bioenergetics

简明释义

英[ˌbaɪəʊˌenəˈdʒetɪks]美[ˌbaɪoˌenərˈdʒetɪks]

n. [生化] 生物能学；生物能疗法

英英释义

单词用法

同义词

反义词

例句

1.Mimicking the photosynthetic functions by using synthetic model compounds is important to further our understanding of the process of bioenergetics.

通过合成的模型化合物模拟光反应中心以及天线的功能对于我们理解生物体光能转换过程是非常重要的。

2.Mimicking the photosynthetic functions by using synthetic model compounds is important to further our understanding of the process of bioenergetics.

通过合成的模型化合物模拟光反应中心以及天线的功能对于我们理解生物体光能转换过程是非常重要的。

3.The body's healing potential is at its peak and bioenergetics weak points are harmonized and the body's own energy flow activated.

此时，身体的愈合潜力达到极点，协调生物能量低点，激活身体自身的能量流动。

4.This is the web page of Journal of Bioenergetics and Biomembranes.

这是《生物能学和生物膜期刊》的网页。

5.Bioenergetics is defined as the study of energy transformation in living organisms.

学的定义是研究活生物体间的能量转化的科学。

6.The bioenergetics of the grass carp was characterized by a high consumption rate, high metabolic expenditure and low growth efficiency.

草鱼的能量学特征为高摄食率、高代谢消耗、低生长效率。

7.The study of bioenergetics is crucial for understanding how living organisms convert energy.

对生物能量学的研究对于理解生物如何转化能量至关重要。

8.In the field of bioenergetics, scientists analyze how cells generate ATP.

在生物能量学领域，科学家分析细胞如何生成ATP。

9.Understanding bioenergetics can help improve athletic performance by optimizing energy use.

理解生物能量学可以通过优化能量使用来提高运动表现。

10.The principles of bioenergetics are applied in developing new treatments for metabolic disorders.

在开发代谢疾病的新治疗方法时应用了生物能量学的原理。

11.Researchers in bioenergetics focus on metabolic pathways and energy production.

从事生物能量学的研究人员专注于代谢途径和能量生产。

作文

Bioenergetics is a fascinating field of study that explores the flow of energy through living systems. This discipline combines aspects of biology, biochemistry, and physics to understand how organisms convert food into energy, which is essential for survival. The term bioenergetics (生物能量学) encompasses various processes, including cellular respiration, photosynthesis, and the metabolism of nutrients. By investigating these processes, scientists can gain insights into how energy production and consumption influence health, growth, and overall functioning in living organisms.One of the primary focuses of bioenergetics (生物能量学) is cellular respiration. This process occurs in the mitochondria of cells, where glucose and oxygen are converted into adenosine triphosphate (ATP), the energy currency of the cell. ATP is vital for numerous cellular functions, such as muscle contraction, nerve impulse transmission, and biosynthesis of macromolecules. Understanding how cells generate ATP allows researchers to explore the implications of energy deficits, which can lead to various health issues, including obesity, diabetes, and heart disease.Another critical aspect of bioenergetics (生物能量学) is photosynthesis, the process by which plants, algae, and some bacteria convert light energy into chemical energy stored in glucose. This process not only sustains plant life but also forms the foundation of the food chain, supporting all other living organisms. By studying photosynthesis, scientists can identify ways to enhance crop yields, develop sustainable agricultural practices, and address food security challenges in a growing global population.Moreover, bioenergetics (生物能量学) plays a significant role in understanding metabolic pathways. These pathways involve a series of chemical reactions that convert nutrients into energy. Different organisms have evolved unique metabolic strategies to optimize energy use, depending on their environment and lifestyle. For instance, some animals have adapted to survive in extreme conditions, such as deep-sea environments or arid deserts, by developing specialized metabolic pathways that allow them to efficiently utilize available resources.In recent years, the field of bioenergetics (生物能量学) has expanded to include research on energy balance and its implications for health. Energy balance refers to the relationship between energy intake and energy expenditure. An imbalance can lead to weight gain or loss, impacting overall health and well-being. Researchers are increasingly focusing on understanding the factors that influence energy balance, including genetics, behavior, and environmental factors. This knowledge is crucial for developing effective interventions to combat obesity and related diseases.Furthermore, advancements in technology have allowed scientists to study bioenergetics (生物能量学) at a molecular level. Techniques such as respirometry, calorimetry, and metabolomics provide valuable data on how organisms metabolize energy and respond to various stimuli. These tools enable researchers to uncover the intricate mechanisms underlying energy production and utilization, paving the way for innovative therapies and strategies to improve health outcomes.In conclusion, bioenergetics (生物能量学) is a multidisciplinary field that provides essential insights into the energy dynamics of living systems. By understanding how organisms produce and utilize energy, we can address critical challenges related to health, nutrition, and sustainability. As research in this area continues to evolve, it holds the promise of unlocking new solutions to improve the quality of life for all living beings.

