Adaptive Neuro-Fuzzy Sliding Mode Control of Multi-Joint Movement Using Intraspinal Microstimulation

During the last decade, intraspinal microstimulation (ISMS) has been proposed as a potential technique for restoring motor function in paralyzed limbs. A major challenge to restoration of a desired functional limb movement through the use of ISMS is the development of a robust control strategy for determining the stimulation patterns. Accurate and stable control of limbs by functional intraspinal microstimulation is a very difficult task because neuromusculoskeletal systems have significant nonlinearity, time variability, large latency and time constant, and muscle fatigue. Furthermore, the controller must be able to compensate the effect of the dynamic interaction between motor neuron pools and electrode sites during ISMS. In this paper, we present a robust strategy for multi-joint control through ISMS in which the system parameters are adapted online and the controller requires no offline training phase. The method is based on the combination of sliding mode control with fuzzy logic and neural control. Extensive experiments on six rats are provided to demonstrate the robustness, stability, and tracking accuracy of the proposed method. Despite the complexity of the spinal neuronal networks, our results show that the proposed strategy could provide accurate tracking control with fast convergence and could generate control signals to compensate for the effects of muscle fatigue.

[1]  Thierry Keller,et al.  Surface-Stimulation Technology for Grasping and Walking Neuroprostheses Improving Quality of Life in Stroke/Spinal Cord Injury Subjects with Rapid Prototyping and Portable FES Systems , 2001 .

[2]  Arash Ajoudani,et al.  A Neuro-Sliding-Mode Control With Adaptive Modeling of Uncertainty for Control of Movement in Paralyzed Limbs Using Functional Electrical Stimulation , 2009, IEEE Transactions on Biomedical Engineering.

[3]  R. Kobetic,et al.  Walking after incomplete spinal cord injury using an implanted FES system: a case report. , 2007, Journal of rehabilitation research and development.

[4]  T. Sinkjaer,et al.  A review of portable FES-based neural orthoses for the correction of drop foot , 2002, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[5]  J. Mortimer,et al.  A method to effect physiological recruitment order in electrically activated muscle , 1991, IEEE Transactions on Biomedical Engineering.

[6]  K. Kilgore,et al.  Efficacy of an implanted neuroprosthesis for restoring hand grasp in tetraplegia: a multicenter study. , 2001, Archives of physical medicine and rehabilitation.

[7]  C J Robinson,et al.  Isometric torque about the knee joint generated by microstimulation of the cat L6 spinal cord. , 1999, IEEE transactions on rehabilitation engineering : a publication of the IEEE Engineering in Medicine and Biology Society.

[8]  E. Condie,et al.  Functional Electrical Stimulation: Standing and Walking After Spinal Cord Injury , 1990 .

[9]  Hamid-Reza Kobravi,et al.  A decentralized adaptive fuzzy robust strategy for control of upright standing posture in paraplegia using functional electrical stimulation. , 2012, Medical engineering & physics.

[10]  V. Mushahwar,et al.  Strategies for Generating Prolonged Functional Standing Using Intramuscular Stimulation or Intraspinal Microstimulation , 2007, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[11]  V. Mushahwar,et al.  Intraspinal microstimulation preferentially recruits fatigue‐resistant muscle fibres and generates gradual force in rat , 2005, The Journal of physiology.

[12]  A. Prochazka,et al.  Intraspinal micro stimulation generates locomotor-like and feedback-controlled movements , 2002, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[13]  J. Mortimer,et al.  Selective activation of small motor axons by quasitrapezoidal current pulses , 1991, IEEE Transactions on Biomedical Engineering.

[14]  Robert Riener,et al.  Walking with WALK! , 2008, IEEE Engineering in Medicine and Biology Magazine.

[15]  V. Mushahwar,et al.  Selective activation of muscle groups in the feline hindlimb through electrical microstimulation of the ventral lumbo-sacral spinal cord. , 2000, IEEE transactions on rehabilitation engineering : a publication of the IEEE Engineering in Medicine and Biology Society.

[16]  C J Robinson,et al.  Multimicroelectrode stimulation within the cat L6 spinal cord: influences of electrode combinations and stimulus interleave time on knee joint extension torque. , 2000, IEEE transactions on rehabilitation engineering : a publication of the IEEE Engineering in Medicine and Biology Society.

[17]  J. Thomas Mortimer,et al.  Recruitment properties of monopolar and bipolar epimysial electrodes , 2006, Annals of Biomedical Engineering.

[18]  D. Graupe,et al.  Ambulation by traumatic T4-12 paraplegics using functional neuromuscular stimulation , 1998, Critical reviews in neurosurgery : CR.

[19]  K W Horch,et al.  Muscle recruitment through electrical stimulation of the lumbo-sacral spinal cord. , 2000, IEEE transactions on rehabilitation engineering : a publication of the IEEE Engineering in Medicine and Biology Society.

[20]  Paul L Gribble,et al.  Role of cocontraction in arm movement accuracy. , 2003, Journal of neurophysiology.

[21]  Hamid-Reza Kobravi,et al.  Decentralized adaptive robust control based on sliding mode and nonlinear compensator for the control of ankle movement using functional electrical stimulation of agonist–antagonist muscles , 2009, Journal of neural engineering.

[22]  Vadim I. Utkin,et al.  A control engineer's guide to sliding mode control , 1999, IEEE Trans. Control. Syst. Technol..