bioplasm

简明释义

英[ˈbaɪəˌplæzəm]美[ˈbaɪəˌplæzəm]

n. 原生质

英英释义

单词用法

同义词

反义词

例句

1.The sterilizer takes advantage of high temperature disinfection principle, which destroys cell bioplasm, denatures protein, and concentrates electrolyte to kill microorganisms.

利用高温干热对微生物有氧化、蛋白质变性、电介质浓缩引起中毒等作用。

2.The sterilizer takes advantage of high temperature disinfection principle, which destroys cell bioplasm, denatures protein, and concentrates electrolyte to kill microorganisms.

利用高温干热对微生物有氧化、蛋白质变性、电介质浓缩引起中毒等作用。

3.In biology, bioplasm 生物质 refers to the living substance within cells.

在生物学中，bioplasm 生物质指的是细胞内的活性物质。

4.Researchers are investigating how bioplasm 生物质 can be used in regenerative medicine.

研究人员正在调查如何在再生医学中使用bioplasm 生物质。

5.The study of bioplasm 生物质 has revealed important insights into cellular processes.

对bioplasm 生物质的研究揭示了细胞过程的重要见解。

6.The interaction between different types of bioplasm 生物质 can lead to new discoveries in genetics.

不同类型的bioplasm 生物质之间的相互作用可能会导致遗传学的新发现。

7.The concept of bioplasm 生物质 is crucial for understanding the origin of life.

理解生命起源时，bioplasm 生物质的概念至关重要。

作文

In the study of biology, the term bioplasm refers to the living substance within a cell. It is a fundamental concept that helps us understand the intricate workings of life at a cellular level. The bioplasm encompasses not only the cytoplasm, which is the gel-like substance filling the cell, but also the organelles and various biomolecules that play critical roles in cellular functions. Understanding bioplasm is essential for students and researchers alike, as it forms the basis of many biological processes.The significance of bioplasm can be observed in various aspects of life. For instance, when studying cellular respiration, we see how the components of bioplasm work together to convert glucose and oxygen into energy. This process is vital for the survival of all living organisms. Similarly, in the context of cell division, the bioplasm ensures that genetic material is accurately replicated and distributed to daughter cells, maintaining the continuity of life.Moreover, the study of bioplasm extends beyond individual cells. It plays a crucial role in understanding how cells interact with each other and their environment. For example, in multicellular organisms, the communication between cells often relies on the substances present within the bioplasm. Signaling molecules, hormones, and neurotransmitters are all part of this living substance, facilitating coordination and response to external stimuli.In recent years, advancements in technology have allowed scientists to explore bioplasm in greater detail. Techniques such as microscopy and molecular biology have unveiled the complexities of cellular structures and functions. Researchers can now visualize the dynamics of bioplasm in real-time, providing insights into how cells behave under different conditions. This knowledge is not only fascinating but also has practical applications in medicine and biotechnology.For instance, understanding the composition and behavior of bioplasm can lead to the development of targeted therapies for diseases. By identifying specific molecules within the bioplasm, scientists can design drugs that effectively interact with these components, improving treatment outcomes for patients. Additionally, the manipulation of bioplasm has potential implications in regenerative medicine, where the goal is to repair or replace damaged tissues and organs.Furthermore, the concept of bioplasm is not limited to human cells; it is applicable across all forms of life. From bacteria to plants and animals, the principles governing bioplasm remain consistent. This universality underscores the interconnectedness of life on Earth and highlights the importance of studying bioplasm in a broader ecological context.In conclusion, bioplasm is a vital concept in biology that represents the living substance within cells. Its study provides valuable insights into cellular functions, interactions, and the overall mechanisms of life. As research continues to evolve, our understanding of bioplasm will undoubtedly deepen, paving the way for new discoveries and innovations that can benefit humanity. Whether in health, disease, or environmental science, the implications of bioplasm are far-reaching and profound, making it an essential area of study for anyone interested in the life sciences.

生物质是生物学研究中的一个术语，指的是细胞内的生物物质。它是一个基本概念，有助于我们理解生命在细胞层面的复杂运作。生物质不仅包括填充细胞的凝胶状物质细胞质，还包括在细胞功能中发挥关键作用的细胞器和各种生物分子。理解生物质对学生和研究者来说至关重要，因为它构成了许多生物过程的基础。生物质的重要性可以在生活的各个方面观察到。例如，在研究细胞呼吸时，我们看到生物质的组成部分如何协同工作，将葡萄糖和氧气转化为能量。这个过程对所有生物的生存至关重要。同样，在细胞分裂的背景下，生物质确保遗传物质被准确复制并分配给子细胞，维持生命的连续性。此外，生物质的研究不仅限于单个细胞。它在理解细胞之间及其与环境的相互作用中也起着至关重要的作用。例如，在多细胞生物中，细胞之间的通信通常依赖于存在于生物质中的物质。信号分子、激素和神经递质都是这一生物物质的一部分，促进了协调和对外部刺激的反应。近年来，技术的进步使科学家能够更详细地探索生物质。显微镜和分子生物学等技术揭示了细胞结构和功能的复杂性。研究人员现在可以实时可视化生物质的动态，为细胞在不同条件下的行为提供了见解。这种知识不仅令人着迷，而且在医学和生物技术中具有实际应用。例如，了解生物质的组成和行为可以导致针对疾病的靶向治疗的发展。通过识别生物质中的特定分子，科学家可以设计有效与这些成分相互作用的药物，从而改善患者的治疗效果。此外，操控生物质在再生医学中具有潜在的意义，其目标是修复或替换受损的组织和器官。此外，生物质的概念并不限于人类细胞；它适用于所有生命形式。从细菌到植物和动物，支配生物质的原则保持一致。这种普遍性强调了地球上生命的相互联系，并突显了在更广泛的生态背景下研究生物质的重要性。总之，生物质是生物学中的一个重要概念，代表细胞内的生物物质。其研究提供了关于细胞功能、相互作用和生命整体机制的宝贵见解。随着研究的不断发展，我们对生物质的理解无疑将加深，为新的发现和创新铺平道路，这些发现和创新可以惠及人类。无论是在健康、疾病还是环境科学中，生物质的影响都是深远而深刻的，使其成为任何对生命科学感兴趣的人必不可少的研究领域。