Articles by Tziporah Thompson in JoVE
अनुकूलित प्रतिरोध प्रशिक्षण मल्टीपल स्केलेरोसिस के साथ व्यक्तियों में आठ सप्ताह में शक्ति में सुधार Jennifer L. Keller1, Nora Fritz1,2, Chen Chun Chiang1, Allen Jiang1, Tziporah Thompson3, Nicole Cornet1, Scott D. Newsome4, Peter A. Calabresi4, Kathleen Zackowski1,2,4 1Motion Analysis Laboratory, Kennedy Krieger Institute, 2Physical Medicine & Rehabilitation, Johns Hopkins University School of Medicine, 3Johns Hopkins University School of Medicine, 4Department of Neurology, Johns Hopkins University School of Medicine हिप कमजोरी एकाधिक काठिन्य के साथ लोगों में चलने की क्षमता को प्रभावित करने के लिए एक आम लक्षण है। पृथक मांसपेशियों को मजबूत बनाने विशिष्ट कमजोरियों को लक्षित करने के लिए एक उपयोगी तरीका है। इस प्रोटोकॉल कूल्हे की मांसपेशियों की ताकत बढ़ाने के लिए व्यायाम बैंड का उपयोग कर एक प्रगतिशील प्रतिरोध प्रशिक्षण कार्यक्रम का वर्णन है।
Other articles by Tziporah Thompson on PubMed
Cerebellar Direct Current Stimulation Enhances On-line Motor Skill Acquisition Through an Effect on Accuracy The Journal of Neuroscience : the Official Journal of the Society for Neuroscience. Feb, 2015 | Pubmed ID: 25698763 The cerebellum is involved in the update of motor commands during error-dependent learning. Transcranial direct current stimulation (tDCS), a form of noninvasive brain stimulation, has been shown to increase cerebellar excitability and improve learning in motor adaptation tasks. Although cerebellar involvement has been clearly demonstrated in adaptation paradigms, a type of task that heavily relies on error-dependent motor learning mechanisms, its role during motor skill learning, a behavior that likely involves error-dependent as well as reinforcement and strategic mechanisms, is not completely understood. Here, in humans, we delivered cerebellar tDCS to modulate its activity during novel motor skill training over the course of 3 d and assessed gains during training (on-line effects), between days (off-line effects), and overall improvement. We found that excitatory anodal tDCS applied over the cerebellum increased skill learning relative to sham and cathodal tDCS specifically by increasing on-line rather than off-line learning. Moreover, the larger skill improvement in the anodal group was predominantly mediated by reductions in error rate rather than changes in movement time. These results have important implications for using cerebellar tDCS as an intervention to speed up motor skill acquisition and to improve motor skill accuracy, as well as to further our understanding of cerebellar function.