Your search keyword '"Peter J. Grahn"' showing total 16 results

1. The Role of Functional Neuroanatomy of the Lumbar Spinal Cord in Effect of Epidural Stimulation

Author

Carlos A. Cuellar, Aldo A. Mendez, Riazul Islam, Jonathan S. Calvert, Peter J. Grahn, Bruce Knudsen, Tuan Pham, Kendall H. Lee, and Igor A. Lavrov

Subjects

spinal cord, swine, neuromodulation, epidural stimulation, functional neuroanatomy, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Human anatomy, QM1-695

Abstract

In this study, the neuroanatomy of the swine lumbar spinal cord, particularly the spatial orientation of dorsal roots was correlated to the anatomical landmarks of the lumbar spine and to the magnitude of motor evoked potentials during epidural electrical stimulation (EES). We found that the proximity of the stimulating electrode to the dorsal roots entry zone across spinal segments was a critical factor to evoke higher peak-to-peak motor responses. Positioning the electrode close to the dorsal roots produced a significantly higher impact on motor evoked responses than rostro-caudal shift of electrode from segment to segment. Based on anatomical measurements of the lumbar spine and spinal cord, significant differences were found between L1-L4 to L5-L6 segments in terms of spinal cord gross anatomy, dorsal roots and spine landmarks. Linear regression analysis between intersegmental landmarks was performed and L2 intervertebral spinous process length was selected as the anatomical reference in order to correlate vertebral landmarks and the spinal cord structures. These findings present for the first time, the influence of spinal cord anatomy on the effects of epidural stimulation and the role of specific orientation of electrodes on the dorsal surface of the dura mater in relation to the dorsal roots. These results are critical to consider as spinal cord neuromodulation strategies continue to evolve and novel spinal interfaces translate into clinical practice.

Published

2017

2. Segment-Specific Orientation of the Dorsal and Ventral Roots for Precise Therapeutic Targeting of Human Spinal Cord

Author

Ahad M. Siddiqui, Luke J. Staehnke, Bruce E. Knudsen, Anthony J. Windebank, Nirusha Lachman, Peter J. Grahn, Priska Summer, Alan Mendez, Ogeneitsega J. Joseph, Prathima Basa, Igor Lavrov, Riazul Islam, and Timur Latypov

Subjects

Aged, 80 and over, Male, Dorsum, Lumbar Vertebrae, General Medicine, Anatomy, Biology, Spinal cord, Therapeutic targeting, Thoracic Vertebrae, Neuromodulation (medicine), Lumbar, medicine.anatomical_structure, Spinal Cord, Cadaver, Cervical Vertebrae, medicine, Humans, Ventral Roots, Female, Anatomic Landmarks, Spinal Nerve Roots, Intervertebral foramen

Abstract

Objective To provide precise description of the dorsal and ventral roots orientation along with the main spinal cord anatomical measurements and their segment-specific variations. Patients and Methods We collected and analyzed the measurements of the spines, spinal cords, and dorsal and ventral roots (C2-L5) of nine adult cadavers (five males and four females). Results This study for the first time provides analysis of the dorsal and ventral roots orientation along with spinal cord anatomical measurements and their segment-specific distribution. The results of this study showed less variability in rostral root angles compared with the caudal. Dorsal and ventral rootlets were oriented mostly perpendicular to the spinal cord at the cervical level and had more parallel orientation to the spinal cord at the thoracic and lumbar segments. The number of rootlets per root was greatest at dorsal cervical and lumbar segments. Spinal cord transverse diameter and width of the dorsal columns were largest at cervical segments. The strongest correlation between the spinal cord and vertebrae structures was found between the length of intervertebral foramen to rostral rootlet distance and vertebral bone length. Conclusion These results demonstrate consistent variation in spinal cord anatomical features across all tested subjects. The results of this study can be used to locate spinal roots and main spinal cord landmarks based on bone marks on computed tomography or X-rays. These results could improve stereotactic surgical procedures and electrode positioning for neuromodulation procedures.

