Ultrasonic Backscatter Imaging for ACL Reconstruction and Shoulder Diseases

This study aims to explore the application of ultrasonic scattering imaging technology in patients after anterior cruciate ligament (ACL) reconstruction and in patients with shoulder musculoskeletal disorders. Ultrasonography is a convenient, real-time, non-invasive, and portable imaging tool commonly used by clinicians for the diagnosis of musculoskeletal system disorders. However, the interpretation of ultrasound images can be affected by factors such as operator experience, probe orientation, machine type, and parameter settings, and most diseases cannot be quantified. Nakagami imaging, based on the backscattering statistical distribution model, is a quantitative assessment method that can reduce subjective human judgment. It extracts the basic physical properties of tissues based on the interaction between ultrasound and tissue microstructure. The Nakagami distribution is an effective model for describing tissue inverse scattering envelope statistics, which can identify tissue ultrasound image features and classify the examined tissue by comparing it with the specified envelope-related scattering conditions.

ACL reconstruction surgery is a commonly performed procedure. Postoperative issues often include joint stiffness, loss of neuromuscular control, muscle mass loss, and muscle strength decline. Changes in muscle quality and volume are associated with a decrease in thigh muscle strength. Both MRI and ultrasound can be used to assess changes in muscle volume and quality. Soft tissue injuries around the shoulder and ankle joints are common in the field of sports medicine. Ultrasound is commonly used to assess the severity of injuries to soft tissues such as the rotator cuff tendons/muscles and surrounding ligaments of the shoulder, as well as the medial and lateral ligament complexes of the ankle. Preliminary results of this study show that Nakagami scattering imaging can visually distinguish layers within normal tendons. The investigative team hypothesizes that ultrasonic Nakagami scattering imaging can provide a method for visualizing and subsequent quantitative analysis of suspected soft tissue lesions in patients after ultrasound scanning, with the goal of achieving standardized diagnostic parameters for soft tissue lesions.

The results of this project may enhance the diagnostic efficacy of musculoskeletal ultrasound for use in musculoskeletal diseases. If successful, it could lead to earlier diagnosis and treatment for these patients, reducing the socioeconomic losses associated with work and competition. Academically, it would establish the institution and team as world leaders in the application of ultrasound inverse scattering imaging technology.