可视化、导航、增强。神经外科医生不断变化的视角。

Visualization, navigation, augmentation. The ever-changing perspective of the neurosurgeon.

作者信息

Boaro A, Moscolo F, Feletti A, Polizzi G M V, Nunes S, Siddi F, Broekman M L D, Sala F

机构信息

Section of Neurosurgery, Department of Neurosciences, Biomedicine and Movement Sciences, University of Verona, Italy.

Department of Neurosurgery, Haaglanden Medical Center, The Hague, Zuid-Holland, the Netherlands.

出版信息

Brain Spine. 2022 Aug 17;2:100926. doi: 10.1016/j.bas.2022.100926. eCollection 2022.

DOI:10.1016/j.bas.2022.100926

PMID:36248169

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9560703/

Abstract

INTRODUCTION

The evolution of neurosurgery coincides with the evolution of visualization and navigation. Augmented reality technologies, with their ability to bring digital information into the real environment, have the potential to provide a new, revolutionary perspective to the neurosurgeon.

RESEARCH QUESTION

To provide an overview on the historical and technical aspects of visualization and navigation in neurosurgery, and to provide a systematic review on augmented reality (AR) applications in neurosurgery.

MATERIAL AND METHODS

We provided an overview on the main historical milestones and technical features of visualization and navigation tools in neurosurgery. We systematically searched PubMed and Scopus databases for AR applications in neurosurgery and specifically discussed their relationship with current visualization and navigation systems, as well as main limitations.

RESULTS

The evolution of visualization in neurosurgery is embodied by four magnification systems: surgical loupes, endoscope, surgical microscope and more recently the exoscope, each presenting independent features in terms of magnification capabilities, eye-hand coordination and the possibility to implement additional functions. In regard to navigation, two independent systems have been developed: the frame-based and the frame-less systems. The most frequent application setting for AR is brain surgery (71.6%), specifically neuro-oncology (36.2%) and microscope-based (29.2%), even though in the majority of cases AR applications presented their own visualization supports (66%).

DISCUSSION AND CONCLUSIONS

The evolution of visualization and navigation in neurosurgery allowed for the development of more precise instruments; the development and clinical validation of AR applications, have the potential to be the next breakthrough, making surgeries safer, as well as improving surgical experience and reducing costs.

摘要

引言

神经外科的发展与可视化和导航技术的发展相契合。增强现实技术能够将数字信息带入真实环境，有望为神经外科医生提供全新的、革命性的视角。

研究问题

概述神经外科可视化和导航的历史及技术方面，并对增强现实（AR）在神经外科的应用进行系统综述。

材料与方法

我们概述了神经外科可视化和导航工具的主要历史里程碑及技术特点。我们系统检索了PubMed和Scopus数据库中AR在神经外科的应用，并特别讨论了它们与当前可视化和导航系统的关系以及主要局限性。

结果

神经外科可视化的发展体现在四种放大系统中：手术放大镜、内窥镜、手术显微镜以及最近的外视镜，每种在放大能力、眼手协调以及实现附加功能的可能性方面都具有独立的特点。在导航方面，已开发出两种独立的系统：基于框架的系统和无框架系统。AR最常见的应用场景是脑部手术（71.6%），特别是神经肿瘤学（36.2%）和基于显微镜的手术（29.2%），尽管在大多数情况下AR应用都有其自身的可视化支持（66%）。

讨论与结论

神经外科可视化和导航的发展催生了更精确的器械；AR应用的开发和临床验证有可能成为下一个突破，使手术更安全，同时改善手术体验并降低成本。

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可视化、导航、增强。神经外科医生不断变化的视角。

Visualization, navigation, augmentation. The ever-changing perspective of the neurosurgeon.

作者信息

机构信息

出版信息

INTRODUCTION

RESEARCH QUESTION

MATERIAL AND METHODS

RESULTS

DISCUSSION AND CONCLUSIONS

引言

研究问题

材料与方法

结果

讨论与结论

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