OBJECTIVE: A behavioural study was conducted to investigate how cerebellar dysfunction associated with multiple sclerosis affects the ability to learn a novel visuo-postural co-ordination task. DESIGN: A prospective design, 2 group by 1 treatment (4 practice blocks). SUBJECTS: Ten patients with multiple sclerosis diagnosed with cerebellar ataxia and 10 age-matched healthy controls. METHODS: Participants stood over a dual force platform (ERBE Balance System) and performed visually guided lateral weight-shifting movements. The task required subjects to gradually transfer weight between sides while maintaining each foot's force vector within visually specified force constraints ranging from 0% to 100% of bodyweight with maximum allowed variation set to +/-20%. The time required to complete the task and the number of spatial errors (noted each time the foot's vector exceeded the +/-20% force constraint) were recorded. Training consisted of 3 blocks of 5 trials separated by 1-minute intervals and followed by 5 retention trials. RESULTS AND CONCLUSION: Statistics revealed a significant decrease in movement time and spatial errors across trial blocks in both groups; however, the group with multiple sclerosis showed a limited and slower rate of performance improvement characterized by increased within- and between-subject variability. These findings may have important implications in the design of rehabilitation protocols for improving motor skill performance in adults with multiple sclerosis.
OBJECTIVE: A behavioural study was conducted to investigate how cerebellar dysfunction associated with multiple sclerosis affects the ability to learn a novel visuo-postural co-ordination task. DESIGN: A prospective design, 2 group by 1 treatment (4 practice blocks). SUBJECTS: Ten patients with multiple sclerosis diagnosed with cerebellar ataxia and 10 age-matched healthy controls. METHODS:Participants stood over a dual force platform (ERBE Balance System) and performed visually guided lateral weight-shifting movements. The task required subjects to gradually transfer weight between sides while maintaining each foot's force vector within visually specified force constraints ranging from 0% to 100% of bodyweight with maximum allowed variation set to +/-20%. The time required to complete the task and the number of spatial errors (noted each time the foot's vector exceeded the +/-20% force constraint) were recorded. Training consisted of 3 blocks of 5 trials separated by 1-minute intervals and followed by 5 retention trials. RESULTS AND CONCLUSION: Statistics revealed a significant decrease in movement time and spatial errors across trial blocks in both groups; however, the group with multiple sclerosis showed a limited and slower rate of performance improvement characterized by increased within- and between-subject variability. These findings may have important implications in the design of rehabilitation protocols for improving motor skill performance in adults with multiple sclerosis.
Authors: Valentina Tomassini; Heidi Johansen-Berg; Laura Leonardi; Luis Paixão; Saad Jbabdi; Jackie Palace; Carlo Pozzilli; Paul M Matthews Journal: Mult Scler Date: 2010-09-10 Impact factor: 6.312
Authors: Camille J Shanahan; Frederique M C Boonstra; L Eduardo Cofré Lizama; Myrte Strik; Bradford A Moffat; Fary Khan; Trevor J Kilpatrick; Anneke van der Walt; Mary P Galea; Scott C Kolbe Journal: Front Neurol Date: 2018-02-02 Impact factor: 4.003
Authors: Giacomo Severini; Sofia Straudi; Claudia Pavarelli; Marco Da Roit; Carlotta Martinuzzi; Laura Di Marco Pizzongolo; Nino Basaglia Journal: J Neuroeng Rehabil Date: 2017-03-11 Impact factor: 4.262