研究者業績

中江 俊介

Shunsuke Nakae

基本情報

所属
藤田医科大学 医学部 医学科 脳神経外科学 講師
学位
医学博士(藤田医科大学)
Master of Science(San Diego State University)

J-GLOBAL ID
201501021123484677
researchmap会員ID
7000012929

論文

 48
  • Koji Ohyama, Shunsuke Nakae, Yuki Uehara
    Infection 2024年6月10日  査読有り
  • 大場 茂生, 杉原 英志, 山田 勢至, 中江 俊介, 西山 悠也, 武藤 淳, 安達 一英, 安部 雅人, 佐谷 秀行, 廣瀬 雄一
    Brain Tumor Pathology 40(Suppl.) 061-061 2023年5月  
  • Shunsuke Nakae, Masanobu Kumon, Takao Teranishi, Shigeo Ohba, Yuichi Hirose
    Brain Sciences 13(3) 482-482 2023年3月13日  査読有り筆頭著者責任著者
    Fence-post catheter techniques are used to use tumor margins when resecting gliomas. In the present study, deep electrodes instead of catheters were used as fence-posts. The case of a 25-year-old female patient whose magnetic resonance images (MRI) revealed a tumor in the left cingulate gyrus is presented in this study. She underwent daily seizures without loss of consciousness under the administration of anti-seizure medications. Despite video electroencephalography (EEG) monitoring, the scalp inter-ictal EEG did not show obvious epileptiform discharges. We were consequently uncertain whether such frequent seizures were epileptic seizures or not. As a result, deep electrodes were used as fence-posts: three deep electrodes were inserted into the tumor’s anterior, lateral, and posterior margins using a navigation-guided method. The highest epileptic discharge was detected from the anterior deep electrode. As a result, ahead of the tumor was extendedly resected, and epileptic discharges were eliminated using EEG. The postoperative MRI revealed that the tumor was resected. The patient has never experienced seizures after the surgery. In conclusion, when supratentorial gliomas complicated by frequent seizures are resected, intraoperative EEG monitoring using deep electrodes as fence-posts is useful for estimating epileptogenic areas.
  • Shunsuke Nakae, Masanobu Kumon, Akio Katagata, Kazuhiro Murayama, Yuichi Hirose
    Brain Sciences 13(3) 396-396 2023年2月25日  査読有り筆頭著者責任著者
    Vagus nerve stimulation (VNS) is an effective surgical option for intractable epilepsy. Although the surgical procedure is not so complicated, vagus nerve detection is sometimes difficult due to its anatomical variations, which may lead to surgical manipulation-associated complications. Thus, this study aimed to visualize the vagus nerve location preoperatively by fused images of three-dimensional computed tomography angiography (3D-CTA) and magnetic resonance imaging (MRI). This technique was applied to two cases. The neck 3D-CTA and MRI were performed, and the fused images were generated using the software. The vagus nerve and its anatomical relationship with the internal jugular vein (IJV) and common carotid artery were clearly visualized. The authors predicted that the vagus nerve was detected by laterally pulling the IJV according to the images. Intraoperatively, the vagus nerve was located as the authors predicted. The time of the surgery until the vagus nerve detection was <60 min in both cases. This novel radiological technique for visualizing the vagus nerve is effective to quickly detect the vagus nerve, which has anatomical variations, during the VNS.
  • Shigeo Ohba, Kazuhiro Murayama, Takao Teranishi, Masanobu Kumon, Shunsuke Nakae, Masao Yui, Kaori Yamamoto, Seiji Yamada, Masato Abe, Mitsuhiro Hasegawa, Yuichi Hirose
    Cancers 15(3) 952-952 2023年2月2日  
    Distinguishing primary central nervous system lymphoma (PCNSL) from glioblastoma, isocitrate dehydrogenase (IDH)-wildtype is sometimes hard. Because the role of operation on them varies, accurate preoperative diagnosis is crucial. In this study, we evaluated whether a specific kind of chemical exchange saturation transfer imaging, i.e., amide proton transfer-weighted (APTw) imaging, was useful to distinguish PCNSL from glioblastoma, IDH-wildtype. A total of 14 PCNSL and 27 glioblastoma, IDH-wildtype cases were evaluated. There was no significant difference in the mean APTw signal values between the two groups. However, the percentile values from the 1st percentile to the 20th percentile APTw signals and the width1–100 APTw signals significantly differed. The highest area under the curve was 0.796, which was obtained from the width1–100 APTw signal values. The sensitivity and specificity values were 64.3% and 88.9%, respectively. APTw imaging was useful to distinguish PCNSL from glioblastoma, IDH-wildtype. To avoid unnecessary aggressive surgical resection, APTw imaging is recommended for cases in which PCNSL is one of the differential diagnoses.

MISC

 31

講演・口頭発表等

 69

共同研究・競争的資金等の研究課題

 4

学術貢献活動

 1