Multiscale modeling using computer simulation is increasingly recognized as a major method, along with data-mining, for assimilating the vast and ever-growing knowledge base in systems biology. This will improve understanding of the links between molecules and disease manifestation for translational research to the clinic. The bridging of chemophysiology (chemical signaling in neurons and astrocytes) with electrophysiology provides a fundamental connection that will necessarily underpin higher organizational scales. Multiscale models are particularly dif?cult to simulate in neurobiology du to the elongated nature of neural cells (compared to compact cells for many other cell types), and to multiple overlapping of embedded scales (e.g., pyramidal apical dendrite domains at the same temporal and spatial scale as local networks). We are developing the widely used NEURON simulator to accommodate simulation of these complex second-messenger signal interactions that contribute to information processing. In the prior funding period, we added the reaction-diffusion module to NEURON, providing 3D deterministic diffusion linked to reactions situated in cytosol, on or within internal organelles, or on plasma membrane. We also added 1D deterministic diffusion to reduce high computational loads that limited the scope of simulations, noting that the detail of full 3D diffusion is not always needed. As part of these improvements, we extended NEURON's Python interface to include a new set of classes devoted to reaction-diffusion modeling. Additionally, we prepared connectors for interfacing with SBML (Systems Biology Markup Language). In the current proposal, we will build on these advances in order to allow development of mosaic simulations involving combinations of stochastic and deterministic simulation in both 3D and 1D. This will involve the ability to readily switch among these different levels of approximation so that different modeling approaches can be compared. These objectives will be achieved through the following Speci?c Aims:
Aim 1. Multiple multigrid methods: 1D and 3D grids with different sized grids at different locations.
Aim 2. Parallelization using multisplit methods that allow the simulation of a single neuron to be run across multiple processors or across multiple threads on a single processor.
Aim 3. Stochastic simulation using an extended Gillespie method. This will complement additional stochastic methods that will also be made available in NEURON.
Aim 4. Dissemination: new Graphical User Interface for front-end speci?cations for viewing results, model development, model importation and merging, method comparison and multiprocessor deployment. Making the tool accessible to the community via courses, tutorials, example programs, documentation and online help.

Public Health Relevance

The enormous complexity of brain interactions makes understanding brain diseases such as schizophrenia, autism, and Alzheimer disease more dif?cult than understanding diseases in other organs. Part of this complexity lies in the need to understand how the chemicals that underlie learning and memory, and brain energy, interact with the electrical signals that travel along nerve ?bers. We are extending NEURON, one of the most widely used nerve and brain simulators, so that it simulates chemical reactions as well as electric signals and allow these two types of information to be combined to understand disease.

Agency
National Institute of Health (NIH)
Institute
National Institute of Mental Health (NIMH)
Type
Research Project (R01)
Project #
2R01MH086638-06
Application #
9116549
Study Section
Neuroscience and Ophthalmic Imaging Technologies Study Section (NOIT)
Program Officer
Friedman, Fred K
Project Start
2010-06-01
Project End
2021-03-31
Budget Start
2016-06-01
Budget End
2017-03-31
Support Year
6
Fiscal Year
2016
Total Cost
Indirect Cost
Name
Suny Downstate Medical Center
Department
Physiology
Type
Schools of Medicine
DUNS #
040796328
City
Brooklyn
State
NY
Country
United States
Zip Code
11203
Newton, Adam J H; McDougal, Robert A; Hines, Michael L et al. (2018) Using NEURON for Reaction-Diffusion Modeling of Extracellular Dynamics. Front Neuroinform 12:41
Mulugeta, Lealem; Drach, Andrew; Erdemir, Ahmet et al. (2018) Credibility, Replicability, and Reproducibility in Simulation for Biomedicine and Clinical Applications in Neuroscience. Front Neuroinform 12:18
Antic, Srdjan D; Hines, Michael; Lytton, William W (2018) Embedded ensemble encoding hypothesis: The role of the ""Prepared"" cell. J Neurosci Res 96:1543-1559
Neymotin, Samuel A; Talbot, Zoe N; Jung, Jeeyune Q et al. (2017) Tracking recurrence of correlation structure in neuronal recordings. J Neurosci Methods 275:1-9
Lin, Zhongwei; Tropper, Carl; Mcdougal, Robert A et al. (2017) Multithreaded Stochastic PDES for Reactions and Diffusions in Neurons. ACM Trans Model Comput Simul 27:
Lytton, William W; Arle, Jeff; Bobashev, Georgiy et al. (2017) Multiscale modeling in the clinic: diseases of the brain and nervous system. Brain Inform 4:219-230
Ishlam Patoary, Mohammad Nazrul; Tropper, Carl; McDougal, Robert A et al. (2017) Parallel Stochastic discrete event simulation of calcium dynamics in neuron. IEEE/ACM Trans Comput Biol Bioinform :
Lin, Zhongwei; Tropper, Carl; Yao, Yiping et al. (2017) Load balancing for multi-threaded PDES of stochastic reaction-diffusion in neurons. J Simul 11:267-284
Newton, Adam J H; Lytton, William W (2016) Computer modeling of ischemic stroke. Drug Discov Today Dis Models 19:77-83
Lytton, William W; Seidenstein, Alexandra H; Dura-Bernal, Salvador et al. (2016) Simulation Neurotechnologies for Advancing Brain Research: Parallelizing Large Networks in NEURON. Neural Comput 28:2063-90

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