Functional Spinal BiomechanicsOpen OpportunitiesAccurate non-invasive assessment modalities that incorporate both scapular motion and its morphology are currently unavailable, presenting a clear need for sustainable clinical application. To address this need, the Laboratory for Movement Biomechanics (LMB) utilizes a unique optical 4D scanning system (SLOT) to estimate the underlying anatomical structures using non-invasive structured light to produce high-quality images of the human skin surface, both statically and dynamically. By utilizing the clear cutaneous surface contours surrounding the scapula, the application of this technology to the shoulder joint could allow a novel non-invasive and dynamic approach for estimating scapular kinematics that overcomes the challenges associated with soft-tissue artifacts. The key challenge in the development of this approach is the precise identification and tracking of relevant scapula landmarks, as well as soft tissue artifacts, all of which are expected to affect the accuracy of the SLOT-measured kinematics. - Engineering and Technology, Information, Computing and Communication Sciences
- Master Thesis
| Spinal deformities are omnipresent and difficult to assess and monitor accurately. One of the most prevalent spinal deformities in children and adolescents is scoliosis, a three-dimensional deformation of the spine. To date, the standard approach for assessing and monitoring scoliosis is biplanar radiography using ionizing radiation. Thermal imaging has been investigated as a non-invasive adjunctive assessment method, as the scoliotic back shows a typical thermal asymmetry between contralateral sides. In this project, the usefulness and accuracy of thermal imaging in the context of spine assessment will be investigated and evaluated. - Biomechanics, Biomedical Engineering
- ETH Zurich (ETHZ), Internship, Master Thesis
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