{"title":"用于监测骨科椎弓根螺钉锁定力的无源无线智能垫圈","authors":"Che-Fu Liu, Tze-Hong Wong, Hsin-Chuan Wang, Asher Sun, Wensyang Hsu","doi":"10.1155/2024/6690983","DOIUrl":null,"url":null,"abstract":"A pedicle screw is a component for fixation in spine fusion surgery, often for patients with osteoporosis. Spine fusion condition highly depends on whether the pedicle screw is tightly fixed on spine, if not, spine fusion will not work properly. After the surgery, the first 3 months is the most crucial period, and bone healing situation cannot be shown through X-ray before the first radiologic images taken around the sixth week. Therefore, it is helpful to have a nonradiative method to monitor the locking force of the pedicle screw after surgery, especially during the early stage. Here a passive wireless force sensor is developed for monitoring the locking force of the pedicle screw, as we call it a smart washer. By integrating a capacitive ring-shape force sensor with an inductor, a passive LC sensor can be built by measuring the resonant frequency wirelessly. The smart washer is designed and calibrated to establish the relation between the locking force and resonant frequency, and then it is fixed with a screw in a porcine femur, with and without medium between the reader and inductor. When the locking force decreases from 8.3 to 0.9 N, the error is less than 0.5 N, and the maximum wireless sensing distance is 72 mm. However, the medium between the reader and the sensor inductor will affect the resonant frequency, but not the sensitivity. Therefore, the locking force variation can still be calculated by the resonant frequency shift accurately. Furthermore, by designing another five LC sensors with different operating resonant frequency ranges, it is possible to identify locking forces at different locations for more pedicle screws. To our knowledge, no LC force sensor was proposed to monitor the locking force of pedicle screws after surgery in the past.","PeriodicalId":1,"journal":{"name":"Accounts of Chemical Research","volume":null,"pages":null},"PeriodicalIF":16.4000,"publicationDate":"2024-05-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"A Passive Wireless Smart Washer for Locking Force Monitoring on the Orthopedic Pedicle Screw\",\"authors\":\"Che-Fu Liu, Tze-Hong Wong, Hsin-Chuan Wang, Asher Sun, Wensyang Hsu\",\"doi\":\"10.1155/2024/6690983\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"A pedicle screw is a component for fixation in spine fusion surgery, often for patients with osteoporosis. Spine fusion condition highly depends on whether the pedicle screw is tightly fixed on spine, if not, spine fusion will not work properly. After the surgery, the first 3 months is the most crucial period, and bone healing situation cannot be shown through X-ray before the first radiologic images taken around the sixth week. Therefore, it is helpful to have a nonradiative method to monitor the locking force of the pedicle screw after surgery, especially during the early stage. Here a passive wireless force sensor is developed for monitoring the locking force of the pedicle screw, as we call it a smart washer. By integrating a capacitive ring-shape force sensor with an inductor, a passive LC sensor can be built by measuring the resonant frequency wirelessly. The smart washer is designed and calibrated to establish the relation between the locking force and resonant frequency, and then it is fixed with a screw in a porcine femur, with and without medium between the reader and inductor. When the locking force decreases from 8.3 to 0.9 N, the error is less than 0.5 N, and the maximum wireless sensing distance is 72 mm. However, the medium between the reader and the sensor inductor will affect the resonant frequency, but not the sensitivity. Therefore, the locking force variation can still be calculated by the resonant frequency shift accurately. Furthermore, by designing another five LC sensors with different operating resonant frequency ranges, it is possible to identify locking forces at different locations for more pedicle screws. 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引用次数: 0
摘要
椎弓根螺钉是脊柱融合手术中的固定部件,通常用于骨质疏松症患者。脊柱融合的状况在很大程度上取决于椎弓根螺钉是否紧密地固定在脊柱上,否则脊柱融合将无法正常进行。术后前 3 个月是最关键的时期,在第 6 周左右拍摄第一张 X 光片之前,骨愈合情况无法通过 X 光片显示出来。因此,采用非辐射方法监测术后椎弓根螺钉的锁定力很有帮助,尤其是在早期阶段。在此,我们开发了一种用于监测椎弓根螺钉锁定力的无源无线力传感器,我们称之为智能垫圈。通过将电容式环形力传感器与电感器集成在一起,可以通过无线测量谐振频率建立一个无源 LC 传感器。我们设计并校准了智能垫圈,以确定锁定力与共振频率之间的关系,然后用螺钉将其固定在猪股骨上,读取器与电感器之间有无介质。当锁定力从 8.3 N 减小到 0.9 N 时,误差小于 0.5 N,最大无线感应距离为 72 mm。然而,读取器和感应器之间的介质会影响谐振频率,但不会影响灵敏度。因此,仍然可以通过谐振频率偏移准确计算出锁定力的变化。此外,通过设计另外五个具有不同工作谐振频率范围的 LC 传感器,可以识别更多椎弓根螺钉在不同位置的锁定力。据我们所知,过去没有人提出用 LC 力传感器来监测椎弓根螺钉术后的锁定力。
A Passive Wireless Smart Washer for Locking Force Monitoring on the Orthopedic Pedicle Screw
A pedicle screw is a component for fixation in spine fusion surgery, often for patients with osteoporosis. Spine fusion condition highly depends on whether the pedicle screw is tightly fixed on spine, if not, spine fusion will not work properly. After the surgery, the first 3 months is the most crucial period, and bone healing situation cannot be shown through X-ray before the first radiologic images taken around the sixth week. Therefore, it is helpful to have a nonradiative method to monitor the locking force of the pedicle screw after surgery, especially during the early stage. Here a passive wireless force sensor is developed for monitoring the locking force of the pedicle screw, as we call it a smart washer. By integrating a capacitive ring-shape force sensor with an inductor, a passive LC sensor can be built by measuring the resonant frequency wirelessly. The smart washer is designed and calibrated to establish the relation between the locking force and resonant frequency, and then it is fixed with a screw in a porcine femur, with and without medium between the reader and inductor. When the locking force decreases from 8.3 to 0.9 N, the error is less than 0.5 N, and the maximum wireless sensing distance is 72 mm. However, the medium between the reader and the sensor inductor will affect the resonant frequency, but not the sensitivity. Therefore, the locking force variation can still be calculated by the resonant frequency shift accurately. Furthermore, by designing another five LC sensors with different operating resonant frequency ranges, it is possible to identify locking forces at different locations for more pedicle screws. To our knowledge, no LC force sensor was proposed to monitor the locking force of pedicle screws after surgery in the past.
期刊介绍:
Accounts of Chemical Research presents short, concise and critical articles offering easy-to-read overviews of basic research and applications in all areas of chemistry and biochemistry. These short reviews focus on research from the author’s own laboratory and are designed to teach the reader about a research project. In addition, Accounts of Chemical Research publishes commentaries that give an informed opinion on a current research problem. Special Issues online are devoted to a single topic of unusual activity and significance.
Accounts of Chemical Research replaces the traditional article abstract with an article "Conspectus." These entries synopsize the research affording the reader a closer look at the content and significance of an article. Through this provision of a more detailed description of the article contents, the Conspectus enhances the article's discoverability by search engines and the exposure for the research.