Procedural Skill Initiation, Chunks & Execution; Contributions of Offline Consolidation

Bhatia, Sanjeev Rai

02 October 2013

It has been suggested that improvement in the performance of many motor sequence tasks such as playing musical instruments, operating complex machinery or tools, and/or performing a variety of athletic activities results from the learner’s ability to parse the movement into fundamental action primitives called motor chunks. Moreover, it has been suggested that the organization of motor chunks within a sequential behavior can be influenced by consolidation occurring outside the boundary of practice during which reorganization can occur leading to faster sequence production. The present study involved modest practice of a discrete sequence production task (DSPT) followed by subsequent assessment of performance of this task either immediately after the completion of practice or after a 24-hr delay. Of critical interest was the change in performance from the end of training to the test phase in three features of the sequence implementation namely sequence initiation, motor chunk transition, and element execution components. It was anticipated that motor chunk transition would be susceptible to significantly greater offline enhancement in the 24-hr delayed test case. Based on the extant literature it was also expected that sequence initiation and/or execution processes may also be sensitive to offline consolidation. No evidence emerged that supported the proposal that motor chunk transitions revealed additional gains following a longer interval between training and test. It is possible this effect was underestimated because of some imprecision in the manner in which motor chunk transitions were identified. There was clear evidence for offline gains for both sequence initiation and element execution processes. These data are difficult to interpret within the framework of a number of contemporary accounts of sequence production such as the dual-processor model in which sequence production is governed by a cognitive and motor processor.

Chunking

Motor Sequence Learning

Procedural skill

Offline enhancement

Consolidation

Neural mechanisms of speech motor learning in persons who stutter

Oh, Anna

08 April 2016

Fluent speech production requires rapid coordination among respiratory, laryngeal, and articulatory processes and is mediated by multiple neural systems (Bohland & Guenther, 2006). Stuttering is a fluency disorder characterized by core deficits in speech motor planning. Previous research indicates people who stutter (PWS) exhibit deficits in speech motor sequence learning and are slower and less accurate over practice relative to fluent speakers (Ludlow, Siren, & Zikira, 2004; Namasivayam & VanLieshout, 2004; Smits-Bandstra & De Nil, 2007; Smits-Bandstra, De Nil, & Saint-Cyr, 2006). Furthermore, the neural bases of impaired speech motor sequence learning in PWS are not well understood. We present a study in which PWS (n=18) and persons with fluent speech (PFS) (n=17) were taught phonotactically illegal (e.g. gbesb) and phonotactically legal (e.g. blerk) speech motor sequences over two practice sessions. Functional magnetic resonance imaging (fMRI) was used to investigate brain regions underlying the production of learned illegal syllables and novel illegal syllables. With practice, subjects produced syllables more accurately, which is indicative of motor sequence learning. Our findings suggest a speech motor performance deficit in PWS. Furthermore, these findings indicate speech motor sequence learning relies on a speech motor sequence learning network.

Speech therapy

fMRI

Speech

Stuttering

Motor sequence learning

Speech Motor Sequence Learning in Parkinson Disease and Normal Aging: Acquisition, Consolidation, and Automatization

Whitfield, Jason A.

01 October 2014

No description available.

Speech Therapy

Acoustics

Behavioral Sciences

Cognitive Psychology

Neurosciences

Speech Motor Sequence Learning

Parkinson disease

Aging

Motor Sequence Learning

Consolidation

Automatization

Automaticity

Dual-task

Sleep Quality

Speech Acoustics

Basal Ganglia

The role of alpha oscillations in premotor-cerebellar connectivity in motor sequence learning: Insights from transcranial alternating current stimulation

