Safety control strategy of spinal lamina cutting based on force and cutting depth signals

IF 8.4 2区 计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Jian Zhang, Yonghong Zhang, Shanshan Liu, Xuquan Ji, Sizhuo Liu, Zhuofu Li, Baoduo Geng, Weishi Li, Tianmiao Wang
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引用次数: 0

Abstract

Laminectomy is one of the most common posterior spinal operations. Since the lamina is adjacent to important tissues such as nerves, once damaged, it can cause serious complications and even lead to paralysis. In order to prevent the above injuries and complications, ultrasonic bone scalpel and surgical robots have been introduced into spinal laminectomy, and many scholars have studied the recognition method of the bone tissue status. Currently, almost all methods to achieve recognition of bone tissue are based on sensor signals collected by high-precision sensors installed at the end of surgical robots. However, the previous methods could not accurately identify the state of spinal bone tissue. Innovatively, the identification of bone tissue status was regarded as a time series classification task, and the classification algorithm LSTM-FCN was used to process fusion signals composed of force and cutting depth signals, thus achieving an accurate classification of the lamina bone tissue status. In addition, it was verified that the accuracy of the proposed method could reach 98.85% in identifying the state of porcine spinal laminectomy. And the maximum penetration distance can be controlled within 0.6 mm, which is safe and can be used in practice.

Abstract Image

基于力和切割深度信号的脊柱薄片切割安全控制策略
脊柱椎板切除术是最常见的脊柱后路手术之一。由于脊柱椎板与神经等重要组织相邻,一旦损伤,会引起严重的并发症,甚至导致瘫痪。为了防止上述损伤和并发症的发生,超声骨刀和手术机器人被引入脊柱椎板切除术中,许多学者对骨组织状态的识别方法进行了研究。目前,几乎所有实现骨组织识别的方法都是基于安装在手术机器人末端的高精度传感器采集的传感器信号。然而,以往的方法无法准确识别脊柱骨组织的状态。创新性地将骨组织状态识别视为时间序列分类任务,并使用分类算法 LSTM-FCN 处理由力和切割深度信号组成的融合信号,从而实现了对薄层骨组织状态的准确分类。此外,还验证了所提出的方法在识别猪脊柱椎板切除状态方面的准确率可达 98.85%。而且最大穿透距离可控制在 0.6 毫米以内,安全可靠,可用于实际操作。
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来源期刊
CAAI Transactions on Intelligence Technology
CAAI Transactions on Intelligence Technology COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE-
CiteScore
11.00
自引率
3.90%
发文量
134
审稿时长
35 weeks
期刊介绍: CAAI Transactions on Intelligence Technology is a leading venue for original research on the theoretical and experimental aspects of artificial intelligence technology. We are a fully open access journal co-published by the Institution of Engineering and Technology (IET) and the Chinese Association for Artificial Intelligence (CAAI) providing research which is openly accessible to read and share worldwide.
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