitivity via Kir channels in the astrocytes and the mural cells.To gain a mechanistic understanding of the tES effects on neurovascular coupling (NVC), we used a physiologically constrained multi-compartmental model (having nested pathways) for modal analysis to study the dynamic properties of the system for the output changes in blood vessel circumference and their natural frequencies in the frequency domain. Then, we used the open-source rsHRF toolbox and the functional magnetic resonance imaging (fMRI)-tDCS dataset to show the effects of anodal tDCS on hemodynamic response function (HRF) in the grey matter and at three regions of interest in the grey matter underlying anodal electrode (FC5), cathodal electrode (FP2), and an independent site remote from the electrodes (PZ). A canonical HRF model and a Finite Impulse Response (FIR) model captured the anodal tDCS effects on the temporal profile of the HRF. The modal analysis characterized the tES's vascular effects through neuronal and non-neuronal pathways, where stable modes were found for the smooth muscle cell compartment in the 0Hz-0.05Hz range.Our study showed tDCS onset effects on the neurovascular coupling (and HRF) for verum and sham tDCS conditions that were different from the no tDCS condition, which questions the validity of the placebo. Therefore, it is crucial to avoid fitting a common HRF for the whole brain, and disentangling the tES effect on the HRF is critical to the fMRI-tES studies. Future studies also need to address the trade-off between bias (in canonical HRF) and variance (in FIR HRF) that can be achieved by applying a mechanistic grey-box model.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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Transcranial electrical stimulation effects on neurovascular coupling

Arora

Dutta

2022

Preprint

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Human-In-The-Loop Optimization of Transcranial Electrical Stimulation Effects: A Computational Perspective Based on Systems Analysis

Arora¹,

Dutta²

2022

Preprint

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Individual differences in the responsiveness of the brain to transcranial electrical stimulation (tES) is increasingly demonstrated in large variability in the tES effects. Anatomically detailed computational brain models have been developed to address this variability; however, static brain models are not ‘realistic’ in accounting for the dynamic state of the brain. Therefore, human-in-the-loop optimization is proposed in this perspective article based on an extensive systems analysis of the tES neurovascular effects. First, modal analysis was conducted using a physiologically detailed neurovascular model that found stable modes in the 0 Hz to 0.05 Hz range for the pathway for vessel response through the smooth muscle cells, measured with functional near-infrared spectroscopy (fNIRS). tES effects in the 0 Hz to 0.05 Hz range can also be measured with functional magnetic resonance imaging (fMRI)-tDCS data with a maximum TR=10sec. Therefore, we investigated an open-source fMRI-tDCS dataset that used a TR=3.36sec. We found that both the anodal tDCS condition and sham tDCS condition had similar Finite Impulse Response at the region of interest underlying the anode and a remote location, which indicated a global hemodynamic effect of sham tDCS beyond the intended transient sensations. Here, transient sensations can have arousal effects on the hemodynamics so we conducted a healthy case series for black box modeling of fNIRS-pupillometry of short-duration tDCS effects. The block exogeneity test rejected the claim that tDCS is not a 1-step Granger-cause of the fNIRS total hemoglobin changes (HbT) and pupil dilation changes (p<0.05). Also, grey-box modeling using fNIRS of the tDCS effects in chronic stroke showed HbT response to be significantly different (paired-sample t-test, p<0.05) between the ipsilesional and the contralesional hemisphere for primary motor cortex tDCS and cerebellar tDCS which was subserved by the smooth muscle cells. Here, our perspective is that various physiological pathways subserving tES effects can lead to state-trait variability that can be challenging for clinical translation. Therefore, we conducted a case study on human-in-the-loop optimization using our reduced dimension model and a stochastic, derivative-free Covariance Matrix Adaptation Evolution Strategy. Future studies need to investigate human-in-the-loop optimization of tES for reducing inter-subject and intra-subject variability in tES effects.

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Perspective: Disentangling the effects of tES on neurovascular unit

Arora

Dutta

2023

Front. Neurol.

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Transcranial electrical stimulation (tES) can modulate the neurovascular unit, including the perivascular space morphology, but the mechanisms are unclear. In this perspective article, we used an open-source “rsHRF toolbox” and an open-source functional magnetic resonance imaging (fMRI) transcranial direct current stimulation (tDCS) data set to show the effects of tDCS on the temporal profile of the haemodynamic response function (HRF). We investigated the effects of tDCS in the gray matter and at three regions of interest in the gray matter, namely, the anodal electrode (FC5), cathodal electrode (FP2), and an independent site remote from the electrodes (PZ). A “canonical HRF” with time and dispersion derivatives and a finite impulse response (FIR) model with three parameters captured the effects of anodal tDCS on the temporal profile of the HRF. The FIR model showed tDCS onset effects on the temporal profile of HRF for verum and sham tDCS conditions that were different from the no tDCS condition, which questions the validity of the sham tDCS (placebo). Here, we postulated that the effects of tDCS onset on the temporal profile of HRF are subserved by the effects on neurovascular coupling. We provide our perspective based on previous work on tES effects on the neurovascular unit, including mechanistic grey-box modeling of the effects of tES on the vasculature that can facilitate model predictive control (MPC). Future studies need to investigate grey-box modeling of online effects of tES on the neurovascular unit, including perivascular space, neurometabolic coupling, and neurovascular coupling, that can facilitate MPC of the tES dose-response to address the momentary (“state”) and phenotypic (“trait”) factors.

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Transcranial direct current stimulation with functional magnetic resonance imaging: a detailed validation and operational guide

Cited by 6 publications

References 24 publications

Transcranial electrical stimulation effects on neurovascular coupling

Transcranial electrical stimulation effects on neurovascular coupling

Human-In-The-Loop Optimization of Transcranial Electrical Stimulation Effects: A Computational Perspective Based on Systems Analysis

Perspective: Disentangling the effects of tES on neurovascular unit

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