Chronic Stroke Clinical Trial
— BE-TOPOfficial title:
Neuroimaging Biomarkers Toward an Optimized and Personalized Action Observation Treatment in Chronic Stroke Patients: New Strategies to Maximize the Efficacy of Upper Limb Functional Rehabilitation.
Much recent interest was raised by the use of Action Observation Treatment (AOT) in stroke patients rehabilitation. AOT, well-grounded in neurophysiology, is an updated approach, based on mirror neuron system (MNS) used to rebuild motor function despite injuries by engaging the brain regions active during action execution in individuals with limited mobility. This project aims at identifying, for the first time in Italy, neurophysiological electroencephalographic (EEG) biomarkers able to predict rehabilitation outcomes and providing an innovative optimized AOT rehabilitation protocol for chronic Stroke outpatients. EEG will be recorded to identify the most effective stimuli, quantify changes/recovery, profile patients. Moreover, an innovative AOT home-based program will be implemented. The translational research results will ensure advances in the optimization and personalization of the rehabilitative process thus contributing to improve the quality of life of chronic stroke patients. Stroke is a leading cause of death and one of the greatest causes of long-term disability that interferes with a good quality of life. Nowadays the rehabilitation interventions are the major component of patient's care to achieve functional outcome. In the last few years, in order to improve Activity of Daily Living (ADL), new noninvasive strategies have emerged as rehabilitative treatments rather than traditional physical therapies. The Action Observation Treatment (AOT), supported by results collected through randomized controlled trials, is one of these. This new rehabilitation approach is based on the properties of the Mirror Neuron System (MNS; 11-13). The extensive research of the last 20 years on the human MNS (hMNS) showed its importance not only in action recognition but also in motor intentions and other social cognitive functions. Lastly, because recruited also in damage brain (18,19), the MNS is demonstrated to provide satisfactory rehabilitative outcomes. The AOT takes advantage of the opportunity to restore functions despite the patient's impairment and it seems to be a valid example of translational medicine from basic neuroscience to rehabilitation. To date, neurophysiological outcomes were never used for translational purposes aimed to the optimization of the therapy and no evidence, in Italy, related to the effectiveness of the home-based program were proposed.
Status | Recruiting |
Enrollment | 80 |
Est. completion date | January 30, 2023 |
Est. primary completion date | November 30, 2022 |
Accepts healthy volunteers | No |
Gender | All |
Age group | 18 Years to 80 Years |
Eligibility | Inclusion Criteria: - chronic stroke (never experienced AOT); - first-ever unilateral stroke due to ischemia provoking a clinically evident upper limb/hand deficit; - diagnosis verified by brain imaging (MRI); - cognitive function sufficient to understand the experimental instructions - Chedoke-McMaster stroke Assessment Scale score greater than 1; - informed written consent to participate in the study. Exclusion Criteria: - bilateral impairment, - severe sensory deficits in the paretic upper limb, - cognitive impairment or behavioral dysfunction, - refusal or inability to provide informed consent and - other current severe medical problems. |
Country | Name | City | State |
---|---|---|---|
Italy | Casa di Cura del Policlinico di Milano | Milan | MI |
Italy | IRCCS San Raffaele Pisana | Rome | RM |
Lead Sponsor | Collaborator |
---|---|
IRCCS San Raffaele | Casa di Cura del Policlinico di Milano |
Italy,
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* Note: There are 28 references in all — Click here to view all references
Type | Measure | Description | Time frame | Safety issue |
---|---|---|---|---|
Other | Change in Box and Block Test (BBT) | The Box and Block Test (BBT) measures unilateral gross manual dexterity. It is a quick, simple and inexpensive test. It can be used with a wide range of populations, including clients with stroke. | At baseline-day 0 (T0), the middle of the treatment-day 15 (T1), at the end treatment-day 30 (T2), and at the follow up visit-day 90 (2 months both for the hospital-based and for the home based program) (T3) | |
Other | Change in Modified Ashworth Scale (MSA) | The Modified Ashworth scale (MAS) measures resistance during passive soft-tissue stretching and is used as a simple measure of spasticity.[1] Scoring (taken from Bohannon and Smith, 1987):
0: No increase in muscle tone Slight increase in muscle tone, manifested by a catch and release or by minimal resistance at the end of the range of motion when the affected part(s) is moved in flexion or extension 1+: Slight increase in muscle tone, manifested by a catch, followed by minimal resistance throughout the remainder (less than half) of the Range Of Motion (ROM) More marked increase in muscle tone through most of the ROM, but affected part(s) easily moved Considerable increase in muscle tone, passive movement difficult Affected part(s) rigid in flexion or extension |
At baseline-day 0 (T0), the middle of the treatment-day 15 (T1), at the end treatment-day 30 (T2), and at the follow up visit-day 90 (2 months both for the hospital-based and for the home based program) (T3) | |
Other | Change in Modified Bartel Index (mBI) | The Modified Bartel Index (mBI) is an ordinal scale used to measure performance in activities of daily living (ADL). Each performance item is rated on this scale with a given number of points assigned to each level or ranking. It uses ten variables describing ADL and mobility. A higher number is associated with a greater likelihood of being able to live at home with a degree of independence following discharge from hospital. | At baseline-day 0 (T0), the middle of the treatment-day 15 (T1), at the end treatment-day 30 (T2), and at the follow up visit-day 90 (2 months both for the hospital-based and for the home based program) (T3) | |
Other | Change in Chedoke-McMaster Stroke Assessment scale | The Chedoke-McMaster Stroke Assessment measures physical impairment and disability in people with stroke and other neurological impairment. The measure consists of an Impairment Inventory and an Activity Inventory (Moreland, Gowland, Van Hullenaar, & Huijbregts, 1993). The first inventory aims to determine the presence and severity of common physical impairments, to classify or stratify patients when planning, selecting interventions and evaluating their effectiveness and to predict outcomes. The second inventory measures changes in physical function (Gowland, Stratford, Ward, Moreland, Torresin, Van Hullenar, Sanford, Barreca, Vanspall, & Plews, 1993).
