View clinical trials related to Nerve.
Filter by:Neuromuscular diseases are rare diseases for which significant progress has been made in the context of diagnosis thanks to advances in molecular techniques, but the intimate mechanisms of lesion formation remain poorly understood. Advances in cellular and molecular biology, the development of a few animal models, such as transgenic mice, which make it possible to mimic human pathology have made it possible to better understand the physiopathology of these diseases. However, they still do so very imperfectly and incompletely, making it even more necessary than ever to study diseased human muscle tissue to find new avenues of research or to confirm results obtained by experimentation. The purpose of this collection of tissue samples for neuro-muscular purposes is to collect such samples under the best conditions in order to promote basic and translational research on muscle diseases. This is why the CHU de Bordeaux wishes to keep the remainders of samples taken as part of the treatment to constitute a collection of biological samples and associated data kept according to quality standards and in compliance with the regulations in force.
The purpose of this study is to determine the efficacy of simultaneous innervation to prevent graft bone resorption in maxillofacial reconstruction. It may provide basis for future clinical trials and new strategies for improving the functional reconstruction of large jaw bone defects.
A novel algorithm for bioimpedance measurements to detect nerve tissue, and discriminate it from other tissue types has been developed in a porcine model, by analysing a complex impedance dataset based on multiple measurement frequencies. It must now be confirm that the previous results are applicable in humans. Measurements from 24 predefined needle positions will be obtained in 16 of the 32 volunteers that are included in the study (part A). A new algorithm to detect nerve tissue will be developed based on these measurement results. Further impedance algorithms will be developed for other tissue type. The efficacy of the algorithms (sensitivity and specificity) will be evaluated in the 16 following volunteers (part B).