In 1985, Professor KWOH first introduced robots into neurosurgery. Since then, advancements of stereotactic frames, radiographic imaging, and neuronavigation have led to the dominance of classic stereotactic robots. A comprehensive retrieval was performed using academic databases and search agents to acquire professional information, with a cutoff date of June, 2024. This reveals a multitude of emerging technologies are coming to the forefront, including tremor filtering, motion scaling, obstacle avoidance, force sensing, which have made significant contributions to the high efficiency, high precision, minimally invasive, and exact efficacy of robot-assisted neurosurgery. Those technologies have been applied in innovative magnetic resonance-compatible neurosurgical robots, such as Neuroarm and Neurobot, with real-time image-guided surgery. Despite these advancements, the major challenge is considered as magnetic resonance compatibility in terms of space, materials, driving, and imaging. Future research directions are anticipated to focus on 1) robotic precise perception; 2) artificial intelligence; and 3) the advancement of telesurgery.
Keyphrases
- minimally invasive
- robot assisted
- magnetic resonance
- artificial intelligence
- high efficiency
- big data
- high resolution
- machine learning
- current status
- deep learning
- contrast enhanced
- brain metastases
- deep brain stimulation
- parkinson disease
- health information
- computed tomography
- coronary artery disease
- fluorescence imaging
- single molecule
- acute coronary syndrome
- social media
- mass spectrometry
- atrial fibrillation