{"title":"Training on a 3D-Printed Simulation Model Improves Accuracy in External Ventricular Drain Placement.","authors":"Michael Kosterhon, Merih Ö Turgut, Matthias Gielisch, Julian Graef, Florian Ringel","doi":"10.1227/ons.0000000000001491","DOIUrl":null,"url":null,"abstract":"<p><strong>Background and objectives: </strong>External ventricular drain (EVD) placement is a critical, lifesaving procedure in cranial neurosurgery, often performed manually using anatomical landmarks that vary between individuals. This study evaluates the efficacy of a 3-dimensional (3D)-printed EVD training model designed to improve the accuracy of this procedure.</p><p><strong>Methods: </strong>Computed tomography scans from 3 patients were used to create 3D-printed head models with narrow, wide, and normal ventricles. Twenty-five neurosurgeons participated in a three-round training protocol: pre-training, training with neuronavigation and a standardized protocol, and post-training. The accuracy of EVD placement was measured using an optical navigation system, and participants' confidence levels were assessed through questionnaires.</p><p><strong>Results: </strong>Training significantly enhanced EVD placement accuracy. Pre-training, only 55.3% of placements were intraventricular (Kakarla grade 1), which increased to 84.0% post-training ( P < .001). The distance to the ideal entry point improved from 5.8 mm (SD, ±3.7 mm) to 4.1 mm (SD, ±1.5 mm), and the distance to the target point improved from 12.6 mm (SD, ±5.8 mm) to 8.3 mm (SD, ±4.0 mm) ( P < .001 for both). The time to identify entry points and puncture the ventricles also improved significantly. Left-sided EVDs were more frequently misplaced. In addition, right-handed participants (n = 24) performed better when placing left-sided EVDs with their right hand. Participants with more than 6 years of experience were more likely to misplace the EVD and overestimate their placement accuracy compared with less experienced participants. Post-training, both experienced and less experienced neurosurgeons achieved similar success rates. Confidence in EVD placement and puncture direction significantly increased post-training.</p><p><strong>Conclusion: </strong>A standardized training protocol using a 3D-printed model significantly improves the accuracy and confidence of neurosurgeons in EVD placement. Regular training is recommended to maintain high clinical performance, emphasizing the need for standardized procedures and the use of neuronavigation for complex cases.</p>","PeriodicalId":54254,"journal":{"name":"Operative Neurosurgery","volume":" ","pages":"418-427"},"PeriodicalIF":1.4000,"publicationDate":"2025-02-18","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Operative Neurosurgery","FirstCategoryId":"3","ListUrlMain":"https://doi.org/10.1227/ons.0000000000001491","RegionNum":4,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"CLINICAL NEUROLOGY","Score":null,"Total":0}
引用次数: 0
Abstract
Background and objectives: External ventricular drain (EVD) placement is a critical, lifesaving procedure in cranial neurosurgery, often performed manually using anatomical landmarks that vary between individuals. This study evaluates the efficacy of a 3-dimensional (3D)-printed EVD training model designed to improve the accuracy of this procedure.
Methods: Computed tomography scans from 3 patients were used to create 3D-printed head models with narrow, wide, and normal ventricles. Twenty-five neurosurgeons participated in a three-round training protocol: pre-training, training with neuronavigation and a standardized protocol, and post-training. The accuracy of EVD placement was measured using an optical navigation system, and participants' confidence levels were assessed through questionnaires.
Results: Training significantly enhanced EVD placement accuracy. Pre-training, only 55.3% of placements were intraventricular (Kakarla grade 1), which increased to 84.0% post-training ( P < .001). The distance to the ideal entry point improved from 5.8 mm (SD, ±3.7 mm) to 4.1 mm (SD, ±1.5 mm), and the distance to the target point improved from 12.6 mm (SD, ±5.8 mm) to 8.3 mm (SD, ±4.0 mm) ( P < .001 for both). The time to identify entry points and puncture the ventricles also improved significantly. Left-sided EVDs were more frequently misplaced. In addition, right-handed participants (n = 24) performed better when placing left-sided EVDs with their right hand. Participants with more than 6 years of experience were more likely to misplace the EVD and overestimate their placement accuracy compared with less experienced participants. Post-training, both experienced and less experienced neurosurgeons achieved similar success rates. Confidence in EVD placement and puncture direction significantly increased post-training.
Conclusion: A standardized training protocol using a 3D-printed model significantly improves the accuracy and confidence of neurosurgeons in EVD placement. Regular training is recommended to maintain high clinical performance, emphasizing the need for standardized procedures and the use of neuronavigation for complex cases.
背景和目的:外脑室引流(EVD)放置是脑神经外科手术中一个关键的、挽救生命的手术,通常使用因人而异的解剖标志手动进行。本研究评估了三维(3D)打印的EVD培训模型的有效性,该模型旨在提高该程序的准确性。方法:利用3例患者的计算机断层扫描,建立三维打印的头部模型,分别具有窄、宽和正常的脑室。25名神经外科医生参加了三轮训练方案:训练前、神经导航和标准化方案训练以及训练后。使用光学导航系统测量EVD放置的准确性,并通过问卷评估参与者的信心水平。结果:训练显著提高了EVD放置的准确性。训练前,只有55.3%的位置是在脑室内(Kakarla等级1),训练后增加到84.0% (P < 0.001)。理想入点距离由5.8 mm (SD,±3.7 mm)改善至4.1 mm (SD,±1.5 mm),目标点距离由12.6 mm (SD,±5.8 mm)改善至8.3 mm (SD,±4.0 mm)(两者P < 0.001)。识别进入点和穿刺心室的时间也显著提高。左侧evd更常被放错位置。此外,右撇子参与者(n = 24)在用右手放置左侧evd时表现更好。与经验不足的参与者相比,有6年以上经验的参与者更有可能放错EVD并高估其放置准确性。训练后,经验丰富和经验不足的神经外科医生取得了相似的成功率。训练后对EVD放置和穿刺方向的信心显著提高。结论:使用3d打印模型的标准化训练方案可显著提高神经外科医生在EVD放置方面的准确性和信心。建议定期培训以保持较高的临床表现,强调需要标准化的程序和对复杂病例使用神经导航。
期刊介绍:
Operative Neurosurgery is a bi-monthly, unique publication focusing exclusively on surgical technique and devices, providing practical, skill-enhancing guidance to its readers. Complementing the clinical and research studies published in Neurosurgery, Operative Neurosurgery brings the reader technical material that highlights operative procedures, anatomy, instrumentation, devices, and technology. Operative Neurosurgery is the practical resource for cutting-edge material that brings the surgeon the most up to date literature on operative practice and technique
京公网安备 11010802042870号
京ICP备2023020795号-1
分享
求助内容:
应助结果提醒方式:
扫码关注我们
