J Rapp, B Sandurkov, A Lindenthal, L Mallaun, W Hemmert, B Gleich
{"title":"周围神经的波动和弯曲有利于线圈位置投射横向野。","authors":"J Rapp, B Sandurkov, A Lindenthal, L Mallaun, W Hemmert, B Gleich","doi":"10.1088/2057-1976/ae0ad8","DOIUrl":null,"url":null,"abstract":"<p><p>For peripheral magnetic stimulation it is widely accepted that the field components parallel to the nerve are responsible for stimulation. However, experimental findings have often suggested that transverse field components contribute as well or are even dominant. A reason for that discrepancy could be undulations or curving of the nerve. As a consequence, the question of ideal coil placement for magnetic stimulation is still not conclusively answered. To identify beneficial coil positions, we quantified the impact of undulation and nerve bending in this study. First, we performed neuronal simulations with different extent of fascicle and fibre undulations inside the field distribution of a figure-of-8 coil. Second, we simulated median nerve stimulation using an anatomical model of the forearm to include the contribution of nerve bending. Third, we conducted median nerve stimulation on healthy subjects with different wrist positions to manipulate undulations. Our simulations suggested both fascicle and fibre undulations cause transverse field components to cause lower thresholds than parallel ones. Simulations on median nerve stimulation showed that the position of the coil in relation to the nerve course has more impact than the orientation itself. Finally, the experimental validations confirmed that transverse coil positions produce smaller stimulation thresholds. Further, we saw that bending the wrist has a potential influence on thresholds, possibly due to undulations. We conclude that placing a round coil centrally above the nerve yields the lowest thresholds.</p>","PeriodicalId":8896,"journal":{"name":"Biomedical Physics & Engineering Express","volume":" ","pages":""},"PeriodicalIF":1.6000,"publicationDate":"2025-10-03","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Undulations and bending in peripheral nerves benefit coil positions projecting transverse fields.\",\"authors\":\"J Rapp, B Sandurkov, A Lindenthal, L Mallaun, W Hemmert, B Gleich\",\"doi\":\"10.1088/2057-1976/ae0ad8\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>For peripheral magnetic stimulation it is widely accepted that the field components parallel to the nerve are responsible for stimulation. However, experimental findings have often suggested that transverse field components contribute as well or are even dominant. A reason for that discrepancy could be undulations or curving of the nerve. As a consequence, the question of ideal coil placement for magnetic stimulation is still not conclusively answered. To identify beneficial coil positions, we quantified the impact of undulation and nerve bending in this study. First, we performed neuronal simulations with different extent of fascicle and fibre undulations inside the field distribution of a figure-of-8 coil. Second, we simulated median nerve stimulation using an anatomical model of the forearm to include the contribution of nerve bending. Third, we conducted median nerve stimulation on healthy subjects with different wrist positions to manipulate undulations. Our simulations suggested both fascicle and fibre undulations cause transverse field components to cause lower thresholds than parallel ones. Simulations on median nerve stimulation showed that the position of the coil in relation to the nerve course has more impact than the orientation itself. Finally, the experimental validations confirmed that transverse coil positions produce smaller stimulation thresholds. Further, we saw that bending the wrist has a potential influence on thresholds, possibly due to undulations. 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Undulations and bending in peripheral nerves benefit coil positions projecting transverse fields.
For peripheral magnetic stimulation it is widely accepted that the field components parallel to the nerve are responsible for stimulation. However, experimental findings have often suggested that transverse field components contribute as well or are even dominant. A reason for that discrepancy could be undulations or curving of the nerve. As a consequence, the question of ideal coil placement for magnetic stimulation is still not conclusively answered. To identify beneficial coil positions, we quantified the impact of undulation and nerve bending in this study. First, we performed neuronal simulations with different extent of fascicle and fibre undulations inside the field distribution of a figure-of-8 coil. Second, we simulated median nerve stimulation using an anatomical model of the forearm to include the contribution of nerve bending. Third, we conducted median nerve stimulation on healthy subjects with different wrist positions to manipulate undulations. Our simulations suggested both fascicle and fibre undulations cause transverse field components to cause lower thresholds than parallel ones. Simulations on median nerve stimulation showed that the position of the coil in relation to the nerve course has more impact than the orientation itself. Finally, the experimental validations confirmed that transverse coil positions produce smaller stimulation thresholds. Further, we saw that bending the wrist has a potential influence on thresholds, possibly due to undulations. We conclude that placing a round coil centrally above the nerve yields the lowest thresholds.
期刊介绍:
BPEX is an inclusive, international, multidisciplinary journal devoted to publishing new research on any application of physics and/or engineering in medicine and/or biology. Characterized by a broad geographical coverage and a fast-track peer-review process, relevant topics include all aspects of biophysics, medical physics and biomedical engineering. Papers that are almost entirely clinical or biological in their focus are not suitable. The journal has an emphasis on publishing interdisciplinary work and bringing research fields together, encompassing experimental, theoretical and computational work.
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