Traditional dental micromotors, commonly used for various restorative and surgical procedures, often rely on manual control systems that can compromise both precision and safety. Because the operator must frequently adjust speed and torque manually, it increases the risk of hand fatigue, operational errors, and cross-contamination in a clinical setting. The need to touch multiple control surfaces during treatment can inadvertently transfer microorganisms, posing hygiene concerns for both patients and dental professionals. Moreover, manual systems limit the level of precision required for delicate procedures such as cavity preparation, endodontic access, or implant placement. These challenges reduce overall efficiency, increase procedure time, and may affect treatment outcomes. In modern dental practice, there is growing demand for micromotors that offer automated control, enhanced accuracy, and touch-free operation. Integrating digital sensors, smart feedback systems, and ergonomic designs can greatly improve user comfort and procedural safety.