ObjectiveThis article aims to summarize the historical evolution of thyroid cancer classification and explore the establishment of a precise classification system based on molecular characteristics and its impact on clinical applications.MethodsA literature review was conducted to analyze and organize the recent influences of molecular classification of thyroid cancer on clinical diagnosis and treatment. ResultsIn recent years, the classification of thyroid cancer has introduced molecular features such as BRAF and RAS mutations, highlighting the close association between these molecular characteristics and prognosis. For example, the BRAF V600E mutation is associated with high aggressiveness in papillary thyroid cancer, while RAS mutations suggest malignant potential in follicular tumors. With the advancement of multi-omics research, classification strategies based on multi-omics have shown significant value in the diagnosis, monitoring, treatment, and prognostic assessment of thyroid cancer. Although multi-omics integration has significantly improved the accuracy of prognostic assessments in thyroid cancer, there are still limitations, including imprecise detection of tumor heterogeneity and insufficient sensitivity and specificity of molecular biomarker detection. ConclusionsThe classification of thyroid cancer is developing towards the integration of molecular features to achieve more precise diagnosis and treatment. To accomplish this goal, it is necessary to overcome the challenges of tumor heterogeneity and the limitations of detection technologies in the future, and to promote the practical application of molecular classification in clinical settings.
The use of a filling block can improve the initial stability of the fixation plate in the open wedge high tibial osteotomy (OWHTO), and promote bone healing. However, the biomechanical effects of filling block structures and materials on OWHTO remain unclear. OWHTO anatomical filling block model was designed and built. The finite element analysis method was adopted to study the influence of six filling block structure designs and four different materials on the stress of the fixed plate, tibia, screw, and filling block, and the micro-displacement at the wedge gap of the OWHTO fixation system. After the filling block was introduced in the OWHTO, the maximum von Mises stress of the fixation plate was reduced by more than 30%, the maximum von Mises stress of the tibia decreased by more than 15%, and the lateral hinge decreased by 81%. When the filling block was designed to be filled in the posterior position of the wedge gap, the maximum von Mises stress of the fixation system was 97.8 MPa, which was smaller than other filling methods. The minimum micro-displacement of osteotomy space was –2.9 μm, which was larger than that of other filling methods. Compared with titanium alloy and tantalum metal materials, porous hydroxyapatite material could obtain larger micro-displacement in the osteotomy cavity, which is conducive to stimulating bone healing. The results demonstrate that OWHTO with a filling block can better balance the stress distribution of the fixation system, and a better fixation effect can be obtained by using a filling block filled in the posterior position. Porous HA used as the material of the filling block can obtain a better bone healing effect.