Gehirn-Maschine-Interfaces (Brain-Machine Interfaces, BMI) zur Rehabilitation von Schlaganfall

 

 Buy Article Permissions and Reprints

Zusammenfassung

BMI übersetzt Hirnsignale in Signale für körper-externe Maschinen und Computer ohne Beteiligung des motorischen Systems. BMIs wurden zur Rehabilitation von chronischem Schlaganfall meist in Kombination mit funktioneller Elek­trostimulation (FES), Robotern und Neuroprothesen und Physiotherapie benutzt. Zusätzlich zeigt Neurofeedback- und Biofeedbacktraining vielversprechende Ergebnisse als zusätzliche Rehabilitationsstrategie. Wenig gut kontrollierte klinische Studien mit hinreichend großen und homogenen Patientenstichproben stehen zur Verfügung, die meisten sind „proof-of-principle“ Versuche mit kleinen Stichproben. Die Kombination aus BMI-Neuroprothesen-Training mit Verhaltens-orientierter Physiotherapie hat sich als die wirksamste nicht-invasive Strategie bei schwerst gelähmten chronischen Schlaganfallpatienten erwiesen. In der Zukunft sollten invasive BMI-Trainings mit internalisierter FES und anderen drahtlosen und tragbaren Prothesen geprüft werden.

Abstract

BMI translates a brain signal to an external device without any motor involvement. BMIs have been used for rehabilitation of chronic stroke in combination with output devices such as functional electrical stimulation (FES), robots and exosceletons as a neuroprosthetic device, and physiotherapy. In addition, neurofeedback and biofeedback (usually using electromyographic (EMG) feedback) shows great promise as a rehabilitation strategy. However, very few adequately controlled studies with large enough patient samples are available, most report proof-of-principle strategies. The combination of BMI with behaviorally oriented physiotherapy to generalize BMI-treatment effects to the home environment proved to be the most efficient non-invasive rehabilitation strategy for severely paralyzed stroke victims. Future directions should test invasive.

• Literatur

• 1 Birbaumer N, Elbert T, Canavan A et al. Slow Potentials of the Cerebral Cortex and Behavior. Physiological Reviews 1990; 70: 1-41
  PubMedSearch in Google Scholar
• 2 Birbaumer N, Cohen L. Brain-Computer-Interfaces (BCI): Communication and Restoration of Movement in Paralysis. The Journal of Physiology. 2007; 579 (Pt3) 621-636
  PubMedSearch in Google Scholar
• 3 Birbaumer N, Ruiz S, Sitaram R. Learned regulation of brain metabolism. Trends in Cognitive Sciences, TICS- 2013; 1197
  PubMedSearch in Google Scholar
• 4 Buch E, Weber C, Cohen LG et al. Think to move: a neuromagnetic brain-computer interface (BCI) system for chronic stroke. 2008; Stroke 39: 910-917
  CrossrefPubMedSearch in Google Scholar
• 5 Buch ER, Shanechi AM, Fourkas AD et al. Parietofrontal integrity determines neural modulation associated with grasping imagery after stroke. Brain 2012; 135: 596-614
  CrossrefPubMedSearch in Google Scholar
• 6 Collinger JL, Wodlinger B, Downey JE et al. High-performance neuroprosthetic control by an individual with tetraplegia. The Lancet 2013; 381: 557-564
  CrossrefPubMedSearch in Google Scholar
• 7 Dobkin BH. Brain-computer interface technology as a tool to augment plasticity and outcomes for neurological rehabilitation. J Physiol 2007; 579: 637-642
  CrossrefPubMedSearch in Google Scholar
• 8 Fetz EE. Operant conditioning of cortical unit activity. Science 1969; 163: 955-958
  CrossrefPubMedSearch in Google Scholar
• 9 Ganguly K, Secundo L, Ranade G et al. Cortical representation of ipsilateral arm movements in monkey and man. J Neurosci 2009; 29: 12948-12956
  CrossrefPubMedSearch in Google Scholar
• 10 Hochberg LR, Serruya MD, Friehs GM et al. Neuronal ensemble control of prosthetic devices by a human with tetraplegia. Nature 2006; 442: 164-171
  CrossrefPubMedSearch in Google Scholar
• 11 Hochberg LR, Bacher D, Jarosiewicz B et al. Reach and grasp by people with tetraplegia using a neurally controlled robotic arm. Nature 2012; 485: 372-375
  CrossrefPubMedSearch in Google Scholar
• 12 Koralek AC, Jin X, Long JD et al. Corticostriatal plasticity is necessary for learning intentional neuroprosthetic skills. Nature 2012; 483: 331-335
  CrossrefPubMedSearch in Google Scholar
• 13 Nishimura Y, Perlmutter SI, Fetz EE. Restoration of upper limb movement via artificial corticospinal and musculospinal connections in a monkey with spinal cord injury. Front Neural Circuits 2013; 7: 57
  PubMedSearch in Google Scholar
• 14 Ramos-Murguialday A, Schürholz M, Caggiano V et al. Proprioceptive feedback and brain computer interface (BCI) based neuroprostheses. PloS ONE 2012; 7: e47048
  CrossrefPubMedSearch in Google Scholar
• 15 Ramos-Murguialday A, Broetz D, Rea M et al. Brain-machine-interface in chronic stroke rehabilitation: a controlled study. Annals of Neurology 2013;
  PubMedSearch in Google Scholar
• 16 Shibata K, Watanabe T, Takeo S et al. Perceptual learning incepted by decoded fMRI neurofeedback without stimulus presentation. Science 2011; 334: 1413-1415
  CrossrefPubMedSearch in Google Scholar
• 17 Silvoni S, Ramos-Murguialday A, Cavinato M et al. Brain-Computer-interface in stroke: a review of progress. Clinical EEG and Neuroscience 2011; 42: 245-252
  CrossrefPubMedSearch in Google Scholar
• 18 Silvoni S, Cavinato M, Volpato C et al. (in press). An assisted-force-feedback brain-machine interface for motor-rehabilitation. Frontiers in Neuroprosthetics
  PubMed
• 19 Silvoni S, Cavinato M, Volpato C et al. Amyotrophic Lateral Sclerosis progression and stability of brain-computer interface communication. Amyotrophic Lateral Sclerosis and Frontotemporal Degeneration, early online 2013; 1-7
  PubMedSearch in Google Scholar
• 20 Waldert S, Preissl H, Demandt E et al. Hand movement direction decoded from MEG and EEG. J Neurosci 2008; 28: 1000-1008
  CrossrefPubMedSearch in Google Scholar