Published

2021

3. Multifactorial motor behavior assessment for real-time evaluation of emerging therapeutics to treat neurologic impairments

Author

Tori Riccelli, Jodi L. Silvernail, Carlos A. Cuellar, Suelen Lucio Boschen, Igor Lavrov, Riazul Islam, Ben Felmlee, and Peter J. Grahn

Subjects

0301 basic medicine, Spinal cord diseases, lcsh:Medicine, Electric Stimulation Therapy, Motor Activity, Serotonergic, Open field, Article, Midbrain, 03 medical and health sciences, 0302 clinical medicine, Physical Conditioning, Animal, medicine, Paralysis, Animals, Humans, Treadmill, lcsh:Science, Spinal cord, Multidisciplinary, business.industry, lcsh:R, Motor control, Disease Management, Electric Stimulation, Rats, Electrophysiology, Disease Models, Animal, 030104 developmental biology, medicine.anatomical_structure, Female, lcsh:Q, medicine.symptom, Psychomotor Disorders, business, Neuroscience, 030217 neurology & neurosurgery, Locomotion

Abstract

Integrating multiple assessment parameters of motor behavior is critical for understanding neural activity dynamics during motor control in both intact and dysfunctional nervous systems. Here, we described a novel approach (termed Multifactorial Behavioral Assessment (MfBA)) to integrate, in real-time, electrophysiological and biomechanical properties of rodent spinal sensorimotor network activity with behavioral aspects of motor task performance. Specifically, the MfBA simultaneously records limb kinematics, multi-directional forces and electrophysiological metrics, such as high-fidelity chronic intramuscular electromyography synchronized in time to spinal stimulation in order to characterize spinal cord functional motor evoked potentials (fMEPs). Additionally, we designed the MfBA to incorporate a body weight support system to allow bipedal and quadrupedal stepping on a treadmill and in an open field environment to assess function in rodent models of neurologic disorders that impact motor activity This novel approach was validated using, a neurologically intact cohort, a cohort with unilateral Parkinsonian motor deficits due to midbrain lesioning, and a cohort with complete hind limb paralysis due to T8 spinal cord transection. In the SCI cohort, lumbosacral epidural electrical stimulation (EES) was applied, with and without administration of the serotonergic agonist Quipazine, to enable hind limb motor functions following paralysis. The results presented herein demonstrate the MfBA is capable of integrating multiple metrics of motor activity in order to characterize relationships between EES inputs that modulate mono- and polysynaptic outputs from spinal circuitry which in turn, can be used to elucidate underlying electrophysiologic mechanisms of motor behavior by synchronizing these datasets to metrics of movement and behavior. These results also demonstrate that proposed MfBA is an effective tool to integrate biomechanical and electrophysiology metrics, synchronized to therapeutic inputs such as EES or pharmacology, during body weight supported treadmill or open field motor activities, to target a high range of variations in motor behavior as a result of neurological deficit at the different levels of CNS.

Published

2019

4. The Translesional Spinal Network and Its Reorganization after Spinal Cord Injury

Author

Anthony J. Windebank, Ahad M. Siddiqui, Nicolas N. Madigan, Riazul Islam, Igor Lavrov, Petr Krupa, Peter J. Grahn, and Bingkun K. Chen

Subjects

0301 basic medicine, Motor training, Neuroprosthetics, medicine.medical_treatment, 03 medical and health sciences, Spinal circuits, 0302 clinical medicine, Neuroplasticity, medicine, Humans, heterocyclic compounds, Spinal cord injury, Spinal Cord Injuries, Rehabilitation, business.industry, General Neuroscience, Recovery of Function, Functional recovery, medicine.disease, Neuromodulation (medicine), enzymes and coenzymes (carbohydrates), 030104 developmental biology, Spinal Cord, Neurology (clinical), business, Neuroscience, 030217 neurology & neurosurgery

Abstract

Evidence from preclinical and clinical research suggest that neuromodulation technologies can facilitate the sublesional spinal networks, isolated from supraspinal commands after spinal cord injury (SCI), by reestablishing the levels of excitability and enabling descending motor signals via residual connections. Herein, we evaluate available evidence that sublesional and supralesional spinal circuits could form a translesional spinal network after SCI. We further discuss evidence of translesional network reorganization after SCI in the presence of sensory inputs during motor training. In this review, we evaluate potential mechanisms that underlie translesional circuitry reorganization during neuromodulation and rehabilitation in order to enable motor functions after SCI. We discuss the potential of neuromodulation technologies to engage various components that comprise the translesional network, their functional recovery after SCI, and the implications of the concept of translesional network in development of future neuromodulation, rehabilitation, and neuroprosthetics technologies.

