Feasibility of High Repetition Upper Extremity Rehabilitation for Children with Unilateral Cerebral Palsy.

AIMS: In pediatric upper extremity rehabilitation, feasible repetition rates are unknown. Our objectives were to examine repetition rates during rehabilitation and their impact on outcomes. METHODS: Children with unilateral cerebral palsy due to perinatal stroke (n = 55, median 10 y 7 mo, 30 males) received Constraint-Induced Movement Therapy (CIMT) followed by Bimanual Therapy, each for 5 days. Repetitions were documented during one-on-one therapy (1.5 h/day). Outcomes included the Assisting Hand Assessment (AHA), Jebsen Taylor Test of Hand Function (JTTHF), and Box and Block Test (BBT). Means and standard deviations for motor outcomes and frequencies for repetition rates were calculated. Factors associated with repetition rates and outcome change were explored using standard linear regression. RESULTS: Repetitions/hour averaged 365 ± 165 during CIMT and 285 ± 103 during Bimanual Therapy. Higher repetition rates were associated with higher baseline function by older age, a main effect of younger age, and improving motor skill (p < .05). Higher repetition rates corresponded with improvement of the AHA and BBT (p < .05, standardized ß = 0.392, 0.358). CONCLUSIONS: Results suggest high repetition therapy is feasible in school-aged children with perinatal stroke, albeit with high individual variability. Multiple associations between repetition rates and baseline function and change point to the clinical importance of this measurable and potentially modifiable factor.

Goals of children with unilateral cerebral palsy in a brain stimulation arm rehabilitation trial.

AIM: To explore relationships between category classifications for children's rehabilitation goals, outcomes, and participant characteristics. METHOD: Children with hemiparetic cerebral palsy due to perinatal stroke rated self-selected goals with the Canadian Occupational Performance Measure (COPM) and completed the Assisting Hand Assessment (AHA) and Box and Block Test (BBT), at baseline and 6 months, in a randomized, controlled 10-day neuromodulation rehabilitation trial using repetitive transcranial magnetic stimulation. Goals were classified with the Canadian Model of Occupational Performance and Engagement and the International Classification of Functioning, Disability and Health. Analysis included standard linear regression. RESULTS: Data for 45 participants (mean age 11y 7mo, SD 3y 10mo, range 6-19y, 29 males, 16 females) on 186 goals were included. Self-care goal percentage corresponded with baseline BBT by age (standardized ß=-0.561, p=0.004). Leisure goal percentage corresponded with baseline BBT (standardized ß=0.419, p=0.010). AHA change corresponded with productivity goals (standardized ß=0.327, p=0.029) and age (standardized ß=0.481, p=0.002). COPM change corresponded with baseline COPM and age by AHA change (p<0.05). INTERPRETATION: Younger children with lower motor function were more likely to select self-care goals while those with better function tended to select leisure goals. Functional improvement corresponded with older age and productivity goals. COPM change scores reflected functional improvement among older children. Children chose functionally and developmentally appropriate goals. Consequently, children should be free to set goals that matter to them. WHAT THIS PAPER ADDS: Children in a brain stimulation trial chose divergent upper extremity functional goals. Younger children with lower ability chose more self-care goals. Children with higher ability chose more leisure goals. Older children's goal ratings reflected objective functional motor gains. Children chose goals appropriate to their function and level of development.

Bilateral actigraphic quantification of upper extremity movement in hemiparetic children with perinatal stroke: a case control study.

BACKGROUND: Hemiparetic cerebral palsy impacts millions of people worldwide. Assessment of bilateral motor function in real life remains a major challenge. We evaluated quantification of upper extremity movement in hemiparetic children using bilateral actigraphy. We hypothesized that movement asymmetry correlates with standard motor outcome measures. METHODS: Hemiparetic and control participants wore bilateral wrist Actiwatch2 (Philips) for 48 h with movement counts recorded in 15-s intervals. The primary outcome was a novel statistic of movement asymmetry, the Actigraphic Movement Asymmetry Index (AMAI). Relationships between AMAI and standard motor outcomes (Assisting Hand Assessment, Melbourne Assessment, and Box and Block Test [BB]) were explored with Pearson or Spearman correlation. RESULTS: 30 stroke (mean 11 years 2 months (3 years 10 months); 13 female, 17 male) and 23 control (mean 11 years 1 month (4 years 5 months); 8 female, 15 male) were enrolled. Stroke participants demonstrated higher asymmetry. Correlations between AMAI and standard tests were moderate and strongest during sleep (BB: r = 0.68, p < 0.01). CONCLUSIONS: Standard tests may not reflect the extent of movement asymmetry during daily life in hemiparetic children. Bilateral actigraphy may be a valuable complementary tool for measuring arm movement, potentially enabling improved evaluation of therapies with a focus on child participation.

Sensorimotor Robotic Measures of tDCS- and HD-tDCS-Enhanced Motor Learning in Children.

