Your search keyword '"Moria Ankry"' showing total 6 results

1. Rotational field TMS: Comparison with conventional TMS based on motor evoked potentials and thresholds in the hand and leg motor cortices

Author

Yiftach Roth, Gaby S. Pell, Noam Barnea-Ygael, Moria Ankry, Yafit Hadad, Ami Eisen, Yuri Burnishev, Aron Tendler, Elisha Moses, and Abraham Zangen

Subjects

TMS, Rotational field, Unidirectional, Motor cortex, MEP, Motor threshold, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Background: Transcranial magnetic stimulation (TMS) is a rapidly expanding technology utilized in research and neuropsychiatric treatments. Yet, conventional TMS configurations affect primarily neurons that are aligned parallel to the induced electric field by a fixed coil, making the activation orientation-specific. A novel method termed rotational field TMS (rfTMS), where two orthogonal coils are operated with a 90° phase shift, produces rotation of the electric field vector over almost a complete cycle, and may stimulate larger portion of the neuronal population within a given brain area. Objective: To compare the physiological effects of rfTMS and conventional unidirectional TMS (udTMS) in the motor cortex. Methods: Hand and leg resting motor thresholds (rMT), and motor evoked potential (MEP) amplitudes and latencies (at 120% of rMT), were measured using a dual-coil array based on the H7-coil, in 8 healthy volunteers following stimulation at different orientations of either udTMS or rfTMS. Results: For both target areas rfTMS produced significantly lower rMTs and much higher MEPs than those induced by udTMS, for comparable induced electric field amplitude. Both hand and leg rMTs were orientation-dependent. Conclusions: rfTMS induces stronger physiologic effects in targeted brain regions at significantly lower intensities. Importantly, given the activation of a much larger population of neurons within a certain brain area, repeated application of rfTMS may induce different neuroplastic effects in neural networks, opening novel research and clinical opportunities.

Published

2020

2. Rotational field TMS: Comparison with conventional TMS based on motor evoked potentials and thresholds in the hand and leg motor cortices

Author

Abraham Zangen, Elisha Moses, Yafit Hadad, Moria Ankry, Yiftach Roth, Noam Barnea-Ygael, Ami Eisen, Aron Tendler, Yuri Burnishev, and Gaby S. Pell

Subjects

Adult, Male, medicine.medical_treatment, Population, Biophysics, Stimulation, 050105 experimental psychology, lcsh:RC321-571, Motor threshold, 03 medical and health sciences, 0302 clinical medicine, Rotational field, Electric field, Neuroplasticity, medicine, Humans, 0501 psychology and cognitive sciences, Evoked potential, education, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Physics, Leg, education.field_of_study, Electromyography, General Neuroscience, 05 social sciences, MEP, Evoked Potentials, Motor, Hand, Transcranial Magnetic Stimulation, Transcranial magnetic stimulation, medicine.anatomical_structure, Electromagnetic coil, TMS, Unidirectional, Motor cortex, Female, Neurology (clinical), Neuroscience, 030217 neurology & neurosurgery

Abstract

Background Transcranial magnetic stimulation (TMS) is a rapidly expanding technology utilized in research and neuropsychiatric treatments. Yet, conventional TMS configurations affect primarily neurons that are aligned parallel to the induced electric field by a fixed coil, making the activation orientation-specific. A novel method termed rotational field TMS (rfTMS), where two orthogonal coils are operated with a 90° phase shift, produces rotation of the electric field vector over almost a complete cycle, and may stimulate larger portion of the neuronal population within a given brain area. Objective To compare the physiological effects of rfTMS and conventional unidirectional TMS (udTMS) in the motor cortex. Methods Hand and leg resting motor thresholds (rMT), and motor evoked potential (MEP) amplitudes and latencies (at 120% of rMT), were measured using a dual-coil array based on the H7-coil, in 8 healthy volunteers following stimulation at different orientations of either udTMS or rfTMS. Results For both target areas rfTMS produced significantly lower rMTs and much higher MEPs than those induced by udTMS, for comparable induced electric field amplitude. Both hand and leg rMTs were orientation-dependent. Conclusions rfTMS induces stronger physiologic effects in targeted brain regions at significantly lower intensities. Importantly, given the activation of a much larger population of neurons within a certain brain area, repeated application of rfTMS may induce different neuroplastic effects in neural networks, opening novel research and clinical opportunities.

