ABSTRACT
BACKGROUND:Recently, studies on three-dimensional reconstruction and biomechanics became more and more. Three-dimensional models of organs were established by modeling software based on image data using computer. Mechanical analysis was conducted using finite element analysis software. After literature retrieval, we found that the principle of three-dimensional reconstruction of human organs is not clear, and the process description is relatively simple. Some is not accorded with the fact. Above studies cannot guide related research. OBJECTIVE:To explore the principle, process, results and further application of three-dimensional reconstruction models of organs, and to provide evidence for future studies. METHODS:We retrieved China National Knowledge Infrastructure for representative literatures about three-dimensional reconstruction of human organs using the computer, and analyzed the principle, process, results and further application of three-dimensional reconstruction models of organs. RESULTS AND CONCLUSION:In combination with established three-dimensional bone models, we explained the principle, process, and application of three-dimensional reconstruction in detail, and laid the theoretical foundation for subsequent biomechanical research. With continuous development of tissue engineering technology, scholars have begun to study the pathogenesis of bone injury from various angles and different aspects so as to better prevent and treat this disease. The related research is stil in its primary stage, and stil needs further investigations.
ABSTRACT
BACKGROUND:Finite element analysis has been widely used for the research of bone and joint biomechanics, but the reports about finite element analysis of distal tibial articular surface defect are rare at home and abroad. OBJECTIVE:To establish ankle three-dimensional finite element model, produce distal tibial articular surface defects with different areas, and to simulate the distal tibial articular surface deformation and displacement under the different phases, thus predict the maximum al owable degree of distal tibial articular surface defect and explore the mechanics pathogenesis of ankle traumatic arthritis. METHODS:Continuous tomographic images were obtained by multi-slice spiral CT scan of a normal adult male ankle, and then the images were imported into the Mimics medicine modeling software to generate a entity model;the large general-purpose finite element analysis software ANSYS 13.0 was used for meshing, material property assignment and generating a finite element model. Restricted boundary conditions and simulated ankle distal end axial force, and then the stress distribution and displacement results of distal tibial articular surface in different phases were obtained. RESULTS AND CONCLUSION:The total number of units of the established finite element model of ankle joint was 157 990, and the total number of nodes was 193 801. On three phases, with the increase of the distal tibial defect area, the contact area was gradual y decreased, especial y in plantar flexion with the defect diameter of 13 mm, the change of the area was most obvious;The contact area of the neutral position was largest;with the increase of the distal tibial defect area in the neutral position and dorsiflexion, the peak stress was increased gradual y, and significantly increased after the diameter changed into 11-13 mm;in the neutral position and 10° of dorsiflexion, the peak stress mainly concentrated in the posteromedial and posterolateral quadrant;in 10° of plantar flexion, the change was complex, and when the diameter was 11-13 mm, the peak stress was increased gradual y with the increasing of defect area, when the diameter increased to 13 mm, the peak stress reached maximum. The maximum diameter of distal tibial articular surface defect was considered to be 11-13 mm. The joint function wil be affected when the diameter of distal tibial articular cartilage and bone bed defects was more than 11-13 mm.