Restraint to Induce Stress in Mice and Rats

Karl T. Schmidt

doi:10.3791/67387

JoVE Journal
Neuroscience

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JoVE Journal Neuroscience

Restraint to Induce Stress in Mice and Rats

マウスおよびラットにおけるストレス誘発抑制

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03:48 min

December 6, 2024

DOI: 10.3791/67387-v

Karl T. Schmidt¹

¹Department of Psychological and Brain Sciences,Fairfield University

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Overview

This article discusses methods for inducing stress responses in rodent models, specifically using physical restraint stress in mice and rats. The research examines how stress impacts neurobiological mechanisms, particularly concerning substance use disorders, and evaluates the effects on noradrenergic systems following stress exposure.

Key Study Components

Area of Science

Neuroscience
Psychobiology
Animal models of stress

Background

Stress can significantly influence behavioral responses and neurobiological processes.
The link between stress and substance use disorders is an area of active research.
Restraint stress is a commonly used method due to its ease of use and adaptability.
Noradrenergic signaling alterations have been associated with heightened arousal and PTSD.

Purpose of Study

To investigate the behavioral effects of stress and its relation to substance use disorders.
To assess the physiological changes in noradrenergic systems resulting from stress exposure.
To provide a detailed methodology for implementing physical restraint stress in rodent models.

Methods Used

Rodent models, specifically mice and rats, were utilized for the stress exposure studies.
Physical restraint was applied using modified conical tubes to ensure ventilation.
The selected groups included home cage control, acute restraint stress, and chronic restraint stress.
Stress exposure duration was defined based on group assignments, with monitoring every 20 minutes during restraint.
Post-stress, animals were returned to their home cages, and physiological changes were assessed.

Main Results

Plasma corticosterone levels increased significantly after single stress exposure.
Repeated stress resulted in a reduction of corticosterone levels compared to naive controls.
Altered norepinephrine release was noted across various stimulation parameters following stress exposure.
These findings highlight the lasting impact of stress on neurochemical systems.

Conclusions

The study validates the use of restraint stress as a model for investigating the neurobiological impacts of stress.
The insights into noradrenergic alterations can inform approaches to substance use disorder interventions.
Overall, this research enhances understanding of the mechanistic pathways linking stress and behavioral disorders.

Frequently Asked Questions

What are the advantages of using restraint stress in research?

Restraint stress is cost-effective and easy to perform, allowing researchers to model aspects of various human disorders.

How is the restraint stress method implemented?

Mice or rats are placed in modified conical tubes with ventilation, and their physical behavior is monitored during and after the stress exposure.

What biological responses are observed following stress exposure?

Notable changes include increased corticosterone levels and altered norepinephrine release, both relevant to stress-related disorders.

How can this method be adapted for different studies?

The parameters of stress exposure—such as duration and frequency—can be modified to investigate various neurobiological outcomes.

What key limitations should be considered when using this model?

Consideration must be given to the individual variability in stress response and potential welfare issues associated with physical restraint.

What are some future research directions following this study?

Future studies may focus on the specific mechanisms underlying altered drug-induced behaviors resulting from stress exposure.

この記事では、マウスとラットの身体拘束ストレスを使用してストレス応答を誘発する手順について説明します。げっ歯類モデルで拘束応力を選択して使用する際に注意すべき追加の考慮事項について説明します。

私の研究は、ストレスの影響に影響を与える神経生物学的メカニズム、乱用薬物の行動への影響、および両者の交差に焦点を当てています。要するに、私の研究室では、ストレス体験が物質使用障害にどのように寄与するか、そしてこの関係に対処するための介入をどのように開発できるかに答えようとしています。私の研究によると、ストレスへの曝露は、ストレスの経験を超えて持続する方法でノルアドレナリン作動性システムを変化させることが示されています。

ノルアドレナリン作動性シグナル伝達のこれらの増加は、PTSDやその他の障害に特徴的な覚醒反応の高まりを強調する可能性があります。.他のストレス誘発アプローチと比較して、拘束は安価で、実行が容易で、不安、うつ病、物質使用障害、心的外傷後ストレス障害などの人間の障害の側面をモデル化するのに有用であり、幅広いパラメーターで適応できます。今後、私の研究室では、ストレスや曝露による薬物誘発性行動の変化の根底にあるメカニズムに焦点を当てていきます。

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