Abstract
The goal of creating cutting-edge medical devices is deeply based on technological advances and innovative design principles. People increasingly want to improve their quality of life, ensure their safety, health, and take full advantage of technological developments. Diagnostic and restorative directions of medicine are among those fields that are constantly evolving. Patients with various health issues, including both physical and mental challenges, are at the center of these developments, requiring ongoing care to manage their conditions effectively. This study focuses on integrating advanced technologies, particularly Artificial Intelligence (AI), into the medical field to enhance diagnostic device functionality, accuracy, and connectivity. The primary objective is to develop medical equipment that simplifies the diagnostic process, improves efficiency, and enhances the accuracy of clinical assessments. The methodology is based on the systematic design and optimization of diagnostic tools incorporating AI-driven data analysis, which enables more accurate and personalized patient assessments. As a result of the study, four therapeutic medical devices integrating infrared radiation and Artificial Intelligence (AI) have been designed. These devices are developed to enhance patient care and improve overall quality of life by providing advanced noninvasive diagnostic and therapeutic solutions. Experimental evaluations confirm that all four devices operate exclusively through non-invasive methods, thereby minimizing patient discomfort, pain, and the risk of infection or post-procedural complications. The application of infrared radiation technology demonstrates high precision and reliability in medical diagnostics, while AI-driven analysis contributes to enhanced efficiency and the personalization of therapeutic interventions.
Keywords: AI in Design, Design Research, Healthcare Design, Medical Equipment, Noninvasive Technology.