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相关概念视频

Ligand-Gated Ion Channel Receptor: Gating Mechanism01:30

Ligand-Gated Ion Channel Receptor: Gating Mechanism

Ligand-gated ion channels are transmembrane proteins that play a vital role in intercellular communication and functions of the nervous system. They allow the influx of ions across the membrane once the neurotransmitter binds, allowing the subsequent transmission of electrical excitation across the neurons. Other ligand-gated ion channels, like the γ-aminobutyric acid (GABA) receptor, permit anions like chloride into the cells on the binding of the GABA molecule. Their entry into the cell...
Drugs Acting on Autonomic Ganglia: Blockers01:28

Drugs Acting on Autonomic Ganglia: Blockers

Ganglionic blockers inhibit autonomic activity by blocking nicotinic receptors in the autonomic ganglia, suppressing impulse transmission. These blockers lack selectivity between sympathetic and parasympathetic ganglia and are ineffective as neuromuscular junction antagonists. They can be categorized into two groups:
Nondepolarizing (Competitive) Neuromuscular Blockers: Mechanism of Action01:17

Nondepolarizing (Competitive) Neuromuscular Blockers: Mechanism of Action

Nondepolarizing neuromuscular blockers induce paralysis by competitively blocking nicotinic acetylcholine receptors at the muscle end plate. Examples include pancuronium, mivacurium, vecuronium, and rocuronium. These quaternary ammonium derivatives are administered intravenously, are poorly absorbed, and are excreted via the kidneys.
Competitive antagonists prevent acetylcholine from binding to its receptor, inhibiting membrane depolarization. Without conformational changes or intrinsic...
Nondepolarizing (Competitive) Neuromuscular Blockers: Pharmacological Actions01:27

Nondepolarizing (Competitive) Neuromuscular Blockers: Pharmacological Actions

Nondepolarizing neuromuscular blockers prevent the membrane depolarization of muscle cells and inhibit muscle contraction. These are usually administered with anesthetics to achieve complete muscle relaxation. Upon administration, these drugs first block the small, rapidly contracting muscles of the face and hands, followed by the larger muscles of the trunk and the intercostal muscles. The diaphragm is the last muscle to be affected.
Although all competitive neuromuscular blockers are designed...

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相关实验视频

Updated: Jun 2, 2026

An Implantable System For Chronic In Vivo Electromyography
09:52

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Published on: April 21, 2020

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适用于可穿戴生物电子的紧可逆神经阻塞系统.

Seong Ho Yeon, Christian Landis, Guillermo Herrera-Arcos

    Annual International Conference of the IEEE Engineering in Medicine and Biology Society. IEEE Engineering in Medicine and Biology Society. Annual International Conference
    |March 5, 2025
    PubMed
    概括
    此摘要是机器生成的。

    研究人员开发了一种紧的硬件系统,用于可逆电神经阻塞,从而推进生物电子学. 这种新工具有助于研究神经回路和神经疾病,并有可能用于可穿戴的临床应用.

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    科学领域:

    • 生物电子学 生物电子学
    • 神经科学是一个神经科学.
    • 生物医学工程 生物医学工程

    背景情况:

    • 神经阻断对于研究神经功能和治疗神经系统疾病至关重要.
    • 现有的神经阻塞方法可能缺乏精度或可逆性.
    • 生物电子技术的进步为精确的神经接口提供了新的可能性.

    研究的目的:

    • 为了引入一种新的,紧的硬件架构,用于可逆电神经阻断.
    • 评估拟议系统的设计原则和性能.
    • 为了证明系统的实用性,在机床上和生物电子研究的体内环境中进行生物电子研究.

    主要方法:

    • 硬件设计和制造一个紧的电气神经阻塞系统.
    • 对系统的电气和功能参数进行基板评估.
    • 使用小鼠模型进行体内验证,以评估神经阻断的有效性和可逆性.

    主要成果:

    • 成功实现了紧的硬件架构用于神经阻断.
    • 在长板实验中展示了强大的和可逆的神经阻塞.
    • 在活体动物模型中验证系统在实现可逆神经阻塞方面的有效性.

    结论:

    • 开发的硬件架构为生物电子研究提供了多功能工具.
    • 这个系统有助于研究神经疾病和神经电路.
    • 这项技术对未来的可穿戴临床干预充满了希望.