Application of multi-modal neuroimaging data information management system in functional neurosurgery

doi:10.3969/j.issn.1672-6731.2024.07.005

Abstract

Abstract:

Background: Multi-modal neuroimaging examinations play a crucial role in the diagnosis and treatment of functional neurosurgery. However, there is currently a lack of effective management for these complex data in clinical practice. This study attempts to establish a feasible multi- modal neuroimaging data information management system and evaluate its application effects. Methods: By standardizing clinical diagnosis and treatment processes, analyzing the nodes where imaging data were generated, and streamlining data flow routes, establishing storage naming conventions, setting up storage servers, and training specialized personnel, we designed and applied a multi-modal neuroimaging data information management system. The primary evaluation indicators were the archiving rates of 5 types of data: structural sequences, other preoperative images, postoperative electrode CT, electrode reconstruction, and postoperative CT/MRI. The secondary evaluation indicators included the total man-hours consumed for data archiving and the average man-hours consumed per case. Results: Without multi-modal neuroimaging data information management (control group, n = 64), the total manpower consumption was 192 man-hours, with an average of 3 man-hours per case. With multi-modal neuroimaging data information management (data management group, n = 50), the total manpower consumption was 84 man-hours, with an average of 1.68 man-hours per case. The data management group had higher archiving rates compared to the control group: structural sequences [100% (50/50) vs. 32.81% (21/64); χ² = 11.383, P = 0.001], other preoperative images [96% (48/50) vs. 26.56% (17/64); χ² = 13.839, P = 0.000], postoperative electrode CT [96% (48/50) vs. 32.81% (21/64); χ² = 10.409, P = 0.001], electrode reconstruction [96% (48/50) vs. 32.81% (21/64); χ² = 10.409, P = 0.001], postoperative CT/MRI [96% (48/50) vs. 15.63% (10/64); χ² = 22.169, P = 0.000]. Conclusions: Designing a multi-modal neuroimaging data information management system that aligns with clinical practice and reasonably setting data collection and archiving nodes can effectively improve data archiving rates, save manpower resources, ensure the complete storage of clinical data, and ensure the smooth operation of clinical tasks, and enhance clinical diagnosis and treatment levels.

Key words: Neurosurgery, Neuroimaging, Electronic data processing, Health workforce

摘要：

研究背景: 多模态神经影像学检查在功能神经外科的诊断与治疗中发挥重要作用，但目前临床对这些复杂数据的管理有所欠缺。本研究尝试建立一套可行的多模态神经影像学数据信息管理系统并评估其应用效果。方法: 通过规范临床诊疗流程、分析影像学数据产生节点及梳理数据流动线路、建立存储命名规则，以及搭建存储服务器、培训专业人员等措施，设计并应用多模态神经影像学数据信息管理系统，以术前结构序列、其他术前影像、电极术后CT、电极重建、术后CT/MRI共5类数据的归档率作为主要评估指标，以数据归档消耗的总人·时和每例病例消耗的平均人·时作为次要评估指标。结果: 未进行多模态神经影像学数据信息管理（对照组，64例）的情况下，总人力消耗为192人·时，平均为3人·时/例；进行多模态神经影像学数据信息管理（数据管理组，50例）的情况下，总人力消耗84人·时，平均为1.68人·时/例。数据管理组术前结构序列[100%（50/50）对32.81%（21/64）；χ²=11.383，P=0.001]、其他术前影像[96%（48/50）对26.56%（17/64）；χ²=13.839，P=0.000]、电极术后CT[96%（48/50）对32.81%（21/64）；χ²=10.409，P=0.001]、电极重建[96%（48/50）对32.81%（21/64）；χ²=10.409，P=0.001]、术后CT/MRI[96%（48/50）对15.63%（10/64）；χ²=22.169，P=0.000]数据归档率均高于对照组。结论: 设计契合临床的多模态神经影像学数据信息管理系统，合理设置数据收集和归档节点，可以有效提高数据归档率，节约人力资源，保障临床数据的完备存储和临床诊疗的顺畅运行，有利于提高临床诊断与治疗水平。

关键词: 神经外科（学）, 神经成像, 电子数据处理, 卫生人力

Run-shi GAO, Guo-jun ZHANG, Xue-yuan WANG, Xiu-mei WANG, Tao YU, Yong-sheng HU. Application of multi-modal neuroimaging data information management system in functional neurosurgery[J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2024, 24(7): 525-531.

