State-of-the art implantable actuating devices, such as automated prosthetics, have time-limited operational capacities because they are sustained by batteries which, ultimately, rely on external power sources to be recharged. INTEGRATE proposes a radically new way to solve this problem: use metabolic energy from the patient to power implanted devices. To achieve this ambitious goal, INTEGRATE will develop i) new 3D printable soft actuating materials inspired by human muscles whit high performances and low power consumption and ii) an artificial organ capable of harvesting metabolic (biochemical) energy and transforming it into electricity. The actuating materials (Bionic Muscles) will be prepared via the self-assembly of biocompatible colloidal liquid crystals and stimuli-responsive polymers. A modular design and 3D printability will offer the possibility to manufacture these materials on the basis of the patient’s anatomy and needs. The Energy-Harvesting Organ will be capable of converting pH differences within various body fluids (e.g. gastric juice and saliva) into electricity with high efficiency, providing the necessary power to sustain the Bionic Muscles. This research has the potential to revolutionize the field of implantable devices and will lead to a turning point in robotics, wearable technologies, materials science, energy conversion, and materials engineering.