Microvascular Anastomosis Training in Neurosurgery: A Review.

IF 1.3 Q3 SURGERY Minimally Invasive Surgery Pub Date : 2018-03-28 eCollection Date: 2018-01-01 DOI:10.1155/2018/6130286
Vadim A Byvaltsev, Serik K Akshulakov, Roman A Polkin, Sergey V Ochkal, Ivan A Stepanov, Yerbol T Makhambetov, Talgat T Kerimbayev, Michael Staren, Evgenii Belykh, Mark C Preul
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引用次数: 29

Abstract

Cerebrovascular diseases are among the most widespread diseases in the world, which largely determine the structure of morbidity and mortality rates. Microvascular anastomosis techniques are important for revascularization surgeries on brachiocephalic and carotid arteries and complex cerebral aneurysms and even during resection of brain tumors that obstruct major cerebral arteries. Training in microvascular surgery became even more difficult with less case exposure and growth of the use of endovascular techniques. In this text we will briefly discuss the history of microvascular surgery, review current literature on simulation models with the emphasis on their merits and shortcomings, and describe the views and opinions on the future of the microvascular training in neurosurgery. In "dry" microsurgical training, various models created from artificial materials that simulate biological tissues are used. The next stage in training more experienced surgeons is to work with nonliving tissue models. Microvascular training using live models is considered to be the most relevant due to presence of the blood flow. Training on laboratory animals has high indicators of face and constructive validity. One of the future directions in the development of microsurgical techniques is the use of robotic systems. Robotic systems may play a role in teaching future generations of microsurgeons. Modern technologies allow access to highly accurate learning environments that are extremely similar to real environment. Additionally, assessment of microsurgical skills should become a fundamental part of the current evaluation of competence within a microneurosurgical training program. Such an assessment tool could be utilized to ensure a constant level of surgical competence within the recertification process. It is important that this evaluation be based on validated models.

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神经外科微血管吻合训练综述。
脑血管病是世界上传播最广的疾病之一,它在很大程度上决定了发病率和死亡率的结构。微血管吻合技术在头臂动脉、颈动脉及复杂脑动脉瘤的血运重建术中,甚至在脑大动脉阻塞的脑肿瘤切除术中都具有重要意义。随着病例暴露的减少和血管内技术应用的增加,微血管手术的培训变得更加困难。在本文中,我们将简要讨论微血管手术的历史,回顾目前关于模拟模型的文献,重点讨论它们的优点和缺点,并描述对神经外科微血管训练的未来的看法和意见。在“干式”显微外科训练中,使用由模拟生物组织的人造材料制作的各种模型。培训更有经验的外科医生的下一阶段是使用非活体组织模型。由于血流的存在,使用活体模型的微血管训练被认为是最相关的。实验动物训练具有较高的面子效度和建构效度指标。显微外科技术的未来发展方向之一是机器人系统的使用。机器人系统可能会在未来几代显微外科医生的教学中发挥作用。现代技术使我们能够获得与真实环境极其相似的高精度学习环境。此外,显微外科技能的评估应该成为当前显微神经外科培训计划中能力评估的一个基本部分。这种评估工具可用于确保在重新认证过程中保持恒定的手术能力水平。重要的是,这种评估应基于经过验证的模型。
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来源期刊
CiteScore
3.00
自引率
0.00%
发文量
8
审稿时长
16 weeks
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