Skip Nav Destination
Close Modal
Update search
NARROW
Format
Journal
Date
Availability
1-2 of 2
Pedro A. M. Mediano
Close
Follow your search
Access your saved searches in your account
Would you like to receive an alert when new items match your search?
Sort by
Journal Articles
Publisher: Journals Gateway
Network Neuroscience (2024) 8 (4): 1590–1612.
Published: 10 December 2024
FIGURES
| View All (5)
Abstract
View article
PDF
Different whole-brain computational models have been recently developed to investigate hypotheses related to brain mechanisms. Among these, the Dynamic Mean Field (DMF) model is particularly attractive, combining a biophysically realistic model that is scaled up via a mean-field approach and multimodal imaging data. However, an important barrier to the widespread usage of the DMF model is that current implementations are computationally expensive, supporting only simulations on brain parcellations that consider less than 100 brain regions. Here, we introduce an efficient and accessible implementation of the DMF model: the FastDMF. By leveraging analytical and numerical advances—including a novel estimation of the feedback inhibition control parameter and a Bayesian optimization algorithm—the FastDMF circumvents various computational bottlenecks of previous implementations, improving interpretability, performance, and memory use. Furthermore, these advances allow the FastDMF to increase the number of simulated regions by one order of magnitude, as confirmed by the good fit to fMRI data parcellated at 90 and 1,000 regions. These advances open the way to the widespread use of biophysically grounded whole-brain models for investigating the interplay between anatomy, function, and brain dynamics and to identify mechanistic explanations of recent results obtained from fine-grained neuroimaging recordings.
Includes: Supplementary data
Journal Articles
Publisher: Journals Gateway
Network Neuroscience (2024) 8 (4): 1032–1050.
Published: 10 December 2024
FIGURES
| View All (7)
Abstract
View article
PDF
Low-intensity transcranial ultrasound stimulation (TUS) is a noninvasive technique that safely alters neural activity, reaching deep brain areas with good spatial accuracy. We investigated the effects of TUS in macaques using a recent metric, the synergy minus redundancy rank gradient, which quantifies different kinds of neural information processing. We analyzed this high-order quantity on the fMRI data after TUS in two targets: the supplementary motor area (SMA-TUS) and the frontal polar cortex (FPC-TUS). The TUS produced specific changes at the limbic network at FPC-TUS and the motor network at SMA-TUS and altered the sensorimotor, temporal, and frontal networks in both targets, mostly consistent across macaques. Moreover, there was a reduction in the structural and functional coupling after both stimulations. Finally, the TUS changed the intrinsic high-order network topology, decreasing the modular organization of the redundancy at SMA-TUS and increasing the synergistic integration at FPC-TUS. Author Summary This article aims to elucidate how the transcranial ultrasound stimulation (TUS) could reorganize the brain as measured by the computation of redundancy and synergy. Our results showed that the TUS produced target-specific changes in the synergy minus redundancy rank gradient distribution at the limbic network at the frontal polar cortex (FPC-TUS) and the motor network at the supplementary motor area (SMA-TUS) and alterations in common, independent of the target, on the sensorimotor, temporal, and frontal networks. Moreover, the TUS changed the intrinsic high-order network topology, reducing the modular organization of the redundancy at SMA-TUS and increasing the synergistic integration at FPC-TUS.
Includes: Supplementary data