With the continuous innovation of the concept of foot and ankle surgery, accurate surgical planning has become a key link to improve patient prognosis and restore function.

In recent years, the plantar pressure distribution system has gradually become an important auxiliary tool in the planning of foot and ankle surgery with its advanced sensing technology and data analysis capabilities.

The system collects the force data of various areas of the sole of the foot in real time when the patient walks or stands, forms a detailed pressure distribution map, and provides doctors with objective and quantitative biomechanical information, which helps to accurately evaluate the severity of foot lesions and their impact on overall foot function.

In foot and ankle surgery, the mechanical state of the foot directly determines the development of pathological changes and the effect of surgery.

The plantar pressure distribution system can comprehensively record the patient's plantar force in static and dynamic states, revealing common deformities such as arch collapse, hallux valgus, flat feet and their accompanying abnormal force points.

These data provide a scientific basis for surgical planning, enabling doctors to accurately grasp the lesion site and pathological mechanism, and then formulate a surgical plan that meets the individual anatomical characteristics and biomechanical characteristics of the patient.

In addition, during the preoperative planning stage, the system can also be used to simulate the effects of different surgical interventions on plantar pressure distribution.

With the help of computer simulation technology, doctors can predict the redistribution of pressure after surgical operations such as osteotomy, soft tissue release or reconstruction, thereby optimizing the surgical design and selecting appropriate fixation devices and correction angles.

This data-driven surgical planning model not only reduces surgical risks, but also improves the success rate of postoperative foot function recovery and reduces the occurrence of complications.

During the postoperative rehabilitation stage, the plantar pressure distribution system also plays an important role.

By regularly detecting changes in the patient's plantar pressure, doctors can monitor the postoperative rehabilitation process in real time, evaluate the effectiveness of the rehabilitation training program, and adjust the treatment strategy in time to ensure the gradual recovery and long-term stability of the biomechanical function of the foot.

This dynamic monitoring and feedback mechanism provides a strong guarantee for individualized rehabilitation management and promotes patients to return to normal life and work as soon as possible.

In addition, with the continuous optimization of sensor technology and data processing algorithms, the plantar pressure distribution system continues to improve its capabilities in real-time monitoring and multi-dimensional data fusion.

The system can not only provide detailed pressure maps under different motion states, but also provide doctors with dynamic evaluation data by long-term tracking and monitoring of patients' gait changes. This all-round, multi-period data monitoring makes surgical planning and postoperative management more refined, laying a solid foundation for the implementation of individualized treatment strategies.

In the planning of foot and ankle surgery, the plantar pressure distribution system not only helps with disease diagnosis and surgical plan formulation by providing accurate and objective biomechanical data, but also provides a scientific basis for postoperative rehabilitation.

With the continuous advancement of technology, the system is expected to achieve higher levels of intelligent and automated applications in the future, provide solid technical support for precise treatment of foot and ankle surgery, and ultimately improve the quality of life of patients and clinical treatment effects.