Lata, S., Chakravorty, Shibani, Mitra, Tamoghni, Pradhan, Prasanti Kumari, Mohanty, Soumyakanta, Patel, Paritosh, Jha, Ealisha, Panda, Pritam Kumar, Verma, Suresh K., Suar, Mrutyunjay, Lata, S., Chakravorty, Shibani, Mitra, Tamoghni, Pradhan, Prasanti Kumari, Mohanty, Soumyakanta, Patel, Paritosh, Jha, Ealisha, Panda, Pritam Kumar, Verma, Suresh K., and Suar, Mrutyunjay
Plasma is regularly alluded to as the fourth form of matter. Its bounty presence in nature along with its potential antibacterial properties has made it a widely utilized disinfectant in clinical sciences. Thermal plasma and nonthermal (or cold atmospheric) plasma (NTP) are two types of plasma. Atoms and heavy particles are both available at the same temperature in thermal plasma. Cold atmospheric plasma (CAP) is intended to be nonthermal since its electrons are hotter than the heavier particles at ambient temperature. Direct barrier discharge (DBD), atmospheric plasma pressure jet (APPJ), etc. methods can be used to produce plasma, however, all follow a basic concept in their generation. This review focuses on the anticipated uses of cold atmospheric plasma in dentistry, such as its effectiveness in sterilizing dental instruments by eradicating bacteria, its advantage in dental cavity decontamination over conventional methods, root canal disinfection, its effects on tooth whitening, the benefits of plasma treatment on the success of dental implant placement, and so forth. Moreover, the limitations and probable solutions has also been anticipated. These conceivable outcomes thus have proclaimed the improvement of more up-to-date gadgets, for example, the plasma needle and plasma pen, which are efficient in treating the small areas like root canal bleaching, biofilm disruption, requiring treatment in dentistry.