Magnetoencephalography （MEG） is a noninvasive functional neuroimaging modality that achieves millisecond temporal resolution by recording the faint magnetic fields generated by neurons. Compared with electroencephalography （EEG）， MEG is more sensitive to the tangential currents in the cerebral sulci and can perform source localization with better accuracy and stability. Traditional superconducting quantum interference device systems are bulky and reliant on cryogenic liquid helium， while the novel optically pumped magnetometer （OPM） systems are wearable and can operate at room temperature and enhance signal-to-noise ratios， thereby holding promise for wide clinical application. In terms of clinical application， MEG can localize epileptogenic foci that are not detected by EEG during preoperative epilepsy evaluation and improve the precision of resection through markers such as high frequency oscillations. For preoperative brain tumor management， MEG accurately delineates motor and language functional areas， avoids the issue of neurovascular uncoupling （NVU） caused by tumors， and helps to achieve safe resection with a larger extent in combination with image navigation. MEG can also detect early EEG spectral changes in the brain of patients with Alzheimer’s disease and is thus used as a biomarker for evaluating the efficacy of new therapies. In Parkinson’s disease， pathological beta oscillations revealed by MEG are correlated with the severity of motor symptoms， and the synchronized MEG-deep brain stimulation analysis can optimize stimulation targets and parameters. In autism spectrum disorder （ASD）， MEG （especially OPM-based MEG） can effectively overcome compliance challenges in sensory-sensitive and pediatric populations， accurately capture excitation / inhibition imbalance and γ oscillation abnormalities， and promote the paradigm shift to the precise diagnosis and treatment of ASD based on objective neurophysiological biomarkers. With the development of OPM technology， MEG is playing an increasingly critical role in localization， surgical guidance， early diagnosis， and treatment optimization， thereby continuously promoting the precise diagnosis and treatment of neurological disorders.