Efficient implementation of a real-time estimation system for thalamocortical hidden Parkinsonian properties

Real-time estimation of dynamical characteristics of thalamocortical cells, such as dynamics of ion channels and membrane potentials, is useful and essential in the study of the thalamus in Parkinsonian state. However, measuring the dynamical properties of ion channels is extremely challenging experimentally and even impossible in clinical applications. This paper presents and evaluates a real-time estimation system for thalamocortical hidden properties. For the sake of efficiency, we use a field programmable gate array for strictly hardware-based computation and algorithm optimization. In the proposed system, the FPGA-based unscented Kalman filter is implemented into a conductance-based TC neuron model. Since the complexity of TC neuron model restrains its hardware implementation in parallel structure, a cost efficient model is proposed to reduce the resource cost while retaining the relevant ionic dynamics. Experimental results demonstrate the real-time capability to estimate thalamocortical hidden properties with high precision under both normal and Parkinsonian states. While it is applied to estimate the hidden properties of the thalamus and explore the mechanism of the Parkinsonian state, the proposed method can be useful in the dynamic clamp technique of the electrophysiological experiments, the neural control engineering and brain-machine interface studies.

[1]  P. Conn,et al.  Distribution and roles of metabotropic glutamate receptors in the basal ganglia motor circuit: implications for treatment of Parkinson's disease and related disorders. , 2000, Pharmacology & therapeutics.

[2]  D. McCormick,et al.  A model of the electrophysiological properties of thalamocortical relay neurons. , 1992, Journal of neurophysiology.

[3]  P. Goadsby,et al.  Modulation of nocioceptive transmission with calcitonin gene-related peptide receptor antagonists in the thalamus. , 2010, Brain : a journal of neurology.

[4]  Gregory Cohen,et al.  An FPGA Implementation of a Polychronous Spiking Neural Network with Delay Adaptation , 2013, Front. Neurosci..

[5]  L. M. Ward,et al.  The thalamus: gateway to the mind. , 2013, Wiley interdisciplinary reviews. Cognitive science.

[6]  Jeffrey K. Uhlmann,et al.  Unscented filtering and nonlinear estimation , 2004, Proceedings of the IEEE.

[7]  D. Jaeger,et al.  Short-Term Plasticity Shapes the Response to Simulated Normal and Parkinsonian Input Patterns in the Globus Pallidus , 2002, The Journal of Neuroscience.

[8]  Jiang Wang,et al.  Digital implementations of thalamocortical neuron models and its application in thalamocortical control using FPGA for Parkinson's disease , 2016, Neurocomputing.

[9]  A. Szücs,et al.  Extended dynamic clamp: controlling up to four neurons using a single desktop computer and interface , 2001, Journal of Neuroscience Methods.

[10]  Ying-Shieh Kung,et al.  FPGA-Based Speed Control IC for PMSM Drive With Adaptive Fuzzy Control , 2007, IEEE Transactions on Power Electronics.

[11]  J. Rinzel,et al.  Emergent spindle oscillations and intermittent burst firing in a thalamic model: specific neuronal mechanisms. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[12]  Teresa Orlowska-Kowalska,et al.  FPGA Implementation of the Multilayer Neural Network for the Speed Estimation of the Two-Mass Drive System , 2011, IEEE Transactions on Industrial Informatics.

[13]  Dong Wang,et al.  Complex Learning in Bio-plausible Memristive Networks , 2015, Scientific Reports.

[14]  Q. Gong,et al.  Altered resting-state functional connectivity of thalamus in earthquake-induced posttraumatic stress disorder: A functional magnetic resonance imaging study , 2011, Brain Research.

[15]  Robert W. Peoples,et al.  Nature of the neurotoxic membrane actions of amyloid-β on hippocampal neurons in Alzheimer's disease , 2014, Neurobiology of Aging.

[16]  Warren M. Grill,et al.  Relative contributions of local cell and passing fiber activation and silencing to changes in thalamic fidelity during deep brain stimulation and lesioning: a computational modeling study , 2011, Journal of Computational Neuroscience.

[17]  Eve Marder,et al.  The dynamic clamp comes of age , 2004, Trends in Neurosciences.

[18]  D. McCormick,et al.  Simulation of the currents involved in rhythmic oscillations in thalamic relay neurons. , 1992, Journal of neurophysiology.

[19]  Simon J. Mitchell,et al.  Direct measurement of somatic voltage clamp errors in central neurons , 2008, Nature Neuroscience.

[20]  Eric Monmasson,et al.  Fully Integrated FPGA-Based Controller for Synchronous Motor Drive , 2009, IEEE Transactions on Industrial Electronics.

[21]  Andrew S. Cassidy,et al.  A million spiking-neuron integrated circuit with a scalable communication network and interface , 2014, Science.

[22]  Paola Piccini,et al.  Priorities in Parkinson's disease research , 2011, Nature Reviews Drug Discovery.

[23]  Arash Ahmadi,et al.  Digital Multiplierless Implementation of Biological Adaptive-Exponential Neuron Model , 2014, IEEE Transactions on Circuits and Systems I: Regular Papers.

[24]  S. Hughes,et al.  Dynamic clamp study of Ih modulation of burst firing and δ oscillations in thalamocortical neurons in vitro , 1998, Neuroscience.

