Premotor and Posterior Parietal Cortex Activity is Increased for Slow, as well as Fast Walking Poststroke: An fNIRS Study
CONCLUSIONS: Brain activation is not linearly related to gait speed. Ipsilesional prefrontal cortex, bilateral premotor, and bilateral posterior parietal cortices are important areas for gait speed modulation and could be an area of interest for neurostimulation.PMID:37868191 | PMC:PMC10589070 | DOI:10.1155/2023/2403175 (Source: Neural Plasticity)
Source: Neural Plasticity - October 23, 2023 Category: Neurology Authors: Shannon B Lim Sue Peters Chieh-Ling Yang Lara A Boyd Teresa Liu-Ambrose Janice J Eng Source Type: research
Premotor and Posterior Parietal Cortex Activity is Increased for Slow, as well as Fast Walking Poststroke: An fNIRS Study
CONCLUSIONS: Brain activation is not linearly related to gait speed. Ipsilesional prefrontal cortex, bilateral premotor, and bilateral posterior parietal cortices are important areas for gait speed modulation and could be an area of interest for neurostimulation.PMID:37868191 | PMC:PMC10589070 | DOI:10.1155/2023/2403175 (Source: Neural Plasticity)
Source: Neural Plasticity - October 23, 2023 Category: Neurology Authors: Shannon B Lim Sue Peters Chieh-Ling Yang Lara A Boyd Teresa Liu-Ambrose Janice J Eng Source Type: research
Premotor and Posterior Parietal Cortex Activity is Increased for Slow, as well as Fast Walking Poststroke: An fNIRS Study
CONCLUSIONS: Brain activation is not linearly related to gait speed. Ipsilesional prefrontal cortex, bilateral premotor, and bilateral posterior parietal cortices are important areas for gait speed modulation and could be an area of interest for neurostimulation.PMID:37868191 | PMC:PMC10589070 | DOI:10.1155/2023/2403175 (Source: Neural Plasticity)
Source: Neural Plasticity - October 23, 2023 Category: Neurology Authors: Shannon B Lim Sue Peters Chieh-Ling Yang Lara A Boyd Teresa Liu-Ambrose Janice J Eng Source Type: research
Premotor and Posterior Parietal Cortex Activity is Increased for Slow, as well as Fast Walking Poststroke: An fNIRS Study
CONCLUSIONS: Brain activation is not linearly related to gait speed. Ipsilesional prefrontal cortex, bilateral premotor, and bilateral posterior parietal cortices are important areas for gait speed modulation and could be an area of interest for neurostimulation.PMID:37868191 | PMC:PMC10589070 | DOI:10.1155/2023/2403175 (Source: Neural Plasticity)
Source: Neural Plasticity - October 23, 2023 Category: Neurology Authors: Shannon B Lim Sue Peters Chieh-Ling Yang Lara A Boyd Teresa Liu-Ambrose Janice J Eng Source Type: research
Premotor and Posterior Parietal Cortex Activity is Increased for Slow, as well as Fast Walking Poststroke: An fNIRS Study
CONCLUSIONS: Brain activation is not linearly related to gait speed. Ipsilesional prefrontal cortex, bilateral premotor, and bilateral posterior parietal cortices are important areas for gait speed modulation and could be an area of interest for neurostimulation.PMID:37868191 | PMC:PMC10589070 | DOI:10.1155/2023/2403175 (Source: Neural Plasticity)
Source: Neural Plasticity - October 23, 2023 Category: Neurology Authors: Shannon B Lim Sue Peters Chieh-Ling Yang Lara A Boyd Teresa Liu-Ambrose Janice J Eng Source Type: research
Premotor and Posterior Parietal Cortex Activity is Increased for Slow, as well as Fast Walking Poststroke: An fNIRS Study
CONCLUSIONS: Brain activation is not linearly related to gait speed. Ipsilesional prefrontal cortex, bilateral premotor, and bilateral posterior parietal cortices are important areas for gait speed modulation and could be an area of interest for neurostimulation.PMID:37868191 | PMC:PMC10589070 | DOI:10.1155/2023/2403175 (Source: Neural Plasticity)
