Stroke Clinical Trial
Official title:
Efficacy of a Multi-segmental Robotic and Technological Upper Limb Rehabilitation Program, Compared With Traditional Therapy, in Individuals With Acute and Sub-acute Stroke: a Multicenter, Randomized, Controlled Clinical Trial.
Stroke is frequently associated with significant disability and impaired quality of life. Persistent motor impairment is common with often incomplete recovery of motor function in response to rehabilitation, mainly in the upper limbs. Robot-mediated therapy has been proposed as a viable approach for the rehabilitation of the upper limb, but as the evidence quality is low, more rigorous studies are needed. Previous studies have focused on the effects of devices acting on a limited number of joints, often limiting the workspace on a plane. This study aims to evaluate the efficacy of a multi-set of robotic and technological devices for the rehabilitation of the upper limb in sub-acute stroke patients.
Stroke is the first cause of disability in the world, with a very high social impact.
Recovery is partial in 85% of stroke survivors, 35% of whom have a persisting serious
disability. The increase in lifespan is leading to a rise in the incidence of stroke, and
therefore to a rise in the number of people requiring a rehabilitation program.
Rehabilitation programs are mainly focused on walking recovery, with insufficient attention
being paid to upper limb recovery. Thirty to 60% of patients treated with conventional
therapy present functional deficits of the paretic arm, resulting in an impairment of
activities of daily living.
Robot-mediated therapy (RT) has been proposed in the literature as a viable approach for the
rehabilitation of the upper limb. A first meta-analysis of 262 subjects showed that when the
duration/intensity of conventional therapy (CT) is matched with that of the robot-assisted
therapy, no difference exists between the two groups in terms of motor recovery, activities
of daily living, strength or motor control; instead, when the RT is added to CT, a greater
effectiveness can be observed, when compared with regular CT alone (5). A subsequent
meta-analysis by Mehrholz et al., including 19 trials (involving 666 subjects), showed that
RT was more effective than other interventions in improving patients' activities of daily
living (SMD 0.43, 95% confidence interval (CI) 0.11 to 0.75, P = 0.009, I2 = 67%). In the
same sample, stratified by time since disease onset, the analysis confirmed that RT was more
effective in improving the activities of daily living in the 224 acute and sub-acute patients
(within 3 months of stroke onset) (SMD 0.64, 95% CI 0.14 to 1.15, P=0.01, I2 =69%). The same
findings were not confirmed in 334 chronic patients (more than 3 months after stroke) (SMD
0.85, 95% CI -0.27 to 1.97, P=0.14, I2 =94%). As for the other outcomes, robotic therapy was
more effective in improving upper extremity function (SMD 0.45, 95% CI 0.20 to 0.69, P =
0.0004, I2 = 45%), but not muscular strength (SMD 0.48, 95% CI -0.06 to 1.03, P = 0.08, I2 =
79%). Finally, RT was well accepted by patients, there was no marked increase in the number
of drop-outs, and serious adverse events were rare and unrelated to the robotic treatment
(6).
In an update of their meta-analysis, published in 2015, the same research team confirmed that
RT was more effective than other therapies in improving activities of daily living (SMD 0.37,
95% confidence interval (CI) 0.11 to 0.64, P = 0.005, I² = 62%), motor function (SMD 0.35,
95% CI 0.18 to 0.51, P < 0.0001, I² = 36%) and strength (SMD 0.36, 95% CI 0.01 to 0.70, P =
0.04, I² = 72%) of the upper limb. RT was well accepted by patients, there was no marked
increase in the number of drop-outs (RD 0.00, 95% CI -0.02 to 0.03, P = 0.84, I² = 0%), and
serious adverse events were rare and unrelated to the robotic treatment. However, the authors
concluded that the evidence quality was low, highlighting the need for more rigorous studies.
It should be noted that the authors of the review highlighted the fact that the studies
reviewed were heterogeneous in terms of study design (two arms, four arms, parallel groups or
cross-over, duration of follow-up and selection criteria), of the devices used for the
therapeutic treatment, of the patients' characteristics (time since disease onset), of the
methodological protocols (methods of randomization, of the blindness of the outcome assessors
to group allocation, and of the presence or absence of an intention to treat analysis).
However, the authors emphasized that limitations such as the inability to blind the therapist
and participants, i.e. the so-called contamination (provision of the intervention to the
control group), and co-intervention (when the same therapist unintentionally provides
additional care to either treatment or comparison group) has often been present in
rehabilitation studies. Moreover, they pointed out that sometimes the sample is selected
according to comorbidities, age, spasticity or pain; instead, in clinical practice patients
are often older, and the prevalence of comorbidity, pain, spasticity and/or limitations of
articular function is higher than that reported in the studies analyzed. Therefore, inclusion
criteria that allow the effects of a robotic treatment to be evaluated on a larger sample of
patients with stroke, with clinical characteristics as close as possible to the real-world
clinical setting, are desirable.
Many authors have highlighted the impact on costs and the greater sustainability of the RT
when compared with the CT. The latter requires a ratio of one therapist to one patient, while
RT, after adequate training of the therapist, allows a ratio of one therapist to every three
or four patients, depending on the technology used.
RT allows patients' improvements to be assessed even after a single treatment session, to
constantly monitor the rehabilitation program and therefore to better define the best
rehabilitation strategies. In fact, thanks to the possibility the systems available, it is
possible to customize the treatment based on the patients' clinical characteristics. Last but
not least, robotic devices involve and motivate patients, providing them with visual and
auditory feedback through virtual reality programs in the form of games. Training progresses
through increasingly difficult stages that can be linked by patients to their own progress.
This becomes an important stimulus to increase the active participation of patients in the
rehabilitation program.
Almost all scientific papers in the literature have focused on the effects of the use of one
or, at most, two robotic devices, compared with a conventional approach.
However, even though the anatomy and the motor function of the upper limbs, especially the
hand, is extremely complex, all but a very few commercial devices act on a limited number of
joints and limit the workspace on a plane. By contrast, during conventional therapy the whole
upper limb is routinely treated and the three-dimensional space, in which the upper limb is
normally required to move to accomplish daily activities, is normally explored. In the light
of the above, it is very difficult to compare the effects of robotic and traditional
approaches.
This results in the need for a multi-set of robots and electromechanical systems, each of
which acts on a different joint and/or on a different plane, in upper limb rehabilitation in
stroke patients. To the best of our knowledge, the effects of a similar approach, i.e. the
use of a multi-set of robotic devices to restore motor function in patients with stroke, have
never been compared with those of a conventional approach. Moreover, the effects should
ideally be explored on a large sample of subjects that are representative of clinical
practice.
Hypothesis. The rationale behind the study is that a multi-set of robotic devices used to
treat the whole upper limb may be more effective than conventional treatments in improving
upper limb motor performance, since they raise the degree of motivation and participation
among patients, and provide a more intensive, standardized and individualized treatment.
Therefore, the investigators wish to verify this hypothesis on a large sample of subjects,
within a multicenter study using the same multi-set of robotic devices and the same outcome
measures, to obtain better-quality scientific evidence than that currently available in the
literature.
Aim: to assess, using evidence-based criteria (RCT), the effectiveness of a rehabilitation
program targeting all the upper limb joints in stroke patients, using a multi-set of robotic
and technological systems, by comparing it with that of a conventional approach.
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