[1] Yan X, Zhang J, Shi J, et al.Cerebral and functional adaptation with chronic hypoxia exposure: a multi-modal MRI study[J]. Brain research, 2010, 1348(12): 21-29. [2] Yan X, Zhang J, Gong Q, et al.Adaptive influence of long term high altitude residence on spatial working memory: an fMRI study[J]. Brain and cognition, 2011, 77(1): 53-59. [3] Getu A.Ethiopian Native Highlander’s Adaptation to Chronic High-Altitude Hypoxia[J]. BioMed Research International, 2022, 2022(4):1-5. [4] Perger E, Baillieul S, Esteve F, et al.Nocturnal hypoxemia, blood pressure, vascular status and chronic mountain sickness in the highest city in the world[J]. Annals of medicine, 2022, 54(1): 1884-1893. [5] Zhao J, Zhang R, Yu Q, et al. Characteristics of EEG activity during high altitude hypoxia and lowland reoxygenation[J]. Brain research, 2016(10), 1648: 243-249. [6] 陈甄, 张广波, 周迪, 等. 急性高原低氧环境对不同情绪状态脑电功率的影响[J]. 中国应用生理学杂志, 2020, 36(6): 556-561. [7] 马海林, 莫婷, 曾桐奥, 等. 长期高海拔暴露影响移居者空间工作记忆--来自时域和频域分析的证据[J]. 生理学报, 2020, 72(2): 181-189. [8] Qureshi MB, Afzaal M, Qureshi MS, et al.Machine learning-based EEG signals classification model for epileptic seizure detection[J]. Multimedia Tools and Applications, 2021, 80(12): 17849-17877. [9] Ruiz de Miras J, Ibáñez-Molina AJ, Soriano MF, et al. Schizophrenia classification using machine learning on resting state EEG signal[J]. Biomedical Signal Processing and Control, 2023, 79(1): 104233. [10] 刘冰,韩布新,安心,等. 急性高原低氧对静息态脑电功率的影响研究进展[J]. 中国全科医学,2017,20(29):3683. [11] Hervault M, Zanone PG, Buisson JC, et al.Hold your horses: Differences in EEG correlates of inhibition in cancelling and stopping an action[J]. Neuropsychologia, 2022, 172(29): 108255. [12] Li Y, Wang Y.Effects of Long-Term Exposure to High Altitude Hypoxia on Cognitive Function and Its Mechanism: A Narrative Review[J]. Brain Sciences, 2022, 12(6): 808. [13] Ma H, Zhang D, Li X, et al.Long‐term exposure to high altitude attenuates verbal and spatial working memory: Evidence from an event‐related potential study[J]. Brain and Behavior, 2019, 9(4): e01256. [14] 郭福美,王长明,陶格同,等. 长期高原环境暴露对知觉闭合功能的影响[J]. 中华行为医学与脑科学杂志,2021,30(5):446-451. [15] Ma H, Wang Y, Wu J, et al.Long-term exposure to high altitude affects response inhibition in the conflict-monitoring stage[J]. Scientific Reports, 2015, 5(1): 1-10. [16] Zhang D, Ma H, Huang J, et al.Exploring the impact of chronic high‐altitude exposure on visual spatial attention using the ERP approach[J]. Brain and Behavior, 2018, 8(5): e00944. [17] West R, Jakubek K, Wymbs N, et al.Neural correlates of conflict processing[J]. Experimental brain research, 2005, 167(1): 38-48. [18] Isa NEM, Amir A, Ilyas MZ, et al.Motor imagery classification in Brain computer interface (BCI) based on EEG signal by using machine learning technique[J]. Bulletin of Electrical Engineering and Informatics, 2019, 8(1): 269-275. [19] Knott V, Mahoney C, Kennedy S, et al.EEG power, frequency, asymmetry and coherence in male depression[J]. Psychiatry Research: Neuroimaging, 2001, 106(2): 123-140. [20] Mumtaz W, Ali SSA, Yasin MAM, et al.A machine learning framework involving EEG-based functional connectivity to diagnose major depressive disorder (MDD)[J]. Medical & biological engineering & computing, 2018, 56(2): 233-246. [21] Ding X, Yue X, Zheng R, et al.Classifying major depression patients and healthy controls using EEG, eye tracking and galvanic skin response data[J]. Journal of affective Disorders, 2019, 251(5): 156-161. |