Your search keyword '"Hosomi, Koichi"' showing total 9 results

1. Repetitive transcranial magnetic stimulation restores altered functional connectivity of central poststroke pain model monkeys

Author

Kadono, Yoshinori, Koguchi, Keigo, Okada, Ken-ichi, Hosomi, Koichi, Hiraishi, Motoki, Ueguchi, Takashi, Kida, Ikuhiro, Shah, Adnan, Liu, Guoxiang, Saitoh, Youichi, Kadono, Yoshinori, Koguchi, Keigo, Okada, Ken-ichi, Hosomi, Koichi, Hiraishi, Motoki, Ueguchi, Takashi, Kida, Ikuhiro, Shah, Adnan, Liu, Guoxiang, and Saitoh, Youichi

Abstract

Central poststroke pain (CPSP) develops after a stroke around the somatosensory pathway. CPSP is hypothesized to be caused by maladaptive reorganization between various brain regions. The treatment for CPSP has not been established; however, repetitive transcranial magnetic stimulation (rTMS) to the primary motor cortex has a clinical effect. To verify the functional reorganization hypothesis for CPSP development and rTMS therapeutic mechanism, we longitudinally pursued the structural and functional changes of the brain by using two male CPSP model monkeys (Macaca fuscata) developed by unilateral hemorrhage in the ventral posterolateral nucleus of the thalamus. Application of rTMS to the ipsilesional primary motor cortex relieved the induced pain of the model monkeys. A tractography analysis revealed a decrease in the structural connectivity in the ipsilesional thalamocortical tract, and rTMS had no effect on the structural connectivity. A region of interest analysis using resting-state functional magnetic resonance imaging revealed inappropriately strengthened functional connectivity between the ipsilesional mediodorsal nucleus of the thalamus and the amygdala, which are regions associated with emotion and memory, suggesting that this may be the cause of CPSP development. Moreover, rTMS normalizes this strengthened connectivity, which may be a possible therapeutic mechanism of rTMS for CPSP.

Published

2021

2. A multi-site, multi-disorder resting-state magnetic resonance image database.

Author

C Tanaka, Saori, Yamashita, Ayumu, Yahata, Noriaki, Itahashi, Takashi, Lisi, Giuseppe, Yamada, Takashi, Ichikawa, Naho, Takamura, Masahiro, Yoshihara, Yujiro, Kunimatsu, Akira, Okada, Naohiro, Hashimoto, Ryuichiro, Okada, Go, Sakai, Yuki, Morimoto, Jun, Narumoto, Jin, Shimada, Yasuhiro, Mano, Hiroaki, Yoshida, Wako, Seymour, Ben, Shimizu, Takeshi, Hosomi, Koichi, Saitoh, Youichi, Kasai, Kiyoto, Kato, Nobumasa, Takahashi, Hidehiko, Okamoto, Yasumasa, Yamashita, Okito, Kawato, Mitsuo, Imamizu, Hiroshi, Noriaki, Yahata, C Tanaka, Saori, Yamashita, Ayumu, Yahata, Noriaki, Itahashi, Takashi, Lisi, Giuseppe, Yamada, Takashi, Ichikawa, Naho, Takamura, Masahiro, Yoshihara, Yujiro, Kunimatsu, Akira, Okada, Naohiro, Hashimoto, Ryuichiro, Okada, Go, Sakai, Yuki, Morimoto, Jun, Narumoto, Jin, Shimada, Yasuhiro, Mano, Hiroaki, Yoshida, Wako, Seymour, Ben, Shimizu, Takeshi, Hosomi, Koichi, Saitoh, Youichi, Kasai, Kiyoto, Kato, Nobumasa, Takahashi, Hidehiko, Okamoto, Yasumasa, Yamashita, Okito, Kawato, Mitsuo, Imamizu, Hiroshi, and Noriaki, Yahata

