Neural diffusivity and pre-emptive epileptic seizure intervention.

Erik D Fagerholm,David W Carmichael,Robert Leech,Steven Williams,Karl J Friston,Mark P Richardson,Suejen Perani,Federico E Turkheimer,Chayanin Tangwiriyasakul,Rosalyn J Moran,Inês R Violante,Daniele Marinazzo

doi:10.1371/journal.pcbi.1008448

Abstract

The propagation of epileptic seizure activity in the brain is a widespread pathophysiology that, in principle, should yield to intervention techniques guided by mathematical models of neuronal ensemble dynamics. During a seizure, neural activity will deviate from its current dynamical regime to one in which there are significant signal fluctuations. In silico treatments of neural activity are an important tool for the understanding of how the healthy brain can maintain stability, as well as of how pathology can lead to seizures. The hope is that, contained within the mathematical foundations of such treatments, there lie potential strategies for mitigating instabilities, e.g. via external stimulation. Here, we demonstrate that the dynamic causal modelling neuronal state equation generalises to a Fokker-Planck formalism if one extends the framework to model the ways in which activity propagates along the structural connections of neural systems. Using the Jacobian of this generalised state equation, we show that an initially unstable system can be rendered stable via a reduction in diffusivity–i.e., by lowering the rate at which neuronal fluctuations disperse to neighbouring regions. We show, for neural systems prone to epileptic seizures, that such a reduction in diffusivity can be achieved via external stimulation. Specifically, we show that this stimulation should be applied in such a way as to temporarily mirror the activity profile of a pathological region in its functionally connected areas. This counter-intuitive method is intended to be used pre-emptively–i.e., in order to mitigate the effects of the seizure, or ideally even prevent it from occurring in the first place. We offer proof of principle using simulations based on functional neuroimaging data collected from patients with idiopathic generalised epilepsy, in which we successfully suppress pathological activity in a distinct sub-network prior to seizure onset. Our hope is that this technique can form the basis for future real-time monitoring and intervention devices that are capable of treating epilepsy in a non-invasive manner.

Highlights

There is ongoing interest in using stimulation techniques [1,2,3] to treat epilepsy by directly modifying the physiological states of neural systems [4,5]
Epilepsy is a disease that affects over 50 million people worldwide
We are proposing an innovative treatment of epilepsy that could be achieved by using non-invasive electrical stimulation

Summary

Introduction

There is ongoing interest in using stimulation techniques [1,2,3] to treat epilepsy by directly modifying the physiological states of neural systems [4,5]. There is a pressing need for computational frameworks that are able to model the effects of external stimulation and to guide the development of optimal intervention protocols. Several mathematical models have been put forward to describe the phenomenology of seizure initiation [9] and to predict neurosurgical outcome [10,11], primarily using electroencephalography (EEG) and electrocorticography (ECoG) in patients with focal epilepsy. We propose a novel approach for pre-emptive seizure intervention, based on the computational framework of dynamic causal modelling (DCM) [12] and tested with a combination of EEG and functional magnetic resonance imaging (fMRI) data in patients with idiopathic generalised epilepsy (IGE). We show that the neuronal state equation can be generalised to account for the ways in which signals change– with respect to time–and with respect to the structure of the network within which the signals are constrained to propagate

Methods

Results

Discussion

Conclusion