Project details

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Project: The effect of home based exergame balance training on pediatric ataxia. - A pilot study-

Keywords:
Treatment child Ataxia

Researchers:
prof. dr. ir. N.M. Maurits
Dr. D.A. Sival
C. Lamoth
R. Brandsma
M.M. Schoemaker

Nature of the research:
explorative pilot study, preparation for MD PhD project

Fields of study:
movement sciences neurology rehabilitation

Background / introduction
Early Onset Ataxia (EOA) concerns a group of rare children with heterogeneous, (mostly) degenerative neurologic diseases with ataxia as the leading symptom. Children with EOA reveal motor performances that lack sufficient coordination of arm-, leg-, trunk-, eye- and speech- muscles, resulting in problematic balance, limb coordination and speech (ref 1,2). To date, there is no medication available to ameliorate the progression of ataxia (ref 3). Recent publications in patients with impaired coordination have indicated that training with exergames (virtual video-games) are beneficial for their muscle strength and coordinative functions (ref 4-11). In EOA, it is incompletely known whether the beneficial effect is attributable to improved axial muscle force (providing trunk stability), or to improved cerebellar coordination. Furthermore, before clinical application in EOA children, insight in the optimal exergame strategy for the specific phenotype of the EOA patient is needed, first.
The UMCG has recently developed an ice skating exergame, during which the patient can induce virtual skating movements in a puppet (visible on a screen), by accurately shifting his/her body balance (ref 7,8). In a phenotypically well-circumscribed ambulant subgroup of EOA children, we aim to evaluate the effects of this skating exergame on: 1/ ataxia parameters (by measurements with non-invasive, light weight inertial measurement units (IMUs; ref 12), clinical scores with ataxia rating scales (SARA; ref 13) and pediatric balance scale (ref 14), 2/ muscle parameters (muscle force assessment by dynamometry (ref 15) and muscle ultrasound imaging (ref 16,17), 3/ pre-defined improvement of coordinative functions (goal attainment scores (ref 18).
Research question / problem definition
Can the skating exergame improve coordinative function in a phenotypically well-circumscribed ambulant subgroup of EOA children? And if so, is the outcome attributable to improvement of skeletal muscle force, or to improved cerebellar functioning?
Workplan
During a period of six weeks, five mildly ataxic children and five healthy, age-matched control children have played the skating exergame 3 times a week during 30 minutes in their own home environment. During the game, whole body parameters were recorded by a Kinect-system, that can quantify balance performances every minute during each 30 minute training session. At the outpatient clinics, neurologic data were obtained regarding: a. ataxia rating scale scores (walking, posture, limb kinetics), b. muscle force data (i.e. dynamometry of trunk and limb muscles before, during and at the end of the training period), c. muscle ultrasound parameters (of limb muscles before and after the training period). Now, the data can be analyzed and prepared for a manuscript. The primary objective of this pilot study is to evaluate the feasibility of the ice-skating exergame training in ataxic children. This study serves as a pilot for sample size calculation and study design of a collaborative MD PhD study project to evaluate the clinical application of exergame training in children with EOA.

In collaboration with the multidisciplinary team (pediatric neurology-movement disorders; clinical neuroengineering; human movement & medical sciences), the student participates in:
1. analysis of the kinetic data, 2. evaluation of the outcome parameters, 3. if applicable and requested by the student (in case of satisfactory and substantial contribution), preparation of the manuscript and writing of the MD PhD proposal.
References
References


1. Harding AE. Clinical features and classification of inherited ataxias. Adv Neurol. 1993;61(0091-3952):1-14.
2. Bodranghien F, Bastian A, Casali C, et al. Consensus paper: Revisiting the symptoms and signs of cerebellar syndrome. Cerebellum. 2016;15(3):369-391.
3. Brandsma R, Kremer HP, Sival DA. Riluzole in patients with hereditary cerebellar ataxia. Lancet Neurol. 2016;15(8):788-4422(16)00131-9.
4. Synofzik M, Ilg W. Motor training in degenerative spinocerebellar disease: Ataxia-specific improvements by intensive physiotherapy and exergames. Biomed Res Int. 2014;2014:583507.
5. Schatton C, Synofzik M, Fleszar Z, Giese MA, Schols L, Ilg W. Individualized exergame training improves postural control in advanced degenerative spinocerebellar ataxia: A rater-blinded, intra-individually controlled trial. Parkinsonism Relat Disord. 2017;39:80-84.
6. Ilg W, Schatton C, Schicks J, Giese MA, Schols L, Synofzik M. Video game-based coordinative training improves ataxia in children with degenerative ataxia. Neurology. 2012;79(20):2056-2060.
7. van Diest M, Stegenga J, Wortche HJ, Verkerke GJ, Postema K, Lamoth CJ. Exergames for unsupervised balance training at home: A pilot study in healthy older adults. Gait Posture. 2016;44:161-167.
8. Soancatl Aguilar V, Lamoth CJC, Maurits NM, Roerdink JBTM. Assessing dynamic postural control during exergaming in older adults: A probabilistic approach. Gait Posture. 2017;60:235-240.
9. van Diest M, Lamoth CJ, Stegenga J, Verkerke GJ, Postema K. Exergaming for balance training of elderly: State of the art and future developments. J Neuroeng Rehabil. 2013;10:101-0003-10-101.
10. Jelsma D, Geuze RH, Mombarg R, Smits-Engelsman BC. The impact of wii fit intervention on dynamic balance control in children with probable developmental coordination disorder and balance problems. Hum Mov Sci. 2014;33:404-418.
11. Smits-Engelsman BC, Jelsma LD, Ferguson GD, Geuze RH. Motor learning: An analysis of 100 trials of a ski slalom game in children with and without developmental coordination disorder. PLoS One. 2015;10(10):e0140470.
12. Mannini A, Martinez-Manzanera O, Lawerman TF, et al. Automatic classification of gait in children with early-onset ataxia or developmental coordination disorder and controls using inertial sensors. Gait Posture. 2017;52:287-292.
13. Lawerman TF, Brandsma R, Burger H, Burgerhof JGM, Sival DA, the Childhood Ataxia and Cerebellar Group of the European Pediatric Neurology Society. Age-related reference values for the pediatric scale for assessment and rating of ataxia: A multicentre study. Dev Med Child Neurol. 2017;59(10):1077-1082.
14. Franjoine MR, Gunther JS, Taylor MJ. Pediatric balance scale: A modified version of the berg balance scale for the school-age child with mild to moderate motor impairment. Pediatr Phys Ther. 2003;15(2):114-128.
15. Sival DA, Pouwels ME, Van Brederode A, et al. In children with friedreich ataxia, muscle and ataxia parameters are associated. Dev Med Child Neurol. 2011;53(6):529-534.
16. Brandsma R, Verbeek RJ, Maurits NM, et al. Visual screening of muscle ultrasound images in children. Ultrasound Med Biol. 2014;40(10):2345-2351.
17. Maurits NM, Beenakker EA, van Schaik DE, Fock JM, van der Hoeven JH. Muscle ultrasound in children: Normal values and application to neuromuscular disorders. Ultrasound Med Biol. 2004;30(0301-5629; 8):1017-1027.
18. Kiresuk TJ, Lund SH, Larsen NE. Measurement of goal attainment in clinical and health care programs. Drug Intell Clin Pharm. 1982;16(2):145-153.
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