Organ transportation has yet to be substantially innovated. If organs could be moved by drone, Instead of ill-timed commercial aircraft or expensive charter flights, when a patient in need of an organ transplant is eventually paired with a donor, every second matters. As more time passes between the organ's removal and transplantation into the recipient, lifesaving organs could be transplanted more quickly. The organ's post-transplant performance deteriorates. To increase the odds of success, organs must be sent from point A to point B as fast and safely as feasible. Drones can save lives all over the world by carrying medical supplies or vaccines to difficult-to-reach locations, but there are a few problems that need to be resolved, such as monitoring and preserving container temperature and humidity. In order to address these issues, a smart container that is integrated with a thermoelectric cooler module and a temperature sensor has been created. This ensures that medical supplies or organs are transported safely by maintaining the temperature. We also look at the area where unmanned aerial vehicles are selfcontained devices with propellers that may be turned in different directions to vary their motion. Technology for organ preservation and an Arduino drone control circuit. The Arduino part explains how to build up a breadboard circuit, including how to connect buttons, resistors, and sensors. It emphasizes how crucial correct wiring is to operation. The Cold Storage Preservation approach, namely the use of HTK and Collins solutions to preserve organ viability during transit, is covered in the section on organ preservation. The importance of these techniques in medical physiology is emphasized.
Artificial Intelligence, Internet of Things, Arduino, Internet of Drones, Healthcare.