Published

2020

5. Supraspinal and Afferent Signaling Facilitate Spinal Sensorimotor Network Excitability After Discomplete Spinal Cord Injury: A Case Report

Author

Alena Militskova, Elvira Mukhametova, Elsa Fatykhova, Safar Sharifullin, Carlos A. Cuellar, Jonathan S. Calvert, Peter J. Grahn, Tatiana Baltina, and Igor Lavrov

Subjects

030506 rehabilitation, medicine.medical_specialty, Supine position, spinal cord stimulation, Case Report, Stimulation, lcsh:RC321-571, 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, AIS-A, Paralysis, discomplete spinal cord injury, Medicine, Spinal cord injury, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, business.industry, General Neuroscience, sub-lesional spinal circuitry, medicine.disease, Spinal cord, spinal cord injury, Electrophysiology, medicine.anatomical_structure, Facilitation, medicine.symptom, 0305 other medical science, business, 030217 neurology & neurosurgery, Lumbosacral joint, Neuroscience

Abstract

Objective: In this study we evaluated the role of residual supraspinal and afferent signaling and their convergence on the sublesional spinal network in subject diagnosed with complete paralysis (AIS-A). Methods: A combination of electrophysiologic techniques with positional changes and subject-driven reinforcement maneuvers was implemented in this study. Electrical stimulation was applied transcutaneously at the T9-L2 vertebra levels and the spinal cord motor evoked potentials (SEMP) were recorded from leg muscles. To test the influence of positional changes, the subject was placed in (i) supine, (ii) upright with partial body weight bearing (less than 30% body weight support), and (iii) vertically suspended without body weight bearing (100% body weight support) positions. Results: Increase in amplitude of SEMP was observed during transition from supine to upright position, supporting the role of sensory input in lumbosacral network excitability. Additionally, amplitudes of SEMP were facilitated during reinforcement maneuvers, indicating a supralesional influence on sub-lesional network. After initial assessment, subject underwent rehabilitation therapy with following electrophysiological testing that reviled facilitation of SEMP. Conclusions: These results demonstrate that combination of electrophysiological techniques with positional and reinforcement maneuvers can add to the diagnostics of discomplete SCI. These findings also support an idea that integration of supraspinal and afferent information on sub-lesional circuitry plays a critical role in facilitation of spinal sensorimotor network in discomplete SCI.

Published

2020

6. Segment-specific orientation of the dorsal and ventral roots for precise therapeutic targeting of human spinal cord

Author

Peter J. Grahn, Anthony J. Windebank, Nirusha Lachman, Alan Mendez, Priska Summer, Ogeneitsega J. Joseph, Prathima Basa, Ahad M. Siddiqui, Riazul Islam, Timur Latypov, Igor Lavrov, Luke J. Staehnke, and Bruce E. Knudsen

Subjects

business.industry, Anatomy, medicine.disease, Spinal cord, Spinal column, Neuromodulation (medicine), medicine.anatomical_structure, Lumbar, Cadaver, medicine, Intervertebral foramen, business, Spinal cord injury, Vertebral column

Abstract

An understanding of spinal cord functional neuroanatomy is essential for diagnosis and treatment of multiple disorders including, chronic pain, movement disorders, and spinal cord injury. Till now, no information is available on segment-specific spinal roots orientation in humans. In this study we collected neuroanatomical measurements of the dorsal and ventral roots from C2-L5, as well as spinal cord and vertebral bone measurements from adult cadavers. Spatial orientation of dorsal and ventral roots were measured and correlated to the anatomical landmarks of the spinal cord and vertebral column. The results show less variability in rostral root angles compared to the caudal angles across all segments. Dorsal and ventral rootlets were oriented mostly perpendicular to the spinal cord at the cervical level and demonstrate more parallel orientation at the thoracic and lumbar segments. The number of rootlets was the highest in dorsal cervical and lumbar segments. Spinal cord transverse diameter and size of the dorsal columns were largest at cervical and lumbar segments. The strongest correlation was found between the length of intervertebral foramen to rostral rootlet and vertebral bone length. These results could be used to locate spinal roots and spinal cord landmarks based on bone marks on CT or X-rays. These results also provide background for future correlations between anatomy of spinal cord and spinal column structures that could improve stereotactic surgical procedures and electrode positioning for spinal cord neuromodulation.One Sentence SummaryThis is the first detailed analysis of the segment-specific dorsal and ventral spinal roots spatial orientation measured and correlated to the anatomical landmarks of the spinal cord and vertebral column for human.

