The primary objective of root canal treatment is to remove inflamed pulp tissue and bacteria within the root canal to prevent apical periodontitis. Therefore, cleaning efficacy of root canal is the most critical factor affecting the success rate of root canal treatment. Several studies have shown that ultrasonic irrigation provides better root canal cleaning efficacy than other irrigation methods. However, the complex structure of the root canal system poses a challenge to achieving ideal cleaning efficacy, particularly in the apical region. Ultrasonic irrigation is a widely used clinical method for root canal cleaning, and the cavitation effect is one of the physical mechanisms expected to achieve cleaning ability. However, studies have found that the power of ultrasonic irrigation instruments used to trigger the cavitation effect is high and thus increases the risk of instrumental fracture during clinical treatment. Accordingly, in this study, we first investigated the mechanisms of the induction of cavitation effect by ultrasonic irrigation instruments to optimize the current root canal treatment strategy. Microbubbles have been widely used in the medical field due to their ability to produce sonoporation, drug delivery, and the enhancement of ultrasound image contrast. However, there have been limited studies on the applications of microbubbles in root canal treatment. Since microbubbles have the potential to serve as cavitation nuclei in the irrigants, the reduction of the threshold for inducing cavitation effect followed by the improvement of root canal cleaning efficiency may be achieved. Therefore, we developed a novel shelled microbubble-based irrigants aiming to reduce the threshold for inducing the cavitation effect and improve the root canal cleaning efficiency during root canal treatment. Finally, we validated the effectiveness of the designed strategies using an ex vivo tooth model. Currently, there is no appropriate method that allows us to real-time image and quantify the cavitation events in root canal models. Hence, cavitation effects have always been qualitatively evaluated without direct evidence of their occurrence. Since the high-frequency ultrasonic imaging system has high image resolution and can be used for real-time observation, for the first time, we used it to successfully observe and quantify the cavitation effects induced by ultrasonic irrigation instruments within the root canal, enabling a more refined quantification of the cavitation effects in terms of space, time, and intensity. Furthermore, by examining the oscillation mode of the ultrasonic irrigation instruments, we found that many parameters crossly affect the cavitation effect. We also developed irrigants containing non-shelled or shelled microbubbles and applied them during ultrasonic irrigation. It was found that the reduced threshold for inducing cavitation effect could be successfully achieved by using non-shelled or shelled microbubble-based irrigants. Finally, we proved the positive correlation between the cavitation effect and root canal cleaning efficacy in the ex vivo tooth model. The root canal cleaning efficacy, especially for the apical region where infection sources are more likely to remain, was also significantly improved when applying the developed shelled microbubble-based irrigants. In summary, we have successfully demonstrated the occurrence of the cavitation events and proved the positive correlation between the cavitation effect and root canal cleaning efficacy by utilizing the high-frequency ultrasound imaging system. Additionally, we have developed an innovative strategy for root canal treatment that involves using shelled microbubble-based irrigants, which has led to a significant improvement in root canal cleaning efficacy. This approach reduces the utilization of ultrasonic power, thereby lowering the risk of clinical instrumental fracture and ensuring safer and optimized root canal cleaning, thus increasing the success rate of root canal treatment. Future research can focus on developing novel ultrasonic devices that can efficiently transmit energy to induce the cavitation effect. In addition, the use of next-generation irrigants with antibacterial effects by loading antibacterial drugs on the shell layer of microbubbles could also be explored.