Stroke Clinical Trial
Official title:
Enriched Environments for Stroke Rehabilitation; Pilot Study to Determine Appropriate Outcome Measures and Their Sensitivity to Different Training Protocols
Stroke contributes significantly to the incidence of disabilities, with upper limb (UL)
motor impairment being especially prevalent. Animal studies suggest that post-stroke motor
recovery is largely attributable to adaptive plasticity in brain motor areas. While some
environmental training factors contributing to plastic mechanisms have been identified in
animals, translation of this knowledge to the clinical setting is insufficient. Optimal
recovery may be related to both external (e.g., feedback type) and internal factors (e.g.,
cognitive ability, motivation). Clinically feasible methods for training are needed. Use of
enriched virtual environments (VEs) may provide a way to address these needs. Outcome
measures that best reflect recovery need to be identified since this is an essential step to
evaluate the effect of novel training programs for UL motor recovery in stroke.
The research question is which clinical and kinematic outcome measures best reflect motor
performance recovery after a targeted upper limb treatment intervention. Aim 1 is to compare
changes in outcome measures recorded before and after an upper limb intervention in stroke
subjects to motor performance in healthy subjects. Aim 2 is to determine motor performance
between-group differences sample size is based on knowledge of expected outcome measure mean
score differences between groups. Hypothesis. 1: Specific clinical and kinematic outcome
measures will be sensitive to within-group (pre-post intervention training) changes.
Hypothesis. 2: Specific clinical and kinematic outcome measures will be sensitive to
between-group (healthy vs. patients in enriched vs. conventional intervention groups.
Sixteen chronic stroke survivors and 8 age- and sex-matched healthy controls will
participate. Patients will be matched on cognitive and motor impairment levels and divided
into two groups. Using an single subject (A-B-A) research design, kinematics during two
pre-tests, 3 weeks apart, will be recorded for test-retest reliability. Stroke groups will
practice varied upper limb reaching movements (15 45-minute sessions in 3 weeks) in
environments providing different motivation/feedback levels. Pre- and post motor performance
evaluations will be done with clinical tests and a Test Task with specific motor performance
requirements. A Transfer Task will also be recorded. By comparing data analysis methods
(3-Dimensional (3D) analysis of different markers or placements), the investigators will
identify which kinematic outcome measures best reflect motor improvement in post-test and
follow-up sessions (retention).
The expected results are identification of two primary and two secondary outcome measures
that reflect upper limb motor recovery and can distinguish between motor recovery and
compensation. The results will be used to design a randomized control trial to determine the
efficacy of VE-based treatment on arm motor recovery. The goal is to determine how extrinsic
(environmental) and intrinsic (personal) motivational factors affect motor learning in
stroke survivors with cognitive and physical impairment. Knowledge gained can also be used
for rehabilitation of other neurological and orthopedic pathologies.
A. Scientific Background
Stroke is the third leading cause of death in Western countries and upper limb (UL)
sensorimotor dysfunction contributes significantly to the incidence of physical disabilities
and handicaps (Olsen 1990). One explanation for poor arm recovery is the focus on task
accomplishment rather than performance quality. This may reinforce alterative (compensatory)
movement strategies instead of encouraging the reappearance of pre-morbid movement patterns
(recovery). Although the rehabilitative goal is recovery of function, whether this is
achieved through true motor recovery or compensation is still under debate. Indeed, for some
patients with severe impairment, compensation should be encouraged to maximize functional
ability. Alternatively, for those with good prognosis, motor recovery is emphasized for
several reasons. First, given appropriate training, recovery can continue well into the
chronic stage of stroke (e.g., Michaelsen & Levin 2004). Second, while compensation may
assist immediate performance, it may lead to longer-term problems such as pain and
contracture (Ada et al. 1994; Levin 1997). Third, permitting compensations could encourage
learned nonuse limiting the capacity for subsequent motor gains (Allred et al. 2005). While
performance gains have been documented after repetitive training of isolated movements
(e.g., Whitall et al. 2000), few studies have addressed whether patients can use explicit
information to optimize motor skill acquisition and whether true behavioural recovery
occurs. Points to consider in developing optimal training programs is that learning occurs
when participants are motivated, practice a variety of related tasks and are given relevant
feedback (Nudo & Friel 1999; Winstein et al. 1999). In addition, patients may not benefit
from variable practice until missing motor elements are recovered (Carr & Shepherd 1987) and
motor relearning is related to physical and cognitive impairment level (Cirstea et al.
2006).