Published

2020

7. Preferential activation of spinal sensorimotor networks via lateralized transcutaneous spinal stimulation in neurologically intact humans

Author

Peter J. Grahn, Dimitry G. Sayenko, Gerome A Manson, and Jonathan S. Calvert

Subjects

Adult, Male, genetic structures, Physiology, Functional Laterality, 03 medical and health sciences, 0302 clinical medicine, Paralysis, Medicine, Humans, Muscle, Skeletal, Spinal cord injury, 030304 developmental biology, 0303 health sciences, Spinal Cord Stimulation, business.industry, General Neuroscience, Spinal stimulation, Lumbosacral Region, medicine.disease, Evoked Potentials, Motor, Neuromodulation (medicine), Spinal Cord, Transcutaneous Electric Nerve Stimulation, Female, medicine.symptom, business, Neuroscience, 030217 neurology & neurosurgery

Abstract

Transcutaneous spinal stimulation (TSS), a noninvasive technique to modulate sensorimotor circuitry within the spinal cord, has been shown to enable a wide range of functions that were thought to be permanently impaired in humans with spinal cord injury. However, the extent to which TSS can be used to target specific mediolateral spinal cord circuitry remains undefined. We tested the hypothesis that TSS applied unilaterally to the skin ~2 cm lateral to the midline of the lumbosacral spine selectively activates ipsilateral spinal sensorimotor circuitry, resulting in ipsilateral activation of downstream lower extremity neuromusculature. TSS cathodes and anodes were positioned lateral from the midline of the spine in 15 healthy subjects while supine, and the timing of TSS pulses was synchronized to recordings of lower extremity muscle activity and force. At motor threshold, left and right TSS-evoked muscle activity was significantly higher in the ipsilateral leg compared with contralateral recordings from the same muscles. Similarly, we observed a significant increase in force production in the ipsilateral leg compared with the contralateral leg. Delivery of paired TSS pulses, during which an initial stimulus was applied to one side of the spinal cord and 50 ms later a second stimulus was applied to the contralateral side, revealed that ipsilateral leg muscle responses decreased following the initial stimulus, whereas contralateral muscle responses did not decrease, indicating side-specific activation of lateral spinal sensorimotor circuitry. Our results indicate TSS can selectively engage ipsilateral neuromusculature via lumbosacral sensorimotor networks responsible for lower extremity function in healthy humans. NEW & NOTEWORTHY We demonstrate the selectivity of transcutaneous spinal stimulation (TSS), which has been shown to enable function in humans with chronic paralysis. Specifically, we demonstrate that TSS applied to locations lateral to the spinal cord can selectively activate ipsilateral spinal sensorimotor networks. We quantified lumbosacral spinal network activity by recording lower extremity muscle electromyography and force. Our results suggest lumbosacral TSS engages side-specific spinal sensorimotor networks associated with ipsilateral lower extremity function in humans.

Published

2019

8. Epidural electrical stimulation assisted gait improvements in spinal cord injured rats using a combinatorial strategy with scaffolds, compounds, cells, and motor training

Author

Priska Summer, Bingkun Chen, Emilee Manske, Shuya Zhang, Ahad M. Siddiqui, Dallece E. Curley, Anthony J. Windebank, Jodi L. Silvernail, Bruce E. Knudsen, Michael J. Yaszemski, Nicolas N. Madigan, Carlos A. Cuellar, Igor Lavrov, Tammy Strickland, Riazul Islam, Timur Latypov, Peter J. Grahn, and Jarred J. Nesbitt

Subjects

medicine.medical_specialty, medicine.anatomical_structure, Gait (human), Physical medicine and rehabilitation, Motor training, business.industry, medicine, Surgery, Orthopedics and Sports Medicine, Stimulation, Neurology (clinical), Spinal cord, business

Published

2020

9. Electrophysiological Guidance of Epidural Electrode Array Implantation over the Human Lumbosacral Spinal Cord to Enable Motor Function after Chronic Paralysis

Author

Megan L. Gill, Yury Gerasimenko, Cesar Lopez, Lisa A. Beck, Kristin D. Zhao, Jonathan S. Calvert, Igor Lavrov, Dimitry G. Sayenko, Kendall H. Lee, Peter J. Grahn, V. Reggie Edgerton, Meegan G. Van Straaten, Margaux B. Linde, Daniel D. Veith, Jeffrey A. Strommen, and Desmond A. Brown

