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Bone vibration measurement using ultrasound; application to detection of hip prosthesis loosening


Reference:

Rowlands, A., Duck, F. and Cunningham, J. L., 2008. Bone vibration measurement using ultrasound; application to detection of hip prosthesis loosening. Medical Engineering & Physics, 30 (3), pp. 278-284.

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Official URL:

http://dx.doi.org/10.1016/j.medengphy.2007.04.017

Abstract

Hip prosthesis loosening can be determined in vivo using a vibration-based technique called vibrometry. In this technique, a low frequency (<1000Hz) sinusoidal vibration is applied to the femoral condyles and the resulting vibration is measured at the greater trochanter. If the prosthesis is securely fixed, the output vibration signal matches that of the input vibration, whereas if the prosthesis is loose, the output vibration signal is distorted and shows the marked presence of harmonics of the input frequency. One of the main problems with this application of this technique is in measuring the output vibration where significant amounts of soft tissue cover the measurement site. In order to circumvent this problem, an ultrasound probe, normally used for the measurement of blood flow, has been used to measure the output vibration. This has been evaluated by comparing the results obtained from the ultrasound probe with those from a conventional accelerometer in models representing a tight and loose hip prosthesis under simulated clinical conditions. The ultrasound probe was able to consistently detect the output vibration, for both the loose and secure prostheses. Under the test conditions used (which attempted to simulate a large thickness of soft tissue), the ultrasound probe was able to produce a greatly enhanced output vibration signal compared to the accelerometer. This suggests that the use of an ultrasound probe to detect mechanically induced vibration through significant amounts of soft tissue appears to be viable and could lead to enhanced detection of prosthesis loosening using this technique.

Details

Item Type Articles
CreatorsRowlands, A., Duck, F. and Cunningham, J. L.
DOI10.1016/j.medengphy.2007.04.017
DepartmentsFaculty of Engineering & Design > Mechanical Engineering
RefereedYes
StatusPublished
ID Code1402

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