Recently, the ineffectiveness of conventional antibiotic treatments against the emergence of multidrug-resistant bacteria induces the development of novel effective disinfection technologies. Ultraviolet lasers, with several features, including high coherence, high directionality, monochromatic, and high intensity were the ideal candidate light source for disinfection; however, lasers are restricted by its inherent detriments such as high directionality, meticulous manufacturing, and the laser speckles. Here, the deep-ultraviolet random laser (DUV-RL) is realized by applying AlGaN Multiple Quantum wells (MQWs) and aluminum nanoparticles as the gain medium and plasmonic scattering centers. We provide proof of concept for the first random laser disinfection, and the results of this DUV-RL treatment are examined by implement this light source on model microbial strain-gram negative bacteria (Escherichia coli). To further exploit the functionality of the DUV-RL treatment, the generality of the treatment, and the disinfection efficiency of random laser treatment with different angle illumination are demonstrated in this study. Above all, it is expected that the success of applying random laser systems on disinfection arena can fulfill the empty piece of current laser treatment and offers another choice to inactivate the bacteria.