Schubert, Christine Viktoria

02 November 2023

Alpha oscillations (8-13 Hz) have been suggested to play an important role in dynamic neural processes underlying learning and memory. The goal of this work was to scrutinize the role of alpha oscillations in communication within a cortico-cerebellar network implicated in motor sequence learning. To this end, we conducted two EEG experiments using a serial reaction time task. In the first experiment, we explored changes in alpha power and cross-channel alpha coherence as subjects learned a motor sequence. We found a gradual decrease in spectral alpha power over left premotor cortex (PMC) and sensorimotor cortex (SM1) during learning blocks. In addition, alpha coherence between left PMC/SM1 and left cerebellar crus I was specifically decreased during sequence learning, possibly reflecting a functional decoupling in the broader motor learning network. In the second experiment in a different cohort, we applied 10Hz transcranial alternating current stimulation (tACS), a method shown to entrain local oscillatory activity, to left M1 (lM1) and right cerebellum (rCB) during sequence learning. We observed a tendency for diminished learning following rCB tACS compared to sham, but not following lM1 tACS. Learning-related alpha power following rCB tACS was increased in left PMC, possibly reflecting increase in local inhibitory neural activity. Importantly, learning-specific alpha coherence between left PMC and right cerebellar lobule VIIb was enhanced following rCB tACS. These findings provide strong evidence for a causal role of alpha oscillations in controlling information transfer in a premotor-cerebellar loop during motor sequence learning. Our findings are consistent with a model in which sequence learning may be impaired by enhancing premotor cortical alpha oscillation via external modulation of cerebellar oscillations.:1 List of Abbreviations 2 Introduction 2.1 Motor Learning Stages 2.2 Motor Learning Tasks 2.3 Motor Learning Network 2.4 Theoretical Models of Motor Learning 2.5 Functional Connectivity of Motor Brain Regions 2.6 Effective Connectivity of Motor Brain Regions 2.7 Oscillations in Neuronal Communication 2.8 Alpha Oscillations 2.8.1 Role of Alpha Oscillations in Motor Sequence Learning 2.9 Transcranial Electric Stimulation 2.9.1 Transcranial Alternating Current Stimulation (tACS) 2.10 Summary of Study Rationale 3 Publication 4 Summary 5 List of References 6 Supplementary Materials 7 Contribution of Authors / Darstellung des eigenen Beitrags 8 Declaration of Authorship 9 Curriculum Vitae 10 Publication and Presentation 11 Acknowledgement / Danksagung

info:eu-repo/classification/ddc/610

ddc:610

Motor Sequence Learning Deficits in Idiopathic Parkinson’s Disease Are Associated With Increased Substantia Nigra Activity

Tzvi, Elinor, Bey, Richard, Nitschke, Matthias, Brüggemann, Norbert, Classen, Joseph, Münte, Thomas F., Krämer, Ulrike M., Rumpf, Jost-Julian

27 March 2023

Previous studies have shown that persons with Parkinson’s disease (pwPD) share specific deficits in learning new sequential movements, but the neural substrates of this impairment remain unclear. In addition, the degree to which striatal dopaminergic denervation in PD affects the cortico-striato-thalamo-cerebellar motor learning network remains unknown. We aimed to answer these questions using fMRI in 16 pwPD and 16 healthy age-matched control subjects while they performed an implicit motor sequence learning task. While learning was absent in both pwPD and controls assessed with reaction time differences between sequential and random trials, larger error-rates during the latter suggest that at least some of the complex sequence was encoded. Moreover, we found that while healthy controls could improve general task performance indexed by decreased reaction times across both sequence and random blocks, pwPD could not, suggesting disease-specific deficits in learning of stimulus-response associations. Using fMRI, we found that this effect in pwPD was correlated with decreased activity in the hippocampus over time. Importantly, activity in the substantia nigra (SN) and adjacent bilateral midbrain was specifically increased during sequence learning in pwPD compared to healthy controls, and significantly correlated with sequence-specific learning deficits. As increased SN activity was also associated (on trend) with higher doses of dopaminergic medication as well as disease duration, the results suggest that learning deficits in PD are associated with disease progression, indexing an increased drive to recruit dopaminergic neurons in the SN, however, unsuccessfully. Finally, there were no differences between pwPD and controls in task modulation of the cortico-striato-thalamo-cerebellar network. However, a restricted nigral-striatal model showed that negative modulation of SN to putamen connection was larger in pwPD compared to controls during random trials, while no differences between the groups were found during sequence learning. We speculate that learning-specific SN recruitment leads to a relative increase in SN- > putamen connectivity, which returns to a pathological reduced state when no learning takes place

info:eu-repo/classification/ddc/610

ddc:610

Modulation du système glutamatergique pendant l’apprentissage moteur : une étude de spectroscopie par résonance magnétique fonctionnelle