Source: Neural Plasticity - October 23, 2023 Category: Neurology Authors: Shannon B Lim Sue Peters Chieh-Ling Yang Lara A Boyd Teresa Liu-Ambrose Janice J Eng Source Type: research
Premotor and Posterior Parietal Cortex Activity is Increased for Slow, as well as Fast Walking Poststroke: An fNIRS Study
CONCLUSIONS: Brain activation is not linearly related to gait speed. Ipsilesional prefrontal cortex, bilateral premotor, and bilateral posterior parietal cortices are important areas for gait speed modulation and could be an area of interest for neurostimulation.PMID:37868191 | PMC:PMC10589070 | DOI:10.1155/2023/2403175 (Source: Neural Plasticity)
Source: Neural Plasticity - October 23, 2023 Category: Neurology Authors: Shannon B Lim Sue Peters Chieh-Ling Yang Lara A Boyd Teresa Liu-Ambrose Janice J Eng Source Type: research
Premotor and Posterior Parietal Cortex Activity is Increased for Slow, as well as Fast Walking Poststroke: An fNIRS Study
CONCLUSIONS: Brain activation is not linearly related to gait speed. Ipsilesional prefrontal cortex, bilateral premotor, and bilateral posterior parietal cortices are important areas for gait speed modulation and could be an area of interest for neurostimulation.PMID:37868191 | PMC:PMC10589070 | DOI:10.1155/2023/2403175 (Source: Neural Plasticity)
Source: Neural Plasticity - October 23, 2023 Category: Neurology Authors: Shannon B Lim Sue Peters Chieh-Ling Yang Lara A Boyd Teresa Liu-Ambrose Janice J Eng Source Type: research
Premotor and Posterior Parietal Cortex Activity is Increased for Slow, as well as Fast Walking Poststroke: An fNIRS Study
CONCLUSIONS: Brain activation is not linearly related to gait speed. Ipsilesional prefrontal cortex, bilateral premotor, and bilateral posterior parietal cortices are important areas for gait speed modulation and could be an area of interest for neurostimulation.PMID:37868191 | PMC:PMC10589070 | DOI:10.1155/2023/2403175 (Source: Neural Plasticity)
Source: Neural Plasticity - October 23, 2023 Category: Neurology Authors: Shannon B Lim Sue Peters Chieh-Ling Yang Lara A Boyd Teresa Liu-Ambrose Janice J Eng Source Type: research
Premotor and Posterior Parietal Cortex Activity is Increased for Slow, as well as Fast Walking Poststroke: An fNIRS Study
CONCLUSIONS: Brain activation is not linearly related to gait speed. Ipsilesional prefrontal cortex, bilateral premotor, and bilateral posterior parietal cortices are important areas for gait speed modulation and could be an area of interest for neurostimulation.PMID:37868191 | PMC:PMC10589070 | DOI:10.1155/2023/2403175 (Source: Neural Plasticity)
Source: Neural Plasticity - October 23, 2023 Category: Neurology Authors: Shannon B Lim Sue Peters Chieh-Ling Yang Lara A Boyd Teresa Liu-Ambrose Janice J Eng Source Type: research
Premotor and Posterior Parietal Cortex Activity is Increased for Slow, as well as Fast Walking Poststroke: An fNIRS Study
CONCLUSIONS: Brain activation is not linearly related to gait speed. Ipsilesional prefrontal cortex, bilateral premotor, and bilateral posterior parietal cortices are important areas for gait speed modulation and could be an area of interest for neurostimulation.PMID:37868191 | PMC:PMC10589070 | DOI:10.1155/2023/2403175 (Source: Neural Plasticity)
Source: Neural Plasticity - October 23, 2023 Category: Neurology Authors: Shannon B Lim Sue Peters Chieh-Ling Yang Lara A Boyd Teresa Liu-Ambrose Janice J Eng Source Type: research
