Your search keyword '"Allen Yin"' showing total 5 results

1. Interactions of encoding and decoding problems to understand motor control

Author

Lee E. Miller, Matthew G. Perich, Allen Yin, Li Zheng, Shixian Wen, and Laurent Itti

Subjects

0303 health sciences, business.industry, Computer science, Deep learning, Motor control, 03 medical and health sciences, 0302 clinical medicine, Dynamics (music), Encoding (memory), Spike (software development), Artificial intelligence, business, 030217 neurology & neurosurgery, Decoding methods, 030304 developmental biology

Abstract

Learning a map from movement to neural data (Encoding Problem) and vice versa (Decoding Problem) are crucial to understanding motor control. A principled encoding model that understands underlying neural dynamics can help better solve the decoding problem. Here, we develop a new generative encoding model leveraging deep learning that autonomously captures neural dynamics. After training, the model can synthesize spike trains given any observed kinematics, under the guidance of the learned neural dynamics. When neural data from other sessions or subjects are limited, synthesized spike trains can improve cross-session and cross-subject decoding performance of a Brain Computer Interface decoder. For cross-subject, even with ample data for both subjects, neural dynamics learned from a previous subject can transfer useful knowledge that improves the best achievable decoding performance for the new subject. The approach is general and fully data-driven, and hence could apply to neuroscience encoding and decoding problems beyond motor control.

Published

2019

2. Place Cell-Like Activity in the Primary Sensorimotor and Premotor Cortex During Monkey Whole-Body Navigation

Author

Po-He Tseng, Miguel A. L. Nicolelis, Sankaranarayani Rajangam, Mikhail A. Lebedev, and Allen Yin

Subjects

0301 basic medicine, Science, Movement, Place cell, Hippocampal formation, Biology, Somatosensory system, Article, Premotor cortex, 03 medical and health sciences, medicine, Animals, Brain–computer interface, Neurons, Multidisciplinary, Functional specialization, Motor Cortex, Somatosensory Cortex, Proprioception, Macaca mulatta, Unexpected finding, 030104 developmental biology, medicine.anatomical_structure, Brain-Computer Interfaces, Medicine, Whole body, Neuroscience, Spatial Navigation

Abstract

Primary motor (M1), primary somatosensory (S1) and dorsal premotor (PMd) cortical areas of rhesus monkeys previously have been associated only with sensorimotor control of limb movements. Here we show that a significant number of neurons in these areas also represent body position and orientation in space. Two rhesus monkeys (K and M) used a wheelchair controlled by a brain-machine interface (BMI) to navigate in a room. During this whole-body navigation, the discharge rates of M1, S1, and PMd neurons correlated with the two-dimensional (2D) room position and the direction of the wheelchair and the monkey head. This place cell-like activity was observed in both monkeys, with 44.6% and 33.3% of neurons encoding room position in monkeys K and M, respectively, and the overlapping populations of 41.0% and 16.0% neurons encoding head direction. These observations suggest that primary sensorimotor and premotor cortical areas in primates are likely involved in allocentrically representing body position in space during whole-body navigation, which is an unexpected finding given the classical hierarchical model of cortical processing that attributes functional specialization for spatial processing to the hippocampal formation.

Published

2018

3. A novel paraplegia model in awake behaving macaques

Author

Yoon Woo Byun, Mikhail A. Lebedev, David B. MacLeod, Allen Yin, Roberto J. Manson, Laura M. O. Oliveira, Katie Z. Zhuang, Max O. Krucoff, and Dennis A. Turner

Subjects

0301 basic medicine, Male, Epinephrine, Physiology, Walking, 03 medical and health sciences, 0302 clinical medicine, Lumbar, Port (medical), Catheters, Indwelling, medicine, Paralysis, Animals, Anesthetics, Local, Wakefulness, Muscle, Skeletal, Spinal cord injury, Spinal Cord Injuries, Paraplegia, General Neuroscience, Neurological Rehabilitation, Lidocaine, medicine.disease, Macaca mulatta, 030104 developmental biology, Targeted drug delivery, Innovative Methodology, Female, medicine.symptom, Psychology, Neuroscience, Adrenergic alpha-Agonists, 030217 neurology & neurosurgery, Muscle Contraction

