Litcius/Paper detail

Long-Term Desynchronization by Coordinated Reset Stimulation in a Neural Network Model With Synaptic and Structural Plasticity

Thanos Manos, Sandra Diaz-Pier, Peter A. Tass

2021Frontiers in Physiology29 citationsDOIOpen Access PDF

Abstract

Several brain disorders are characterized by abnormal neuronal synchronization. To specifically counteract abnormal neuronal synchrony and, hence, related symptoms, coordinated reset (CR) stimulation was computationally developed. In principle, successive epochs of synchronizing and desynchronizing stimulation may reversibly move neural networks with plastic synapses back and forth between stable regimes with synchronized and desynchronized firing. Computationally derived predictions have been verified in pre-clinical and clinical studies, paving the way for novel therapies. However, as yet, computational models were not able to reproduce the clinically observed increase of desynchronizing effects of regularly administered CR stimulation intermingled by long stimulation-free epochs. We show that this clinically important phenomenon can be computationally reproduced by taking into account structural plasticity (SP), a mechanism that deletes or generates synapses in order to homeostatically adapt the firing rates of neurons to a set point-like target firing rate in the course of days to months. If we assume that CR stimulation favorably reduces the target firing rate of SP, the desynchronizing effects of CR stimulation increase after long stimulation-free epochs, in accordance with clinically observed phenomena. Our study highlights the pivotal role of stimulation- and dosing-induced modulation of homeostatic set points in therapeutic processes.

Topics & Concepts

StimulationNeuroscienceReset (finance)Homeostatic plasticityNeuroplasticitySynaptic plasticityDeep brain stimulationSynchronization (alternating current)Biological neural networkInhibitory postsynaptic potentialSpike-timing-dependent plasticitySynchronizingSet (abstract data type)BiologyMetaplasticityComputer scienceMedicineReceptorInternal medicineEconomicsFinancial economicsTelecommunicationsDiseaseProgramming languageChannel (broadcasting)Parkinson's diseaseTransmission (telecommunications)Computer networkNeuroscience and Neural EngineeringNeurological disorders and treatmentsNeural dynamics and brain function