Modulation of neurometabolites in sensory processing brain areas during motor learning

IF 4.4 2区医学 Q1 NEUROSCIENCES

Journal of Physiology-London Pub Date : 2025-09-14 DOI:10.1113/JP287349

Hong Li, Amirhossein Rasooli, Geraldine Rodríguez-Nieto, Mark Mikkelsen, Dante Mantini, Stefan Sunaert, Sima Chalavi, Stephan P. Swinnen

{"title":"Modulation of neurometabolites in sensory processing brain areas during motor learning","authors":"Hong Li, Amirhossein Rasooli, Geraldine Rodríguez-Nieto, Mark Mikkelsen, Dante Mantini, Stefan Sunaert, Sima Chalavi, Stephan P. Swinnen","doi":"10.1113/JP287349","DOIUrl":null,"url":null,"abstract":"<div>\n \n <section>\n \n \n <div>GABA and glutamate (Glu) play pivotal roles in learning. Here, we investigated whether neurometabolites in specific sensory processing brain areas were differentially modulated depending on the type of feedback provided during motor learning and whether this was associated with behavioural progress. Fifty healthy human adults were trained on a bimanual tracking task for 5 days (Day 1 to Day 5) when receiving either concurrent (CA-VFB) or terminal (TA-VFB) augmented visual feedback. In two brain areas involved in sensory processing, that is the primary somatosensory cortex (S1) and medial temporal visual area (MT/V5), concentrations of GABA+ (GABA + macromolecules) and Glx (Glu + glutamine) were determined by acquiring magnetic resonance spectroscopy at three time points on Day 1 and Day 5: baseline (Pre-Scan), during (Mid-Scan) and after (Post-Scan) task training. Behaviourally, performance progress was more pronounced on Day 1 compared to Day 5. Neurochemically, there was a significant difference in the modulation of neurometabolites between the S1 and MT/V5 regions, specifically in Glx levels on Day 1. Additionally, there was a significant difference in the modulation of neurometabolites between Day 1 and Day 5, specifically in GABA+ levels in the S1 area and Glx levels in the MT/V5 area. Furthermore, a greater increase in individual S1 Glx levels on Day 5 correlated with larger behavioural progress. Our findings suggest that neurometabolites in task-related sensory processing brain areas show a differential modulation and contribute to long-term retention of visuomotor learning.\n\n <figure>\n <div><picture>\n <source></source></picture><p></p>\n </div>\n </figure>\n </div>\n </section>\n \n <section>\n \n <h3> Key points</h3>\n \n <div>\n <ul>\n \n <li>GABA and glutamate play crucial roles in motor learning, yet how these neurometabolites are modulated within specific sensory processing brain regions based on the type of feedback provided during different phases of motor learning remains unclear.</li>\n \n <li>We used a repeated measures magnetic resonance spectroscopy design to measure the concentration of neurometabolites in the primary somatosensory cortex (S1) and medial temporal visual area (MT/V5) before, during and after motor training, focusing on the initial and late learning phases.</li>\n \n <li>In the initial learning phase, Glx (glutamate + glutamine) modulation differed between S1 and MT/V5. Furthermore, in S1, GABA modulation differed between the initial and late phases, and, in MT/V5, Glx modulation also varied between these phases. A greater increase in individual S1 Glx levels on Day 5 correlated with larger behavioural progress.</li>\n \n <li>These findings suggest that distinct biological changes occur in task-related sensory processing areas across different phases of motor learning.</li>\n </ul>\n </div>\n </section>\n </div>","PeriodicalId":50088,"journal":{"name":"Journal of Physiology-London","volume":"603 19","pages":"5681-5700"},"PeriodicalIF":4.4000,"publicationDate":"2025-09-14","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Physiology-London","FirstCategoryId":"3","ListUrlMain":"https://physoc.onlinelibrary.wiley.com/doi/10.1113/JP287349","RegionNum":2,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"NEUROSCIENCES","Score":null,"Total":0}

引用次数: 0

Abstract

GABA and glutamate (Glu) play pivotal roles in learning. Here, we investigated whether neurometabolites in specific sensory processing brain areas were differentially modulated depending on the type of feedback provided during motor learning and whether this was associated with behavioural progress. Fifty healthy human adults were trained on a bimanual tracking task for 5 days (Day 1 to Day 5) when receiving either concurrent (CA-VFB) or terminal (TA-VFB) augmented visual feedback. In two brain areas involved in sensory processing, that is the primary somatosensory cortex (S1) and medial temporal visual area (MT/V5), concentrations of GABA+ (GABA + macromolecules) and Glx (Glu + glutamine) were determined by acquiring magnetic resonance spectroscopy at three time points on Day 1 and Day 5: baseline (Pre-Scan), during (Mid-Scan) and after (Post-Scan) task training. Behaviourally, performance progress was more pronounced on Day 1 compared to Day 5. Neurochemically, there was a significant difference in the modulation of neurometabolites between the S1 and MT/V5 regions, specifically in Glx levels on Day 1. Additionally, there was a significant difference in the modulation of neurometabolites between Day 1 and Day 5, specifically in GABA+ levels in the S1 area and Glx levels in the MT/V5 area. Furthermore, a greater increase in individual S1 Glx levels on Day 5 correlated with larger behavioural progress. Our findings suggest that neurometabolites in task-related sensory processing brain areas show a differential modulation and contribute to long-term retention of visuomotor learning.

