Monitoring Fine and Associative Motor Learning in Mice Using the Erasmus Ladder

Alice Staffa; Moumita Chatterjee; Ariadna Diaz-Tahoces; Felix Leroy; Isabel Perez-Ota&#241;o

doi:10.3791/65958

Erasmus Ladder를 사용한 생쥐의 미세 및 연상 운동 학습 모니터링

JoVE Journal
Neuroscience

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JoVE Journal Neuroscience

Monitoring Fine and Associative Motor Learning in Mice Using the Erasmus Ladder

Erasmus Ladder를 사용한 생쥐의 미세 및 연상 운동 학습 모니터링

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08:51 min

December 15, 2023

DOI: 10.3791/65958-v

Alice Staffa*¹, Moumita Chatterjee*¹, Ariadna Diaz-Tahoces*¹, Felix Leroy¹, Isabel Perez-Otaño¹

¹Instituto de Neurociencias, Sant Joan d’Alacant,Spain - Consejo Superior de Investigaciones Científicas and Universidad Miguel Hernández

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Overview

This article presents a protocol for assessing fine motor performance and motor learning using the Erasmus Ladder in a non-invasive, automated manner. The focus is on evaluating different aspects of motor behavior and understanding underlying neural mechanisms in both healthy and disease models.

Key Study Components

Area of Science

Neuroscience
Motor Learning
Behavioral Assessment

Background

Investigates brain plasticity and neural circuits involved in motor function.
Current methods lack sensitivity and require extensive time and resources.
The Erasmus Ladder enables a more efficient and accurate assessment of motor learning.
Focus on myelin plasticity as it relates to complex motor skill learning.

Purpose of Study

To establish an automated protocol for evaluating motor performance in mice.
To differentiate among types of motor learning in a streamlined manner.
To provide a robust framework that can be adapted for various experimental needs.

Methods Used

The Erasmus Ladder platform is used for non-invasive motor performance assessment.
Mice are tested to evaluate motor skill learning and associative learning.
Multiple experimental protocols can be customized based on research needs.
Data collection and analysis are automated to enhance precision.

Main Results

Showed significant learning curves in motor performance over time.
Highlighted the reduction in missteps during ladder crossings, indicating improved learning.
Performance variations were noted in undisturbed and challenge trials, underscoring adaptability.
Results suggest the Erasmus Ladder is an effective tool for studying motor learning in both healthy and diseased states.

Conclusions

This protocol demonstrates a significant advancement in studying fine motor behaviors.
The methodology can ultimately aid in understanding the neural mechanisms behind motor learning and dysfunction in diseases.
Encourages further research by allowing diverse experimental designs within a single framework.

Frequently Asked Questions

What are the advantages of using the Erasmus Ladder?

The Erasmus Ladder offers a non-invasive, automated method for assessing fine motor performance, enhancing accuracy and reducing resource needs compared to traditional methods.

How is the biological model implemented in this study?

Mice are used as the primary biological model, with various motor learning tasks customized based on experimental goals, enabling the study of both healthy and disease-affected behaviors.

What types of data are obtained using the Erasmus Ladder?

Data on motor performance, learning progress, anxiety responses, and baseline motivation can be obtained, allowing comprehensive analysis of motor behavior.

How can this method be adapted for different studies?

The protocol can be customized in terms of trial types and parameters, accommodating a wide range of research questions in motor learning and plasticity.

What are the limitations of using the Erasmus Ladder?

While the Erasmus Ladder enhances data collection efficiency, careful consideration of experimental design and mouse cohort selection is crucial to avoid variability in results.

How does this study contribute to understanding motor learning?

It provides insights into different types of motor learning processes and their underlying neural mechanisms, which is essential for targeting interventions in motor dysfunction.

이 기사에서는 Erasmus Ladder라는 장치를 사용하여 소근육 운동 성능에 대한 비침습적이고 자동화된 평가와 도전에 대한 적응 및 연상 운동 학습을 허용하는 프로토콜을 제시합니다. 작업 난이도를 적정하여 주요 정도에서 미묘한 정도에 이르는 운동 장애를 감지할 수 있습니다.

실험실에서는 뇌 가소성을 연구합니다. 우리의 목표 중 하나는 관여하는 신경 회로와 메커니즘을 식별하고 질병의 잘못된 점을 이해하여 부족한 개입에 적합한 표적을 찾을 수 있도록 하는 것입니다. 우리의 중요한 요구 사항 중 하나는 건강한 마우스와 질병 모델에서 유전자 조작의 영향을 평가하고, 가소성을 유도하고, 평가하기 위한 강력한 교육 프로토콜을 갖추는 것입니다.

현재 연구에서는 쥐의 행동을 평가하기 위해 민감하고 다재다능하며 자동화된 기술이 필요합니다. 우리는 주로 운동 행동 학습에 관심이 있으며 전통적인 테스트는 순차적 구현이 필요하므로 상당한 시간과 자원이 소비됩니다. 또한 기존 테스트의 정확도가 항상 충분한 것은 아닙니다.

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