Transcranial direct-current stimulation (tDCS) enhances motor learning in adults. We have demonstrated that anodal tDCS and high-definition (HD) tDCS of the motor cortex can enhance motor skill acquisition in children, but behavioral mechanisms remain unknown. Robotics can objectively quantify complex sensorimotor functions to better understand mechanisms of motor learning. We aimed to characterize changes in sensorimotor function induced by tDCS and HD-tDCS paired motor learning in children within an interventional trial. Healthy, right-handed children (12-18 y) were randomized to anodal tDCS, HD-tDCS, or sham targeting the right primary motor cortex during left-hand Purdue pegboard test (PPT) training over five consecutive days. A KINARM robotic protocol quantifying proprioception, kinesthesia, visually guided reaching, and an object hit task was completed at baseline, posttraining, and six weeks later. Effects of the treatment group and training on changes in sensorimotor parameters were explored. Twenty-four children (median 15.5 years, 52% female) completed all measures. Compared to sham, both tDCS and HD-tDCS demonstrated enhanced motor learning with medium effect sizes. At baseline, multiple KINARM measures correlated with PPT performance. Following training, visually guided reaching in all groups was faster and required less corrective movements in the trained arm (H(2) = 9.250, p = 0.010). Aspects of kinesthesia including initial direction error improved across groups with sustained effects at follow-up (H(2) = 9.000, p = 0.011). No changes with training or stimulation were observed for position sense. For the object hit task, the HD-tDCS group moved more quickly with the right hand compared to sham at posttraining (χ 2(2) = 6.255, p = 0.044). Robotics can quantify complex sensorimotor function within neuromodulator motor learning trials in children. Correlations with PPT performance suggest that KINARM metrics can assess motor learning effects. Understanding how tDCS and HD-tDCS enhance motor learning may be improved with robotic outcomes though specific mechanisms remain to be defined. Exploring mechanisms of neuromodulation may advance therapeutic approaches in children with cerebral palsy and other disabilities.

BCI-activated electrical stimulation in children with perinatal stroke and hemiparesis: A pilot study.

Background: Perinatal stroke (PS) causes most hemiparetic cerebral palsy (CP) and results in lifelong disability. Children with severe hemiparesis have limited rehabilitation options. Brain computer interface- activated functional electrical stimulation (BCI-FES) of target muscles may enhance upper extremity function in hemiparetic adults. We conducted a pilot clinical trial to assess the safety and feasibility of BCI-FES in children with hemiparetic CP. Methods: Thirteen participants (mean age = 12.2 years, 31% female) were recruited from a population-based cohort. Inclusion criteria were: (1) MRI-confirmed PS, (2) disabling hemiparetic CP, (3) age 6-18 years, (4) informed consent/assent. Those with neurological comorbidities or unstable epilepsy were excluded. Participants attended two BCI sessions: training and rehabilitation. They wore an EEG-BCI headset and two forearm extensor stimulation electrodes. Participants' imagination of wrist extension was classified on EEG, after which muscle stimulation and visual feedback were provided when the correct visualization was detected. Results: No serious adverse events or dropouts occurred. The most common complaints were mild headache, headset discomfort and muscle fatigue. Children ranked the experience as comparable to a long car ride and none reported as unpleasant. Sessions lasted a mean of 87 min with 33 min of stimulation delivered. Mean classification accuracies were (M = 78.78%, SD = 9.97) for training and (M = 73.48, SD = 12.41) for rehabilitation. Mean Cohen's Kappa across rehabilitation trials was M = 0.43, SD = 0.29, range = 0.019-1.00, suggesting BCI competency. Conclusion: Brain computer interface-FES was well -tolerated and feasible in children with hemiparesis. This paves the way for clinical trials to optimize approaches and test efficacy.

Clinical provision of compensatory visual training after neurological injury: example of a multisite outpatient program.

AIM: Treatment efficacy is established via controlled research trials, but treatment in real-world clinical environments is typically highly variable and may differ from research protocols by necessity. Here, we examined provision of visual retraining for adults after neurological injury at an outpatient rehabilitation program in Calgary, Canada. METHODS: Retrospective chart audits extracted demographic data, assessment outcomes, and details related to provision of training. RESULTS: Treatment was provided to individuals with both visual field and visual-perceptual impairments due to neurological injury (mostly stroke). Tools and techniques of visual retraining at this program are discussed, the common denominator being repetitive practice of compensatory visual behaviors. Across this multisite program, there was significant variability in the number of treatment sessions, 13.00 (±10.21) sessions for those with visual-perceptual impairments and 14.41 (±9.63) sessions for those with field loss. Descriptive statistics and confidence intervals suggest improved outcomes on some measures for those with visual field and visual perceptual impairments. CONCLUSIONS: Our data suggest that visual retraining is feasible in this clinical outpatient setting. Implications for rehabilitation This program of visual retraining was provided to individuals with visual impairment (e.g., hemianopia) and visual perceptual impairment (e.g., unilateral spatial neglect) as a result of neurological injury. In this outpatient program, visual rehabilitation was feasible and appeared to improve outcomes among a heterogeneous clinical population. Fundamental characteristics of visual compensatory training at this program included repetitive practice of adaptive scanning behaviors across multiple contexts to promote automaticity and generalization of skills.