To date, most studies have used only clinical measures to evaluate functional change (e.g.,
Jang et al. 2003) without considering how movement is performed. This study will focus on
the ability to distinguish between whether functional improvement results from an increase
in compensation or from true motor recovery. This can only be done by correlating functional
improvement (clinical measures) with changes in arm motor patterns through detailed movement
analysis (kinematics). Since there are a large number of possible kinematic indicators of
improvement, the investigators need to identify which measures are most indicative of
change. This is a first step in the determination of clinically meaningful outcome measures
to be used in randomized control trials of the effectiveness of interventions. Clinical
salience is essential to translate knowledge from research studies to evidence-based
practice (van Peppen et al. 2007).
B. Study Design: 1. Detailed Plan of the Study
Two groups of 8 stroke subjects will participate in an A-B-A design in which data from
post-intervention (within one week of the completion of the intervention) and follow-up (one
month after the completion of the intervention)tests will be compared to data from two
pre-tests (held at beginning and end of the first week of the study just prior to the start
of the intervention). Multiple clinical and kinematic motor performance outcomes will be
measured to determine which ones best describe arm motor recovery. This will be done by
comparing changes in outcomes before and after training to mean scores of 8 age- and
gender-matched healthy volunteers (recorded in a single session). Stroke survivors will
practice movement in two different training environments providing different levels of
motivation and feedback: Training Environment 1 will be created in a 2D video-based VR
environment that will provide high motivation, Knowledge of Results (KR) about motor outcome
(i.e., speed, precision) and non-specific Knowledge of Performance (KP) feedback about trunk
movement. Environment 2 will be created in a physical environment that provides only KP
feedback but no KR or additional motivation.
Training Protocol: After baseline evaluations (physical & cognitive), stroke groups will
practice pointing to 6 standardized targets placed just beyond reach (12 trials per target)
during an acquisition phase of 15 sessions spaced over three weeks (3 sessions/wk, 72
trials/session). This practice regimen incorporates elements necessary for optimal motor
learning: 1) Varied practice: Although the movements are not new motor tasks, they should be
re-acquired during stroke recovery. Our aim is not teach subjects a novel task but to
identify how a movement performed sub-optimally may be improved with practice. 2) Intensive
practice: The number of repetitions per session was chosen according to studies by Cirstea
and Levin (2000). Thus, 72 trials per session (3 blocks of 24 trials, 5 min rest between
blocks) are considered as 'intensive' practice, which is a necessary element for a
successful training program. Following the acquisition phase, evaluations which will be
repeated after 3mos to evaluate retention and transfer of motor skills.
2. Methods: Subjects Eight stroke subjects per group will be recruited. They will be matched
for age and for initial arm motor severity (± 5 pts on the Fugl-Meyer Arm Assessment). Eight
age- and sex-matched healthy subjects will be recruited as a control group.
Subject Recruitment: Patients will be recruited from Haim Sheba Hospital discharge lists
using a procedure in place since 2005. Screening will be done by clinical research
associates. Potential participants meeting inclusion criteria 1-3 and exclusion criteria
will be sent an explanatory letter inviting them to contact study investigators. Informed
consent will be obtained from each participant. Control subjects will be recruited from the
community.
Training Environments: Motivation and Feedback: Training will be done in the Dept. of
Occupational Therapy located at the Sheba Medical Center. Training environments will allow
us to evaluate the effect of combining different degrees of motivation and feedback on motor
outcome. Environment 1 is highly motivating (novel and fun) since training is presented as a
game in which the learner tries to beat his own score in subsequent sessions. Targets are
presented as balls in a video-based VR system (Gesture Xtreme). The patient sits in front of
a 36 inch display of the 6 target scene. The patient's image is captured by a video camera
and inserted into the scene displayed on the monitor. The task is to point to each of the
targets which appear in a random sequence. Feedback will provide pertinent information for
motor learning (KR, KP, game score). Environment 2 incorporates the same number and
disposition of targets as Env. 1 but they will be presented in a physical environment on a
wooden frame in front of the subject. KR and KP feedback will be provided as verbal cues by
the experimenter as is done usually in the clinic. However, they will be no additional
motivational information (game score).
Preliminary Outcome Measures: Clinical Before and after training in both stroke groups,
blinded evaluators will measure clinical scores of arm motor impairment and function
(Fugl-Meyer Arm Score, Reaching Performance Scale, Box and Blocks test, Wolf Motor Function
Test, Motor Activity Log) as well as cognitive function. All tests are valid and reliable
and are regularly used in clinical practice.