Abstract

Machine learning classifiers for psychiatric disorders using resting-state functional magnetic resonance imaging (rs-fMRI) have recently attracted attention as a method for directly examining relationships between neural circuits and psychiatric disorders. To develop accurate and generalizable classifiers, we compiled a large-scale, multi-site, multi-disorder neuroimaging database. The database comprises resting-state fMRI and structural images of the brain from 993 patients and 1,421 healthy individuals, as well as demographic information such as age, sex, and clinical rating scales. To harmonize the multi-site data, nine healthy participants ("traveling subjects") visited the sites from which the above datasets were obtained and underwent neuroimaging with 12 scanners. All participants consented to having their data shared and analyzed at multiple medical and research institutions participating in the project, and 706 patients and 1,122 healthy individuals consented to having their data disclosed. Finally, we have published four datasets: 1) the SRPBS Multi-disorder Connectivity Dataset 2), the SRPBS Multi-disorder MRI Dataset (restricted), 3) the SRPBS Multi-disorder MRI Dataset (unrestricted), and 4) the SRPBS Traveling Subject MRI Dataset.

Published

2021

3. Repetitive transcranial magnetic stimulation restores altered functional connectivity of central poststroke pain model monkeys

Author

Kadono, Yoshinori, Koguchi, Keigo, Okada, Ken-ichi, Hosomi, Koichi, Hiraishi, Motoki, Ueguchi, Takashi, Kida, Ikuhiro, Shah, Adnan, Liu, Guoxiang, Saitoh, Youichi, Kadono, Yoshinori, Koguchi, Keigo, Okada, Ken-ichi, Hosomi, Koichi, Hiraishi, Motoki, Ueguchi, Takashi, Kida, Ikuhiro, Shah, Adnan, Liu, Guoxiang, and Saitoh, Youichi

Abstract

Central poststroke pain (CPSP) develops after a stroke around the somatosensory pathway. CPSP is hypothesized to be caused by maladaptive reorganization between various brain regions. The treatment for CPSP has not been established; however, repetitive transcranial magnetic stimulation (rTMS) to the primary motor cortex has a clinical effect. To verify the functional reorganization hypothesis for CPSP development and rTMS therapeutic mechanism, we longitudinally pursued the structural and functional changes of the brain by using two male CPSP model monkeys (Macaca fuscata) developed by unilateral hemorrhage in the ventral posterolateral nucleus of the thalamus. Application of rTMS to the ipsilesional primary motor cortex relieved the induced pain of the model monkeys. A tractography analysis revealed a decrease in the structural connectivity in the ipsilesional thalamocortical tract, and rTMS had no effect on the structural connectivity. A region of interest analysis using resting-state functional magnetic resonance imaging revealed inappropriately strengthened functional connectivity between the ipsilesional mediodorsal nucleus of the thalamus and the amygdala, which are regions associated with emotion and memory, suggesting that this may be the cause of CPSP development. Moreover, rTMS normalizes this strengthened connectivity, which may be a possible therapeutic mechanism of rTMS for CPSP.

Published

2021

4. BCI training to move a virtual hand reduces phantom limb pain: A randomized crossover trial

Author

50418513, Yanagisawa, Takufumi, Fukuma, Ryohei, Seymour, Ben, Tanaka, Masataka, Hosomi, Koichi, Yamashita, Okito, Kishima, Haruhiko, Kamitani, Yukiyasu, Saitoh, Youichi, 50418513, Yanagisawa, Takufumi, Fukuma, Ryohei, Seymour, Ben, Tanaka, Masataka, Hosomi, Koichi, Yamashita, Okito, Kishima, Haruhiko, Kamitani, Yukiyasu, and Saitoh, Youichi

