ganglionated

简明释义

英[ˌɡæŋɡliəˈneɪtɪd]美[ˌɡæŋɡliəˈneɪtɪd]

有神经节的

英英释义

单词用法

同义词

反义词

例句

1.Objective The study try to establish a new model of focal atrial fibrillation(AF) by stimulating the ganglionated plexus(GP) located at the base of the pulmonary veins(PVs).

目的探讨一种通过刺激自主神经结丛来建立持续局灶性心房颤动（房颤）动物模型的新方法。

2.Objective The study try to establish a new model of focal atrial fibrillation(AF) by stimulating the ganglionated plexus(GP) located at the base of the pulmonary veins(PVs).

目的探讨一种通过刺激自主神经结丛来建立持续局灶性心房颤动（房颤）动物模型的新方法。

3.The nervous system is often described as being ganglionated due to the presence of clusters of nerve cell bodies.

由于神经细胞体的聚集，神经系统常被描述为神经节状。

4.In certain animals, the ganglionated structure of their nervous system allows for rapid reflex actions.

在某些动物中，其神经系统的神经节状结构允许快速的反射动作。

5.Researchers are studying the ganglionated formations in the brains of different species to understand evolutionary differences.

研究人员正在研究不同物种大脑中的神经节状结构，以理解进化差异。

6.The ganglionated arrangement of neurons can be crucial for processing sensory information efficiently.

神经元的神经节状排列对于有效处理感官信息至关重要。

7.In medical imaging, identifying ganglionated areas can help diagnose neurological disorders.

在医学成像中，识别神经节状区域可以帮助诊断神经系统疾病。

作文

The nervous system is a complex and intricate network that plays a crucial role in the functioning of living organisms. One fascinating aspect of this system is its structure, particularly the presence of various types of neurons and ganglia. Among these, the term ganglionated refers to regions within the nervous system where groups of nerve cell bodies are clustered together. This organization allows for more efficient processing and transmission of information throughout the body. Understanding the significance of ganglionated structures can provide insights into how the nervous system operates and how it can adapt to different stimuli. In the human body, there are several key areas where ganglionated formations are found. For instance, the autonomic nervous system contains numerous ganglia that help regulate involuntary functions such as heart rate, digestion, and respiratory rate. These ganglia serve as relay points, allowing signals to be transmitted quickly and effectively. The ganglionated nature of these clusters means that they can process multiple signals simultaneously, enhancing the overall responsiveness of the body. Moreover, the study of ganglionated structures is not limited to humans; it extends to other species as well. In many animals, particularly those with more primitive nervous systems, ganglia can be observed as the primary centers for neural processing. For example, in certain invertebrates, the nervous system is organized around a series of ganglionated clusters that facilitate movement and sensory perception. This evolutionary perspective highlights the fundamental importance of ganglionated formations in the development of more complex nervous systems. Research into ganglionated networks also has significant implications for understanding neurological diseases. Conditions such as Parkinson's disease and Alzheimer's disease involve the degeneration of specific neuronal populations, including those located in ganglionated areas. By studying these regions, scientists hope to uncover the mechanisms behind these diseases and develop targeted therapies that can restore function or alleviate symptoms. Furthermore, advancements in medical technology have allowed for greater exploration of ganglionated structures through imaging techniques. These technologies enable researchers to visualize the brain and spinal cord in real-time, providing valuable data on how ganglionated networks interact during various activities. This knowledge not only enhances our understanding of normal physiological processes but also aids in diagnosing and treating neurological disorders. In conclusion, the term ganglionated encapsulates a vital aspect of the nervous system's architecture. From facilitating quick communication between nerve cells to playing a critical role in health and disease, ganglionated structures are essential for the proper functioning of living organisms. As research continues to evolve, the importance of understanding these networks will undoubtedly grow, paving the way for new discoveries in neuroscience and medicine. The more we learn about ganglionated formations, the better equipped we will be to address the challenges posed by neurological conditions and improve the quality of life for those affected by them.

神经系统是一个复杂而精细的网络，在生物体的功能中发挥着至关重要的作用。这个系统的一个迷人方面是它的结构，特别是各种类型的神经元和神经节的存在。在这些中，术语ganglionated指的是神经系统内神经细胞体聚集在一起的区域。这种组织使得信息在整个身体中更有效地处理和传递。理解ganglionated结构的重要性可以提供关于神经系统如何运作以及如何适应不同刺激的见解。 在人类身体中，有几个关键区域可以发现ganglionated形成。例如，自主神经系统包含许多神经节，帮助调节心率、消化和呼吸速率等非自愿功能。这些神经节作为中转站，允许信号快速有效地传递。ganglionated的这种集群性质意味着它们可以同时处理多个信号，从而增强身体的整体反应能力。 此外，研究ganglionated结构并不限于人类；它也扩展到其他物种。在许多动物中，特别是那些具有更原始神经系统的动物，可以观察到神经节作为神经处理的主要中心。例如，在某些无脊椎动物中，神经系统围绕一系列ganglionated集群组织，这些集群促进运动和感知。这种进化视角突显了ganglionated形成在更复杂神经系统发展中的基本重要性。 对ganglionated网络的研究也对理解神经疾病具有重要意义。帕金森病和阿尔茨海默病等疾病涉及特定神经元群体的退化，包括位于ganglionated区域的那些。通过研究这些区域，科学家希望揭示这些疾病背后的机制，并开发能够恢复功能或缓解症状的针对性疗法。 此外，医疗技术的进步使得通过成像技术更大程度地探索ganglionated结构成为可能。这些技术使研究人员能够实时可视化大脑和脊髓，为了解ganglionated网络在各种活动中的相互作用提供了宝贵的数据。这些知识不仅增强了我们对正常生理过程的理解，而且有助于诊断和治疗神经疾病。 总之，术语ganglionated概括了神经系统架构的一个重要方面。从促进神经细胞之间的快速通信到在健康和疾病中发挥关键作用，ganglionated结构对于生物体的正常功能至关重要。随着研究的不断发展，理解这些网络的重要性无疑会增加，为神经科学和医学的新发现铺平道路。我们对ganglionated形成了解得越多，就越能有效应对神经疾病带来的挑战，提高受影响者的生活质量。