Perinatal stroke: mapping and modulating developmental plasticity.

Most cases of hemiparetic cerebral palsy are caused by perinatal stroke, resulting in lifelong disability for millions of people. However, our understanding of how the motor system develops following such early unilateral brain injury is increasing. Tools such as neuroimaging and brain stimulation are generating informed maps of the unique motor networks that emerge following perinatal stroke. As a focal injury of defined timing in an otherwise healthy brain, perinatal stroke represents an ideal human model of developmental plasticity. Here, we provide an introduction to perinatal stroke epidemiology and outcomes, before reviewing models of developmental plasticity after perinatal stroke. We then examine existing therapeutic approaches, including constraint, bimanual and other occupational therapies, and their potential synergy with non-invasive neurostimulation. We end by discussing the promise of exciting new therapies, including novel neurostimulation, brain-computer interfaces and robotics, all focused on improving outcomes after perinatal stroke.

Analyzing the barriers and supports of knowledge translation using the PEO model.

BACKGROUND: Knowledge translation is a current and growing force in Canada's health care environment. PURPOSE: The intent of this paper is to examine current research related to barriers and facilitators of knowledge translation relevant to occupational therapy from the perspective of the person-environment-occupation (PEO) model. KEY ISSUES: Minimum competency and best practice are established drivers of research use in occupational therapy. Knowledge translation is not only complementary to these established drivers but offers a valuable contribution to the profession. Current research offers insight into the facilitators and obstacles of knowledge translation in occupational therapy, and the PEO model provides a framework for this analysis. IMPLICATIONS: Several influences across different levels of the practice system may facilitate or hinder knowledge translation. Awareness of the current research related to these influences, in concert with an awareness of individual circumstances, is an essential precursor to developing more effective knowledge translation strategies.

Translating knowledge to practice: an occupational therapy perspective.

BACKGROUND/AIM: Translating knowledge to practice, also called 'knowledge translation', is increasingly recognised as a driving force to strengthen and improve the healthcare system. How knowledge translation fits with occupational therapy practice deserves examination. METHODS: This paper will explore how an action process model, the Knowledge-To-Action Process, may advance knowledge translation in occupational therapy. Occupational therapists typically view knowledge in a broad sense, encompassing research, tacit knowledge, expert opinion and client evidence. The Knowledge-To-Action Process facilitates application of client, therapist and research knowledge to occupational therapy practice. RESULTS: Examination of knowledge translation through the lens of the Knowledge-To-Action Process creates awareness of the value of client, therapist and research knowledge. It also highlights opportunities as practitioners to implement knowledge translation. CONCLUSIONS: Models able to flexibly reflect an occupational therapy perspective of knowledge have a potentially vital role in successful knowledge translation. Furthermore, these models allow therapists and other stakeholders to analyse complex situations and identify targeted knowledge translation strategies.

A Case of Neuromuscular Electrical Stimulation for Childhood Stroke Hyperkinesis: A Brief Report.

AIM: Some conditions within specific populations are so rare rigorous evidence is unavailable. Childhood hyperkinesis is one example, yet presents an opportunity to examine sensation's contribution to motor function. METHODS: The patient experienced functional difficulty from hyperkinesis as a result of childhood stroke. Home-based passive neuromuscular electrical stimulation (NMES) was implemented an hour/day, six days/week, over 6 weeks (36 hours). Clinical and robotic measures (Assisting Hand Assessment, Box and Block Test, Jebsen Taylor Test of Hand Function, Kinarm) were administered before and after the intervention and at 9 months. RESULTS: NMES was feasible and well tolerated. Clinically important gains of arm function were maintained at 9 months. Robotic measures showed improved hyperkinesis, namely reduced movement segmentation and improved target approximation, in addition to improved proprioceptive function after NMES. CONCLUSION: This case study illustrates the use of NMES within a previously unexplored population and highlights the potential importance of sensory systems to motor gains.

Enriched childhood experiences moderate age-related motor and cognitive decline.

Aging is associated with deterioration of skilled manual movement. Specifically, aging corresponds with increased reaction time, greater movement duration, segmentation of movement, increased movement variability, and reduced ability to adapt to external forces and inhibit previously learned sequences. Moreover, it is thought that decreased lateralization of neural function in older adults may point to increased neural recruitment as a compensatory response to deterioration of key frontal and intra-hemispheric networks, particularly of callosal structures. However, factors that mediate age-related motor decline are not well understood. Here we show that music training in childhood is associated with reduced age-related decline of bimanual and unimanual motor skills in a MIDI keyboard motor learning task. Compared to older adults without music training, older adults with more than a year of music training demonstrated proficient bimanual and unimanual movement, evidenced by enhanced speed and decreased movement errors. Further, this group demonstrated significantly better implicit learning in the weather prediction task, a non-motor task. The performance of older adults with music training in those tasks was comparable to young adults. Older adults, however, displayed greater verbal ability compared to young adults irrespective of a past history of music training. Our results indicate that music training early in life may reduce age-associated decline of neural motor and cognitive networks.