第45卷第5期
               ·610 ·                            南 京    医 科 大 学 学         报                        2025年5月


                   troscopy study［J］. Front Neurol，2022，13：965856    15：728151
             ［21］NI J，JIANG W，GONG X，et al. Effect of rTMS interven⁃  ［33］MA X C，PENG Y，ZHONG L D，et al. Hemodynamic sig⁃
                   tion on upper limb motor function after stroke：a study  nal changes during volitional swallowing in dysphagia pa⁃
                   based on fNIRS［J］. Front Aging Neurosci，2022，14：  tients with different unilateral hemispheric stroke and
                   1077218                                           brainstem stroke：a near⁃infrared spectroscopy study［J］.
             ［22］WANG H W，XIONG X，ZHANG K X，et al. Motor net⁃        Brain Res Bull，2024，207：110880
                   work reorganization after motor imagery training in stroke  ［34］LIN S S，WANG D，SANG H J，et al. Predicting poststroke
                   patients with moderate to severe upper limb impairment［J］.  dyskinesia with resting ⁃ state functional connectivity in
                   CNS Neurosci Ther，2023，29（2）：619-632              the motor network［J］. Neurophotonics，2023，10（2）：
             ［23］HE X，LEI L，YU G，et al. Asymmetric cortical activation  025001
                   in healthy and hemiplegic individuals during walking：a  ［35］HAN Q Y，ZHANG M，LI W H，et al. Wavelet coherence
                   functional near ⁃ infrared spectroscopy neuroimaging  analysis of prefrontal tissue oxyhaemoglobin signals as
                   study［J］. Front Neurol，2022，13：1044982            measured using near⁃infrared spectroscopy in elderly sub⁃
             ［24］CLARK D J，ROSE D K，BUTERA K A，et al. Rehabilita⁃    jects with cerebral infarction［J］. Microvasc Res，2014，
                   tion with accurate adaptability walking tasks or steady  95：108-115
                   state walking：a randomized clinical trial in adults post⁃  ［36］LAMBERTI N，MANFREDINI F，NARDI F，et al. Corti⁃
                   stroke［J］. Clin Rehabil，2021，35（8）：1196-1206      cal oxygenation during a motor task to evaluate recovery
             ［25］CALIANDRO P，MOLTENI F，SIMBOLOTTI C，et al. Exo⁃      in subacute stroke patients：a study with near ⁃ infrared
                   skeleton⁃assisted gait in chronic stroke：an EMG and func⁃  spectroscopy［J］. Neurol Int，2022，14（2）：322-335
                   tional near⁃infrared spectroscopy study of muscle activa⁃  ［37］WANG D，WANG J，ZHAO H B，et al. The relationship
                   tion patterns and prefrontal cortex activity［J］. Clin Neuro⁃  between the prefrontal cortex and limb motor function in
                   physiol，2020，131（8）：1775-1781                     stroke：a study based on resting⁃state functional near⁃in⁃
             ［26］LIM S B，YANG C L，PETERS S，et al. Phase⁃dependent    frared spectroscopy［J］. Brain Res，2023，1805：148269
                   brain activation of the frontal and parietal regions during  ［38］孙妍玉，吴  晋. 神经网络重塑促进脑卒中后功能修复
                   walking after stroke ⁃ an fNIRS study［J］. Front Neurol，  的研究进展［J］. 南京医科大学学报（自然科学版），
                   2022，13：904722                                    2023，43（4）：577-581
             ［27］FUJIMOTO H，MIHARA M，HATTORI N，et al. Cortical       SUN Y Y，WU J. Research progress on the critical role of
                   changes underlying balance recovery in patients with  neural network remodeling in functional recovery after
                   hemiplegic stroke［J］. Neuroimage，2014，85（Pt 1）：547-  stroke［J］. Journal of Nanjing Medical University（Natural
                   554                                               Sciences），2023，43（4）：577-581
             ［28］MIHARA M，FUJIMOTO H，HATTORI N，et al. Effect of  ［39］XU G C，HUO C C，YIN J H，et al. Test⁃retest reliability
                   neurofeedback facilitation on poststroke gait and balance  of fNIRS in resting⁃state cortical activity and brain net⁃
                   recovery［J］. Neurology，2021，96（21）：e2587-e2598    work assessment in stroke patients［J］. Biomed Opt Ex⁃
             ［29］KOYANAGI M，YAMADA M，HIGASHI T，et al. The use⁃       press，2023，14（8）：4217-4236
                   fulness of functional near⁃infrared spectroscopy for the as⁃  ［40］XU G C，CHEN T D，YIN J H，et al. Lateralization of cor⁃
                   sessment of post⁃stroke depression［J］. Front Hum Neuro⁃  tical activity，networks，and hemodynamic lag after stroke：
                   sci，2021，15：680847                                a resting⁃state fNIRS study［J］. J Biophotonics，2024，17
             ［30］KONG Y，PENG W N，LI J，et al. Alteration in brain func⁃  （7）：e202400012
                   tional connectivity in patients with post⁃stroke cognitive  ［41］YE S J，TAO L，GONG S，et al. Upper limb motor assess⁃
                   impairment during memory task：a fNIRS study［J］. J  ment for stroke with force，muscle activation and interhemi⁃
                   Stroke Cerebrovasc Dis，2023，32（9）：107280          spheric balance indices based on sEMG and fNIRS［J］.
             ［31］OBAYASHI S. The supplementary motor area responsible  Front Neurol，2024，15：1337230
                   for word retrieval decline after acute thalamic stroke re⁃  ［42］CHEN S M，ZHANG X L，CHEN X X，et al. The assess⁃
                   vealed by coupled SPECT and near⁃infrared spectros⁃  ment of interhemispheric imbalance using functional near⁃
                   copy［J］. Brain Sci，2020，10（4）：247                 infrared spectroscopic and transcranial magnetic stimula⁃
             ［32］GILMORE N，YÜCEL M A，LI X G，et al. Investigating     tion for predicting motor outcome after stroke［J］. Front
                   language and domain⁃general processing in neurotypicals  Neurosci，2023，17：1231693
                   and individuals with aphasia ⁃ a functional near ⁃ infrared  ［43］YANG Z，YE L，YANG L N，et al. Early screening of post⁃
                   spectroscopy pilot study［J］. Front Hum Neurosci，2021，  stroke fall risk：a simultaneous multimodal fNIRs ⁃ EMG