biochemic

简明释义

英[ˌbaɪoʊˈkɛmɪk]美[ˌbaɪoʊˈkɛmɪk]

adj. 生物化学的

英英释义

单词用法

同义词

反义词

例句

1.Using yeast as model organism, study the contribution of epigenetic regulation to the maintenance of genomic stability, by epigenetic, molecular genetic and biochemic approaches.

以酵母为模式生物，利用表观遗传，分子遗传和生物化学等手段，研究表观遗传调控在维持基因组稳定性中的作用。

2.Using yeast as model organism, study the contribution of epigenetic regulation to the maintenance of genomic stability, by epigenetic, molecular genetic and biochemic approaches.

以酵母为模式生物，利用表观遗传，分子遗传和生物化学等手段，研究表观遗传调控在维持基因组稳定性中的作用。

3.The biochemic characteristics, synthesis, functional activity, identification and application of theanine are summarized in this paper. Its development trend is also introduced.

本文综述了茶氨酸的主要生化特性、合成方法、生理功能、鉴别方法及其应用，并对其开发应用前景进行了展望。

4.Researchers are exploring biochemic 生物化学的 markers for early disease detection.

研究人员正在探索用于早期疾病检测的生物化学的标志物。

5.Many biochemic 生物化学的 pathways are involved in metabolism.

许多生物化学的途径参与了代谢过程。

6.The biochemic 生物化学的 analysis revealed unexpected results in the protein structure.

这项生物化学的分析揭示了蛋白质结构中的意外结果。

7.The study of biochemic 生物化学的 processes is crucial for understanding cellular functions.

研究生物化学的过程对于理解细胞功能至关重要。

8.Understanding biochemic 生物化学的 interactions can lead to new drug developments.

理解生物化学的相互作用可以推动新药的开发。

作文

Biochemistry is a fascinating field that merges biology and chemistry to explore the chemical processes within and related to living organisms. The term biochemic (生物化学的) is often used to describe anything pertaining to this interdisciplinary science. In recent years, the importance of biochemic research has grown exponentially as we seek to understand the molecular mechanisms of life. From the way our cells communicate to how they metabolize nutrients, biochemic studies provide insights that are crucial for advancements in medicine, agriculture, and environmental science.One significant area of biochemic research is drug development. Scientists utilize knowledge from biochemic processes to design and synthesize new pharmaceuticals that can target specific pathways in the body. For instance, understanding the structure and function of proteins can lead to the creation of inhibitors that block disease-causing enzymes. This approach has revolutionized the treatment of various conditions, including cancer and infectious diseases.Another critical aspect of biochemic research is its application in genetics. With the advent of technologies like CRISPR, scientists can manipulate genetic material at the molecular level. This biochemic technique allows for precise edits to DNA, paving the way for potential cures for genetic disorders. The implications of such advancements are profound, as they could lead to treatments that not only alleviate symptoms but address the root causes of diseases.Moreover, biochemic studies play a vital role in understanding metabolic pathways. Metabolism encompasses all the chemical reactions that occur within an organism to maintain life. By investigating these pathways, researchers can uncover how different factors, such as diet and exercise, impact our health. For example, the study of biochemic reactions related to glucose metabolism has provided insights into diabetes management, helping patients regulate their blood sugar levels more effectively.Environmental science also benefits greatly from biochemic research. Understanding the biochemical processes that occur in ecosystems can inform conservation efforts and sustainable practices. For instance, studying the decomposition of organic matter reveals how nutrients are recycled in nature. This knowledge is essential for developing strategies to combat soil degradation and promote biodiversity.In conclusion, the field of biochemic research is integral to many aspects of modern science and society. Its applications extend beyond the laboratory, impacting healthcare, agriculture, and environmental sustainability. As we continue to unravel the complexities of life at the molecular level, the significance of biochemic studies will only grow. Embracing this knowledge not only enhances our understanding of biological processes but also equips us with the tools to tackle some of the most pressing challenges facing humanity today.

生物化学是一个迷人的领域，它将生物学和化学结合在一起，探索与生物体内及相关的化学过程。术语biochemic（生物化学的）通常用于描述与这一跨学科科学相关的任何事物。近年来，biochemic研究的重要性急剧增加，因为我们寻求理解生命的分子机制。从我们的细胞如何交流到它们如何代谢营养，biochemic研究提供了对医学、农业和环境科学进步至关重要的见解。biochemic研究的一个重要领域是药物开发。科学家利用biochemic过程中的知识设计和合成可以针对身体中特定途径的新药物。例如，理解蛋白质的结构和功能可以导致抑制剂的创建，这些抑制剂可以阻止致病酶。这种方法彻底改变了各种疾病的治疗，包括癌症和传染病。biochemic研究的另一个关键方面是其在遗传学中的应用。随着CRISPR等技术的出现，科学家可以在分子水平上操纵遗传物质。这种biochemic技术允许对DNA进行精确编辑，为潜在的遗传疾病治疗铺平了道路。这种进展的影响深远，因为它可能导致不仅缓解症状，还能解决疾病根本原因的治疗。此外，biochemic研究在理解代谢途径方面也发挥着至关重要的作用。代谢包括在生物体内维持生命所发生的所有化学反应。通过研究这些途径，研究人员可以揭示饮食和锻炼等不同因素如何影响我们的健康。例如，关于葡萄糖代谢的biochemic反应的研究提供了对糖尿病管理的见解，帮助患者更有效地调节血糖水平。环境科学也极大受益于biochemic研究。理解生态系统中发生的生化过程可以为保护工作和可持续实践提供信息。例如，研究有机物的分解揭示了养分在自然界中的循环。这一知识对于制定应对土壤退化和促进生物多样性的战略至关重要。总之，biochemic研究领域是现代科学和社会许多方面不可或缺的一部分。它的应用超越了实验室，影响着医疗保健、农业和环境可持续性。随着我们继续揭开生命在分子水平上的复杂性，biochemic研究的重要性只会增加。拥抱这一知识不仅增强了我们对生物过程的理解，还为我们提供了解决当今人类面临的一些最紧迫挑战的工具。