Augmented Reality Surgical Navigation System for External Ventricular Drain

Chiou, Shin-Yan; Zhang, Zhiyue; Liu, Hao‐Li; Yan, Jiun-Lin; Wei, Kuo-Chen; Chen, Pin-Yuan

doi:10.3390/healthcare10101815

Cited by 11 publications

(14 citation statements)

References 32 publications

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“…The substantial, expensive hardware systems and complex workflows challenge the widespread adoption of microscope-based navigation. Hence, there has been increasing interest in smaller, low-cost, and easy-to-use alternatives for AR-guided interventions, such as projector-based [18,19], smartphone-based [20][21][22][23][24], tablet-based [22,[25][26][27], and head-mounted display (HMD)-based AR [7,8,10,28]. These AR paradigms are widely used as "low-cost navigation" in underdeveloped regions or healthcare facilities with limited resources.…”

Section: Introductionmentioning

confidence: 99%

A Novel Registration Method for a Mixed Reality Navigation System Based on a Laser Crosshair Simulator: A Technical Note

Qi,

Bopp,

Nimsky

et al. 2023

Bioengineering

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Mixed Reality Navigation (MRN) is pivotal in augmented reality-assisted intelligent neurosurgical interventions. However, existing MRN registration methods face challenges in concurrently achieving low user dependency, high accuracy, and clinical applicability. This study proposes and evaluates a novel registration method based on a laser crosshair simulator, evaluating its feasibility and accuracy. A novel registration method employing a laser crosshair simulator was introduced, designed to replicate the scanner frame’s position on the patient. The system autonomously calculates the transformation, mapping coordinates from the tracking space to the reference image space. A mathematical model and workflow for registration were designed, and a Universal Windows Platform (UWP) application was developed on HoloLens-2. Finally, a head phantom was used to measure the system’s target registration error (TRE). The proposed method was successfully implemented, obviating the need for user interactions with virtual objects during the registration process. Regarding accuracy, the average deviation was 3.7 ± 1.7 mm. This method shows encouraging results in efficiency and intuitiveness and marks a valuable advancement in low-cost, easy-to-use MRN systems. The potential for enhancing accuracy and adaptability in intervention procedures positions this approach as promising for improving surgical outcomes.

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Section: Introductionmentioning

confidence: 99%

A Novel Registration Method for a Mixed Reality Navigation System Based on a Laser Crosshair Simulator: A Technical Note

Qi,

Bopp,

Nimsky

et al. 2023

Bioengineering

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“…Overall, the primary areas of neurosurgery where AR is most extensively applied include spinal surgery, NN, and education [6,51]. Its application is also beneficial in hydrocephalus surgery [52], neuroimaging [53,54], surgery for brain tumors [55], cerebrovascular pathology [56], ventricular system surgery [57], neurotrauma [58], and neurodegenerative pathology [59].…”

Section: Discussionmentioning

confidence: 99%

Augmented Reality Integration in Skull Base Neurosurgery: A Systematic Review

Begagić,

Bečulić,

Pugonja

et al. 2024

Medicina

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Background and Objectives: To investigate the role of augmented reality (AR) in skull base (SB) neurosurgery. Materials and Methods: Utilizing PRISMA methodology, PubMed and Scopus databases were explored to extract data related to AR integration in SB surgery. Results: The majority of 19 included studies (42.1%) were conducted in the United States, with a focus on the last five years (77.8%). Categorization included phantom skull models (31.2%, n = 6), human cadavers (15.8%, n = 3), or human patients (52.6%, n = 10). Microscopic surgery was the predominant modality in 10 studies (52.6%). Of the 19 studies, surgical modality was specified in 18, with microscopic surgery being predominant (52.6%). Most studies used only CT as the data source (n = 9; 47.4%), and optical tracking was the prevalent tracking modality (n = 9; 47.3%). The Target Registration Error (TRE) spanned from 0.55 to 10.62 mm. Conclusion: Despite variations in Target Registration Error (TRE) values, the studies highlighted successful outcomes and minimal complications. Challenges, such as device practicality and data security, were acknowledged, but the application of low-cost AR devices suggests broader feasibility.

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“…Unlike previous studies, our feasibility study is the first to demonstrate the impact of real-time visualization of the catheter position in corresponding 2D MRI slices using the Microsoft HoloLens. 11,21,22 Ventriculostomy and EVD placement are among the most common procedures in neurosurgery and are usually among the first procedures performed by inexperienced neurosurgical residents. The most common technique of ventricular puncture is freehand placement according to the predefined external anatomical landmarks (Kocher's point, ipsilateral medial canthus, and external auditory canal).…”

Section: Discussionmentioning

confidence: 99%

IMAGINER: improving accuracy with a mixed reality navigation system during placement of external ventricular drains. A feasibility study

Grunert,

Winkler,

Wach

et al. 2024

Neurosurgical Focus

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OBJECTIVE The placement of a ventricular catheter, that is, an external ventricular drain (EVD), is a common and essential neurosurgical procedure. In addition, it is one of the first procedures performed by inexperienced neurosurgeons. With or without surgical experience, the placement of an EVD according to anatomical landmarks only can be difficult, with the potential risk for inaccurate catheter placement. Repeated corrections can lead to avoidable complications. The use of mixed reality could be a helpful guide and improve the accuracy of drain placement, especially in patients with acute pathology leading to the displacement of anatomical structures. Using a human cadaveric model in this feasibility study, the authors aimed to evaluate the accuracy of EVD placement by comparing two techniques: mixed reality and freehand placement. METHODS Twenty medical students performed the EVD placement procedure with a Cushing’s ventricular cannula on the right and left sides of the ventricular system. The cannula was placed according to landmarks on one side and with the assistance of mixed reality (Microsoft HoloLens 2) on the other side. With mixed reality, a planned trajectory was displayed in the field of view that guides the placement of the cannula. Subsequently, the actual position of the cannula was assessed with the help of a CT scan with a 1-mm slice thickness. The bony structure as well as the left and right cannula positions were registered to the CT scan with the planned target point before the placement procedure. CloudCompare software was applied for registration and evaluation of accuracy. RESULTS EVD placement using mixed reality was easily performed by all medical students. The predefined target point (inside the lateral ventricle) was reached with both techniques. However, the scattering radius of the target point reached through the use of mixed reality (12 mm) was reduced by more than 54% compared with the puncture without mixed reality (26 mm), which represents a doubling of the puncture accuracy. CONCLUSIONS This feasibility study specifically showed that the integration and use of mixed reality helps to achieve more than double the accuracy in the placement of ventricular catheters. Because of the easy availability of these new tools and their intuitive handling, we see great potential for mixed reality to improve accuracy.

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Augmented Reality Surgical Navigation System for External Ventricular Drain

Cited by 11 publications

References 32 publications

A Novel Registration Method for a Mixed Reality Navigation System Based on a Laser Crosshair Simulator: A Technical Note

A Novel Registration Method for a Mixed Reality Navigation System Based on a Laser Crosshair Simulator: A Technical Note

Augmented Reality Integration in Skull Base Neurosurgery: A Systematic Review

IMAGINER: improving accuracy with a mixed reality navigation system during placement of external ventricular drains. A feasibility study

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