Proulx, Sébastien

12 1900

La présente étude avait pour but d’explorer les modulations fonctionnelles putaminales du signal de spectroscopie par résonance magnétique (SRM) combiné du glutamate et de la glutamine (Glx), ainsi que de l’acide γ-aminobutyrique (GABA) en lien avec l’apprentissage d’une séquence motrice. Nous avons émis l’hypothèse que les concentrations de Glx seraient spécifiquement augmentées pendant et après la pratique d’une telle tâche, et ce comparativement à une condition d’exécution motrice simple conçue pour minimiser l’apprentissage. La tâche d’appuis séquentiels des doigts (« finger taping task ») utilisée est connue pour induire un apprentissage moteur évoluant en phases, avec une progression initialement rapide lors de la première session d’entraînement (phase rapide), puis lente lors de sessions subséquentes (phase lente). Cet apprentissage est également conçu comme dépendant de processus « on-line » (pendant la pratique) d’acquisition et « off-line » (entre les périodes de pratique) de consolidation de la trace mnésique de l’habilité motrice. Une grande quantité de données impliquent le système de neurotransmission glutamatergique, principalement par l’action de ses récepteurs N-Méthyl-D-aspartate (NMDAR) et métabotropiques (mGluR), dans une multitude de domaine de la mémoire. Quelques-unes de ces études suggèrent que cette relation s’applique aussi à des mémoires de type motrice ou dépendante du striatum. De plus, certains travaux chez l’animal montrent qu’une hausse des concentrations de glutamate et de glutamine peut être associée à l’acquisition et/ou consolidation d’une trace mnésique. Nos mesures de SRM à 3.0 Tesla, dont la qualité ne s’est avérée satisfaisante que pour le Glx, démontrent qu’une telle modulation des concentrations de Glx est effectivement détectable dans le putamen après la performance d’une tâche motrice. Elles ne nous permettent toutefois pas de dissocier cet effet putativement attribuable à la plasticité du putamen associée à l’apprentissage moteur de séquence, de celui de la simple activation neuronale causée par l’exécution motrice. L’interprétation de l’interaction non significative, montrant une plus grande modulation par la tâche motrice simple, mène cependant à l’hypothèse alternative que la plasticité glutamatergique détectée est potentiellement plus spécifique à la phase lente de l’apprentissage, suggérant qu’une seconde expérience ainsi orientée et utilisant une méthode de SRM plus sensible au Glx aurait donc de meilleures chances d’offrir des résultats concluants. / The present study explored motor learning-related functional changes in putaminal combined glutamate and glutamine (Glx) and γ-Aminobutyric acid (GABA) magnetic resonance spectroscopy (MRS) signal. It was hypothesized that Glx concentrations would specifically increase during and after learning of a sequential finger tapping task (sFTT), as compared to execution of a simple motor task designed to elicit minimal learning. Learning of sFTT is known to evolve in an initial fast progressing stage during the first practice session (fast learning stage), followed by a slower progression during later sessions (slow learning stage). It is also thought to depend on both on-line (during practice sessions) acquisition and off-line (between practice sessions) consolidation processes to create, transform and assure retention of a motor skill memory trace. A body of data implicates glutamatergic neurotransmission, especially through its N-Methyl-D-aspartate (NMDAR) and metabotropic (mGluR) receptors, in many memory systems, some of which apply to motor learning and striatal-dependant learning. Moreover, some animal studies suggest that Glx concentrations can be upregulated in relation to memory acquisition and/or consolidation. Our MRS acquisitions, of which the quality happened to be sufficient only for Glx quantification, allowed the detection of an augmentation in putaminal Glx occurring after motor task execution. However, our data could not ascribe this modulation specifically to motor learning related plastic changes, at the exclusion of simple neural activation related to motor execution. Nevertheless, the interpretation of the non-significant interaction, showing a larger Glx change in response to the simple motor task compared to sFTT, leads to the possibility that the detected glutamatergic plasticity may be specifically associated to the slow learning phase. We therefore suggest that testing this alternate hypothesis in a second experiment, using an MRS technique with more sensibility to Glx could yield more convincing results.