Abstract

Objective: To determine whether training with a brain–computer interface (BCI) to control an image of a phantom hand, which moves based on cortical currents estimated from magnetoencephalographic signals, reduces phantom limb pain. Methods: Twelve patients with chronic phantom limb pain of the upper limb due to amputation or brachial plexus root avulsion participated in a randomized single-blinded crossover trial. Patients were trained to move the virtual hand image controlled by the BCI with a real decoder, which was constructed to classify intact hand movements from motor cortical currents, by moving their phantom hands for 3 days (“real training”). Pain was evaluated using a visual analogue scale (VAS) before and after training, and at follow-up for an additional 16 days. As a control, patients engaged in the training with the same hand image controlled by randomly changing values (“random training”). The 2 trainings were randomly assigned to the patients. This trial is registered at UMIN-CTR (UMIN000013608). Results: VAS at day 4 was significantly reduced from the baseline after real training (mean [SD], 45.3 [24.2]–30.9 [20.6], 1/100 mm; p = 0.009 < 0.025), but not after random training (p = 0.047 > 0.025). Compared to VAS at day 1, VAS at days 4 and 8 was significantly reduced by 32% and 36%, respectively, after real training and was significantly lower than VAS after random training (p < 0.01). Conclusion: Three-day training to move the hand images controlled by BCI significantly reduced pain for 1 week. Classification of evidence: This study provides Class III evidence that BCI reduces phantom limb pain.

Published

2020

5. Induced sensorimotor brain plasticity controls pain in phantom limb patients

Author

50418513, Yanagisawa, Takufumi, Fukuma, Ryohei, Seymour, Ben, Hosomi, Koichi, Kishima, Haruhiko, Shimizu, Takeshi, Yokoi, Hiroshi, Hirata, Masayuki, Yoshimine, Toshiki, Kamitani, Yukiyasu, Saitoh, Youichi, 50418513, Yanagisawa, Takufumi, Fukuma, Ryohei, Seymour, Ben, Hosomi, Koichi, Kishima, Haruhiko, Shimizu, Takeshi, Yokoi, Hiroshi, Hirata, Masayuki, Yoshimine, Toshiki, Kamitani, Yukiyasu, and Saitoh, Youichi

Abstract

The cause of pain in a phantom limb after partial or complete deafferentation is an important problem. A popular but increasingly controversial theory is that it results from maladaptive reorganization of the sensorimotor cortex, suggesting that experimental induction of further reorganization should affect the pain, especially if it results in functional restoration. Here we use a brain–machine interface (BMI) based on real-time magnetoencephalography signals to reconstruct affected hand movements with a robotic hand. BMI training induces significant plasticity in the sensorimotor cortex, manifested as improved discriminability of movement information and enhanced prosthetic control. Contrary to our expectation that functional restoration would reduce pain, the BMI training with the phantom hand intensifies the pain. In contrast, BMI training designed to dissociate the prosthetic and phantom hands actually reduces pain. These results reveal a functional relevance between sensorimotor cortical plasticity and pain, and may provide a novel treatment with BMI neurofeedback.

Published

2016

6. Real-time control of a neuroprosthetic hand by magnetoencephalographic signals from paralysed patients

Author

50418513, Fukuma, Ryohei, Yanagisawa, Takufumi, Saitoh, Youichi, Hosomi, Koichi, Kishima, Haruhiko, Shimizu, Takeshi, Sugata, Hisato, Yokoi, Hiroshi, Hirata, Masayuki, Kamitani, Yukiyasu, Yoshimine, Toshiki, 50418513, Fukuma, Ryohei, Yanagisawa, Takufumi, Saitoh, Youichi, Hosomi, Koichi, Kishima, Haruhiko, Shimizu, Takeshi, Sugata, Hisato, Yokoi, Hiroshi, Hirata, Masayuki, Kamitani, Yukiyasu, and Yoshimine, Toshiki