No helper needed 7 Complete Independence (Timely, Safely) 6 Modified Independence 5 Supervision A helper needed 4 Minimal Assist (Client = 75%) 3 Moderate Assist (Client = 50%) Complete Dependence 2 Maximal Assist (Client = 25%) 1 Total Assist (Client = 0%) |
At baseline-day 0 (T0), the middle of the treatment-day 15 (T1), at the end treatment-day 30 (T2), and at the follow up visit-day 90 (2 months both for the hospital-based and for the home based program) (T3) | |
Other | Change in Mini-Mental state examination (MMSE) | Il Mini-Mental State Examination (MMSE) (Folstein et al., 1975), is a neuropsychological test for the assessment of intellectual efficiency disorders and the presence of cognitive deterioration.
The total score is between a minimum of 0 and a maximum of 30 points, where a score of 30 represents the best cognitive condition, and 0 the worst. The Mini-Mental state examination (MMSE) is often used as a screening tool in the investigation of subjects with dementia, and with neuropsychological syndromes of different nature. |
At baseline-day 0 (T0), at the end treatment-day 30 (T2) and at the follow up visit-day 90 (2 months both for the hospital-based and for the home based program) (T3) | |
Other | Change in ElectroEncephaloGraphy (EEG) | Electroencephalography (EEG) is an electrophysiological monitoring method to record electrical activity of the brain. It is noninvasive, with the electrodes placed over the scalp. Each conscious and unconscious mental function is the result of the electrical communication among the human brain neurons. It is not possible to record in a no-invasive way the electrical activity related to each neuron, however the EEG technique is able to measure the voltage fluctuations over the scalp caused by the concomitant electrical activity of a neurons population. Such voltage fluctuations could be characterized in terms of spectral content (EEG rhythms or bands) or of time-domain characteristics (Evoked Potentials and Event-Related Potentials). Alph (8-13 Htz), Beta (14-30 Htz) and Mu (8-13 Htz) bandwidth will be registered. The last band will be analysed specifically to investigate the motor areas and mirror neuron system's activity. | At baseline-day 0 (T0), at the end treatment-day 30 (T2) and at the follow up visit-day 90 (2 months both for the hospital-based and for the home based program) (T3) | |
Other | Change in surface ElectroMioGraphy (sEMG) - arm and shoulder muscles | Surface electromyography (sEMG) is a non-invasive procedure involving the detection, recording and interpretation of the electric activity of groups of muscles at rest (i.e., static) and during activity (i.e., dynamic). The procedure is performed using a single or an array of electrodes placed on the skin surface over the muscles to be tested. Recording can also be made using a hand-held device, which is applied to the skin surface at different sites. Electrical activity is assessed by computer analysis of the frequency spectrum, amplitude, or root mean square of the electrical action potential. | At baseline-day 0 (T0), at the end treatment-day 30 (T2) and at the follow up visit-day 90 (2 months both for the hospital-based and for the home based program) (T3) | |
Primary | Change in Fugl-Meyer (FM) Test | The Fugl-Meyer Assessment (FMA) is a stroke-specific, performance-based impairment index. It is designed to assess motor functioning, balance, sensation and joint functioning in patients with post-stroke hemiplegia. It is applied clinically and in research to determine disease severity, describe motor recovery, and to plan and assess treatment. The scale is comprised of five domains and there are 155 items in total:
Motor functioning (the score ranges from 0 (hemiplegia) to 100 points (normal motor performance). Divided into 66 points for upper extremity and 34 points for the lower extremity. Sensory functioning (from 0 to 24 points) Balance (from 0 to 14) Joint range of motion (from 0 to 44) Joint pain (from 0 to 44 ) Scale items are scored on the basis of ability to complete the item using a 3-point ordinal scale where 0=cannot perform, 1=performs partially and 2=performs fully. The total possible scale score is 226. |
At baseline-day 0 (T0), the middle of the treatment-day 15 (T1), at the end treatment-day 30 (T2), and at the follow up visit-day 90 (2 months both for the hospital-based and for the home based program) (T3) | |
Secondary | Change in Frenchay Arm Test (FAT) | The Frenchay Arm Test (FAT) is a measure of upper extremity proximal motor control and dexterity during ADL performance in patients with impairments resulting from neurological conditions. The FAT is an upper extremity specific measure of activity limitation. | At baseline-day 0 (T0), the middle of the treatment-day 15 (T1), at the end treatment-day 30 (T2), and at the follow up visit-day 90 (2 months both for the hospital-based and for the home based program) (T3) |
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