electrogenic

简明释义

英[/ɪˌlɛktroʊˈdʒɛnɪk/]美[/ɪˌlɛktroʊˈdʒɛnɪk/]

adj. 产生电的

英英释义

单词用法

同义词

反义词

例句

1.Marked differences were observed in the electrogenic property natdependence of mucosal influx and sensitivity to phlorizin.

观察到了生电性质、黏膜注入和根皮苷敏感性方面显著的区别。

2.Marked differences were observed in the electrogenic property natdependence of mucosal influx and sensitivity to phlorizin.

观察到了生电性质、黏膜注入和根皮苷敏感性方面显著的区别。

3.The research team discovered a new type of bacteria that is highly electrogenic 电生性的, capable of generating electricity from organic matter.

研究小组发现了一种新型细菌，具有很强的电生性电生性的，能够从有机物中产生电能。

4.In bioengineering, electrogenic 电生性的 microbes are used to create sustainable energy solutions.

在生物工程中，电生性电生性的微生物被用来创造可持续的能源解决方案。

5.The electrogenic 电生性的 properties of certain algae have attracted attention for biofuel production.

某些藻类的电生性电生性的特性引起了对生物燃料生产的关注。

6.Researchers are exploring the use of electrogenic 电生性的 bacteria in wastewater treatment processes.

研究人员正在探索在废水处理过程中使用电生性电生性的细菌。

7.The electrogenic 电生性的 capabilities of these microorganisms can be harnessed for energy generation.

这些微生物的电生性电生性的能力可以用于能源生成。

作文

In the realm of biology and physiology, the term electrogenic refers to the ability of certain cells or organisms to generate electrical potentials. This phenomenon is particularly significant in the study of nerve and muscle tissues, where the generation of electrical signals is crucial for communication within the body. For instance, neurons, which are the fundamental units of the nervous system, rely on electrogenic processes to transmit signals across synapses. These electrical impulses allow for rapid responses to stimuli, enabling organisms to react swiftly to their environment. Moreover, electrogenic mechanisms are not limited to animals; they are also observed in various microorganisms. Certain bacteria and archaea exhibit electrogenic properties that allow them to transfer electrons to external electron acceptors. This capability is essential for their survival in environments lacking oxygen, as these organisms can utilize alternative pathways for energy production. For example, Geobacter sulfurreducens, a type of bacteria, can conduct electricity and is being studied for its potential applications in bioenergy and bioremediation. The understanding of electrogenic cells has profound implications in medicine and biotechnology. In cardiology, for instance, the heart's rhythmic contractions are a result of electrogenic activity initiated by pacemaker cells. These cells create action potentials that spread through the heart muscle, coordinating contractions and maintaining a steady heartbeat. Disruptions in this electrogenic process can lead to arrhythmias, which may necessitate medical interventions such as pacemakers or defibrillators. Additionally, researchers are exploring the potential of electrogenic cells in developing bioelectronic devices. By harnessing the natural electrical activity of living cells, scientists aim to create innovative solutions for monitoring health conditions or even powering small devices. The integration of electrogenic cells with electronic components could pave the way for advancements in wearable technology, enabling real-time health monitoring and personalized medical care. In summary, the concept of electrogenic is integral to our understanding of biological systems and their functions. From the transmission of nerve impulses to the functioning of the heart, electrogenic processes play a vital role in sustaining life. Furthermore, the exploration of these mechanisms offers exciting opportunities for technological advancements in medicine and environmental science. As we continue to unravel the complexities of electrogenic phenomena, we may unlock new pathways for innovation that could significantly enhance our quality of life and our understanding of biological processes.

在生物学和生理学领域，术语electrogenic指的是某些细胞或生物体生成电位的能力。这种现象在神经和肌肉组织的研究中尤为重要，因为电信号的产生对身体内部的沟通至关重要。例如，神经元是神经系统的基本单位，依赖于electrogenic过程在突触之间传递信号。这些电脉冲使得有机体能够迅速对刺激作出反应，从而能够快速适应环境。 此外，electrogenic机制不仅限于动物；它们在各种微生物中也有观察到。某些细菌和古菌表现出electrogenic特性，使其能够将电子转移到外部电子受体。这种能力对于它们在缺氧环境中的生存至关重要，因为这些生物可以利用替代途径进行能量生产。例如，Geobacter sulfurreducens是一种细菌，能够导电，并正在被研究其在生物能源和生物修复中的潜在应用。 对electrogenic细胞的理解在医学和生物技术中具有深远的意义。在心脏病学中，例如，心脏的节律收缩是由起搏细胞的electrogenic活动引发的。这些细胞产生的动作电位在心肌中传播，协调收缩并维持稳定的心跳。这种electrogenic过程的干扰可能导致心律失常，可能需要医疗干预，如起搏器或除颤器。 此外，研究人员正在探索在开发生物电子设备中利用electrogenic细胞的潜力。通过利用活细胞的自然电活动，科学家们旨在创造监测健康状况或甚至为小型设备供电的创新解决方案。将electrogenic细胞与电子元件结合，可能为可穿戴技术的进步铺平道路，使实时健康监测和个性化医疗成为可能。 总之，electrogenic的概念是我们理解生物系统及其功能的基础。从神经冲动的传递到心脏的功能，electrogenic过程在维持生命方面发挥着至关重要的作用。此外，对这些机制的探索为医学和环境科学中的技术进步提供了激动人心的机会。随着我们继续揭示electrogenic现象的复杂性，我们可能会打开新的创新路径，从而显著提高我们的生活质量和对生物过程的理解。