Global brain dynamics are strongly dependent on the interaction of several interconnected networks that differently contribute to generating them. To improve the understanding of mechanisms that subtend physiological and pathological brain dynamics, brain networks need to be investigated at different organizational scales. Both experiments on single cells in animals and at the brain circuitry level in humans can provide important insight into the functional proprieties of the brain. Nevertheless, none of them alone can provide a full description of the physiological mechanisms of brain functioning. One of the most useful approaches to combine multi-scale experimental results is computational modeling, which aims to infer biophysical mechanisms at the basis of brain functioning by simulating the behavior of interconnected networks of neurons and microcircuits.
Novel comprehensive modeling frameworks have been developed to combine mathematical data-driven models with global brain data, thus bridging the gap between microscale, mesoscale, and macroscale. Dynamic Causal Modelling (DCM) and The Virtual Brain (TVB) are two of the most used tools, which have been developed to address the issue. The strength of these frameworks is their versatility since they can exploit the rich global information provided by several non-invasive techniques, such as MRI, EEG, MEG, or PET, in order to emulate brain dynamics either related to task execution or to basal activity.
This Research Topic includes studies aiming to integrate multi-scale experimental results and allowing an in-depth investigation of the structure-function relationships at the basis of global brain dynamics, either in physiological or pathological conditions. The scope extends from studies on humans that investigate whole-brain functions in the context of physiological states, psychiatric and neurological disorders, to translational studies in animals and to computational modeling using “low levels” simulators, such as NEST and NEURON. The potential of these studies is to provide novel information into specific pathological mechanisms, such as brain rewiring and compensatory plasticity.
We welcome authors to focus on the following (but not limited to) topics:
• Characterization of whole-brain functional dynamics using techniques such as MRI, EEG, MEG, both in physiological and pathological conditions
• Characterization of microcircuit functioning using cellular and multicellular recordings, both in physiological and pathological conditions
• Computational modeling of brain dynamics, either concerning global brain activity or the activity of specific circuits
• Application of multi-scale modeling to mesoscale or macroscale experimental data
Global brain dynamics are strongly dependent on the interaction of several interconnected networks that differently contribute to generating them. To improve the understanding of mechanisms that subtend physiological and pathological brain dynamics, brain networks need to be investigated at different organizational scales. Both experiments on single cells in animals and at the brain circuitry level in humans can provide important insight into the functional proprieties of the brain. Nevertheless, none of them alone can provide a full description of the physiological mechanisms of brain functioning. One of the most useful approaches to combine multi-scale experimental results is computational modeling, which aims to infer biophysical mechanisms at the basis of brain functioning by simulating the behavior of interconnected networks of neurons and microcircuits.
Novel comprehensive modeling frameworks have been developed to combine mathematical data-driven models with global brain data, thus bridging the gap between microscale, mesoscale, and macroscale. Dynamic Causal Modelling (DCM) and The Virtual Brain (TVB) are two of the most used tools, which have been developed to address the issue. The strength of these frameworks is their versatility since they can exploit the rich global information provided by several non-invasive techniques, such as MRI, EEG, MEG, or PET, in order to emulate brain dynamics either related to task execution or to basal activity.
This Research Topic includes studies aiming to integrate multi-scale experimental results and allowing an in-depth investigation of the structure-function relationships at the basis of global brain dynamics, either in physiological or pathological conditions. The scope extends from studies on humans that investigate whole-brain functions in the context of physiological states, psychiatric and neurological disorders, to translational studies in animals and to computational modeling using “low levels” simulators, such as NEST and NEURON. The potential of these studies is to provide novel information into specific pathological mechanisms, such as brain rewiring and compensatory plasticity.
We welcome authors to focus on the following (but not limited to) topics:
• Characterization of whole-brain functional dynamics using techniques such as MRI, EEG, MEG, both in physiological and pathological conditions
• Characterization of microcircuit functioning using cellular and multicellular recordings, both in physiological and pathological conditions
• Computational modeling of brain dynamics, either concerning global brain activity or the activity of specific circuits
• Application of multi-scale modeling to mesoscale or macroscale experimental data