Premotor and Posterior Parietal Cortex Activity is Increased for Slow, as well as Fast Walking Poststroke: An fNIRS Study
CONCLUSIONS: Brain activation is not linearly related to gait speed. Ipsilesional prefrontal cortex, bilateral premotor, and bilateral posterior parietal cortices are important areas for gait speed modulation and could be an area of interest for neurostimulation.PMID:37868191 | PMC:PMC10589070 | DOI:10.1155/2023/2403175 (Source: Neural Plasticity)
Source: Neural Plasticity - October 23, 2023 Category: Neurology Authors: Shannon B Lim Sue Peters Chieh-Ling Yang Lara A Boyd Teresa Liu-Ambrose Janice J Eng Source Type: research
Clinical Research Progress of the Post-Stroke Upper Limb Motor Function Improvement via Transcutaneous Auricular Vagus Nerve Stimulation
Neural Plast. 2023 Sep 25;2023:9532713. doi: 10.1155/2023/9532713. eCollection 2023.ABSTRACTStroke is a disease with high morbidity and disability, and motor impairment is a common sequela of stroke. Transcutaneous auricular vagus nerve stimulation (taVNS) is a type of non-invasive stimulation, which can effectively improve post-stroke motor dysfunction. This review discusses stimulation parameters, intervention timing, and the development of innovative devices for taVNS. We further summarize the application of taVNS in improving post-stroke upper limb motor function to further promote the clinical research and application...
Source: Neural Plasticity - October 4, 2023 Category: Neurology Authors: Xiaolong Shi Jingjun Zhao Shutian Xu Meng Ren Yuwei Wu Xixi Chen Zhiqing Zhou Songmei Chen Yu Huang Yuanli Li Chunlei Shan Source Type: research
Clinical Research Progress of the Post-Stroke Upper Limb Motor Function Improvement via Transcutaneous Auricular Vagus Nerve Stimulation
Neural Plast. 2023 Sep 25;2023:9532713. doi: 10.1155/2023/9532713. eCollection 2023.ABSTRACTStroke is a disease with high morbidity and disability, and motor impairment is a common sequela of stroke. Transcutaneous auricular vagus nerve stimulation (taVNS) is a type of non-invasive stimulation, which can effectively improve post-stroke motor dysfunction. This review discusses stimulation parameters, intervention timing, and the development of innovative devices for taVNS. We further summarize the application of taVNS in improving post-stroke upper limb motor function to further promote the clinical research and application...
Source: Neural Plasticity - October 4, 2023 Category: Neurology Authors: Xiaolong Shi Jingjun Zhao Shutian Xu Meng Ren Yuwei Wu Xixi Chen Zhiqing Zhou Songmei Chen Yu Huang Yuanli Li Chunlei Shan Source Type: research
Clinical Research Progress of the Post-Stroke Upper Limb Motor Function Improvement via Transcutaneous Auricular Vagus Nerve Stimulation
Neural Plast. 2023 Sep 25;2023:9532713. doi: 10.1155/2023/9532713. eCollection 2023.ABSTRACTStroke is a disease with high morbidity and disability, and motor impairment is a common sequela of stroke. Transcutaneous auricular vagus nerve stimulation (taVNS) is a type of non-invasive stimulation, which can effectively improve post-stroke motor dysfunction. This review discusses stimulation parameters, intervention timing, and the development of innovative devices for taVNS. We further summarize the application of taVNS in improving post-stroke upper limb motor function to further promote the clinical research and application...
Source: Neural Plasticity - October 4, 2023 Category: Neurology Authors: Xiaolong Shi Jingjun Zhao Shutian Xu Meng Ren Yuwei Wu Xixi Chen Zhiqing Zhou Songmei Chen Yu Huang Yuanli Li Chunlei Shan Source Type: research
