The experience of the surgeon is indeed important and should not be underestimated. But this is an era of highly developed technology, many high-tech means have been introduced into neurosurgery, the era of surgery based only on the experience of doctors has passed. Even the most powerful martial artists cannot escape the continuous strafing of submachine guns. The surgeon’s experience combined with the skillful use of optimized high-tech tools is the key to guaranteeing the surgical results. Compared to other cranial surgeries, glioma surgery best demonstrates the value of high-technology tools in neurosurgery and is the most widely used. New technologies for surgical resection assistance help to achieve the maximum removal of glioma with safety. Currently, anatomical neuroimaging navigation, functional neuroimaging navigation, intraoperative arousal, neurophysiological monitoring, intraoperative magnetic resonance combined with functional imaging neurological navigation, fluorescence-guided microsurgery, and real-time intraoperative ultrasound image localization are carried out in China. For non-functional area gliomas are recommended: neuronavigation, intraoperative MRI, and intraoperative ultrasound. Gone are the days of relying solely on the naked eye or surgical microscope for surgery. For gliomas in functional areas, we recommend: intraoperative subcortical and subcortical direct electrical stimulation under arousal, neuronavigation, intraoperative MRI, intraoperative ultrasound, cortical somatosensory evoked potentials to localize the central sulcus, and motor evoked potentials to monitor motor areas. Currently, intraoperative arousal with intraoperative electrical cortical stimulation for functional area localization in patients with functional glioma is considered to be the gold standard for determining functional brain areas. We were the first in China to perform intraoperative high-field MRI combined with functional neural navigation for glioma surgery. Its main advantages are preoperative three-dimensional visualization of lesions and tumors, which can be used to develop optimal surgical plans (virtual reality); intraoperative microscopic functional neuronavigation technology allows the operator to see tumors and functional structures that were not originally visible under the operating microscope, making surgery simple and the surgical operation evidence-based, and surgery no longer overly dependent on the operator’s experience (augmented reality); intraoperative magnetic resonance scanning can detect Accidental residual lesions and updated brain drift. The extent of resection is improved by intraoperative re-excision. With the cooperation of the anesthesiology department, we have maturely applied intraoperative awake craniotomy and intraoperative cortical and subcortical electrical stimulation to locate functional areas such as speech and movement, and organically combined the traditional advantages of intraoperative MRI combined with functional neuronavigation to resect gliomas in functional areas, reaching the highest international level of technical support at present. We try to ensure that patients achieve maximum lesion removal, minimum functional damage and optimal patient recovery.