Knee Implant Loosening Detection: A Vibration Analysis Investigation

Arami, Arash; Delaloye, Jean-Romain; Rouhani, Hossein; Jolles, Brigitte M.; Aminian, Kamiar

doi:10.1007/s10439-017-1941-2

Cited by 21 publications

(22 citation statements)

References 45 publications

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“…The most sensitive band was found to be above 1500 Hz. (T1-C5) Arami et al [50] also provided a technology to detect loosening states of tibial knee implants.…”

Section: Monitoring Methods and Technologies For Cemented Fixationsmentioning

confidence: 99%

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Altering the Course of Technologies to Monitor Loosening States of Endoprosthetic Implants

Cachão

Santos

Bernardo

et al. 2019

Sensors

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Musculoskeletal disorders are becoming an ever-growing societal burden and, as a result, millions of bone replacements surgeries are performed per year worldwide. Despite total joint replacements being recognized among the most successful surgeries of the last century, implant failure rates exceeding 10% are still reported. These numbers highlight the necessity of technologies to provide an accurate monitoring of the bone–implant interface state. This study provides a detailed review of the most relevant methodologies and technologies already proposed to monitor the loosening states of endoprosthetic implants, as well as their performance and experimental validation. A total of forty-two papers describing both intracorporeal and extracorporeal technologies for cemented or cementless fixation were thoroughly analyzed. Thirty-eight technologies were identified, which are categorized into five methodologies: vibrometric, acoustic, bioelectric impedance, magnetic induction, and strain. Research efforts were mainly focused on vibrometric and acoustic technologies. Differently, approaches based on bioelectric impedance, magnetic induction and strain have been less explored. Although most technologies are noninvasive and are able to monitor different loosening stages of endoprosthetic implants, they are not able to provide effective monitoring during daily living of patients.

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“…The most sensitive band was found to be above 1500 Hz. (T1-C5) Arami et al [50] also provided a technology to detect loosening states of tibial knee implants.…”

Section: Monitoring Methods and Technologies For Cemented Fixationsmentioning

confidence: 99%

“…The loose implant (in red) can be characterized (by comparison with the fixed, in blue) by an increase in the resonance frequency and by the appearance of harmonics in the output signal. Adapted from the work in[50] under the Creative Commons Attribution 4.0 International License: http://creativecommons.org/licenses/by/4.0/.…”

mentioning

confidence: 99%

Altering the Course of Technologies to Monitor Loosening States of Endoprosthetic Implants

Cachão

Santos

Bernardo

et al. 2019

Sensors

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“…every 6 or 12 months). However, detection of early stages of loosening are ambiguous and can be subjective due to low specificity and accuracy [13,14]. This limits the use of X-ray techniques in detecting early loosening, although it is considered the gold standard in confirming implant loosening.…”

Section: A Current Diagnostic Techniquesmentioning

confidence: 99%

A New Diagnostic Technique to Detect Early Migration of Joint Prostheses

et al. 2021

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“…In recent years, non-imaging techniques in the framework of vibrational analysis of the bone-prosthesis system (also known as vibrometry, modal analysis, etc.) have been developed for intraoperative fixation evaluation [5], [7], [11], [15]- [19], osseointegration assessment [20]- [23], and postoperative loosening diagnosis [24]- [32]. Development of instrumented (sensorintegrated) prostheses [22], [27], [28], [33], [34] with telemetric systems for in vivo monitoring [35], [36], establishment of new techniques based on acoustics [23], [34], use of ultrasound probes instead of conventional sensors like accelerometers [30], and extracorporeal shockwave excitation [31] are amongst the recent efforts towards the vibrational analysis of the boneprosthesis systems.…”

Section: Introductionmentioning

confidence: 99%

“…In most of previous studies the bone-prosthesis system was excited over a narrow frequency band (e.g., <1 kHz [25], [26], 0.1-1.2 kHz [24], 0.1-1.5 kHz [30], 1.2-2 kHz [17], [19], 0.1-2 kHz [29], and 0.03-3 kHz [32]). However, the most sensitive band for excitation was found above 4 kHz during the insertion of prosthesis in a THA [11], and between 12 and 15 kHz for the shoulder joint [18].…”

Section: Introductionmentioning

confidence: 99%

A Vibrational Technique for In Vitro Intraoperative Prosthesis Fixation Monitoring

Yousefsani

Dejnabadi

Guyen³

et al. 2020

IEEE Trans. Biomed. Eng.

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In this paper, a new vibrational modal analysis technique was developed for intraoperative cementless prosthesis fixation evaluation upon hammering. Methods: An artificial bone (Sawbones)-prosthesis system was excited by sweeping of a sine signal over a wide frequency range. The exponential sine sweep technique was implemented to the response signal in order to determine the linear impulse response. Recursive Fourier transform enhancement (RFTE) technique was applied to the linear impulse response signal in order to enhance the frequency spectrum with sharp and distinguishable peak values indicating distinct high natural frequencies of the system (ranging from 15 kHz to 90 kHz). The experiment was repeated with 5 Sawbones-prosthesis samples. Upon successive hammering during the prosthesis insertion, variation of each natural frequency was traced. Results: Compared to classical Fast Fourier Transform, RFTE provided a better tracing and enhancement of frequency components during insertion. Three different types of frequency evolving trends (monotonically increasing, insensitive, and plateau-like) were observed for all samples, as confirmed by a new finite element simulation of the prosthesis dynamic insertion. Two main mechanical phenomena (i.e., geometrical compaction and compressive stress) were shown to govern these trends in opposite ways. Followup of the plateau-like trend upon hammering showed that the frequency shift is a good indicator of fixation. Conclusion: Alongside the individual follow-up of frequency shifts, combinatorial frequency analysis provides new objective information on the mechanical stability of Sawboneprosthesis fixation. Significance: The proposed vibrational technique based on RTFE can provide the surgeon with a new assistive diagnostic technique during the surgery by indicating when the bone-prosthesis fixation is acceptable, and beyond of which further hammering should be done cautiously to avoid bone fracture.

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Knee Implant Loosening Detection: A Vibration Analysis Investigation

Cited by 21 publications

References 45 publications

Altering the Course of Technologies to Monitor Loosening States of Endoprosthetic Implants

Altering the Course of Technologies to Monitor Loosening States of Endoprosthetic Implants

A New Diagnostic Technique to Detect Early Migration of Joint Prostheses

A Vibrational Technique for In Vitro Intraoperative Prosthesis Fixation Monitoring

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