electrocyte

简明释义

英[ɪˈlɛktrəˌsaɪt]美[ɪˈlɛktrəˌsaɪt]

发电细胞

英英释义

单词用法

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反义词

例句

1.All fish generate electricity with a specialized type of cell called an electrocyte.

所有使用电场的鱼类都使用一种专门发电的细胞来产生电流。

2.All fish generate electricity with a specialized type of cell called an electrocyte.

所有使用电场的鱼类都使用一种专门发电的细胞来产生电流。

3.The research focused on the role of electrocytes in generating electric fields in certain fish species.

这项研究集中在电细胞在某些鱼类中产生电场的作用。

4.Scientists discovered that electrocytes can be used to develop bioelectric devices.

科学家发现电细胞可以用于开发生物电设备。

5.In electric eels, electrocytes are stacked to produce a powerful shock.

在电鳗中，电细胞被堆叠以产生强大的电击。

6.The study of electrocytes is crucial for understanding bioelectricity in marine life.

对电细胞的研究对于理解海洋生物中的生物电现象至关重要。

7.Researchers are exploring how electrocytes can inspire new technologies in renewable energy.

研究人员正在探索电细胞如何激发可再生能源的新技术。

作文

In the fascinating world of biology, there are many specialized cells that perform unique functions. One such cell is the electrocyte, which plays a crucial role in the generation of electric fields in certain species of fish. Understanding the function and significance of electrocytes can illuminate the intricate relationship between anatomy and behavior in aquatic environments. The term electrocyte refers to a type of cell that is capable of generating electricity. These cells are primarily found in electric fish, such as the electric eel and the knifefish. The biology of these fish is remarkable; they have evolved to develop specialized organs composed of numerous electrocytes that work together to produce electric discharges. When an electrocyte is stimulated, it undergoes a rapid change in membrane potential, resulting in the movement of ions across the cell membrane. This movement generates a small electric current. However, when thousands of electrocytes are activated simultaneously, the cumulative effect produces a significant electric shock that can be used for navigation, communication, and even stunning prey. The study of electrocytes not only reveals the complexity of biological systems but also highlights the evolutionary adaptations that allow certain species to thrive in their environments. For instance, electric eels can generate up to 600 volts, a remarkable feat that serves various purposes, from hunting to self-defense. This adaptation showcases how nature has optimized cellular mechanisms for survival. Moreover, electrocytes serve as a fascinating subject for scientific research. Understanding how these cells function at a molecular level can lead to advancements in bioengineering and medicine. Researchers are exploring the potential applications of electrocytes in developing bio-inspired technologies, such as artificial muscles and energy storage systems. By mimicking the properties of these cells, scientists aim to create innovative solutions that could transform various industries. In addition to their biological and technological significance, electrocytes also raise intriguing questions about the nature of electricity and its role in living organisms. The ability of fish to generate electric fields challenges our traditional understanding of sensory perception and communication. It opens up new avenues of exploration in the fields of neurobiology and ecology, prompting researchers to investigate how electric signals influence social interactions among fish. In conclusion, the electrocyte is a remarkable cell that exemplifies the wonders of evolution and adaptation in the natural world. Its ability to generate electricity not only aids in the survival of electric fish but also inspires scientific innovation. As we continue to study electrocytes, we gain deeper insights into the complexities of life and the potential for harnessing biological principles for technological advancement. The exploration of these unique cells represents a blend of biology, technology, and ecology, underscoring the interconnectedness of all living things.

在生物学的迷人世界中，有许多专门的细胞执行独特的功能。其中一种细胞是电细胞，它在某些鱼类产生电场的过程中发挥着关键作用。理解电细胞的功能和重要性可以阐明解剖学与水生环境行为之间的复杂关系。 术语电细胞指的是一种能够产生电力的细胞。这些细胞主要存在于电鱼中，例如电鳗和刀鱼。这些鱼的生物学非常显著；它们进化出了由众多电细胞组成的特殊器官，这些细胞共同作用以产生电击。 当一个电细胞受到刺激时，它的膜电位会迅速变化，导致离子穿过细胞膜移动。这种运动会产生微小的电流。然而，当成千上万的电细胞同时被激活时，累积效应会产生显著的电击，可以用于导航、交流甚至震撼猎物。 对电细胞的研究不仅揭示了生物系统的复杂性，还突出了某些物种在其环境中生存的进化适应性。例如，电鳗可以产生高达600伏的电压，这是一个显著的成就，服务于从狩猎到自我防御的各种目的。这种适应展示了自然如何优化细胞机制以实现生存。 此外，电细胞也是科学研究中的一个迷人主题。了解这些细胞在分子水平上的功能可以推动生物工程和医学的进步。研究人员正在探索电细胞在开发仿生技术方面的潜在应用，例如人工肌肉和能量储存系统。通过模仿这些细胞的特性，科学家们旨在创造出可能改变各个行业的创新解决方案。 除了生物学和技术的重要性，电细胞还提出了有关电的本质及其在生物体中作用的有趣问题。鱼类生成电场的能力挑战了我们对感知和交流的传统理解。它为神经生物学和生态学领域的探索开辟了新的途径，促使研究人员调查电信号如何影响鱼类之间的社会互动。 总之，电细胞是一种非凡的细胞，体现了自然界进化和适应的奇迹。它产生电力的能力不仅有助于电鱼的生存，还激励着科学创新。随着我们继续研究电细胞，我们对生命复杂性的理解将更加深入，并且有潜力利用生物原理推动技术进步。这些独特细胞的探索代表了生物学、技术和生态学的结合，强调了所有生物之间的相互联系。