Glutamate

Spectroscopie par résonance magnétique

Plasticité cérébrale

Apprentissage moteur de séquence

Habileté motrice

Consolidation

Magnetic resonance spectroscopy

Neural plasticity

Motor sequence learning

Modulation du système glutamatergique pendant l’apprentissage moteur : une étude de spectroscopie par résonance magnétique fonctionnelle

Proulx, Sébastien

12 1900

La présente étude avait pour but d’explorer les modulations fonctionnelles putaminales du signal de spectroscopie par résonance magnétique (SRM) combiné du glutamate et de la glutamine (Glx), ainsi que de l’acide γ-aminobutyrique (GABA) en lien avec l’apprentissage d’une séquence motrice. Nous avons émis l’hypothèse que les concentrations de Glx seraient spécifiquement augmentées pendant et après la pratique d’une telle tâche, et ce comparativement à une condition d’exécution motrice simple conçue pour minimiser l’apprentissage. La tâche d’appuis séquentiels des doigts (« finger taping task ») utilisée est connue pour induire un apprentissage moteur évoluant en phases, avec une progression initialement rapide lors de la première session d’entraînement (phase rapide), puis lente lors de sessions subséquentes (phase lente). Cet apprentissage est également conçu comme dépendant de processus « on-line » (pendant la pratique) d’acquisition et « off-line » (entre les périodes de pratique) de consolidation de la trace mnésique de l’habilité motrice. Une grande quantité de données impliquent le système de neurotransmission glutamatergique, principalement par l’action de ses récepteurs N-Méthyl-D-aspartate (NMDAR) et métabotropiques (mGluR), dans une multitude de domaine de la mémoire. Quelques-unes de ces études suggèrent que cette relation s’applique aussi à des mémoires de type motrice ou dépendante du striatum. De plus, certains travaux chez l’animal montrent qu’une hausse des concentrations de glutamate et de glutamine peut être associée à l’acquisition et/ou consolidation d’une trace mnésique. Nos mesures de SRM à 3.0 Tesla, dont la qualité ne s’est avérée satisfaisante que pour le Glx, démontrent qu’une telle modulation des concentrations de Glx est effectivement détectable dans le putamen après la performance d’une tâche motrice. Elles ne nous permettent toutefois pas de dissocier cet effet putativement attribuable à la plasticité du putamen associée à l’apprentissage moteur de séquence, de celui de la simple activation neuronale causée par l’exécution motrice. L’interprétation de l’interaction non significative, montrant une plus grande modulation par la tâche motrice simple, mène cependant à l’hypothèse alternative que la plasticité glutamatergique détectée est potentiellement plus spécifique à la phase lente de l’apprentissage, suggérant qu’une seconde expérience ainsi orientée et utilisant une méthode de SRM plus sensible au Glx aurait donc de meilleures chances d’offrir des résultats concluants. / The present study explored motor learning-related functional changes in putaminal combined glutamate and glutamine (Glx) and γ-Aminobutyric acid (GABA) magnetic resonance spectroscopy (MRS) signal. It was hypothesized that Glx concentrations would specifically increase during and after learning of a sequential finger tapping task (sFTT), as compared to execution of a simple motor task designed to elicit minimal learning. Learning of sFTT is known to evolve in an initial fast progressing stage during the first practice session (fast learning stage), followed by a slower progression during later sessions (slow learning stage). It is also thought to depend on both on-line (during practice sessions) acquisition and off-line (between practice sessions) consolidation processes to create, transform and assure retention of a motor skill memory trace. A body of data implicates glutamatergic neurotransmission, especially through its N-Methyl-D-aspartate (NMDAR) and metabotropic (mGluR) receptors, in many memory systems, some of which apply to motor learning and striatal-dependant learning. Moreover, some animal studies suggest that Glx concentrations can be upregulated in relation to memory acquisition and/or consolidation. Our MRS acquisitions, of which the quality happened to be sufficient only for Glx quantification, allowed the detection of an augmentation in putaminal Glx occurring after motor task execution. However, our data could not ascribe this modulation specifically to motor learning related plastic changes, at the exclusion of simple neural activation related to motor execution. Nevertheless, the interpretation of the non-significant interaction, showing a larger Glx change in response to the simple motor task compared to sFTT, leads to the possibility that the detected glutamatergic plasticity may be specifically associated to the slow learning phase. We therefore suggest that testing this alternate hypothesis in a second experiment, using an MRS technique with more sensibility to Glx could yield more convincing results.