高润石, 张国君, 王雪原, 王秀梅, 遇涛, 胡永生. 多模态神经影像学数据信息管理系统在功能神经外科的应用[J]. 中国现代神经疾病杂志, 2024, 24(7): 525-531.

/ / Recommend / Download Citations

URL: http://journal11.magtechjournal.com/cjcnn/EN/10.3969/j.issn.1672-6731.2024.07.005

http://journal11.magtechjournal.com/cjcnn/EN/Y2024/V24/I7/525

Figures/Tables 5

Figure 1 Flowchart of data collection and archiving nodes designed according to the clinical pathway.

Table 1. Comparison of imaging data archiving rates between the data management group and the control group [case (%)]

组别	例数	术前结构序列	其他术前影像	电极术后CT	电极重建	术后CT/MRI
对照组	64	21（32.81）	17（26.56）	21（32.81）	21（32.81）	10（15.63）
数据管理组	50	50（100.00）	48（96.00）	48（96.00）	48（96.00）	48（96.00）
χ²值		11.383	13.839	10.409	10.409	22.169
P值		0.001	0.000	0.001	0.001	0.000

Figure 2 Comparison of electrode contact display effects between the open‐source imaging software (3D Slicer) based on the multi‐modal neuroimaging data information management system and commercial surgical planning software The open‐source imaging software could not only distinguish brain gyri and sulci with different colors (Panel 2a), but also display electrode contact coordinates individually (Panel 2b). The commercial surgical planning software could only move along the electrode implantation path using a slider, but lacked the function to locate electrode contacts (Panel 2c, 2d).

Figure 3 Comparison of multi‐modal imaging display effects in 3D and 2D perspectives The 3D perspective of the fusion of PET and structural sequences (front view, bottom view, right lateral view, and left lateral view from left to right) showed the reduced metabolism in the right temporal lobe was significant and intuitive (blue areas indicate, Panel 3a). The 2D perspective of the fusion of PET and structural sequences (coronal, axial, and sagittal views from left to right) showed the reduced metabolism in the right temporal lobe (blue and green areas indicate, Panel 3b).

Figure 4 3D electrode reconstruction displayed of D‐3, D‐4 and D‐5 electrode contacts from Figure 2. In the virtual space of the software, the brain structure model could be sliced to reveal electrode contacts which located deep within the brain tissue. By overlaying PET metabolic information on the brain structure model, the metabolic status of the electrode locations could be observed.