Subjects

Adult, Epidural Space, Male, 030506 rehabilitation, medicine.medical_specialty, Intraoperative Neurophysiological Monitoring, electrically evoked spinal motor potentials, Stimulation, Neurosurgical Procedures, 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, medicine, Electrode array, Paralysis, Lumbosacral spinal cord, Humans, Spinal cord injury, Spinal Cord Injuries, Spinal Cord Stimulation, business.industry, Electromyography, Lumbosacral Region, spinal cord intraoperative electrophysiology, Original Articles, Spinal cord, medicine.disease, Evoked Potentials, Motor, Neuromodulation (medicine), Electrodes, Implanted, Electrophysiology, medicine.anatomical_structure, epidural electrical stimulation, spinal cord injury, neuromodulation, Neurology (clinical), medicine.symptom, 0305 other medical science, business, 030217 neurology & neurosurgery, Locomotion

Abstract

Epidural electrical stimulation (EES) of the spinal cord has been shown to restore function after spinal cord injury (SCI). Characterization of EES-evoked motor responses has provided a basic understanding of spinal sensorimotor network activity related to EES-enabled motor activity of the lower extremities. However, the use of EES-evoked motor responses to guide EES system implantation over the spinal cord and their relation to post-operative EES-enabled function in humans with chronic paralysis attributed to SCI has yet to be described. Herein, we describe the surgical and intraoperative electrophysiological approach used, followed by initial EES-enabled results observed in 2 human subjects with motor complete paralysis who were enrolled in a clinical trial investigating the use of EES to enable motor functions after SCI. The 16-contact electrode array was initially positioned under fluoroscopic guidance. Then, EES-evoked motor responses were recorded from select leg muscles and displayed in real time to determine electrode array proximity to spinal cord regions associated with motor activity of the lower extremities. Acceptable array positioning was determined based on achievement of selective proximal or distal leg muscle activity, as well as bilateral muscle activation. Motor response latencies were not significantly different between intraoperative recordings and post-operative recordings, indicating that array positioning remained stable. Additionally, EES enabled intentional control of step-like activity in both subjects within the first 5 days of testing. These results suggest that the use of EES-evoked motor responses may guide intraoperative positioning of epidural electrodes to target spinal cord circuitry to enable motor functions after SCI.

Published

2018

10. Emergence of Epidural Electrical Stimulation to Facilitate Sensorimotor Network Functionality After Spinal Cord Injury

Author

Kristin D. Zhao, Kendall H. Lee, Peter J. Grahn, and Jonathan S. Calvert

Subjects

Epidural Space, medicine.medical_specialty, Activities of daily living, Stimulation, Translational research, 03 medical and health sciences, Grip strength, 0302 clinical medicine, Physical medicine and rehabilitation, medicine, Humans, Respiratory function, Spinal cord injury, Spinal Cord Injuries, Spinal Cord Stimulation, business.industry, General Medicine, Recovery of Function, medicine.disease, Spinal cord, Neuromodulation (medicine), Anesthesiology and Pain Medicine, medicine.anatomical_structure, Neurology, Spinal Cord, Neurology (clinical), Sensorimotor Cortex, Nerve Net, business, 030217 neurology & neurosurgery, Psychomotor Performance

Abstract

Background Traumatic spinal cord injury (SCI) disrupts signaling pathways between the brain and spinal networks below the level of injury. In cases of severe SCI, permanent loss of sensorimotor and autonomic function can occur. The standard of care for severe SCI uses compensation strategies to maximize independence during activities of daily living while living with chronic SCI-related dysfunctions. Over the past several years, the research field of spinal neuromodulation has generated promising results that hold potential to enable recovery of functions via epidural electrical stimulation (EES). Methods This review provides a historical account of the translational research efforts that led to the emergence of EES of the spinal cord to enable intentional control of motor functions that were lost after SCI. We also highlight the major limitations associated with EES after SCI and propose future directions of spinal neuromodulation research. Results Multiple, independent studies have demonstrated return of motor function via EES in individuals with chronic SCI. These enabled motor functions include intentional, controlled movement of previously paralyzed extremities, independent standing and stepping, and increased grip strength. In addition, improvements in cardiovascular health, respiratory function, body composition, and urologic function have been reported. Conclusions EES holds promise to enable functions thought to be permanently lost due to SCI. However, EES is currently restricted to scientific investigation in humans with SCI and requires further validation of factors such as safety and efficacy before clinical translation.

