02:00 min

Simultaneous Plethysmography and Electromyography Recording in an ALS Mouse Model

02:52 min

Real-Time Monitoring of Odorant Receptor Activation in Recombinant Cells

03:11 min

High-Resolution Imaging of Neurotransmitter Receptors at Retinal Synapses

05:12 min

Generating a Middle Cerebral Artery Occlusion in a Rat Pup to Induce Local Brain Ischemia

03:04 min

Immunostaining of Neurons in Mouse Brain Slices Following Fluorescence In Situ Hybridization

04:31 min

Immunofluorescence Staining of Gel-Embedded Patient-Derived Diseased Fibrovascular Tissue

04:06 min

Performing Double Fluorescence In Situ Hybridization to Detect Gene Expression in Mouse Brain Sections

07:03 min

Native Chromatin Immunoprecipitation of Neurosphere Cells

02:13 min

Inducing a Spinal Cord Contusion in a Mouse Model Using a Spinal Cord Injury Coaxial Platform

02:34 min

Impact of Oxygen-Glucose Deprivation and Reoxygenation on Cell-Cell Interactions

02:48 min

Developing Myopia in a Mouse Model Through Lens-Induced Defocusing

04:38 min

Inducing Massive Pontine Hemorrhage in a Rat Model by Autologous Blood Injection

Inducing Depression-like Behavior in a Mouse via Immobilization Stress

作者：

简介：

Overview

This study investigates the effects of immobilization stress on mice, focusing on the release of corticosterone and its impact on glutamate signaling. The methodology involves acclimatizing the mice and inducing chronic stress through repeated immobilization, leading to depression-like behaviors.

Key Study Components

Area of Science

Neuroscience
Behavioral Science
Stress Physiology

Background

Glutamate is an excitatory neurotransmitter crucial for signal transmission in the brain.
Chronic stress can lead to alterations in neurotransmitter systems.
Corticosterone is a stress hormone that affects neuronal function.
Understanding these mechanisms can provide insights into stress-related disorders.

Purpose of Study

To examine the effects of immobilization stress on glutamate receptor signaling.
To investigate the relationship between chronic stress and depression-like behaviors in mice.
To assess the physiological changes induced by corticosterone in the brain.

Methods Used

Isolation and acclimatization of mice in a controlled environment.
Induction of immobilization stress through a restrainer.
Measurement of corticosterone levels and behavioral assessments.
Use of a digital lux meter to control lighting conditions during testing.

Main Results

Chronic immobilization stress led to increased corticosterone release.
Reduction in the number of glutamate receptors was observed.
Mice exhibited decreased interest in activities, indicative of depression-like behaviors.
Signal transmission in neurons was impaired due to altered glutamate response.

Conclusions

Immobilization stress significantly affects neurotransmitter signaling in the brain.
Chronic stress can induce behavioral changes resembling depression.
Further research is needed to explore therapeutic interventions for stress-related disorders.

Frequently Asked Questions

What is the significance of glutamate in the brain?

Glutamate is the primary excitatory neurotransmitter, essential for synaptic transmission and plasticity.

How does immobilization stress affect mice?

It induces physiological changes that can lead to increased corticosterone levels and depression-like behaviors.

What role does corticosterone play in stress response?

Corticosterone is a hormone that mediates the body's response to stress, affecting various brain functions.

How was the stress induced in the study?

Stress was induced through repeated immobilization of the mice in a restrainer.

What behavioral changes were observed in the mice?

Mice showed decreased interest in activities, indicating depression-like behaviors.

What are the implications of this study?

The findings may help in understanding the neurobiological mechanisms underlying stress-related disorders.

Place an isolated and acclimatized mouse in a testing room under moderate lighting to avoid sudden stress.

In a stress-free state, the brain neurons release glutamate, an excitatory neurotransmitter that binds to the receptors on neighboring neurons, facilitating signal transmission.

Gently hold the mouse by the tail to prevent tensing or muscle tightening, then place it on a rough surface.

Next, position the mouse near a covered restrainer, encouraging its voluntary entry into the dark hole within the restrainer.

Immobilize the mouse in the restrainer without injury, inducing immobilization stress.

Repeat this immobilization process over multiple sessions to induce chronic stress, triggering the release of corticosterone, a stress hormone.

Corticosterone diffuses inside the neurons and binds to their glucocorticoid receptors, triggering intracellular signaling that reduces the number of glutamate receptors.

This reduces glutamate response and signal transmission, leading the mouse to develop depression-like behaviors with a decreased interest in activities.

Begin by setting the room to light at 200 lux, using a digital lux meter. House the mouse in a separate cage at least a week before testing, and place the mouse in the testing room for at least 30 minutes before the experiment. Gently hold the mouse tail to avoid tensing the mouse, and then carefully place it on a rough surface.

Cover the restrainer with a small white towel, and then gently place the mouse at the opening of the restrainer so that the mouse enters the restrainer voluntarily. Next, place the closure to restrain the mouse as tight as possible, being careful to avoid damage to the body, such as tail, feet, and testicles.

标签: ,