Abstract

Neuroprosthetic arms might potentially restore motor functions for severely paralysed patients. Invasive measurements of cortical currents using electrocorticography have been widely used for neuroprosthetic control. Moreover, magnetoencephalography (MEG) exhibits characteristic brain signals similar to those of invasively measured signals. However, it remains unclear whether non-invasively measured signals convey enough motor information to control a neuroprosthetic hand, especially for severely paralysed patients whose sensorimotor cortex might be reorganized. We tested an MEG-based neuroprosthetic system to evaluate the accuracy of using cortical currents in the sensorimotor cortex of severely paralysed patients to control a prosthetic hand. The patients attempted to grasp with or open their paralysed hand while the slow components of MEG signals (slow movement fields; SMFs) were recorded. Even without actual movements, the SMFs of all patients indicated characteristic spatiotemporal patterns similar to actual movements, and the SMFs were successfully used to control a neuroprosthetic hand in a closed-loop condition. These results demonstrate that the slow components of MEG signals carry sufficient information to classify movement types. Successful control by paralysed patients suggests the feasibility of using an MEG-based neuroprosthetic hand to predict a patient's ability to control an invasive neuroprosthesis via the same signal sources as the non-invasive method.

Published

2016

7. Eccentric Figure-Eight Coils for Transcranial Magnetic Stimulation

Author

Sekino, Masaki, Ohsaki, Hiroyuki, Takiyama, Yoshihiro, Yamamoto, Keita, Matsuzaki, Taiga, Yasumuro, Yoshihiro, Nishikawa, Atsushi; HNnpWVcN, Maruo, Tomoyuki, Hosomi, Koichi, Saitoh, Youichi, Sekino, Masaki, Ohsaki, Hiroyuki, Takiyama, Yoshihiro, Yamamoto, Keita, Matsuzaki, Taiga, Yasumuro, Yoshihiro, Nishikawa, Atsushi; HNnpWVcN, Maruo, Tomoyuki, Hosomi, Koichi, and Saitoh, Youichi

Abstract

Previously we proposed an eccentric figure-eight coil that can cause threshold stimulation in the brain at lower driving currents. In this study, we performed numerical simulations and magnetic stimulations to healthy subjects for evaluating the advantages of the eccentric coil. The simulations were performed using a simplified spherical brain model and a realistic human brain model. We found that the eccentric coil required a driving current intensity of approximately 18% less than that required by the concentric coil to cause comparable eddy current densities within the brain. The eddy current localization of the eccentric coil was slightly higher than that of the concentric coil. A prototype eccentric coil was designed and fabricated. Instead of winding a wire around a bobbin, we cut eccentric-spiral slits on the insulator cases, and a wire was woven through the slits. The coils were used to deliver magnetic stimulation to healthy subjects; among our results, we found that the current slew rate corresponding to motor threshold values for the concentric and eccentric coils were 86 and 78 A/µs, respectively. The results indicate that the eccentric coil consistently requires a lower driving current to reach the motor threshold than the concentric coil. Future development of compact magnetic stimulators will enable the treatment of some intractable neurological diseases at home. Bioelectromagnetics. 35:55–65, 2015. © 2014 Wiley Periodicals, Inc.

Published

2015

8. Repetitive transcranial magnetic stimulation focusing on patients with neuropathic pain in the upper limb: a randomized sham-controlled parallel trial

Author

Mori, Nobuhiko, Hosomi, Koichi, Nishi, Asaya, Miyake, Akimitsu, Yamada, Tomomi, Matsugi, Akiyoshi, Jono, Yasutomo, Lim, Chanseok, Khoo, Hui Ming, Tani, Naoki, Oshino, Satoru, Saitoh, Youichi, Kishima, Haruhiko, Mori, Nobuhiko, Hosomi, Koichi, Nishi, Asaya, Miyake, Akimitsu, Yamada, Tomomi, Matsugi, Akiyoshi, Jono, Yasutomo, Lim, Chanseok, Khoo, Hui Ming, Tani, Naoki, Oshino, Satoru, Saitoh, Youichi, and Kishima, Haruhiko

