Moving a Paralyzed Hand Through Use of a Brain-Computer Interface
This study will gain information on methods of control of a prosthetic arm in stroke patients or traumatic brain inury patients through a technique called "brain-computer interface" (BCI). BCI allows for direct communication between man and machine. Brain cells communicate by producing electrical impulses that help to create such things as thoughts, memory, consciousness and emotions. In BCI, brain waves are recorded by an electroencephalogram (EEG) through electrodes (small wires) attached to the scalp. The electrodes measure the electrical signals of the brain. These signals are sent to the computer, which translates them into device control commands as messages that reflect a person's intention. This type of brain activity comes from the sensorimotor areas of the brain and can be controlled through voluntarily training to control the hand prosthesis through the BCI.
Healthy normal volunteers and people who have had a stroke or traumatic brain injury more than 12 months ago and have paralysis in the right or left arm, hand or leg and who are between 18 and 80 years of age may be eligible for this study. Candidates are screened with a clinical and neurological examination and magnetic resonance imaging (MRI) of the brain. MRI uses a magnetic field and radio waves to obtain images of the brain. The scanner is a metal cylinder surrounded by a strong magnetic field. During the procedure, the subject lies in the scanner for about 45 minutes, wearing ear plugs to muffle loud knocking sounds that occur with the scanning.
Participants undergo the following procedures:
- Sessions 1-2: Participants are connected to an EEG machine and familiarized with the hand orthosis (training device used in the study) and the tasks required for the study.
- Sessions 3-4: Participants receive baseline transcranial magnetic stimulation (TMS) and fMRI. For TMS, a wire coil is held on the scalp. A brief electrical current is passed through the coil, creating a magnetic pulse that stimulates the brain. The subject may feel a pulling sensation on the skin under the coil and there may be twitching in muscles of the face, arm or leg. The subject may be asked to tense certain muscles slightly or perform other simple actions. The effect of TMS on the muscles is detected with small metal disk electrodes taped to the skin of the arms. fMRI is like a standard MRI (see above), except it is done while the patient performs tasks to learn about brain activity involved in those tasks.
- Sessions 5-8: Participants are asked to repetitively move their hand (patients' paralyzed hand; healthy volunteers' normal hand), tongue and leg in response to three sound tones. After ten trials, they are asked to imagine the same movements 50 to 100 times while the EEG machine is recording brain activity.
- Sessions 9-14: Participants are trained in controlling the hand orthosis. The subject's hand is attached to the orthosis and asked to imagine that they are performing finger or hand movements. This continues until there is an 80-90 percent success rate in achieving hand movement.
- Sessions 15-16: Participants repeat TMS and fMRI for comparison before and after training with the hand orthosis.
- Sessions 17-28: Participants receive additional training with the hand orthosis device (as in sessions 5-8), focusing only on the hand and not other parts of the body.
- Sessions 29-30: Participants undergo repeat TMS and fMRI to compare with the effect following additional training with the hand orthosis.
- Sessions 31-32: Optional makeup sessions if needed because of scheduling problems.
Participants are evaluated in the clinic after 3 months to see if they have benefited from the study.
|Official Title:||Moving a Paralyzed Hand Through a Brain-Computer Interface Controlled by the Affected Hemisphere After Stroke or Traumatic Brain Injury|
|Study Start Date:||October 2005|
Objective: Individuals who have suffered a stroke or traumatic brain injury (TBI) may benefit from the development of new rehabilitative interventions that can improve motor recovery after injury. The purpose of this protocol is to test the hypothesis that oscillatory brain activity that originates in the affected hemisphere in the form of desynchronization of Mu-rhythm of patients with chronic stroke or TBI can be used to drive movements of an orthosis attached to a paralyzed hand through a Brain Computer Interface (BCI). Mu-rhythm is a type of brain wave activity that originates in the sensorimotor areas of the brain that can be controlled voluntarily; it is present in the affected hemisphere of stroke patients and can be used to control the hand prostheses through the BCI interface. Control of Mu-rhythm amplitudes by volition requires training since it does not happen spontaneously. A proof-of-principle sub-experiment will test the hypothesis that in stroke survivors non-invasive cortical stimulation of the ipsilesional primary motor cortex (M1) will facilitate learning to control a hand orthosis through a BCI device. This is the purpose of the training: to teach the subject to control Mu-rhythms.
Study population: The study population will consist of individuals with chronic stroke or TBI that have virtually no movement of their paretic hand and age- and gender- matched healthy volunteers. Healthy volunteers, which may include the age- and gender- matched volunteers, will be recruited to refine instructions given to patients.
Design: This is primarily an intraindividual comparison study, designed to determine if this brain-computer interface (BCI) approach contributes to drive grasping motions through a BCI interface and hand-orthosis. To test the effect of non-invasive cortical stimulation 21 stroke patients will be randomly assigned to three groups (group A, anodal stimulation; group B, cathodal stimulation; group C, sham stimulation). Study of normal volunteers will contribute to (a) set up of the experiment, (b) identifying differences in the training time required to modulate Mu-rhythm in healthy volunteers and patients and (c) to isolate training effects as measured by TMS and fMRI on the healthy brain from training effects on brains affected with stroke or TBI. This information will be treated descriptively within the framework of this protocol but it is also important for designing future studies.
Outcome measures: Behavioral endpoint measure: ability to drive the paralyzed hand orthosis in flexion and extension motions using Mu-rhythm. Physiological endpoint measures: peak fMRI activity in the hand knob representation, and corticomotor excitability as tested with TMS and MEG in ipsilesional and contralesional hand knob representations. Normal volunteers will undergo evaluation of the same physiological endpoint measures as patients.
|Contact: Rita Volochayev, C.R.N.P.||(301) firstname.lastname@example.org|
|Contact: Leonardo G Cohen, M.D.||(301) email@example.com|
|United States, Maryland|
|National Institutes of Health Clinical Center, 9000 Rockville Pike||Recruiting|
|Bethesda, Maryland, United States, 20892|
|Contact: For more information at the NIH Clinical Center contact Patient Recruitment and Public Liaison Office (PRPL) 800-411-1222 ext TTY8664111010 firstname.lastname@example.org|
|Principal Investigator:||Leonardo G Cohen, M.D.||National Institute of Neurological Disorders and Stroke (NINDS)|