physiological chemistry

简明释义

生理化学

英英释义

例句

1.Research in physiological chemistry 生理化学 can lead to breakthroughs in drug development.

在生理化学 physiological chemistry 领域的研究可以导致药物开发的突破。

2.The study of physiological chemistry 生理化学 is essential for understanding how the body functions at a molecular level.

研究生理化学 physiological chemistry 对于理解身体在分子层面如何运作至关重要。

3.Understanding physiological chemistry 生理化学 helps in diagnosing metabolic disorders.

理解生理化学 physiological chemistry 有助于诊断代谢性疾病。

4.In medical school, students learn about physiological chemistry 生理化学 to better grasp the biochemical processes in human health.

在医学院，学生学习生理化学 physiological chemistry 以更好地理解人类健康中的生化过程。

5.The role of enzymes in physiological chemistry 生理化学 is crucial for metabolic reactions.

酶在生理化学 physiological chemistry 中的作用对于代谢反应至关重要。

作文

Physiological chemistry is a fascinating field that bridges the gap between biology and chemistry. It focuses on the chemical processes that occur within living organisms, providing insights into how these processes affect health and disease. Understanding physiological chemistry (生理化学) is crucial for anyone interested in the life sciences, as it lays the foundation for many areas of research and application, including medicine, pharmacology, and biochemistry.At its core, physiological chemistry (生理化学) examines the molecular mechanisms that underpin biological functions. This includes studying the structure and function of biomolecules such as proteins, nucleic acids, lipids, and carbohydrates. By understanding how these molecules interact and contribute to cellular processes, researchers can gain valuable insights into how organisms maintain homeostasis, respond to environmental changes, and ultimately survive.One of the key aspects of physiological chemistry (生理化学) is its emphasis on metabolic pathways. Metabolism encompasses all the chemical reactions that occur within a cell, including catabolism (the breakdown of molecules to release energy) and anabolism (the synthesis of complex molecules from simpler ones). By studying these pathways, scientists can identify how energy is produced and utilized in cells, which is essential for understanding diseases like diabetes and obesity.Moreover, physiological chemistry (生理化学) plays a significant role in drug development. Knowledge of the biochemical pathways involved in disease processes enables researchers to design targeted therapies that can effectively intervene at specific points within these pathways. For instance, many cancer treatments are designed to inhibit the growth of cancer cells by disrupting their metabolic processes. Thus, a deep understanding of physiological chemistry (生理化学) is vital for the advancement of medical science.In addition to its applications in medicine, physiological chemistry (生理化学) also informs our understanding of nutrition and health. Nutritional biochemistry examines how dietary components are metabolized and utilized by the body. This knowledge is crucial for developing dietary guidelines and nutritional interventions that promote health and prevent disease. For example, understanding how different macronutrients are processed can help individuals make informed choices about their diets, leading to better overall health outcomes.Furthermore, the study of physiological chemistry (生理化学) extends to the field of environmental science. Researchers are increasingly aware of how chemicals in the environment can affect biological systems. By understanding the biochemical interactions between pollutants and living organisms, scientists can assess the impact of environmental toxins on human health and ecosystems. This interdisciplinary approach highlights the importance of physiological chemistry (生理化学) in addressing global challenges such as pollution and climate change.In conclusion, physiological chemistry (生理化学) is a vital field that enhances our understanding of the chemical processes that sustain life. Its applications span across medicine, nutrition, and environmental science, making it an essential area of study for anyone interested in the life sciences. As we continue to unravel the complexities of biological systems through the lens of physiological chemistry (生理化学), we pave the way for innovative solutions to health and environmental challenges, ultimately improving the quality of life for all organisms on our planet.

生理化学是一个迷人的领域，它在生物学和化学之间架起了一座桥梁。它专注于生活生物体内发生的化学过程，提供了关于这些过程如何影响健康和疾病的见解。理解生理化学（physiological chemistry）对任何对生命科学感兴趣的人来说都是至关重要的，因为它为许多研究和应用领域奠定了基础，包括医学、药理学和生物化学。在其核心，生理化学（physiological chemistry）研究支撑生物功能的分子机制。这包括研究生物大分子的结构和功能，如蛋白质、核酸、脂质和碳水化合物。通过了解这些分子如何相互作用并对细胞过程作出贡献，研究人员可以获得关于生物体如何维持稳态、对环境变化做出反应以及最终生存的宝贵见解。生理化学（physiological chemistry）的一个关键方面是它对代谢途径的强调。代谢包括细胞内发生的所有化学反应，包括分解代谢（将分子分解以释放能量）和合成代谢（从简单分子合成复杂分子）。通过研究这些途径，科学家们可以识别细胞中能量的产生和利用方式，这对于理解糖尿病和肥胖等疾病至关重要。此外，生理化学（physiological chemistry）在药物开发中也发挥着重要作用。对疾病过程中的生化途径的了解使研究人员能够设计出针对性的治疗方法，可以有效地在这些途径的特定点进行干预。例如，许多癌症治疗旨在通过破坏癌细胞的代谢过程来抑制癌细胞的生长。因此，对生理化学（physiological chemistry）的深入理解对于医学科学的发展至关重要。除了在医学中的应用外，生理化学（physiological chemistry）还丰富了我们对营养和健康的理解。营养生物化学研究饮食成分如何被身体代谢和利用。这一知识对于制定饮食指南和营养干预措施以促进健康和预防疾病至关重要。例如，了解不同宏量营养素的处理方式可以帮助个人做出明智的饮食选择，从而改善整体健康结果。此外，生理化学（physiological chemistry）的研究还扩展到环境科学领域。研究人员越来越意识到环境中的化学物质如何影响生物系统。通过了解污染物与生物体之间的生化相互作用，科学家们可以评估环境毒素对人类健康和生态系统的影响。这种跨学科的方法强调了生理化学（physiological chemistry）在应对全球性挑战如污染和气候变化中的重要性。总之，生理化学（physiological chemistry）是一个重要的领域，增强了我们对维持生命的化学过程的理解。它的应用跨越医学、营养和环境科学，使其成为任何对生命科学感兴趣的人的重要研究领域。随着我们继续通过生理化学（physiological chemistry）的视角揭示生物系统的复杂性，我们为健康和环境挑战的创新解决方案铺平了道路，最终改善我们星球上所有生物的生活质量。