References 23

1	Lapalme-Remis S , Nguyen DK . Neuroimaging of epilepsy. Continuum (Minneap Minn), 2022, 28: 306- 338.
2	Duncan JS , Trimmel K . Advanced neuroimaging techniques in epilepsy. Curr Opin Neurol, 2022, 35: 189- 195. doi: 10.1097/WCO.0000000000001007
3	Ma LT , Zhang WW , Mei JM , Niu CS . Application of multi-modal image fusion three-dimensional reconstruction technology in operation of meningioma in the central area of the brain. Zhongguo Xian Dai Shen Jing Ji Bing Za Zhi, 2022, 22: 187- 194. doi: 10.3969/j.issn.1672-6731.2022.03.011
	马龙涛, 张伟文, 梅加明, 牛朝诗. 多模态影像融合三维重建技术在颅内中央区脑膜瘤手术中的应用. 中国现代神经疾病杂志, 2022, 22: 187- 194. doi: 10.3969/j.issn.1672-6731.2022.03.011
4	Gong R , Bickel S , Tostaeva G , Lado FA , Metha AD , Kuzniecky RI , Bonilha LF , Gleichgerrcht EL . Optimizing surgical planning for epilepsy patients with multimodal neuroimaging and neurophysiology integration: a case study. J Clin Neurophysiol, 2024, 41: 317- 321. doi: 10.1097/WNP.0000000000001071
5	Wu JL , Han JD . Medical artificial intelligence: driven by the fusion of knowledge-guided and data-mining methodologies. Zhongguo Xian Dai Shen Jing Ji Bing Za Zhi, 2023, 23: 1- 4. doi: 10.3969/j.issn.1672-6731.2023.01.001
	巫嘉陵, 韩建达. 医疗人工智能: 知识引导与数据挖掘联合驱动. 中国现代神经疾病杂志, 2023, 23: 1- 4. doi: 10.3969/j.issn.1672-6731.2023.01.001
6	Tshalibe P , Adrigwe J , Lucas S . Clinicians'perspective of picture archiving and communication systems at Charlotte Maxeke Johannesburg Academic Hospital. SA J Radiol, 2023, 27: 2578.
7	Mandel M , Li Y , Figueiredo EG , Teixeira MJ , Steinberg GK . Presurgical planning with open-source horos software for superficial brain arteriovenous malformations. World Neurosurg, 2022, 157: 3- 12. doi: 10.1016/j.wneu.2021.09.081
8	Fisher RS , Acevedo C , Arzimanoglou A , Bogacz A , Cross JH , Elger CE , Engel J Jr , Forsgren L , French JA , Glynn M , Hesdorffer DC , Lee BI , Mathern GW , MoshéSL , Perucca E , Scheffer IE , Tomson T , Watanabe M , Wiebe S . ILAE official report: a practical clinical definition of epilepsy. Epilepsia, 2014, 55: 475- 482. doi: 10.1111/epi.12550
9	China Association Against Epilepsy . Clinical guidelines for epilepsy (2023 revision). Beijing: People's Medical Publishing House, 2023: 61- 73.
	中国抗癫痫协会. 临床诊疗指南癫痫病分册(2023修订版). 北京: 人民卫生出版社, 2023: 61- 73.
10	Hao G , Yan H , Wang X , Gao R , Xue Y , Zhang X , Ni D , Shu W , Qiao L , He L , Yu T . The role of magnetoencephalography in preoperative localization and postoperative outcome prediction in patients with posterior cortical epilepsy. CNS Neurosci Ther, 2024, 30: e14602. doi: 10.1111/cns.14602
11	Vanden Bulcke C , Wynen M , Detobel J , La Rosa F , Absinta M , Dricot L , Macq B , Bach Cuadra M , Maggi P . BMAT: an open-source BIDS managing and analysis tool. Neuroimage Clin, 2022, 36: 103252. doi: 10.1016/j.nicl.2022.103252
12	Bao S , Boyd BD , Kanakaraj P , Ramadass K , Meyer FAC , Liu Y , Duett WE , Huo Y , Lyu I , Zald DH , Smith SA , Rogers BP , Landman BA . Integrating the bids neuroimaging data format and workflow optimization for large-scale medical image analysis. J Digit Imaging, 2022, 35: 1576- 1589. doi: 10.1007/s10278-022-00679-8
13	Costanza D , Coluccia P , Castiello E , Greco A , Meomartino L . Description of a low-cost picture archiving and communication system based on network-attached storage. Vet Radiol Ultrasound, 2022, 63: 249- 253. doi: 10.1111/vru.13061
14	Pérez Hinestroza J , Mazo C , Trujillo M , Herrera A . MRI and CT fusion in stereotactic electroencephalography (SEEG). Diagnostics (Basel), 2023, 13: 3420. doi: 10.3390/diagnostics13223420
15	Eke DO , Bernard A , Bjaalie JG , Chavarriaga R , Hanakawa T , Hannan AJ , Hill SL , Martone ME , McMahon A , Ruebel O , Crook S , Thiels E , Pestilli F . International data governance for neuroscience. Neuron, 2022, 110: 600- 612. doi: 10.1016/j.neuron.2021.11.017
16	Dhudasia MB , Grundmeier RW , Mukhopadhyay S . Essentials of data management: an overview. Pediatr Res, 2023, 93: 2- 3. doi: 10.1038/s41390-021-01389-7
17	Behnam F , Khajouei R , Ahmadian L . The retention duration of digital images in picture archiving and communication systems. Heliyon, 2024, 10: e27847. doi: 10.1016/j.heliyon.2024.e27847
18	Liu Q , Wang J , Wang C , Wei F , Zhang C , Wei H , Ye X , Xu J . FreeSurfer and 3D slicer-assisted seeg implantation for drug-resistant epilepsy. Front Neurorobot, 2022, 16: 848746. doi: 10.3389/fnbot.2022.848746
19	Shi H , Li Y , Wang Y , Guo W , Zhang K , Du Y , Shi H , Qian T . The preoperative evaluation value of 3D-slicer program before microsurgical vascular decompression in patients with hemifacial spasm. Clin Neurol Neurosurg, 2022, 217: 107241. doi: 10.1016/j.clineuro.2022.107241
20	Subash P , Gray A , Boswell M , Cohen SL , Garner R , Salehi S , Fisher C , Hobel S , Ghosh S , Halchenko Y , Dichter B , Poldrack RA , Markiewicz C , Hermes D , Delorme A , Makeig S , Behan B , Sparks A , Arnott SR , Wang Z , Magnotti J , Beauchamp MS , Pouratian N , Toga AW , Duncan D . A comparison of neuroelectrophysiology databases. Sci Data, 2023, 10: 719. doi: 10.1038/s41597-023-02614-0
21	Mandal PK , Jindal K , Maroon JC , Chhikara R , Samkaria A , Joshi M , Roy S , Arora Y . Brain imaging databases. ACS Chem Neurosci, 2023, 14: 1930- 1934. doi: 10.1021/acschemneuro.3c00265
22	Lucas A , Revell A , Davis KA . Artificial intelligence in epilepsy: applications and pathways to the clinic. Nat Rev Neurol, 2024, 20: 319- 336.
23	Sone D . Making the invisible visible: advanced neuroimaging techniques in focal epilepsy. Front Neurosci, 2021, 15: 699176. doi: 10.3389/fnins.2021.699176