Published

2018

11. Enabling Task-Specific Volitional Motor Functions via Spinal Cord Neuromodulation in a Human With Paraplegia

Author

Andrew R. Thoreson, Igor Lavrov, Dimitry G. Sayenko, Meegan G. Van Straaten, V. Reggie Edgerton, Margaux B. Linde, Kendall H. Lee, Parag Gad, Jonathan S. Calvert, Megan L. Gill, Yury Gerasimenko, Jeffrey A. Strommen, Kristin D. Zhao, Aldo A. Mendez, Lisa A. Beck, Peter J. Grahn, Cesar Lopez, and Dina I. Drubach

Subjects

Adult, Male, medicine.medical_specialty, Posture, Stimulation, Electric Stimulation Therapy, Electromyography, Walking, 050105 experimental psychology, Task (project management), 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, Rhythm, Task Performance and Analysis, medicine, Humans, 0501 psychology and cognitive sciences, Muscle, Skeletal, Spinal cord injury, Spinal Cord Injuries, Paraplegia, medicine.diagnostic_test, business.industry, 05 social sciences, General Medicine, medicine.disease, Spinal cord, Neuromodulation (medicine), medicine.anatomical_structure, Treatment Outcome, Spinal Cord, Physical therapy, business, 030217 neurology & neurosurgery

Abstract

We report a case of chronic traumatic paraplegia in which epidural electrical stimulation (EES) of the lumbosacral spinal cord enabled (1) volitional control of task-specific muscle activity, (2) volitional control of rhythmic muscle activity to produce steplike movements while side-lying, (3) independent standing, and (4) while in a vertical position with body weight partially supported, voluntary control of steplike movements and rhythmic muscle activity. This is the first time that the application of EES enabled all of these tasks in the same patient within the first 2 weeks (8 stimulation sessions total) of EES therapy.

Published

2017

12. MRI-Guided Stereotactic System for Delivery of Intraspinal Microstimulation

Author

Stephan J. Goerss, Joel P. Felmlee, Bruce A. Kall, James K. Trevathan, Kevin E. Bennet, Aldo A. Mendez, Jose L. Lujan, Kendall H. Lee, Peter J. Grahn, and Grant W. Mallory

Subjects

0301 basic medicine, Male, Swine, Electric Stimulation Therapy, Article, Stereotaxic Techniques, 03 medical and health sciences, 0302 clinical medicine, medicine, Microstimulation, Animals, Orthopedics and Sports Medicine, Electric stimulation therapy, Spinal Cord Injuries, medicine.diagnostic_test, business.industry, Magnetic resonance imaging, Magnetic Resonance Imaging, Electrodes, Implanted, 030104 developmental biology, Spinal Cord, Stereotaxic technique, Lumbar spine, Neurology (clinical), business, Microelectrodes, 030217 neurology & neurosurgery, Mri guided, Biomedical engineering

Abstract

Laboratory/animal-based proof of principle study.To validate the accuracy of a magnetic resonance imaging (MRI)-guided stereotactic system for intraspinal electrode targeting and demonstrate the feasibility of such a system for controlling implantation of intraspinal electrodes.Intraspinal microstimulation (ISMS) is an emerging preclinical therapy, which has shown promise for the restoration of motor function following spinal cord injury. However, targeting inaccuracy associated with existing electrode implantation techniques remains a major barrier preventing clinical translation of ISMS.System accuracy was evaluated using a test phantom comprised of nine target locations. Targeting accuracy was determined by calculating the root mean square error between MRI-generated coordinates and actual frame coordinates required to reach the target positions. System performance was further validated in an anesthetized pig model by performing MRI-guided intraspinal electrode implantation and stimulation followed by computed tomography of electrode location. Finally, system compatibility with a commercially available microelectrode array was demonstrated by implanting the array and applying a selection of stimulation amplitudes that evoked hind limb responses.The root mean square error between actual frame coordinates and software coordinates, both acquired using the test phantom, was 1.09 ± 0.20 mm. Postoperative computed tomography in the anesthetized pig confirmed spatially accurate electrode placement relative to preoperative MRI. Additionally, MRI-guided delivery of a microwire electrode followed by ISMS evoked repeatable electromyography responses in the biceps femoris muscle. Finally, delivery of a microelectrode array produced repeatable and graded hind limb evoked movements.We present a novel frame-based stereotactic system for targeting and delivery of intraspinal instrumentation. This system utilizes MRI guidance to account for variations in anatomy between subjects, thereby improving upon existing ISMS electrode implantation techniques.N/A.

