From Functional Brain Models to Imaging Data
Lead Research Organisation:
University of Leeds
Department Name: Sch of Computing
Abstract
Neural circuits will be modeled with population density methods. In general, neural circuits are complex and unwieldy, due to the large number of parameters that need to be chosen only a few of which can be determined experimentally. Since the complex of individual neurons can be highly complex already, understanding neural circuits that are comprised by tens of thousands of neurons is difficult. Population density methods reduce the problem in two ways: the individual neural model is reduced to two dimensions, and neural circuits are reduced to populations. Modelling neural circuits as two-dimensional dynamical systems subject to noise simplifies the description considerably, but allows for enough flexibility to capture the rich dynamics demonstrated by more biophysically motivated models.
We will make large-scale models of neural circuits, in cortex and in spinal cord. In cortex, we will contribute to simulations in an existing simulator, The Virtual Brain, which is currently used to find explanations for epileptic seizures. We will add simulations that model the neural state, and not just the observed electrophysiological signal. In spinal cord, we will model the neural circuits that form a Central Pattern Generator and the feedback loops to and from muscles, with the aim of explaining observed EMG signals (Chakarbarty lab, FBS, Leeds). Ultimately, we hope to be able to model disturbed function of the spinal cord, e.g. cerebral palsy, and help to explore strategies to alleviate these conditions, informed by our models.
The project will entail part theoretical development of population level modeling, part development of novel numerical strategies to create simulation techniques, part simulation. Our approach falls broadly under the 'Healthcare Technologies theme, and specifically addresses mathematical biology and non-linear sciences.
The research will also be carried out in alignment with the theory group SP4 of the Human Brain Project, as part of the sub-task bridging scales. The supervisor is PI in this project. One PhD student will be funded by that project and will also work on the development of the theory of simulating neural populations. The implications for this project are substantial networking and dissemination opportunities, and a strengthening of the local group of which Hugh is a part.
We will make large-scale models of neural circuits, in cortex and in spinal cord. In cortex, we will contribute to simulations in an existing simulator, The Virtual Brain, which is currently used to find explanations for epileptic seizures. We will add simulations that model the neural state, and not just the observed electrophysiological signal. In spinal cord, we will model the neural circuits that form a Central Pattern Generator and the feedback loops to and from muscles, with the aim of explaining observed EMG signals (Chakarbarty lab, FBS, Leeds). Ultimately, we hope to be able to model disturbed function of the spinal cord, e.g. cerebral palsy, and help to explore strategies to alleviate these conditions, informed by our models.
The project will entail part theoretical development of population level modeling, part development of novel numerical strategies to create simulation techniques, part simulation. Our approach falls broadly under the 'Healthcare Technologies theme, and specifically addresses mathematical biology and non-linear sciences.
The research will also be carried out in alignment with the theory group SP4 of the Human Brain Project, as part of the sub-task bridging scales. The supervisor is PI in this project. One PhD student will be funded by that project and will also work on the development of the theory of simulating neural populations. The implications for this project are substantial networking and dissemination opportunities, and a strengthening of the local group of which Hugh is a part.
Organisations
People |
ORCID iD |
| Marc De Kamps (Primary Supervisor) | |
| Hugh Osborne (Student) |
Publications
Osborne H
(2021)
MIIND : A Model-Agnostic Simulator of Neural Populations.
in Frontiers in neuroinformatics
Studentship Projects
| Project Reference | Relationship | Related To | Start | End | Student Name |
|---|---|---|---|---|---|
| EP/N509681/1 | 01/10/2016 | 30/09/2021 | |||
| 2042636 | Studentship | EP/N509681/1 | 01/10/2017 | 30/09/2021 | Hugh Osborne |
| Description | MIIND is a software package for simulating interacting populations of neurons. Up to the inception of this project, MIIND provided the ability to simulate populations of one and two dimensional neuron models with the aid of a user built mesh. Using a different computational technique, MIIND now requires no special user-built mesh which was time consuming to construct and the system now supports up to three dimensions for the underlying neuron model. MIIND has been used to simulate interacting populations of neurons in the human spinal cord to demonstrate the behaviour of leg muscles during a static (isometric) contraction task. The resulting spinal cord model was used to identify functionally distinct afferent signals dependent on the angle of the knee. A reduced version of the pre-Botzinger bursting neuron was developed (reduced from four dimensions to two) and used to reproduce the deletions behaviour observed in the Rybak CPG model of fictive locomotion in cats. |
| Exploitation Route | The spinal cord model used to reproduce observed behaviour in the leg muscles provides insight into how future experiments (particularly in isometric tasks) should be set up to account for the effects of limb position. The work also demonstrates how synergy analysis using non-negative matrix factorisation should be used with care to avoid simple categorisation of muscle activity which provides little additional information. MIIND is a tool for efficiently simulating the behaviour of large numbers of populations with high performance. At the mezoscopic scale, where population level behaviour is required while maintaining a causal link to the behaviour of the neurons at the microscopic scale, MIIND is well placed. Furthermore, the visual nature of the software provides an excellent tool for teaching about the behaviour of dynamical systems under the effect of random noise. |
| Sectors | Education,Healthcare,Pharmaceuticals and Medical Biotechnology |
| URL | http://miind.sf.net |