The reactive radicals generated in plasma, such as OH and O, are generally regarded as the major sources for several biomedical applications, like sterilization, tooth bleaching, and tissue regeneration. In this study, we propose a simple APPJ with a steel capillary tube fixed inside a quartz tube and an aluminum ground electrode which is wrapped around the quartz tube. One can simply adjust the arrangement of outer electrodes, which changes the magnitude of electric field and length of surface charges, to obtain the optimal performance for these applications. Results show that the gas temperature, and plasma power consumption increase simultaneously with wider ground width (GW) and larger electrodes gap (G), while radical intensities (O/OH) are only consistent with gap distance; the jet length remains about 40 mm, and the temperature is below 40℃, perfectly acceptable to human body. As for sterilization experiment, cell wall destructions of S. mutans are observed via SEM after plasma exposure, and the bacteria inhibition zone depends strongly on treating time and electrode configuration. Inhibition zone can be increased by 12.8 times by increasing treatment time from 15 s to 60 s, with condition fixed at GW5G-5; and with treating time of 15 s, the killing area is enlarged by an increment of 4 times as adjusting the condition from GW15G-5 to GW15G15. Surface modification of ceramic material also shows great wettability improvement within 15 s, by 79% reduction of contact angle. Since the plasma jet can rapidly kill S. mutans and enhance the hydrophilicity on ceramic surface at the same time, we suggest APPJ a promising method for dental surgery.