The goal of the proposed work is to build a theoretical framework based on phase resetting curves (PRC) for understanding the basic mechanisms of synchronization and phase locking in networks of biological neurons. These phenomena underlie central pattern generation for the production of repetitive motor activity such as locomotion and respiration. Transiently synchronized assemblies of neurons are hypothesized to underlie many cognitive functions, and synchronization is altered in psychiatric disorders such as schizophrenia. Pathological synchronization is involved in epilepsy and tremor. PRCs measure the change in length of a periodic cycle due to an input perturbation to an isolated neuron, and provide useful information regarding the activity of the neuron within a network context. During the previous progress period, two major approaches were explored as theoretical substrates: 1: the phase resetting curves using a spike (or burst) as a perturbation under the assumption of pulsatile coupling and 2) a functional PRC (FPRC) consisting of repeated stimulation with a similar perturbation applied at a fixed delay after each spike (or burst) initiation. The overall goal of the project is to create a very broad theoretical framework that can be used to analyze the biological basis of coordinated oscillatory activity in the nervous system. Therefore we need to develop and test methods to analyze circuits that include neurons exhibiting spike frequency adaptation, neurons that are not intrinsic oscillators, noisy circuits, and circuits whose parameters cannot be defined in detail for every component neuron. The following objectives will be accomplished in the next project period: we will develop and test PRC-based methods to include neurons that are not endogenous pacemakers, to analyze circuits of adapting neurons, and to estimate the robustness of synchronization in the presence of noise and heterogeneity. We will analyze a biological central pattern generator, the pyloric circuit of the lobster and crab, using the methods that we develop. General principles will emerge that should be applicable to many oscillatory networks in the nervous system. A better understanding of these mechanisms will provide tools to determine how synchronization goes awry in neurological disorders such as epilepsy and tremor, or in psychiatric disorders in which cognition is impaired.

Public Health Relevance

The purpose of this work is to understand basic mechanisms of synchronization and pattern formation in the nervous system. Networks of biological neurons can spontaneously generate patterned activity that underlies rhythmic, repetitive motor behaviors such as respiration and locomotion, and transient synchronization in cortical networks is hypothesized to mediate cognitive functions such as attention, perception, and information storage and retrieval. A better understanding of these mechanisms will provide tools to determine how synchronization goes awry in neurological disorders such as epilepsy and tremor, or in psychiatric disorders in which cognition is impaired.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS054281-08
Application #
8402624
Study Section
Special Emphasis Panel (ZRG1-IFCN-L (02))
Program Officer
Liu, Yuan
Project Start
2005-09-15
Project End
2014-12-31
Budget Start
2013-01-01
Budget End
2013-12-31
Support Year
8
Fiscal Year
2013
Total Cost
$339,119
Indirect Cost
$50,424
Name
Louisiana State Univ Hsc New Orleans
Department
Neurosciences
Type
Schools of Medicine
DUNS #
782627814
City
New Orleans
State
LA
Country
United States
Zip Code
70112
Canavier, Carmen C (2015) Phase-resetting as a tool of information transmission. Curr Opin Neurobiol 31:206-13
Thounaojam, Umeshkanta S; Cui, Jianxia; Norman, Sharon E et al. (2014) Slow noise in the period of a biological oscillator underlies gradual trends and abrupt transitions in phasic relationships in hybrid neural networks. PLoS Comput Biol 10:e1003622
Tikidji-Hamburyan, Ruben; Lin, Eric C; Gasparini, Sonia et al. (2014) Effect of heterogeneity and noise on cross frequency phase-phase and phase-amplitude coupling. Network 25:38-62
Bradley, Patrick J; Wiesenfeld, Kurt; Butera, Robert J (2011) Effects of heterogeneity in synaptic conductance between weakly coupled identical neurons. J Comput Neurosci 30:455-69
Achuthan, Srisairam; Butera, Robert J; Canavier, Carmen C (2011) Synaptic and intrinsic determinants of the phase resetting curve for weak coupling. J Comput Neurosci 30:373-90
Chandrasekaran, Lakshmi; Achuthan, Srisairam; Canavier, Carmen C (2011) Stability of two cluster solutions in pulse coupled networks of neural oscillators. J Comput Neurosci 30:427-45
Canavier, Carmen C; Achuthan, Srisairam (2010) Pulse coupled oscillators and the phase resetting curve. Math Biosci 226:77-96
Sieling, Fred H; Canavier, Carmen C; Prinz, Astrid A (2010) Inclusion of noise in iterated firing time maps based on the phase response curve. Phys Rev E Stat Nonlin Soft Matter Phys 81:061923
Preyer, Amanda J; Butera, Robert J (2009) Causes of transient instabilities in the dynamic clamp. IEEE Trans Neural Syst Rehabil Eng 17:190-8
Canavier, Carmen C; Kazanci, Fatma Gurel; Prinz, Astrid A (2009) Phase resetting curves allow for simple and accurate prediction of robust N:1 phase locking for strongly coupled neural oscillators. Biophys J 97:59-73

Showing the most recent 10 out of 15 publications