Kinematic testing: Test Task and Transfer Task:
The investigators will also record kinematic outcome measures characterizing arm and trunk
movements during reaching (elbow extension, shoulder horizontal adduction, shoulder flexion,
scapular movements, trunk displacement).
Our aim is to focus on segmental and joint kinematics during a Test and a Transfer Task
consisting of reaching movements. Test Task will be recorded. The Test target will be placed
in line with the patient's sternum at a distance just beyond the subject's arm length. The
Test Task is similar to movements made to one of the practiced targets. To assess motor
learning, the investigators will determine if elements learned in one task transfer to other
similar tasks. Thus, the investigators will also assess movements made in a Transfer Task,
to a target placed in front of the ipsilateral shoulder 5 centimeters (cm) higher than the
topmost row of trained targets. The Transfer Task is therefore a new movement, not practiced
during the training. Rigid body segmental kinematics will be recorded from sets of 4 passive
reflective markers (0.5 cm diameter spheres) attached to the trunk, upper arm and forearm
segments. This will enable the computation of three translational and three rotational
degrees of freedom per segment. Joint kinematics will be collected from markers fixed on the
sternum, acromion, elbow and wrist via exo-skeletal frames. Marker motion will be recorded
with a calibrated 3 camera opto-electronic motion-capture system (ProReflex MCU-240,
Qualisys) on suitable computer software (Qualisys, Göteborg, Swe). Data collection (100
Hertz, 2-5 seconds) will be triggered by movement of the hand from a central position by
release of a mechanical switch. The accuracy of the measurements of each marker is within an
error of <0.2 cm.
As a first step, the investigators will determine movement times, accuracy, smoothness,
segment and joint rotations and the main components of multi-joint coordination. Cartesian
coordinates (x,y,z) for each segment will be obtained from the segmental marker sets. Raw
data from at least three markers per segment will be used after interpolation of missing
markers (5th-order polynomial). For each trial, movement times and peak velocities will be
determined from endpoint tangential velocity traces. Movement time is the time between the
point at which the tangential velocity exceeds and remains above 5% of its maximum and then
returns to and remains below this level. Movement accuracy in terms of constant extent
errors will be computed as the mean distance (d) between the final endpoint position (x, y,
z) and the position of the target (x0, y0, z0). Constant and variable (SD) directional
errors will also be defined. Movement smoothness will be computed from the tangential
velocity trace using the index of curvature (ratio of endpoint path length to length of a
straight line joining the initial and final positions) and the number of peaks in the
trajectory path. For segment and joint rotations, vectors will be calculated within
reference coordinate systems for the upper and forearm segments.
From the resulting segment centroid motion and segment rotation data different outcome
variables will be calculated. The most relevant ones will define changes in performance with
respect to the endpoint motion and with respect to the whole-arm posture, particularly, the
evolution of the movement over time (time derivatives) and the fragmentation of the
segmental path and posture of the arm while moving towards the different targets. Additional
aspects of movement will be explored in order to find the most appropriate descriptors of
arm motor performance and changes after the proposed clinical interventions.
Change scores will be calculated for each subject to determine an Index of Improvement (IP)
and an Index of Learning (IL). The IP is defined as the change in each variable as a ratio
of post- to pre-test values. An IP of 1 indicates no change whereas negative and positive
values indicate that the value decreased or increased respectively. For some variables,
positive ratios will indicate improvement (endpoint velocity, endpoint smoothness, angle
measures, phase amplitudes) while for others, improvement will be demonstrated by negative
ratios (movement time, movement precision). The IL, used to determine if subjects retain
improvements after training for each follow-up epoch, is defined as the change in the
variable at retention- compared to post-test. IL values of 1 indicate that the improvement
is maintained (no change), of negative value that the parameter decreased and of positive
value that the parameter increased.
Statistical analysis: For our first aim, changes in outcome measures will be determined by
comparing movement outcomes before and after the acquisition and retention phases by
two-repeated measures mixed design ANOVA (MANOVA) and comparing raw means (Time 1, Time 2,
Time 3, Time 4) and change scores (IP, IL) between groups. The investigators will determine
which kinematic measures undergo the most change and thus may be most indicative of motor
recovery (e.g., increase in elbow and/or shoulder movement, decrease in trunk movement) by
investigating which measures are the most different between training groups. The
investigators expect changes in the group training in Environment I to be greater than those
in from the group training in Environment 2.
;
Allocation: Randomized, Intervention Model: Parallel Assignment, Masking: Single Blind (Subject), Primary Purpose: Treatment
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