Key points

GABA and glutamate play crucial roles in motor learning, yet how these neurometabolites are modulated within specific sensory processing brain regions based on the type of feedback provided during different phases of motor learning remains unclear.
We used a repeated measures magnetic resonance spectroscopy design to measure the concentration of neurometabolites in the primary somatosensory cortex (S1) and medial temporal visual area (MT/V5) before, during and after motor training, focusing on the initial and late learning phases.
In the initial learning phase, Glx (glutamate + glutamine) modulation differed between S1 and MT/V5. Furthermore, in S1, GABA modulation differed between the initial and late phases, and, in MT/V5, Glx modulation also varied between these phases. A greater increase in individual S1 Glx levels on Day 5 correlated with larger behavioural progress.
These findings suggest that distinct biological changes occur in task-related sensory processing areas across different phases of motor learning.

Abstract Image

查看原文本刊更多论文

运动学习过程中感觉加工脑区神经代谢物的调节。

GABA和谷氨酸（Glu）在学习中起着关键作用。在这里，我们研究了特定感觉处理脑区的神经代谢物是否根据运动学习过程中提供的反馈类型进行差异调节，以及这是否与行为进步有关。在接受并发（CA-VFB）或终端（TA-VFB）增强视觉反馈时，50名健康成人接受为期5天（第1天至第5天）的双手跟踪任务训练。在参与感觉加工的两个大脑区域，即初级体感皮层（S1）和内侧颞叶视觉区（MT/V5），通过在第1天和第5天的三个时间点：基线（扫描前），扫描中（中）和扫描后（扫描后）任务训练中获取磁共振波谱来测定GABA+ （GABA +大分子）和Glx （Glu +谷氨酰胺）的浓度。从行为上看，与第五天相比，第一天的表现进步更为明显。神经化学方面，S1区和MT/V5区对神经代谢物的调节存在显著差异，特别是第1天的Glx水平。此外，在第1天和第5天之间，神经代谢物的调节存在显著差异，特别是S1区GABA+水平和MT/V5区Glx水平。此外，第5天个体S1 - Glx水平的较大增加与较大的行为进步相关。我们的研究结果表明，与任务相关的感觉加工脑区的神经代谢物表现出不同的调节，并有助于视觉运动学习的长期保留。重点：GABA和谷氨酸在运动学习中起着至关重要的作用，然而这些神经代谢物是如何在特定的感觉处理脑区域内根据运动学习不同阶段提供的反馈类型进行调节的，目前尚不清楚。我们使用重复测量磁共振波谱设计来测量运动训练前、中、后初级体感皮层（S1）和内侧颞叶视觉区（MT/V5）的神经代谢物浓度，重点关注学习初期和后期阶段。在初始学习阶段，Glx（谷氨酸+谷氨酰胺）调节在S1和MT/V5之间存在差异。此外，在S1中，GABA调制在初始阶段和后期阶段有所不同，在MT/V5中，Glx调制在这些阶段之间也有所不同。第5天个体S1 - Glx水平的较大增加与较大的行为进步相关。这些发现表明，在运动学习的不同阶段，与任务相关的感觉加工区域发生了明显的生物学变化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Journal of Physiology-London 医学-神经科学

CiteScore

9.70

自引率

7.30%

发文量

817

审稿时长

2 months

期刊介绍： The Journal of Physiology publishes full-length original Research Papers and Techniques for Physiology, which are short papers aimed at disseminating new techniques for physiological research. Articles solicited by the Editorial Board include Perspectives, Symposium Reports and Topical Reviews, which highlight areas of special physiological interest. CrossTalk articles are short editorial-style invited articles framing a debate between experts in the field on controversial topics. Letters to the Editor and Journal Club articles are also published. All categories of papers are subjected to peer reivew. The Journal of Physiology welcomes submitted research papers in all areas of physiology. Authors should present original work that illustrates new physiological principles or mechanisms. Papers on work at the molecular level, at the level of the cell membrane, single cells, tissues or organs and on systems physiology are all acceptable. Theoretical papers and papers that use computational models to further our understanding of physiological processes will be considered if based on experimentally derived data and if the hypothesis advanced is directly amenable to experimental testing. While emphasis is on human and mammalian physiology, work on lower vertebrate or invertebrate preparations may be suitable if it furthers the understanding of the functioning of other organisms including mammals.