Glutamate

Spectroscopie par résonance magnétique

Plasticité cérébrale

Apprentissage moteur de séquence

Habileté motrice

Consolidation

Magnetic resonance spectroscopy

Neural plasticity

Motor sequence learning

Acquisition et consolidation de représentations distribuées de séquences motrices, mesurées par IRMf

Pinsard, Basile

09 1900

No description available.

consolidation

mémoire motrice séquentielle

sommeil

patron multivarié

similarité représentationnelle

MVPA

IRM fonctionnelle

correction de mouvement

recalage

débruitage

motor sequence learning

sleep

multivariate statistics

pattern

representational similarity

functional MRI

motion correction

realignment

denoising

Corrélats neuroanatomiques de l’apprentissage de séquences motrices chez les personnes jeunes et âgées

Vien, Catherine

05 1900

No description available.

apprentissage moteur

consolidation

matière blanche

vieillissement

sommeil

imagerie de diffusion

polysomnographie

mémoire

Motor sequence learning

White matter

Aging

Sleep

Diffusion weighted imaging

Polysomnography

Memory

肢體感測回饋對序列動作學習之影響 / The effects of body posture visual feedback on motor sequence learning

黃郁茹, Huang, Yu Ju

Unknown Date

本研究以使用者為中心之設計角度出發，探討 Kinect 提供的肢體感測回饋，如何影響序列動作學習，並試圖找出在設計回饋資訊時應注意的要素。本研究提出兩項假設，探討在序列動作學習時，有無肢體感測回饋資訊，對動作表現的影響： H1 使用者在序列動作學習時，提供其肢體感測回饋，可以提高使用者「動作部位精確度」的學習效果。 H2 使用者在序列動作學習時，提供其肢體感測回饋，可以提高使用者對「序列動作完整度」的學習效果。 本研究招募60位受測者，隨機分配到控制組與實驗組。控制組僅提供示範影片，實驗組則同時提供肢體感測回饋。受測者隨示範者練習5次後，在沒有線索輔助下，將所學的六組動作演練一次。研究者同時全程錄影演練過程。結束後，受測者需填答問卷。 透過影片分析，研究者針對「動作部位精確度」及「序列動作完整度」進行評分，以檢視控制組與實驗組在動作表現上之差異。實驗結果卻與研究預期相反，在「動作部位精確度 」與「序列動作完整度」，實驗組都表現較差，且達顯著水準。亦即提供肢體感測回饋，並未提升序列動作的精確度或完整度表現。針對此實驗結果，綜合問卷所得之受測者需求分析，本研究歸因於肢體感測回饋資訊設計不良所致。回饋訊息未能針對使用者需求設計。受測者最需要知道的資訊：動作正確與否、如何修正以及評分標準，實驗組並未能有效獲得。因此，本研究提出肢體感測回饋資訊設計上的三點建議： 1. 系統應給予學習者宏觀概念圖，事先告知學習者序列動作之項目順序。 2. 系統應讓學習者清楚瞭解每個動作之學習項目。 3. 系統除了提供學習者表現獲知的回饋資訊，更需提供修正線索。 / This research was based on user-center design thinking, and discussed how the body posture visual feedback provided by Kinect influenced the learner on motor sequence learning. We tried to find out the key elements of designing feedback. Here we proposed two hypotheses to probe the effects of body posture visual feedback on motor sequence learning: H1 When learning motor sequence, users provided body posture sensing feedback would learn better in “accuracy of moving parts”. H2 When learning motor sequence, users provided body posture sensing feedback would learn better in “completeness of sequence order”. We recruited 60 subjects, and they were distributed into control and experiment group randomly. The control group learned the motor sequence only with demonstrating video; experiment group, on the other side, were provided body posture visual feedback at the same time. All the subjects should practice the motor sequence, which included 6 items, 5 times, then tried to demonstrate the sequence without any cue. They were videotaped at the same time. After that, they should fill out a questionnaire. The researcher scored “accuracy of moving parts”, and “completeness of sequence order” through video analysis, then comparing the differences between two groups. The results were different from what we expected. The experiment group performed significantly worse than control group both in “accuracy of moving parts” and “completeness of sequence order”, which meant providing body posture visual feedback did not enhance the performance of motor sequence learning in both aspects. In the light of the results and the requirements suggested in the questionnaire by subjects, we thought the results caused by bad design of body posture visual feedback, which couldn't fit the users’ needs. The subjects didn’t get the information they need most, like the correctness of their performance, how to adjust the performance and the criteria of scroing. Therefore, we proposed three suggestions on designing body posture visual feedback: 1. The system should provide learners the macro concept of the whole sequence order in advance. 2. The system should let leaners to understand all the movements clearly and thoroughly. 3. The system should provide the information of “Knowledge of Performance”; and further, providing the hints of adjustments.

序列動作學習

肢體感測

視覺回饋

表現獲知

Kinect

Motor Sequence Learning

Body Posture Sensing

Visual Feedback

Knowledge of Performance

Kinect