使用新型力反馈技术评估机器人辅助手术任务中施加到组织上的力

Michael M. Awad, Mathew C. Raynor, Mika Padmanabhan-Kabana, Lana Y. Schumacher, Jeffrey A. Blatnik
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引用次数: 0

摘要

背景缺乏力反馈(FFB)被认为是机器人辅助手术(RAS)的一个技术限制。这项临床前研究旨在评估使用新型集成 FFB 技术施加到组织上的力,该技术允许外科医生感知器械尖端施加的力。方法28 位经验水平各异的外科医生使用 FFB 器械在无生命或活体外模型上执行了三项机器人辅助手术任务,包括牵引、解剖和缝合,同时器械传感器记录并向机器人系统的外科医生手控器传递施加的力。我们使用广义估计方程 (GEE) 模型分析了 FFB 传感器在 "关闭 "设置与 "高 "灵敏度设置(用于牵引)以及 "低"、"中 "和 "高 "灵敏度设置(用于解剖和缝合)相比,在每项任务中施加的平均和最大力。结果在三种机器人辅助手术任务中,在任何灵敏度设置下使用 FFB 都能显著降低对组织施加的平均力和最大力(p < 0.0001)。在 "高 "灵敏度设置下使用 FFB 进行牵引、解剖和间断缝合任务时,可能造成组织损伤的最大作用力分别降低了 36%、41% 和 55%。此外,在执行所有三类任务时,使用全自动无创血压仪都能大幅降低力的差异。一般来说,在所有经验水平的外科医生中都能观察到平均和最大力的降低。结论我们的研究结果表明,在机器人手术系统中集成 FFB 技术,可以显著降低所有经验水平的外科医生在执行手术任务时施加在组织上的力。使用 FFB 所实现的施力减小和施力一致性可减少组织创伤和失血,从而为接受 RAS 的患者带来更好的临床效果。未来的研究对于确定 FFB 器械在实际临床环境中的影响非常重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Evaluation of forces applied to tissues during robotic-assisted surgical tasks using a novel force feedback technology

Evaluation of forces applied to tissues during robotic-assisted surgical tasks using a novel force feedback technology

Background

The absence of force feedback (FFB) is considered a technical limitation in robotic-assisted surgery (RAS). This pre-clinical study aims to evaluate the forces applied to tissues using a novel integrated FFB technology, which allows surgeons to sense forces exerted at the instrument tips.

Methods

Twenty-eight surgeons with varying experience levels employed FFB instruments to perform three robotic-assisted surgical tasks, including retraction, dissection, and suturing, on inanimate or ex-vivo models, while the instrument sensors recorded and conveyed the applied forces to the surgeon hand controllers of the robotic system. Generalized Estimating Equations (GEE) models were used to analyze the mean and maximal forces applied during each task with the FFB sensor at the “Off” setting compared to the “High” sensitivity setting for retraction and to the “Low”, “Medium”, and “High” sensitivity settings for dissection and suturing. Sub-analysis was also performed on surgeon experience levels.

Results

The use of FFB at any of the sensitivity settings resulted in a significant reduction in both the mean and maximal forces exerted on tissue during all three robotic-assisted surgical tasks (p < 0.0001). The maximal force exerted, potentially associated with tissue damage, was decreased by 36%, 41%, and 55% with the use of FFB at the “High” sensitivity setting while performing retraction, dissection, and interrupted suturing tasks, respectively. Further, the use of FFB resulted in substantial reductions in force variance during the performance of all three types of tasks. In general, reductions in mean and maximal forces were observed among surgeons at all experience levels. The degree of force reduction depends on the sensitivity setting selected and the types of surgical tasks evaluated.

Conclusions

Our findings demonstrate that the utilization of FFB technology integrated in the robotic surgical system significantly reduced the forces exerted on tissue during the performance of surgical tasks at all surgeon experience levels. The reduction in the force applied and a consistency of force application achieved with FFB use, could result in decreases in tissue trauma and blood loss, potentially leading to better clinical outcomes in patients undergoing RAS. Future studies will be important to determine the impact of FFB instruments in a live clinical environment.

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