cytoplasmic

简明释义

英[ˌsaɪtəʊˈplæzmɪk]美[ˌsaɪtoʊˈplæzmɪk]

adj. 细胞质的

英英释义

单词用法

同义词

反义词

例句

1.Tissue, Cytoplasmic Protein, Human Tumor, Lung.

组织，细胞质蛋白，人肿瘤，肺。

2.Tissue, Cytoplasmic Protein, Human Disease, Lupus, Kidney.

组织，细胞质蛋白，病人，狼疮，肾。

3.Ultrastructurally, the tumor cells had tapering nuclei with long, delicate cytoplasmic processes associated with prominent subplasmalemmal pinocytotic vesicles.

在超微结构上，肿瘤细胞具有逐渐变细的细胞核，且细胞核具有长而细腻的胞浆突起，并与突出的浆膜下的胞吞小泡相关。

4.Tissue, Cytoplasmic Protein, Human Disease, Lupus, Heart.

组织，细胞质蛋白，病人，狼疮，心脏。

5.Tissue, Cytoplasmic Protein, Human Tumor, Spleen.

组织，细胞质蛋白，人肿瘤，脾。

6.Tissue, Cytoplasmic Protein, Human Fetal Normal, Small intestine.

组织，细胞质蛋白，人正常胚胎，小肠。

7.Tissue, Cytoplasmic Protein, Human Disease, Lupus, Colon.

组织，细胞质蛋白，病人，狼疮，肠。

8.Tissue, Cytoplasmic Protein, Human Tumor, Pharynx.

组织，细胞质蛋白，人肿瘤，咽。

9.Tissue, Cytoplasmic Protein, Human Tumor, Bone.

组织，细胞质蛋白，人肿瘤，骨。

10.The study focused on the role of cytoplasmic 细胞质的 proteins in cell signaling.

这项研究集中在细胞质的蛋白质在细胞信号传导中的作用。

11.Researchers observed cytoplasmic 细胞质的 streaming during the fertilization process.

研究人员观察到在受精过程中有细胞质的流动现象。

12.In plant cells, cytoplasmic 细胞质的 connections are crucial for nutrient transport.

在植物细胞中，细胞质的连接对营养物质运输至关重要。

13.The cytoplasmic 细胞质的 matrix contains various organelles.

细胞质的基质包含各种细胞器。

14.Defects in cytoplasmic 细胞质的 functions can lead to diseases.

在细胞质的功能中出现缺陷可能导致疾病。

作文

The study of cells is fundamental to understanding life itself. One of the most important components of a cell is its cytoplasm, which is often described as the gel-like substance that fills the interior of the cell. Within this context, the term cytoplasmic refers to anything related to the cytoplasm. The cytoplasmic matrix is where many critical cellular processes occur, including metabolic pathways and the synthesis of proteins. In a typical eukaryotic cell, the cytoplasmic environment contains various organelles such as mitochondria, endoplasmic reticulum, and Golgi apparatus, all suspended in the cytoplasmic fluid. Each of these organelles plays a specific role in maintaining the cell's health and functionality. For instance, mitochondria are known as the powerhouses of the cell, converting nutrients into energy through cellular respiration, while the endoplasmic reticulum is involved in the synthesis and transport of proteins and lipids. Moreover, the cytoplasmic structure is not static; it is dynamic and constantly changing. The movement of materials within the cytoplasmic space is essential for cellular communication and function. This movement is facilitated by a network of protein filaments known as the cytoskeleton, which helps maintain the cell's shape and allows for intracellular transport. The cytoskeleton consists of microtubules, intermediate filaments, and actin filaments, each contributing to the overall organization and movement within the cytoplasmic area. Understanding the cytoplasmic components of a cell is crucial for several fields, including medicine and biotechnology. For example, when studying diseases such as cancer, researchers focus on the changes that occur in the cytoplasmic signaling pathways. Abnormalities in these pathways can lead to uncontrolled cell growth and division, which are hallmarks of cancer. By targeting these cytoplasmic signals, scientists hope to develop more effective treatments. Additionally, advancements in microscopy have allowed scientists to visualize the cytoplasmic structures in real-time, providing insights into how cells respond to their environments. Techniques such as fluorescence microscopy enable researchers to tag specific proteins within the cytoplasmic space, allowing them to observe cellular processes as they happen. This has opened new avenues for research, particularly in understanding how cells communicate and coordinate their activities. In conclusion, the term cytoplasmic encompasses a wide range of functions and structures that are vital for cellular life. From the basic mechanics of cellular metabolism to the complex interactions involved in disease progression, the cytoplasmic environment is central to our understanding of biology. As research continues to evolve, the importance of cytoplasmic studies will only grow, highlighting the intricate dance of life at the cellular level.

细胞的研究是理解生命本身的基础。细胞中最重要的组成部分之一是细胞质，通常被描述为填充细胞内部的凝胶状物质。在这个背景下，术语cytoplasmic指的是与细胞质相关的任何事物。cytoplasmic基质是许多关键细胞过程发生的地方，包括代谢途径和蛋白质合成。 在典型的真核细胞中，cytoplasmic环境包含各种细胞器，如线粒体、内质网和高尔基体，所有这些细胞器都悬浮在cytoplasmic液体中。这些细胞器中的每一个都在维持细胞的健康和功能方面发挥着特定的作用。例如，线粒体被称为细胞的动力源，通过细胞呼吸将营养物质转化为能量，而内质网则参与蛋白质和脂质的合成与运输。 此外，cytoplasmic结构并不是静态的；它是动态的，并且不断变化。材料在cytoplasmic空间内的运动对于细胞间的沟通和功能至关重要。这种运动是通过一种称为细胞骨架的蛋白质丝网来促进的，细胞骨架有助于维持细胞的形状并允许细胞内运输。细胞骨架由微管、中间丝和肌动蛋白丝组成，每种成分都有助于cytoplasmic区域的整体组织和运动。 理解细胞的cytoplasmic成分对于包括医学和生物技术在内的多个领域至关重要。例如，在研究癌症等疾病时，研究人员关注cytoplasmic信号通路中发生的变化。这些通路的异常可能导致细胞的无控制生长和分裂，这是癌症的标志性特征。通过针对这些cytoplasmic信号，科学家希望开发出更有效的治疗方法。 此外，显微镜技术的进步使科学家能够实时可视化cytoplasmic结构，从而提供对细胞如何响应其环境的见解。荧光显微镜等技术使研究人员能够标记cytoplasmic空间内的特定蛋白质，从而观察细胞过程的实时发生。这为研究开辟了新的途径，特别是在理解细胞如何沟通和协调其活动方面。 总之，术语cytoplasmic涵盖了一系列对细胞生命至关重要的功能和结构。从细胞代谢的基本机制到涉及疾病进程的复杂相互作用，cytoplasmic环境是我们理解生物学的核心。随着研究的不断发展，cytoplasmic研究的重要性只会增加，突显出细胞层面上生命的复杂舞蹈。