bioenergetic
简明释义
英[ˌbaɪ.oʊ.ɛrˈdʒɛt.ɪk]美[ˌbaɪ.oʊ.ɛrˈdʒɛt.ɪk]
adj. 生物能量学
英英释义
单词用法
同义词
反义词
| 厌氧的 | Anaerobic respiration occurs in environments without oxygen. | 厌氧呼吸发生在没有氧气的环境中。 | |
| 非能量的 | Non-energetic processes do not involve the conversion of energy. | 非能量过程不涉及能量的转化。 |
例句
1.Based on study of metabolic theory, this paper established a series of bioenergetic models describing the relationship between microbial anabolism-catabolism and S_O/X_O ratio.
从底物物质平衡出发,在提出新的代谢概念基础上,系统地建立了描述富底物条件下微生物合成-能量代谢行为的生物数学模型体系。
2.Based on study of metabolic theory, this paper established a series of bioenergetic models describing the relationship between microbial anabolism-catabolism and S_O/X_O ratio.
从底物物质平衡出发,在提出新的代谢概念基础上,系统地建立了描述富底物条件下微生物合成-能量代谢行为的生物数学模型体系。
3.The therapist used a variety of techniques to promote bioenergetic 生物能量的 healing in her clients.
治疗师使用多种技术来促进她的客户的生物能量的疗愈。
4.The clinic specializes in bioenergetic 生物能量的 medicine and holistic health.
该诊所专注于生物能量的医学和整体健康。
5.In the workshop, participants learned about bioenergetic 生物能量的 exercises to release emotional tension.
在研讨会上,参与者学习了如何进行生物能量的练习以释放情绪紧张。
6.The study focused on the effects of bioenergetic 生物能量的 therapies on stress reduction.
这项研究集中于生物能量的疗法对减压的影响。
7.She incorporated bioenergetic 生物能量的 principles into her yoga practice.
她将生物能量的原理融入了她的瑜伽练习中。
作文
The concept of bioenergetic (生物能量学) processes is essential in understanding how living organisms convert energy from their environment into forms that can be utilized for growth, reproduction, and maintenance of life. In the field of biology, bioenergetic (生物能量学) studies focus on the transformation of energy within cells, particularly how energy from food is converted into usable forms through cellular respiration. This process is vital for all forms of life, as it provides the necessary energy to sustain biological functions.One of the most fascinating aspects of bioenergetic (生物能量学) processes is the role of mitochondria, often referred to as the powerhouses of the cell. Mitochondria are responsible for producing adenosine triphosphate (ATP), the energy currency of the cell. Through a series of complex biochemical reactions, including the Krebs cycle and oxidative phosphorylation, mitochondria convert nutrients into ATP, which is then used by the cell to perform various tasks. Understanding these processes not only sheds light on how energy is produced in living organisms but also has implications for health and disease. For instance, mitochondrial dysfunction is linked to several disorders, including metabolic diseases, neurodegenerative conditions, and aging.In addition to cellular respiration, bioenergetic (生物能量学) principles apply to various fields, including ecology and environmental science. Energy flow through ecosystems is a key focus of ecological studies, where researchers examine how energy is transferred from one trophic level to another. For example, plants capture solar energy through photosynthesis, converting it into chemical energy stored in glucose. Herbivores then consume these plants, transferring energy up the food chain. This interconnectedness highlights the importance of energy conservation and efficiency in ecological systems, illustrating how bioenergetic (生物能量学) principles govern the dynamics of life on Earth.Moreover, the study of bioenergetic (生物能量学) systems extends into the realm of human health and wellness. Practices such as yoga and certain therapeutic modalities emphasize the balance of energy within the body. Techniques like breathwork and meditation are believed to enhance bioenergetic (生物能量学) flow, promoting physical and mental well-being. These practices underscore the idea that maintaining a harmonious energy state is crucial for overall health.The exploration of bioenergetic (生物能量学) concepts is not limited to scientific inquiry; it also inspires innovations in technology. For example, bioenergetics can inform the development of renewable energy sources by mimicking natural processes. Researchers are investigating how to harness energy in ways similar to photosynthesis to create sustainable energy solutions.In conclusion, bioenergetic (生物能量学) processes are fundamental to the functioning of life, influencing everything from cellular metabolism to ecological interactions and human health. By studying these processes, we gain valuable insights into the mechanisms that sustain life and the potential applications for improving health and developing sustainable technologies. Understanding bioenergetic (生物能量学) principles is crucial for advancing our knowledge in biology, ecology, and health sciences, ultimately contributing to a more sustainable future.
生物能量学(bioenergetic)过程的概念对于理解生物体如何将环境中的能量转化为可用于生长、繁殖和维持生命的形式至关重要。在生物学领域,生物能量学(bioenergetic)的研究重点是细胞内能量的转化,特别是食物中的能量如何通过细胞呼吸转化为可用形式。这个过程对所有生命形式都是至关重要的,因为它提供了维持生物功能所需的能量。生物能量学(bioenergetic)过程中最引人入胜的一个方面是线粒体的角色,线粒体常被称为细胞的动力源。线粒体负责产生三磷酸腺苷(ATP),这是细胞的能量货币。通过一系列复杂的生化反应,包括克雷布斯循环和氧化磷酸化,线粒体将营养物质转化为ATP,然后细胞利用这些ATP来执行各种任务。理解这些过程不仅揭示了生物体内能量的产生方式,还对健康和疾病具有重要意义。例如,线粒体功能障碍与多种疾病相关,包括代谢疾病、神经退行性疾病和衰老。除了细胞呼吸,生物能量学(bioenergetic)原理还适用于多个领域,包括生态学和环境科学。生态系统中的能量流动是生态研究的一个关键焦点,研究人员考察能量如何从一个营养级转移到另一个营养级。例如,植物通过光合作用捕获太阳能,将其转化为储存在葡萄糖中的化学能。食草动物然后消耗这些植物,将能量向食物链上游转移。这种相互关联性凸显了在生态系统中能量保护和效率的重要性,说明生物能量学(bioenergetic)原理如何支配地球上的生命动态。此外,生物能量学(bioenergetic)系统的研究还延伸到人类健康和福祉的领域。瑜伽和某些治疗方式强调身体内能量的平衡。呼吸练习和冥想等技术被认为能够增强生物能量学(bioenergetic)流动,促进身心健康。这些实践强调了维持和谐的能量状态对整体健康至关重要的观点。对生物能量学(bioenergetic)概念的探索不仅限于科学研究;它还激励着技术创新。例如,生物能量学(bioenergetic)可以为可再生能源的开发提供信息,通过模仿自然过程。研究人员正在研究如何以类似光合作用的方式捕获能量,以创造可持续的能源解决方案。总之,生物能量学(bioenergetic)过程是生命运作的基础,影响着从细胞代谢到生态相互作用以及人类健康的方方面面。通过研究这些过程,我们获得了关于维持生命机制的宝贵见解,以及改善健康和开发可持续技术的潜在应用。理解生物能量学(bioenergetic)原理对于推进我们在生物学、生态学和健康科学方面的知识至关重要,最终有助于实现更可持续的未来。
