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柔性可变透明端口技术在微创神经内镜锁孔手术中的临床应用:一项实用的新技术

Clinical application of flexible and variable transparent endport technology in minimally invasive neuroendoscopic keyhole surgery: a practical new technology.

作者信息

Zhou Long, Mao Shitao, Wang Can, Zhang Huikai, Li Zhiyang, Lu Minghui, Xia Wei, Song Ping, Ye Hui, Zhou Jinjian, Shafiq Zohaib, Chen Qianxue, Cao Fangjun, Cai Qiang

机构信息

Department of Neurosurgery, Renmin Hospital of Wuhan University, No. 238, Jiefang Road, Wuchang District, Wuhan City, 430060, Hubei Province, China.

Department of Neurosurgery, Yangxin County People's Hospital, Building 10, Phase II, Lianhua Lake No. 1, East New District, Yangxin County, Huangshi City, 435200, Hubei Province, China.

出版信息

Sci Rep. 2025 Aug 16;15(1):30029. doi: 10.1038/s41598-025-13141-w.

DOI:10.1038/s41598-025-13141-w
PMID:40819136
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12357948/
Abstract

With the development of endoscopic technology, neuroendoscopy utilizes its advantages such as good illumination, close range observation, and flexible degrees of freedom. Neuroendoscopic surgery can achieve advantages such as minimally invasive, high clearance rate, low incidence of complications, good brain tissue protection, and fewer surgery-related injuries. However, minimally invasive endoscopic surgery also has inherent limitations, since its narrow surgical channels are prone to collapse and require special instrument support. By summarizing the literature on the use of endoport technology in previous neuroendoscopic surgeries, and providing a detailed introduction and summary of our team's newly developed simple variable endoport clinical experience, we analyzed the advantages, disadvantages, and precautions of flexible and variable transparent endport technology. After years of development and refinement, fixed endoport technology has been widely used in neuroendoscopic surgery, but it has certain shortcomings. Our team has developed a variable endoport system using simple and easily accessible materials. Although it has shortcomings in support, it provides good compensation for the flexibility of endport length and diameter, which is of great help for multi-instrument operation and bipolar electrocoagulation hemostasis, making surgical hemostasis more reliable. Meanwhile, the flexible and variable transparent endport system can be completely placed within the bone window, with significantly higher mobility than the hard endport system that cannot be completely placed below the bone window. The flexible and variable transparent endport system material is easy to obtain, manufacture, operate, and has extremely low cost, making it suitable for promotion and use in the vast majority of neurosurgery units, including primary hospitals.

摘要

随着内镜技术的发展,神经内镜利用其照明良好、近距离观察和自由度灵活等优势。神经内镜手术可实现微创、清除率高、并发症发生率低、脑组织保护良好以及手术相关损伤较少等优势。然而,微创内镜手术也有其固有的局限性,因其手术通道狭窄容易塌陷,需要特殊器械支持。通过总结以往神经内镜手术中使用端口技术的文献,并详细介绍和总结我们团队新开发的简易可变端口的临床经验,我们分析了柔性可变透明端口技术的优缺点及注意事项。经过多年的发展和完善,固定端口技术已在神经内镜手术中广泛应用,但存在一定缺点。我们团队利用简单易得的材料开发了一种可变端口系统。虽然它在支撑方面有缺点,但在端口长度和直径的灵活性方面提供了良好的弥补,这对多器械操作和双极电凝止血有很大帮助,使手术止血更可靠。同时,柔性可变透明端口系统可完全置于骨窗内,其活动性明显高于不能完全置于骨窗下方的硬端口系统。柔性可变透明端口系统材料易于获取、制造、操作,成本极低,适合在包括基层医院在内的绝大多数神经外科单位推广使用。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/541f/12357948/096d91254a4b/41598_2025_13141_Fig9_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/541f/12357948/5a6a769ad09a/41598_2025_13141_Fig10_HTML.jpg
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