Published

2020

3. Comparing rotational-field-dTMS to unidirectional-dTMS in healthy volunteers

Author

Ami Eisen, Elisha Moses, Abraham Zangen, Moria Ankry, Y. Hadad, Yiftach Roth, Yuri Burnishev, Aron Tendler, and Gaby S. Pell

Subjects

Field (physics), General Neuroscience, Healthy volunteers, Biophysics, Neurology (clinical), Geodesy, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Geology, lcsh:RC321-571

Published

2019

4. Safety and characterization of a novel multi-channel TMS stimulator

Author

Abraham Zangen, Yechiel Levkovitz, Gaby S. Pell, Moria Ankry, and Yiftach Roth

Subjects

Adult, Male, Materials science, medicine.medical_treatment, Single coil, Biophysics, Stimulation, lcsh:RC321-571, medicine, Humans, Muscle, Skeletal, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Multi channel, Equipment Safety, Pulse (signal processing), Orientation (computer vision), General Neuroscience, Brain, Multi-channel, Stimulator, Transcranial Magnetic Stimulation, Sequential, Transcranial magnetic stimulation, Electromagnetic coil, Female, Neurology (clinical), Simultaneous, Biomedical engineering, Communication channel

Abstract

Background Currently available TMS stimulators have a single channel operating a single coil. Objective To outline and present physical and physiological benefits of a novel convenient multi-channel stimulator, comprising five channels, where the stimulation parameters of each channel are independently controllable. Methods Simultaneous and sequential operation of various channels was tested in healthy volunteers. Paired pulses schemes with various inter-stimulus intervals (ISIs) were studied for the hand APB and the leg AH muscles. Energy consumption and coil heating rates with simultaneous operation of 4 channels was compared to a single figure-8 coil. Results Repetitive operation of separate channels with different stimulation parameters is demonstrated. The operations of various channels can be combined simultaneously or sequentially to induce multiple pulses with ISIs of μs resolution. A universal pattern of inhibition and facilitation as a function of ISI was found, with some dependence on coils configurations and on pulse widths. A strong dependence of the induced inhibition on the relative orientation of the conditioning and test pulses was discovered. The ability of this method to induce inhibition in shallow brain region but not in deeper region, thus focusing the effect in the deep brain region, is demonstrated. A significant saving in energy consumption and a reduction in coil heating were demonstrated for several channels operated simultaneously compared to a standard single channel figure-8 coil. Conclusions The multi-channel stimulator enables the synchronized induction of different excitability modulations to different brain regions using different stimulation patterns in various channels. Multiple pulses operation with coils with various depth profiles can increase the focality of TMS effect in deep brain regions.

Published

2013

5. P643: Safety and characterization of a novel multi-channel TMS stimulator

Author

Moria Ankry, Y. Levkovitz, Yiftach Roth, Abraham Zangen, and Gaby S. Pell

Subjects

Materials science, Orientation (computer vision), Pulse (signal processing), Single coil, Stimulation, Sensory Systems, Brain region, Neurology, Electromagnetic coil, Physiology (medical), Neurology (clinical), Multi channel, Biomedical engineering, Communication channel

Abstract

Background: Currently available TMS stimulators have a single channel operating a single coil. Objective: To outline and present physical and physiological benefits of a novel convenient multi-channel stimulator, comprising five channels, where the stimulation parameters of each channel are independently controllable. Methods: Simultaneous and sequential operation of various channels was tested in healthy volunteers. Paired pulses schemes with various inter-stimulus intervals (ISIs) were studied for the hand APB and the leg AH muscles. Energy consumption and coil heating rates with simultaneous operation of 4 channels was compared to a single figure-8 coil. Results: Repetitive operation of separate channels with different stimulation parameters is demonstrated. The operations of various channels can be combined simultaneously or sequentially to induce multiple pulses with ISIs of ms resolution. A universal pattern of inhibition and facilitation as a function of ISI was found, with some dependence on coils configurations and on pulse widths. A strong dependence of the induced inhibition on the relative orientation of the conditioning and test pulses was discovered. The ability of this method to induce inhibition in shallow brain region but not in deeper region, thus focusing the effect in the deep brain region, is demonstrated. A significant saving in energy consumption and a reduction in coil heating were demonstrated for several channels operated simultaneously compared to a standard single channel figure-8 coil. Conclusions: The multi-channel stimulator enables the synchronized induction of different excitability modulations to different brain regions using different stimulation patterns in various channels. Multiple pulses operation with coils with various depth profiles can increase the focality of TMS effect in deep brain regions.

Published

2014

6. Safety and characterization of a novel multi-channel TMS stimulator

Author

Amit Ginou, Yiftach Roth, Yechiel Levkovitz, Gaby S. Pell, Moria Ankry, and Abraham Zangen

Subjects

General Neuroscience, Biophysics, Neurology (clinical), lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, lcsh:RC321-571

Published

2014