<em>In Vivo</em> Calcium Imaging of Neuronal Ensembles in Networks of Primary Sensory Neurons in Intact Trigeminal Ganglia

John Shannonhouse; Hyeonwi Son; Yan Zhang; Eungyung Kim; Deoksoo Han; Ruben Gomez; Joon Tae Park; Yu Shin Kim

doi:10.3791/68284

インビボ無傷の三叉神経節における一次感覚ニューロンのネットワークにおけるニューロンアン...

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Neuroscience

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JoVE Journal Neuroscience

In Vivo Calcium Imaging of Neuronal Ensembles in Networks of Primary Sensory Neurons in Intact Trigeminal Ganglia

インビボ無傷の三叉神経節における一次感覚ニューロンのネットワークにおけるニューロンアンサンブルのカルシウムイメージング

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07:55 min

August 1, 2025

DOI: 10.3791/68284-v

John Shannonhouse^1,2, Hyeonwi Son^1,2, Yan Zhang^1,2, Eungyung Kim^1,2, Deoksoo Han^1,2, Ruben Gomez^1,2, Joon Tae Park^2,3, Yu Shin Kim^1,2,4

¹Department of Oral & Maxillofacial Surgery, School of Dentistry,University of Texas Health Science Center at San Antonio, ²Department of Endodontics, School of Dentistry,University of Alabama at Birmingham, ³Division of Life Sciences, College of Life Sciences and Bioengineering,Incheon National University, ⁴Programs in Integrated Biomedical Sciences, Translational Sciences, Biomedical Engineering, Radiological Sciences,University of Texas Health Science Center at San Antonio

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Overview

This protocol details in vivo GCaMP calcium imaging of trigeminal ganglion (TG) neurons to investigate peripheral ganglia neural networks related to pain, itch, and touch sensation. It provides step-by-step instructions for TG exposure surgery, in vivo confocal microscopy imaging, and analysis of calcium imaging data generated from neuronal activity.

Key Study Components

Area of Science

Neuroscience
Neuroimaging
Neural Networks

Background

The study addresses the challenges in observing neuronal activity in vivo under physiological conditions.
It focuses on the mechanisms of pain and sensory perception through TG neuron activation.
Understanding calcium dynamics in intact neurons is critical for advancing knowledge in pain and sensory research.

Purpose of Study

To develop a reliable protocol for studying trigeminal ganglion neural activation in response to somatic stimuli.
To complement existing behavioral, cell culture, and immunohistochemistry datasets.
To facilitate the investigation of immediate neuronal responses to various stimuli or drugs.

Methods Used

In vivo GCaMP calcium imaging was employed using confocal microscopy.
The primary biological model involved intact trigeminal ganglion neurons in anesthetized mice.
The protocol includes detailed surgical procedures to expose TG and imaging methodologies before and during stimulation.
Data acquisition involves implementing high-speed and high-resolution scanning protocols to capture neuronal activity.
The analysis includes calculating calcium transient intensities and measuring neuronal diameters for a thorough evaluation.

Main Results

Imaging revealed simultaneous visualization of over 3,000 neurons, capturing both spontaneous and stimulus-evoked calcium signals.
Stimulation of different TG regions showed distinct activation patterns in response to various mechanical and thermal stimuli.
Higher mechanical loads resulted in greater neuronal responsiveness, with notable variances in calcium transient intensity based on stimulus strength.

Conclusions

This study demonstrates a method for observing in vivo neuronal activity and how it can enhance our understanding of sensory processing.
The protocol enables insights into the immediate impact of stimuli on neuronal populations, crucial for sensory research.
This technique has significant implications for investigating mechanisms involved in pain and sensory disorders.

Frequently Asked Questions

What are the advantages of in vivo calcium imaging?

In vivo calcium imaging allows researchers to observe real-time neuronal activity and interactions in a living organism, providing insights into physiological processes that cannot be mimicked in vitro.

How is the trigeminal ganglion accessed for imaging?

The protocol involves making a precise surgical incision and drilling a hole in the skull to expose the trigeminal ganglion for imaging without removing any cortical tissue.

What types of stimuli can be applied during imaging?

Mechanical stimuli such as Von Frey filaments and thermal stimuli can be applied to assess the responsiveness of trigeminal neurons during imaging sessions.

How are the imaging data analyzed?

Data analysis involves measuring calcium transient intensities, neuron diameters, and comparing responses across different stimuli and neuronal populations.

What are the limitations of this protocol?

Challenges include ensuring consistent imaging quality and avoiding damage to surrounding tissues during the surgical procedure, which may affect neuronal responses.

このプロトコルは、無傷の三叉神経節(TG)ニューロンの in vivoGCaMPカルシウムイメージングを記述します。この説明には、TG 曝露手術、TG ニューロンの in vivo 共焦点顕微鏡イメージング、TG ニューロン顕微鏡イメージング中の体細胞刺激の適用、および in vivo GCaMP カルシウムイメージングデータの分析が含まれます。

本研究は末梢神経節ニューラルネットワークに焦点を当て、痛み、かゆみ、触覚に関わる信号や細胞間相互作用の理解を目指しています。ニューロンは刺激を感知しますが、通常の生理学的条件下での in vivo での活動を研究することは依然として非常に困難です。私たちのプロトコルは、刺激に反応して集団レベルでの三叉神経節神経活性化の研究を可能にしますが、これは生理学的に重要ですが、技術的には非常に困難です。

このプロトコルによって生成されたデータは、行動、細胞培養、および免疫組織化学データを強力に補完するものとして機能し、神経節全体に対する刺激または薬物の即時効果の調査を可能にします。まず、麻酔をかけたマウスを温熱パッドの上に置き、体温を摂氏37度に維持し、頭を定位マスクに約15度左に傾けて配置します。乾燥や炎症を防ぐために、目に眼科用軟膏を塗ります。

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