The prolonged wound-healing process caused by pathogen
infection
remains a major public health challenge. The developed electrical
antibiotic administration typically requires metal electrodes wired
to a continuous power supply, restricting their use beyond clinical
environments. To obviate the necessity for antibiotics and an external
power source, we have developed a wearable synergistic electroceutical
device composed of an air self-charging Zn battery. This battery integrates
sustained tissue regeneration and antibacterial modalities while maintaining
more than half of the initial capacity after ten cycles of chemical
charging. In vitro bacterial/cell coculture with the self-charging
battery demonstrates inhibited bacterial activity and enhanced cell
function by simulating the endogenous electric field and dynamically
engineering the microenvironment with released chemicals. This electroceutical
device provides accelerated healing of a bacteria-infected wound by
stimulating angiogenesis and modulating inflammation, while effectively
inhibiting bacterial growth at the wound site. Considering the simple
structure and easy operation for long-term treatment, this self-charging
electroceutical device offers great potential for personalized wound
care.