Abstract

Mori N., Hosomi K., Nishi A., et al. Repetitive transcranial magnetic stimulation focusing on patients with neuropathic pain in the upper limb: a randomized sham-controlled parallel trial. Scientific Reports 14, 11811 (2024); https://doi.org/10.1038/s41598-024-62018-x., This study aimed to evaluate the efficacy and safety of navigation-guided repetitive transcranial magnetic stimulation (rTMS) over the primary motor cortex in patients with neuropathic pain in the upper limb. This randomized, blinded, sham-controlled, parallel trial included a rTMS protocol (10-Hz, 2000 pulses/session) consisting of five daily sessions, followed by one session per week for the next seven weeks. Pain intensity, as well as pain-related disability, quality of life, and psychological status, were assessed. For the primary outcome, pain intensity was measured daily using a numerical rating scale as a pain diary. Thirty patients were randomly assigned to the active rTMS or sham-stimulation groups. In the primary outcome, the decrease (least square [LS] mean ± standard error) in the weekly average of a pain diary at week 9 compared to the baseline was 0.84 ± 0.31 in the active rTMS group and 0.58 ± 0.29 in the sham group (LS mean difference, 0.26; 95% confidence interval, − 0.60 to 1.13). There was no significant effect on the interaction between the treatment group and time point. Pain-related disability score improved, but other assessments showed no differences. No serious adverse events were observed. This study did not show significant pain relief; however, active rTMS tended to provide better results than sham. rTMS has the potential to improve pain-related disability in addition to pain relief.

9. Repetitive transcranial magnetic stimulation focusing on patients with neuropathic pain in the upper limb: a randomized sham-controlled parallel trial

Author

Mori, Nobuhiko, Hosomi, Koichi, Nishi, Asaya, Miyake, Akimitsu, Yamada, Tomomi, Matsugi, Akiyoshi, Jono, Yasutomo, Lim, Chanseok, Khoo, Hui Ming, Tani, Naoki, Oshino, Satoru, Saitoh, Youichi, Kishima, Haruhiko, Mori, Nobuhiko, Hosomi, Koichi, Nishi, Asaya, Miyake, Akimitsu, Yamada, Tomomi, Matsugi, Akiyoshi, Jono, Yasutomo, Lim, Chanseok, Khoo, Hui Ming, Tani, Naoki, Oshino, Satoru, Saitoh, Youichi, and Kishima, Haruhiko

Abstract

Mori N., Hosomi K., Nishi A., et al. Repetitive transcranial magnetic stimulation focusing on patients with neuropathic pain in the upper limb: a randomized sham-controlled parallel trial. Scientific Reports 14, 11811 (2024); https://doi.org/10.1038/s41598-024-62018-x., This study aimed to evaluate the efficacy and safety of navigation-guided repetitive transcranial magnetic stimulation (rTMS) over the primary motor cortex in patients with neuropathic pain in the upper limb. This randomized, blinded, sham-controlled, parallel trial included a rTMS protocol (10-Hz, 2000 pulses/session) consisting of five daily sessions, followed by one session per week for the next seven weeks. Pain intensity, as well as pain-related disability, quality of life, and psychological status, were assessed. For the primary outcome, pain intensity was measured daily using a numerical rating scale as a pain diary. Thirty patients were randomly assigned to the active rTMS or sham-stimulation groups. In the primary outcome, the decrease (least square [LS] mean ± standard error) in the weekly average of a pain diary at week 9 compared to the baseline was 0.84 ± 0.31 in the active rTMS group and 0.58 ± 0.29 in the sham group (LS mean difference, 0.26; 95% confidence interval, − 0.60 to 1.13). There was no significant effect on the interaction between the treatment group and time point. Pain-related disability score improved, but other assessments showed no differences. No serious adverse events were observed. This study did not show significant pain relief; however, active rTMS tended to provide better results than sham. rTMS has the potential to improve pain-related disability in addition to pain relief.