Abstract

Lower limb paralysis from spinal cord injury (SCI) or neurological disease carries a poor prognosis for recovery and remains a large societal burden. Neurophysiological and neuroprosthetic research have the potential to improve quality of life for these patients; however, the lack of an ethical and sustainable nonhuman primate model for paraplegia hinders their advancement. Therefore, our multidisciplinary team developed a way to induce temporary paralysis in awake behaving macaques by creating a fully implantable lumbar epidural catheter-subcutaneous port system that enables easy and reliable targeted drug delivery for sensorimotor blockade. During treadmill walking, aliquots of 1.5% lidocaine with 1:200,000 epinephrine were percutaneously injected into the ports of three rhesus macaques while surface electromyography (EMG) recorded muscle activity from their quadriceps and gastrocnemii. Diminution of EMG amplitude, loss of voluntary leg movement, and inability to bear weight were achieved for 60–90 min in each animal, followed by a complete recovery of function. The monkeys remained alert and cooperative during the paralysis trials and continued to take food rewards, and the ports remained functional after several months. This technique will enable recording from the cortex and/or spinal cord in awake behaving nonhuman primates during the onset, maintenance, and resolution of paraplegia for the first time, thus opening the door to answering basic neurophysiological questions about the acute neurological response to spinal cord injury and recovery. It will also negate the need to permanently injure otherwise high-value research animals for certain experimental paradigms aimed at developing and testing neural interface decoding algorithms for patients with lower extremity dysfunction. NEW & NOTEWORTHY A novel implantable lumbar epidural catheter-subcutaneous port system enables targeted drug delivery and induction of temporary paraplegia in awake, behaving nonhuman primates. Three macaques displayed loss of voluntary leg movement for 60–90 min after injection of lidocaine with epinephrine, followed by a full recovery. This technique for the first time will enable ethical live recording from the proximal central nervous system during the acute onset, maintenance, and resolution of paraplegia.

Published

2017

4. Wireless Cortical Brain-Machine Interface for Whole-Body Navigation in Primates

Author

Allen Yin, Gary Lehew, David Alexander Schwarz, Po-He Tseng, Miguel A. L. Nicolelis, Sankaranarayani Rajangam, and Mikhail A. Lebedev

Subjects

0301 basic medicine, Computer science, Kinematics, Article, 03 medical and health sciences, 0302 clinical medicine, Wheelchair, medicine, Wireless, Animals, Humans, Paralysis, Simulation, Brain–computer interface, Motor Neurons, Multidisciplinary, business.industry, Motor Cortex, Robotics, Cortical neurons, equipment and supplies, Macaca mulatta, Biomechanical Phenomena, body regions, 030104 developmental biology, medicine.anatomical_structure, Wheelchairs, Brain-Computer Interfaces, Artificial intelligence, business, Whole body, Neuroscience, human activities, Microelectrodes, Wireless Technology, 030217 neurology & neurosurgery, Motor cortex

Abstract

Several groups have developed brain-machine-interfaces (BMIs) that allow primates to use cortical activity to control artificial limbs. Yet, it remains unknown whether cortical ensembles could represent the kinematics of whole-body navigation and be used to operate a BMI that moves a wheelchair continuously in space. Here we show that rhesus monkeys can learn to navigate a robotic wheelchair, using their cortical activity as the main control signal. Two monkeys were chronically implanted with multichannel microelectrode arrays that allowed wireless recordings from ensembles of premotor and sensorimotor cortical neurons. Initially, while monkeys remained seated in the robotic wheelchair, passive navigation was employed to train a linear decoder to extract 2D wheelchair kinematics from cortical activity. Next, monkeys employed the wireless BMI to translate their cortical activity into the robotic wheelchair’s translational and rotational velocities. Over time, monkeys improved their ability to navigate the wheelchair toward the location of a grape reward. The navigation was enacted by populations of cortical neurons tuned to whole-body displacement. During practice with the apparatus, we also noticed the presence of a cortical representation of the distance to reward location. These results demonstrate that intracranial BMIs could restore whole-body mobility to severely paralyzed patients in the future.

Published

2016

5. An automatic experimental apparatus to study arm reaching in New World monkeys

Author

Mikhail A. Lebedev, Miguel A. L. Nicolelis, Allen Yin, Gary Lehew, and Jehi An

Subjects

0301 basic medicine, Experimental control, Electrophysiological Phenomena, Platyrrhini, Article, 03 medical and health sciences, Animal model, medicine, Animals, Neurons, Behavior, Animal, General Neuroscience, Motor Cortex, Equipment Design, Neurophysiology, 030104 developmental biology, medicine.anatomical_structure, Models, Animal, Arm, Aotidae, Female, Psychology, Neuroscience, Psychomotor Performance, Motor cortex

Abstract

Several species of the New World monkeys have been used as experimental models in biomedical and neurophysiological research. However, a method for controlled arm reaching tasks has not been developed for these species.We have developed a fully automated, pneumatically driven, portable, and reconfigurable experimental apparatus for arm-reaching tasks suitable for these small primates.We have utilized the apparatus to train two owl monkeys in a visually-cued arm-reaching task. Analysis of neural recordings demonstrates directional tuning of the M1 neurons.Our apparatus allows automated control, freeing the experimenter from manual experiments.The presented apparatus provides a valuable tool for conducting neurophysiological research on New World monkeys.