Chinese Journal of Medical Instrumentation                                         2026年 第50卷 第2期

                                                    综     合     评    述



              [10]   MACE  E,  MONTALDO  G,  OSMANSKI  B  F,  et  al.  vascular  brain  mapping[J].  Front  Neurosci,  2020,  13:
                  Functional  ultrasound  imaging  of  the  brain:  theory  and  1384.
                  basic principles[J]. IEEE Trans Ultrason Ferroelectr Freq  [22]   NORMAN S L, MARESCA D, CHRISTOPOULOS V N,
                  Control, 2013, 60(3): 492-506.                    et al. Single-trial decoding of movement intentions using
              [11]   MARTÍNEZ-FERNÁNDEZ  R,  MÁÑEZ-MIRÓ  J  U,      functional  ultrasound  neuroimaging[J].  Neuron,  2021,
                  RODRÍGUEZ-ROJAS  R,  et  al.  Randomized  trial  of  109(9): 1554-1566. e4.
                  focused  ultrasound  subthalamotomy  for  Parkinson's  [23]   BERTHON B, BERGEL A, MATEI M, et al. Decoding
                  disease[J]. N Engl J Med, 2020, 383(26): 2501-2513.  behavior  from  global  cerebrovascular  activity  using
              [12]   HALPERN C H, SANTINI V, LIPSMAN N, et al. Three-  neural networks[J]. Sci Rep, 2023, 13(1): 3541.
                  year follow-up of prospective trial of focused ultrasound  [24]   GRIGGS  W  S,  NORMAN  S  L,  DEFFIEUX  T,  et  al.
                  thalamotomy  for  essential  tremor[J].  Neurology,  2019,  Decoding  motor  plans  using  a  closed-loop  ultrasonic
                  93(24): e2284-e2293.                              brain–machine  interface[J].  Nat  Neurosci,  2024,  27(1):
              [13]   HONG J W, YOON C, JO K, et al. Recent advances in  196-207.
                  recording  and  modulation  technologies  for  next-  [25]   PELLOW  C,  PIHARDO  S,  PIKE  G  B.  A  systematic
                  generation  neural  interfaces[J].  iScience,  2021,  24(12):  review of preclinical and clinical transcranial ultrasound
                  103550.                                           neuromodulation  and  opportunities  for  functional
              [14]   黄俐杰, 何琼, 王锐, 等. 功能超声成像技术及其应用研                  connectomics[J]. Brain Stimul, 2024, 17(4): 734-751.
                  究进展[J]. 生物医学工程学杂志, 2022, 39(5): 1015-         [26]   DARMANI G, BERGMANN T O, BUTTS PAULY K, et
                  1021.                                             al.  Non-invasive  transcranial  ultrasound  stimulation  for
              [15]   MYRDEN A J B, KUSHKI A, SEJDIĆ E, et al. A brain-  neuromodulation[J].  Clin  Neurophysiol,  2022,  135:  51-
                  computer interface based on bilateral transcranial Doppler  73.
                  ultrasound[J]. PLoS One, 2011, 6(9): e24170.  [27]   LEE K, LEE J M, PHAN T T, et al. Ultrasonocoverslip:
              [16]   KHALAF A, SYBELDON M, SEJDIC E, et al. A brain-  in-vitro platform for high-throughput assay of cell type-
                  computer  interface  based  on  functional  transcranial  specific   neuromodulation   with   ultra-low-intensity
                  doppler  ultrasound  using  wavelet  transform  and  support  ultrasound  stimulation[J].  Brain  Stimul,  2023,  16(5):
                  vector machines[J]. J Neurosci Methods, 2018, 293: 174-  1533-1548.
                  182.                                          [28]   KOSNOFF J, YU K, LIU C, et al. Transcranial focused
              [17]   KHALAF  A,  SEJDIC  E,  AKCAKAYA  M.  A  novel  ultrasound  to  V5  enhances  human  visual  motion  brain-
                  motor  imagery  hybrid  brain  computer  interface  using  computer   interface   by   modulating   feature-based
                  EEG and functional transcranial Doppler ultrasound[J]. J  attention[J]. Nat Commun, 2024, 15(1): 4382.
                  Neurosci Methods, 2019, 313: 44-53.           [29]   YANG  P  F,  PHIPPS  M  A,  JONATHAN  S,  et  al.
              [18]   RABBITO R, ERMINI L, GUIOT C, et al. Transcranial  Bidirectional  and  state-dependent  modulation  of  brain
                  Doppler-based  neurofeedback  to  improve  hemispheric  activity by transcranial focused ultrasound in non-human
                  lateralization[J]. Appl Sci(Basel), 2025, 15(10): 5763.  primates[J]. Brain Stimul, 2021, 14(2): 261-272.
              [19]   RABBITO  R,  GUIOT  C,  ROATTA  S.  Hemispheric  [30]   BENDIG  J,  AURUP  C,  BLACKMAN  S  G,  et  al.
                  lateralization  during  active  and  imagined  movements  Transcranial  functional  ultrasound  imaging  detects
                  assessed  by  transcranial  Doppler  ultrasound[J].  Biomed  focused   ultrasound   neuromodulation   induced
                  Signal Process Control, 2026, 112: 108540.        hemodynamic changes in mouse and nonhuman primate
              [20]   BRUNNER C, GRILLET M, URBAN A, et al. Whole-   brains in vivo[EB/OL]. (2024-03-12)[2025-09-10]. https://
                  brain functional ultrasound imaging in awake head-fixed  doi.org/10.1101/2024.03.08.583971.
                  mice[J]. Nat Protoc, 2021, 16(7): 3547-3571.  [31]   MARTIN E, AUBRY J F, SCHAFER M, et al. ITRUSST
              [21]   SOLOUKEY S, VINCENT A J P E, SATOER D D, et al.  consensus  on  standardised  reporting  for  transcranial
                  Functional ultrasound (fUS) during awake brain surgery:  ultrasound stimulation[J]. Brain Stimul, 2024, 17(3): 607-
                  the  clinical  potential  of  intra-operative  functional  and  615.


















                                                             187