Published

2015

13. Wireless control of intraspinal microstimulation in a rodent model of paralysis

Author

Ju Ho Jeong, John R. Dube, Aimen Kasasbeh, J. Luis Lujan, Christopher J. Kimble, Jan T. Hachmann, Grant W. Mallory, Peter J. Grahn, Kevin E. Bennet, Allan J. Bieber, Darlene A. Lobel, and Kendall H. Lee

Subjects

medicine.medical_treatment, Movement, Article, Rats, Sprague-Dawley, Paralysis, medicine, Functional electrical stimulation, Microstimulation, Animals, Muscle, Skeletal, Neurostimulation, Spinal cord injury, Spinal Cord Injuries, business.industry, Motor control, medicine.disease, Spinal cord, Evoked Potentials, Motor, Electric Stimulation, Rats, Lumbar Spinal Cord, medicine.anatomical_structure, Treatment Outcome, Spinal Cord, Anesthesia, Models, Animal, Female, medicine.symptom, business, Neuroscience, Microelectrodes, Wireless Technology

Abstract

OBJECT Despite a promising outlook, existing intraspinal microstimulation (ISMS) techniques for restoring functional motor control after spinal cord injury are not yet suitable for use outside a controlled laboratory environment. Thus, successful application of ISMS therapy in humans will require the use of versatile chronic neurostimulation systems. The objective of this study was to establish proof of principle for wireless control of ISMS to evoke controlled motor function in a rodent model of complete spinal cord injury. METHODS The lumbar spinal cord in each of 17 fully anesthetized Sprague-Dawley rats was stimulated via ISMS electrodes to evoke hindlimb function. Nine subjects underwent complete surgical transection of the spinal cord at the T-4 level 7 days before stimulation. Targeting for both groups (spinalized and control) was performed under visual inspection via dorsal spinal cord landmarks such as the dorsal root entry zone and the dorsal median fissure. Teflon-insulated stimulating platinum-iridium microwire electrodes (50 μm in diameter, with a 30- to 60-μm exposed tip) were implanted within the ventral gray matter to an approximate depth of 1.8 mm. Electrode implantation was performed using a free-hand delivery technique (n = 12) or a Kopf spinal frame system (n = 5) to compare the efficacy of these 2 commonly used targeting techniques. Stimulation was controlled remotely using a wireless neurostimulation control system. Hindlimb movements evoked by stimulation were tracked via kinematic markers placed on the hips, knees, ankles, and paws. Postmortem fixation and staining of the spinal cord tissue were conducted to determine the final positions of the stimulating electrodes within the spinal cord tissue. RESULTS The results show that wireless ISMS was capable of evoking controlled and sustained activation of ankle, knee, and hip muscles in 90% of the spinalized rats (n = 9) and 100% of the healthy control rats (n = 8). No functional differences between movements evoked by either of the 2 targeting techniques were revealed. However, frame-based targeting required fewer electrode penetrations to evoke target movements. CONCLUSIONS Clinical restoration of functional movement via ISMS remains a distant goal. However, the technology presented herein represents the first step toward restoring functional independence for individuals with chronic spinal cord injury.

Published

2014

14. Optical stimulation for restoration of motor function after spinal cord injury

Author

Kendall H. Lee, Grant W. Mallory, J. Luis Lujan, Peter J. Grahn, and Jan T. Hachmann

Subjects

medicine.medical_specialty, business.industry, Electric Stimulation Therapy, General Medicine, Optogenetics, Spinal cord, medicine.disease, Motor function, Article, medicine.anatomical_structure, Physical medicine and rehabilitation, Spinal Cord, Optical stimulation, medicine, Functional electrical stimulation, Humans, business, Spinal cord injury, Neuroscience, Spinal Cord Injuries

Abstract

Spinal cord injury can be defined as a loss of communication between the brain and the body due to disrupted pathways within the spinal cord. Although many promising molecular strategies have emerged to reduce secondary injury and promote axonal regrowth, there is still no effective cure, and recovery of function remains limited. Functional electrical stimulation (FES) represents a strategy developed to restore motor function without the need for regenerating severed spinal pathways. Despite its technological success, however, FES has not been widely integrated into the lives of spinal cord injury survivors. In this review, we briefly discuss the limitations of existing FES technologies. Additionally, we discuss how optogenetics, a rapidly evolving technique used primarily to investigate select neuronal populations within the brain, may eventually be used to replace FES as a form of therapy for functional restoration after spinal cord injury.

