ganglionic

简明释义

英[ˌɡæŋɡliˈɒnɪk]美[ˌɡæŋɡlɪˈɑːnɪk]

adj. 神经节的

英英释义

单词用法

同义词

反义词

例句

1.Conclusion 1. TH mRNA and TH appearing in same intrinsic cardiac ganglionic neuron demonstrate that a part of intrinsic cardiac ganglionic neurons are possibly adrenergic sympathetic neurons;

结论1证明部分心内神经节的细胞内既出现TH的基因表达 ，同时又有TH ，可能是肾上腺素能的交感神经细胞 ；

2.Conclusion 1. TH mRNA and TH appearing in same intrinsic cardiac ganglionic neuron demonstrate that a part of intrinsic cardiac ganglionic neurons are possibly adrenergic sympathetic neurons;

结论1证明部分心内神经节的细胞内既出现TH的基因表达 ，同时又有TH ，可能是肾上腺素能的交感神经细胞 ；

3.Objective To study and discuss the function of spiral ct in finding basal ganglionic lacunar infarction when ct is scanning traumatic skull.

目的：着重研究讨论螺旋性CT在扫描外伤性头颅时发现基底节区腔隙性梗死的作用。

4.The retina was sectioned for counting the cells in the ganglionic layer of the optic nerve and quantitating optic nerve lesion.

然后进行视网膜切片，计数视神经节细胞层细胞，定量视神经损伤。

5.Apoptosis cells were observed in detached retina, mainly in inner nuclear layer, outer nuclear layer and ganglionic cell layer.

脱离的视网膜在内、外核层发现凋亡标记阳性细胞。

6.Major Topics: Anatomy and Physiology of the Retina, Ganglion-cell Receptive Field Organization, Pre-ganglionic Elements.

主要题目：视网膜的解剖和生理，神经节细胞接收区组成，前神经节元件。

7.Objective: To evaluate the value of MR Imaging (MRI) in diagnosing brachial plexus pre-ganglionic injury.

目的：探讨MRI检查在诊断臂丛神经节前损伤中的影像表现和诊断价值。

8.It suggested that SS was synthesized and stored in rat intrinsic cardiac ganglionic cells.

表明大鼠心内神经节细胞有SS合成和贮存。

9.N-methyl-D-aspartate receptor, and ganglionic acetylcholine receptor in 1 patient each.

甲基-D-天冬氨酸受体，神经节的乙酰胆碱受体。

10.There was no dark cells in ganglionic layer.

神经节细胞层无暗细胞。

11.The doctor explained that the pain was due to a malfunction in the ganglionic 神经节的 system.

医生解释说，疼痛是由于神经节的系统故障引起的。

12.Research on ganglionic 神经节的 cells can provide insights into neurodegenerative diseases.

对神经节的细胞的研究可以为神经退行性疾病提供见解。

13.The ganglionic 神经节的 pathways are crucial for transmitting signals in the nervous system.

这些神经节的通路对于在神经系统中传递信号至关重要。

14.They discovered that the ganglionic 神经节的 activity was altered in patients with chronic pain.

他们发现慢性疼痛患者的神经节的活动发生了改变。

15.The study focused on the role of ganglionic 神经节的 neurons in regulating heart rate.

该研究集中于神经节的神经元在调节心率中的作用。

作文

The human body is an intricate network of systems that work together to maintain homeostasis and support life. Among these systems, the nervous system plays a crucial role in transmitting signals throughout the body. One of the key components of the nervous system is the ganglia, which are clusters of nerve cell bodies. The term ganglionic refers to anything related to these ganglia. Understanding the ganglionic structures and their functions is essential for comprehending how our nervous system operates. Ganglia serve as relay points for nerve signals, acting as hubs where information is processed before being transmitted to other parts of the body. For example, the autonomic nervous system, which controls involuntary bodily functions such as heart rate and digestion, relies heavily on ganglionic connections. These connections help regulate physiological responses to stress, ensuring that the body can react appropriately to different situations. In addition to their role in the autonomic nervous system, ganglionic structures are also involved in sensory processing. Sensory ganglia receive input from various sensory receptors located throughout the body, such as those for touch, pain, and temperature. Once this information is gathered, it is relayed to the central nervous system, where it is interpreted and acted upon. This process underscores the importance of ganglionic pathways in our ability to perceive and interact with the environment around us. Moreover, research into ganglionic activity has significant implications for understanding neurological disorders. Conditions such as Parkinson's disease and multiple sclerosis involve disruptions in the normal functioning of the nervous system, often linked to abnormalities in ganglionic signaling. By studying these pathways, scientists can develop targeted therapies aimed at restoring proper function and alleviating symptoms. Another fascinating aspect of ganglionic structures is their role in the development of the nervous system. During embryonic development, neurons migrate and form ganglionic clusters, which are vital for establishing the overall architecture of the nervous system. This process is tightly regulated, and any disruptions can lead to developmental disorders. In conclusion, the term ganglionic encompasses a wide range of functions and implications within the nervous system. From facilitating communication between different parts of the body to playing a pivotal role in sensory processing and disease mechanisms, ganglionic structures are fundamental to our understanding of biology. As research continues to evolve, the insights gained from studying ganglionic pathways will undoubtedly enhance our knowledge of both healthy and diseased states, paving the way for innovative treatments and interventions. Understanding the intricacies of ganglionic functions not only enriches our comprehension of human physiology but also underscores the remarkable complexity of the biological systems that sustain life.

人体是一个复杂的系统网络，各个系统协同工作以维持体内平衡并支持生命。在这些系统中，神经系统在信号传递中扮演着至关重要的角色。神经系统的关键组成部分之一是神经节，它是神经细胞体的簇。术语ganglionic指的是与这些神经节相关的任何事物。理解ganglionic结构及其功能对于理解我们的神经系统如何运作至关重要。 神经节作为神经信号的中转站，充当信息处理的中心，然后将其传递到身体的其他部分。例如，自主神经系统控制着心率和消化等不自主的身体功能，这一系统在很大程度上依赖于ganglionic连接。这些连接帮助调节对压力的生理反应，确保身体能够适当地应对不同的情况。 除了在自主神经系统中的作用，ganglionic结构还参与感官处理。感觉神经节接收来自身体各个感觉受体的信息，例如触觉、疼痛和温度。一旦这些信息被收集，它就会被传递到中枢神经系统，在那里进行解释和处理。这一过程突显了ganglionic通路在我们感知和与周围环境互动能力中的重要性。 此外，对ganglionic活动的研究对理解神经系统疾病具有重要意义。帕金森病和多发性硬化症等疾病涉及神经系统正常功能的干扰，通常与ganglionic信号的异常有关。通过研究这些通路，科学家们可以开发针对性的疗法，旨在恢复正常功能并缓解症状。 ganglionic结构的另一个迷人方面是它们在神经系统发育中的作用。在胚胎发育过程中，神经元迁移并形成ganglionic簇，这对建立神经系统的整体结构至关重要。这个过程受到严格调控，任何干扰都可能导致发育障碍。 总之，术语ganglionic涵盖了神经系统内广泛的功能和影响。从促进身体不同部分之间的沟通，到在感官处理和疾病机制中发挥关键作用，ganglionic结构对于我们理解生物学至关重要。随着研究的不断发展，研究ganglionic通路所获得的见解无疑将增强我们对健康和疾病状态的知识，为创新的治疗和干预铺平道路。理解ganglionic功能的复杂性不仅丰富了我们对人体生理的理解，也强调了维持生命的生物系统的惊人复杂性。