New method for detection of complex 3D fracture motion--verification of an optical motion analysis system for biomechanical studies

Fracture-healing depends on interfragmentary motion. For improved osteosynthesis and fracture-healing, the micromotion between fracture fragments is undergoing intensive research. The detection of 3D micromotions at the fracture gap still presents a challenge for conventional tactile measurement sys...

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Bibliographic Details
Published in:BMC musculoskeletal disorders 2012-03, Vol.13 (1), p.33-33, Article 33
Main Authors: Doebele, Stefan, Siebenlist, Sebastian, Vester, Helen, Wolf, Petra, Hagn, Ulrich, Schreiber, Ulrich, Stöckle, Ulrich, Lucke, Martin
Format: Article
Language:English
Subjects:
Agreements
Analysis
Bias
Biomechanical Phenomena
Biomechanics
Bone Substitutes - chemistry
Calibration
Design
Elastic Modulus
Equipment Design
Fracture Healing
Fractures
Fractures, Bone - physiopathology
Image Processing, Computer-Assisted - instrumentation
Image Processing, Computer-Assisted - standards
Imaging, Three-Dimensional - instrumentation
Imaging, Three-Dimensional - standards
Measuring instruments
Medical statistics
Methods
Models, Anatomic
Motion
Optical measurements
Quality control
Reproducibility of Results
Resins, Synthetic - chemistry
Statistical analysis
Stress, Mechanical
Studies
Technical Advance
Thermometers
Weight-Bearing
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Summary:Fracture-healing depends on interfragmentary motion. For improved osteosynthesis and fracture-healing, the micromotion between fracture fragments is undergoing intensive research. The detection of 3D micromotions at the fracture gap still presents a challenge for conventional tactile measurement systems. Optical measurement systems may be easier to use than conventional systems, but, as yet, cannot guarantee accuracy. The purpose of this study was to validate the optical measurement system PONTOS 5M for use in biomechanical research, including measurement of micromotion. A standardized transverse fracture model was created to detect interfragmentary motions under axial loadings of up to 200 N. Measurements were performed using the optical measurement system and compared with a conventional high-accuracy tactile system consisting of 3 standard digital dial indicators (1 μm resolution; 5 μm error limit). We found that the deviation in the mean average motion detection between the systems was at most 5.3 μm, indicating that detection of micromotion was possible with the optical measurement system. Furthermore, we could show two considerable advantages while using the optical measurement system. Only with the optical system interfragmentary motion could be analyzed directly at the fracture gap. Furthermore, the calibration of the optical system could be performed faster, safer and easier than that of the tactile system. The PONTOS 5 M optical measurement system appears to be a favorable alternative to previously used tactile measurement systems for biomechanical applications. Easy handling, combined with a high accuracy for 3D detection of micromotions (≤ 5 μm), suggests the likelihood of high user acceptance. This study was performed in the context of the deployment of a new implant (dynamic locking screw; Synthes, Oberdorf, Switzerland).
ISSN:1471-2474
1471-2474
DOI:10.1186/1471-2474-13-33