Research Strength
Based on more than ten years of research foundation in the field of human soft tissue mechanics characterization in the Laboratory of Biomaterials and Soft Materials Mechanics at Tsinghua University, Xijian Technology has developed a quantitative platform technology for soft tissue mechanics by combining clinical and consumer market needs. The company has strong scientific research capabilities, with a research team leading 6 National Natural Science Foundation projects and publishing over 160 SCI papers. The papers have been cited over 5400 times and have an H-index of 37.
Xijian Technology relies on the company's research team to build a systematic service system, serving key links of every stage of research projects and providing tailored application support for researchers. It has cooperated with multiple large tertiary hospitals, universities, research institutes and other units.
Clinical Evidence – Study on Anterior Knee Pain
Anterior knee pain affects about 25% of adults worldwide. The mechanical biomarkers of Xijian Technology can quantitatively describe the force pattern of the quadriceps femoris and predict the degree of patellofemoral instability, providing new ideas for understanding disease mechanisms and guiding targeted treatments such as selective muscle relaxation or strengthening training.
BMC Musculoskeletal Disorders,2025
Experimental measurement scenario
Principle of anterior knee pain
Principles of Shoulder and Neck Pain
Experimental measurement scenario
Clinical Evidence – Shoulder and Neck Pain Study
The mechanical biomarkers of Xijian Technology provide objective and reliable evaluation indicators for the clinical diagnosis of shoulder and neck pain (myofascial pain syndrome) and the precise assessment of acupotomy treatment efficacy.
Chinese Acupuncture & Moxibustion, 2025
Clinical Evidence – Muscle Fatigue Study
Mechanical fatigue of skeletal muscles and tendons is a leading cause of many sports injuries. Xijian Technology's mechanical biomarkers objectively and quantitatively measure mechanical fatigue in skeletal muscles, offering significant value for athlete screening, scientific training, sports-injury prevention, and targeted intervention.
Sports Medicine – Open, 2025
Experimental measurement scenario
Clinical Evidence – Sports Nutrition Research
By accurately quantifying the changes in the mechanical properties of the subject's local skeletal muscles over time, an objective in vivo biomechanical evaluation of the in vivo effects of muscle related drugs, health supplements, and foods can be conducted.