生物能量学是一个迷人的研究领域，探索能量在生物系统中的流动。这个学科结合了生物学、生物化学和物理学的各个方面，以理解生物体如何将食物转化为能量，这对生存至关重要。术语生物能量学（bioenergetics）涵盖了各种过程，包括细胞呼吸、光合作用和营养物质的代谢。通过研究这些过程，科学家可以深入了解能量的产生和消耗如何影响健康、增长和生物体的整体功能。生物能量学（bioenergetics）的一个主要关注点是细胞呼吸。这个过程发生在细胞的线粒体中，在那里，葡萄糖和氧气被转化为三磷酸腺苷（ATP），即细胞的能量货币。ATP对于许多细胞功能至关重要，例如肌肉收缩、神经冲动传导和大分子的生物合成。理解细胞如何生成ATP使研究人员能够探索能量缺乏的影响，这可能导致各种健康问题，包括肥胖、糖尿病和心脏病。生物能量学（bioenergetics）的另一个关键方面是光合作用，这是植物、藻类和一些细菌将光能转化为储存在葡萄糖中的化学能的过程。这个过程不仅维持植物生命，而且构成了食物链的基础，支持所有其他生物体。通过研究光合作用，科学家可以识别提高作物产量的方法，开发可持续的农业实践，并解决全球人口增长带来的粮食安全挑战。此外，生物能量学（bioenergetics）在理解代谢途径方面也发挥着重要作用。这些途径涉及一系列化学反应，将营养物质转化为能量。不同的生物体根据其环境和生活方式进化出独特的代谢策略，以优化能量使用。例如，一些动物已经适应在极端条件下生存，如深海环境或干旱沙漠，通过发展专门的代谢途径，使它们能够高效利用可用资源。近年来，生物能量学（bioenergetics）领域已扩展到包括关于能量平衡及其对健康影响的研究。能量平衡是指能量摄入与能量支出之间的关系。不平衡可能导致体重增加或减少，从而影响整体健康和福祉。研究人员越来越关注理解影响能量平衡的因素，包括遗传、行为和环境因素。这些知识对于开发有效的干预措施以抗击肥胖及相关疾病至关重要。此外，技术的进步使科学家能够在分子水平上研究生物能量学（bioenergetics）。如呼吸测量法、热量测量法和代谢组学等技术提供了有关生物体如何代谢能量以及如何响应各种刺激的宝贵数据。这些工具使研究人员能够揭示能量生产和利用背后的复杂机制，为改善健康结果的创新疗法和策略铺平了道路。总之，生物能量学（bioenergetics）是一个多学科领域，提供了对生物系统能量动态的重要见解。通过理解生物体如何产生和利用能量，我们可以解决与健康、营养和可持续性相关的关键挑战。随着该领域研究的不断发展，它有望为改善所有生物体的生活质量解锁新的解决方案。