Publication

Quality controls for two heel bone ultrasounds used in the Swiss Evaluation of the Methods of Measurement of Osteoporotic Fracture Risk Study

Journal Paper/Review - Jan 1, 2002

Units
PubMed

Citation
Krieg M, Wimpfheimer K, Tanzi F, Pancaldi P, Neff M, Dambacher M, Theiler R, Büche D, Rizzoli R, Lippuner K, Häuselmann H, Tyndall A, Kraenzlin M, Hartl F, Cornuz J, Burckhardt P. Quality controls for two heel bone ultrasounds used in the Swiss Evaluation of the Methods of Measurement of Osteoporotic Fracture Risk Study. Journal of clinical densitometry : the official journal of the International Society for Clinical Densitometry 2002; 5:335-41.
Type
Journal Paper/Review (English)
Journal
Journal of clinical densitometry : the official journal of the International Society for Clinical Densitometry 2002; 5
Publication Date
Jan 1, 2002
Issn Print
1094-6950
Pages
335-41
Brief description/objective

Because of the important morbidity and mortality associated with osteoporosis, it is essential to detect subjects at risk by screening methods, such as bone quantitative ultrasounds (QUSs). Several studies showed that QUS could predict fractures. None, however, compared prospectively different QUS devices, and few data of quality controls (QCs) have been published. The Swiss Evaluation of the Methods of Measurement of Osteoporotic Fracture Risk is a prospective multicenter study that compared three QUSs for the assessment of hip fracture risk in a population of 7609 women age >/=70 yr. Because the inclusion phase lasted 20 mo, and because 10 centers participated in this study, QC became a major issue. We therefore developed a QC procedure to assess the stability and precision of the devices, and for their cross-calibration. Our study focuses on the two heel QUSs. The water bath system (Achilles+) had a higher precision than the dry system (Sahara). The QC results were highly dependent on temperature. QUS stability was acceptable, but Sahara must be calibrated regularly. A sufficient homogeneity among all the Sahara devices could be demonstrated, whereas significant differences were found among the Achilles+ devices. For speed of sound, 52% of the differences among the Achilles+ was explained by the water s temperature. However, for broadband ultrasound attenuation, a maximal difference of 23% persisted after adjustment for temperature. Because such differences could influence measurements in vivo, it is crucial to develop standardized phantoms to be used in prospective multicenter studies.