[1]	Jun-ji WEI, Jian-bo CHANG. Promoting the concept of neurosurgical critical care in primary hospitals [J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2024, 24(6): 403-406.
[2]	Jun-ji WEI. Standardized diagnosis and treatment in neurosurgical critical care patients [J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2023, 23(6): 477-478.
[3]	Tan ZHANG, Yu DING, Li-qun YUAN. Application of percutaneous dilated tracheotomy under direct vision in severe neurosurgical patients [J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2023, 23(6): 503-508.
[4]	GONG Jian. Advancing pediatric neurosurgery in China [J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2023, 23(5): 383-387.
[5]	WANG Ning. The status and role of neurosurgical critical care medicine in the development of neurosurgery [J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2020, 20(8): 671-673.
[6]	WANG Ning, QU Xin. Precise monitoring and complication control for the patients with neurosurgical critical illness can improve their clinical prognosis [J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2020, 20(8): 669-670.
[7]	QI Song-tao. The dawn here is quiet: a guided reading in shout [J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2020, 20(4): 253-254.
[8]	WANG Ren-zhi, FENG Ming. Current situation and problems in skull base surgery [J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2020, 20(3): 144-147.
[9]	CHEN Lei, YANG Xue-jun. Immune-related diseases in neurosurgery [J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2020, 20(2): 136-139.
[10]	WANG Ren-zhi. Improving neurosurgery by using clinical data and intelligent imaging [J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2019, 19(9): 613-614.
[11]	LI Chu-zhong, ZHU Hai-bo, ZONG Xu-yi, WANG Xin-sheng, GUI Song-bai, ZHANG Ya-zhuo. History of endoscopic neurosurgery in China [J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2019, 19(4): 232-236.
[12]	ZHANG Xiao-biao. The history, present situation and future prospect of endoscopic neurosurgery [J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2019, 19(3): 148-153.
[13]	YU Xin-guang, ZHANG Yan-yang. Opportunities and challenges for neurosurgeon in the brain research era [J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2019, 19(12): 915-919.
[14]	SONG Feng-lei, ZHAO Yang, MA Lin, WANG Li-gang, LIU Bo-feng, SUN Peng, SHANG Yun-cai, WANG Guang-yi. Efficacy analysis of early bilateral decompressive craniectomy for severe traumatic brain injury [J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2018, 18(9): 692-696.
[15]	CHEN Zan, ZHAO Xing-hua, XIA Zhi-yuan. A few thoughts on the current situation of neurosurgery spinal subspecialty residency training [J]. Chinese Journal of Contemporary Neurology and Neurosurgery, 2017, 17(10): 762-764.

Please choose a citation manager

Content to export