[25]  Michael Ruse,et al.  Mechanisms and Models , 2007 .

[26]  Fabrizio Marignetti,et al.  A System-on-Chip Sensorless Control for a Permanent-Magnet Synchronous Motor , 2010, IEEE Transactions on Industrial Electronics.

[27]  Ghanim Ullah,et al.  Tracking and control of neuronal Hodgkin-Huxley dynamics. , 2009, Physical review. E, Statistical, nonlinear, and soft matter physics.

[28]  Steven J. Schiff,et al.  Towards model-based control of Parkinson's disease , 2010, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[29]  S. Ferrari,et al.  Author contributions , 2021 .

[30]  W. Dauer,et al.  Parkinson's Disease Mechanisms and Models , 2003, Neuron.

[31]  Jürgen Kurths,et al.  The Unscented Kalman Filter, a Powerful Tool for Data Analysis , 2004, Int. J. Bifurc. Chaos.

[32]  Chen,et al.  A functional magnetic resonance imaging study , 2011 .

[33]  Jonathan E. Rubin,et al.  High Frequency Stimulation of the Subthalamic Nucleus Eliminates Pathological Thalamic Rhythmicity in a Computational Model , 2004, Journal of Computational Neuroscience.

[34]  Wulfram Gerstner,et al.  Adaptive exponential integrate-and-fire model as an effective description of neuronal activity. , 2005, Journal of neurophysiology.

[35]  Mikhail A. Lebedev,et al.  Computing Arm Movements with a Monkey Brainet , 2015, Scientific Reports.

[36]  D J Brooks,et al.  Delayed recovery of movement‐related cortical function in Parkinson's disease after striatal dopaminergic grafts , 2000, Annals of neurology.

[37]  Jürgen Kurths,et al.  Nonlinear Dynamical System Identification from Uncertain and Indirect Measurements , 2004, Int. J. Bifurc. Chaos.

[38]  John Q. Trojanowski,et al.  Chaperone Suppression of α-Synuclein Toxicity in a Drosophila Model for Parkinson's Disease , 2001, Science.

[39]  Bin Deng,et al.  Cost-efficient FPGA implementation of basal ganglia and their Parkinsonian analysis , 2015, Neural Networks.

[40]  A Beuter,et al.  Dynamics of the Subthalamo-pallidal Complex in Parkinson’s Disease During Deep Brain Stimulation , 2008, Journal of biological physics.

[41]  David Eidelberg,et al.  Metabolic brain networks associated with cognitive function in Parkinson's disease , 2007, NeuroImage.

[42]  Vikaas S Sohal,et al.  Intrinsic and Synaptic Dynamics Interact to Generate Emergent Patterns of Rhythmic Bursting in Thalamocortical Neurons , 2006, The Journal of Neuroscience.

[43]  M. Nicolelis,et al.  Unscented Kalman Filter for Brain-Machine Interfaces , 2009, PloS one.

[44]  Tina Toni,et al.  Designing attractive models via automated identification of chaotic and oscillatory dynamical regimes , 2011, Nature communications.

[45]  C. McIntyre,et al.  Cellular effects of deep brain stimulation: model-based analysis of activation and inhibition. , 2004, Journal of neurophysiology.

[46]  R. Uitti,et al.  Thalamic deep brain stimulation for tremor-predominant Parkinson's disease. , 2003, Parkinsonism & related disorders.

[47]  John R. Huguenard,et al.  Reciprocal inhibition controls the oscillatory state in thalamic networks , 2002, Neurocomputing.

[48]  Eric Monmasson,et al.  FPGAs in Industrial Control Applications , 2011, IEEE Transactions on Industrial Informatics.

[49]  James W. Fawcett,et al.  Chondroitinase ABC promotes functional recovery after spinal cord injury , 2002, Nature.

[50]  Wolfgang Stein,et al.  Neuromodulation to the Rescue: Compensation of Temperature-Induced Breakdown of Rhythmic Motor Patterns via Extrinsic Neuromodulatory Input , 2015, PLoS biology.

[51]  Eilon Vaadia,et al.  Kernel-ARMA for Hand Tracking and Brain-Machine interfacing During 3D Motor Control , 2008, NIPS.

[52]  Steven J Schiff,et al.  Kalman filter control of a model of spatiotemporal cortical dynamics , 2008, BMC Neuroscience.

[53]  Yves Frégnac,et al.  Cortically-Controlled Population Stochastic Facilitation as a Plausible Substrate for Guiding Sensory Transfer across the Thalamic Gateway , 2013, PLoS Comput. Biol..

[54]  R. Llinás,et al.  Bursting of thalamic neurons and states of vigilance. , 2006, Journal of neurophysiology.

[55]  R. Grantyn,et al.  Pathological gamma oscillations, impaired dopamine release, synapse loss and reduced dynamic range of unitary glutamatergic synaptic transmission in the striatum of hypokinetic Q175 Huntington mice , 2015, Neuroscience.

[56]  András Lörincz,et al.  Static and Dynamic State Feedback Control Model of Basal Ganglia-Thalamocortical Loops , 1997, Int. J. Neural Syst..