Let iXGenie transform your learning environments with custom simulations built to your curriculum’s exact specifications—fully integrated with your LMS, so you can focus on what matters most: student success.
Showing 1 - 13 of 13 results
Immerse students in the design and testing of neural interfaces that connect the brain to external devices, such as prosthetic limbs and communication aids. Through advanced XR simulations, students will develop and refine brain-computer interfaces (BCIs), analyze EEG signals, and create algorithms for neural control.
Train students in the design and analysis of cardiovascular devices with a focus on hemodynamics and fluid flow through immersive XR simulations. Students will simulate blood flow dynamics and design key devices like stents, heart valves, pacemakers, and vascular grafts, optimizing performance and minimizing complicati
Provide immersive training on robotic-assisted surgery and the design of medical robots through XR simulations. Students will master controlling robotic arms for minimally invasive procedures and learn how to program medical robots for precise tasks like suturing, tissue manipulation, and incision creation.
Empower students to master the design and function of drug delivery systems with a focus on microfluidic devices for precise medication administration. Through immersive simulations, students will design and test microfluidic devices, optimizing fluid dynamics and dosage control for various medical conditions.
Enhance students' understanding of artificial organs and implants through immersive XR simulations. Students will explore the design, function, and integration of artificial organs, including heart, kidney, and joint implants, and simulate their implantation and performance in virtual patients.
Provide hands-on training in the calibration, maintenance, and troubleshooting of clinical equipment used in hospitals and research labs through immersive XR simulations. Students will interact with devices like ventilators, infusion pumps, ECG machines, and defibrillators to enhance their technical skills and ensure o
Explore the principles of biomechanics and motion analysis through immersive XR simulations. Students will analyze human movement, understand forces acting on the body, and assess the performance of musculoskeletal systems in dynamic environments, enhancing their ability to apply these concepts to health, sports, and r
Empower with the skills to design, test, and fit prosthetic limbs and orthotic devices through immersive XR simulations. Users will engage in virtual scenarios to design customized prosthetics, adjust alignment, and optimize comfort and functionality for virtual patients.
Immerse students in the properties and applications of biomaterials used in implants, prosthetics, and tissue engineering through innovative virtual labs. Students will interact with biomaterials like polymers, ceramics, metals, and composites, and design tissue scaffolds for regenerative medicine, enhancing their unde
Enhance students' understanding of medical imaging techniques such as MRI, CT, ultrasound, and X-ray through immersive XR simulations. This interactive platform allows students to control virtual imaging equipment, visualize real-time results, and interpret medical images to identify anatomical structures and diagnose
Equip students with the skills to acquire, process, and analyze biomedical signals such as ECG, EEG, EMG, and blood pressure. Using interactive simulations, learners will explore signal collection from virtual patients, apply signal processing techniques, and interpret data for diagnosing medical conditions.
Provide an in-depth understanding of human anatomy and physiology with a focus on systems relevant to biomedical applications. Using immersive XR technology, students can explore and interact with virtual 3D models of the human body, gaining insights into organ systems, tissues, and cells and their implications for med
Immerse students in the principles of medical device design, prototyping, and testing with a cutting-edge XR-powered simulation. Through virtual scenarios, learners can design devices such as prosthetics, implants, diagnostic tools, and wearables, create interactive 3D models, and simulate their functionality, durabili