Published

2014

15. Implantation of cauda equina nerve roots through a biodegradable scaffold at the conus medullaris in rat

Author

Sandeep Vaishya, Ann M. Schmeichel, Michael J. Yaszemski, Peter J. Grahn, Bingkun K. Chen, Anthony J. Windebank, Bradford L. Currier, Andrew M. Knight, and Robert J. Spinner

Subjects

Nerve root, Cauda Equina, Biocompatible Materials, Pilot Projects, Article, Rats, Sprague-Dawley, Polylactic Acid-Polyglycolic Acid Copolymer, medicine, Animals, Orthopedics and Sports Medicine, Lactic Acid, Axon, Spinal cord injury, Spinal Cord Injuries, Tissue Scaffolds, business.industry, Cauda equina, Anatomy, Recovery of Function, Motor neuron, Spinal cord, medicine.disease, Nerve Regeneration, Rats, Conus medullaris, medicine.anatomical_structure, Ventral nerve cord, Replantation, Surgery, Neurology (clinical), business, Polyglycolic Acid

Abstract

Background context Traumatic injuries occurring at the conus medullaris of the spinal cord cause permanent damage both to the central nervous system and to the cauda equina nerve roots. Purpose This proof-of-concept study was to determine whether implanting the nerve roots into a biodegradable scaffold would improve regeneration after injury. Methods All experimental works involving rats were performed according to the approved guidelines by the Mayo Clinic Institutional Animal Care and Use Committee. Surgical procedures were performed on 32 Sprague-Dawley rats. Four ventral cauda equina nerve roots were reimplanted either directly into the ventral cord stump or through a poly(lactic -co -glycolic acid) (PLGA) scaffold. These experimental groups were compared with a control group in which the nerves were inserted into a muscle fascia barrier that was placed between the spinal cord and the nerve roots. Animals were sacrificed at 4 weeks. Results There was no difference in motor neuron counts in the spinal cord rostral to the injury in all treatment groups, implying equal potential for the regeneration into implanted nerve roots. One-way analysis of variance testing, with Tukey post hoc test, showed a statistically significant improvement in axon regeneration through the injury in the PLGA scaffold treatment group compared with the control (p Conclusions This pilot study demonstrated that a PLGA scaffold improved regeneration of axons into peripheral nerve roots. However, the number of regenerating axons observed was limited and did not lead to functional recovery. Future experiments will employ a different scaffold material and possible growth factors or enzymes to increase axon populations.

Published

2013

16. Large Animal Model for Development of Functional Restoration Paradigms Using Epidural and Intraspinal Stimulation

Author

Grant W. Mallory, Kevin E. Bennet, Peter J. Grahn, Darlene A. Lobel, J. Luis Lujan, Allan J. Bieber, Kendall H. Lee, Ju Ho Jeong, Jan T. Hachmann, and Loribeth Q. Evertz

Subjects

Epidural Space, Swine, lcsh:Medicine, Electric Stimulation Therapy, Stimulation, Electromyography, Bioinformatics, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Functional electrical stimulation, lcsh:Science, Spinal cord injury, Spinal Cord Injuries, 030304 developmental biology, 0303 health sciences, Multidisciplinary, Muscle fatigue, medicine.diagnostic_test, business.industry, lcsh:R, Recovery of Function, Motor neuron, Spinal cord, medicine.disease, Epidural space, Disease Models, Animal, medicine.anatomical_structure, Spinal Cord, Brain-Computer Interfaces, Quality of Life, lcsh:Q, Female, business, Neuroscience, 030217 neurology & neurosurgery, Research Article

Abstract

Restoration of movement following spinal cord injury (SCI) has been achieved using electrical stimulation of peripheral nerves and skeletal muscles. However, practical limitations such as the rapid onset of muscle fatigue hinder clinical application of these technologies. Recently, direct stimulation of alpha motor neurons has shown promise for evoking graded, controlled, and sustained muscle contractions in rodent and feline animal models while overcoming some of these limitations. However, small animal models are not optimal for the development of clinical spinal stimulation techniques for functional restoration of movement. Furthermore, variance in surgical procedure, targeting, and electrode implantation techniques can compromise therapeutic outcomes and impede comparison of results across studies. Herein, we present a protocol and large animal model that allow standardized development, testing, and optimization of novel clinical strategies for restoring motor function following spinal cord injury. We tested this protocol using both epidural and intraspinal stimulation in a porcine model of spinal cord injury, but the protocol is suitable for the development of other novel therapeutic strategies. This protocol will help characterize spinal circuits vital for selective activation of motor neuron pools. In turn, this will expedite the development and validation of high-precision therapeutic targeting strategies and stimulation technologies for optimal restoration of motor function in humans.

Published

2013