biomagnetism 是一个合成词,由两个词组成,biology(生物学)和 magnetism(磁学)。biomagnetism 是生物学和磁学之间的交叉学科,主要研究生物体中的磁学现象。
发音:/ba????m?ɡn?z?m/
英语范文:
Biology and magnetism are closely related fields. Biomagnetism is a subfield of biology that studies magnetic phenomena in living organisms.
在生物学和磁学之间存在着密切的联系。生物磁学是生物学的一个子领域,它研究生物体内的磁现象。
Biology and biomagnetism are both fascinating fields that have opened up a new window for understanding the world around us.
生物学和生物磁学这两个领域都令人着迷,它们为我们理解周围的世界打开了一扇新的窗口。
英语作文音标和基础释义:
biomagnetism [ba???] /?m?ɡn?z?m/ - 生物磁学
be closely related [?klen?s] /?rel?nt/ - 紧密相关的
subfield [?s?bfi?ld] - 子领域,分支领域
study magnetic phenomena [?n?f??n] /?ɑ?z?m?t?k/ - 研究磁学现象
living organisms [?l?v??] /???z?nst?mz/ - 活着的生物体
opened up a new window [?w?nd?] /?w?nt?/ - 打开了一扇新的窗口
have opened up - 已经打开
fascinating [?f?s?n?t??] - 令人着迷的
understanding [??nd?r] /?st?nd??/ - 理解,领悟
world around us [?w??rld] /?a?r?nd?m/ - 我们周围的世界
Biomagnetism: The Mysteries of Life's Magnetic Symphony
Biomagnetism is a fascinating field of research that explores the magnetic properties of living organisms. It bridges the gap between physics and biology, revealing the intricate interplay between magnetic fields and life processes.
In biomagnetism, magnetic properties of cells, tissues, and organs are studied using magnetic resonance imaging (MRI) techniques. These techniques allow researchers to visualize magnetic fields generated by living systems and their response to external magnetic stimuli.
One of the most exciting applications of biomagnetism is its potential role in early cancer detection. MRI-based biomagnetism can identify subtle changes in magnetic fields caused by the growth and movement of cancer cells. These changes can indicate the presence of cancer at an early stage, enabling more effective treatment planning.
Another area of biomagnetism research is magnetobiology, which explores the effects of magnetic fields on living systems. Magnetic fields have been shown to affect cellular functions, such as gene expression and protein synthesis. Understanding these effects could lead to new therapeutic strategies for diseases such as neurodegenerative disorders and cardiovascular diseases.
In conclusion, biomagnetism is an exciting field of research that sheds light on the magnetic properties of life. By studying magnetic fields generated by living systems, we can gain a deeper understanding of the complex interactions between biology and physics. This knowledge could lead to new insights into the diagnosis and treatment of various diseases, opening up a whole new world of possibilities for medicine.
biomagnetism
Biology and magnetism are two fields that are closely related. Biomagnetism is the study of magnetic properties of living organisms. It is a relatively new field that has gained increasing interest in recent years.
One of the main applications of biomagnetism is in medical diagnosis and treatment. Magnetic fields can be used to detect diseases such as cancer and neurological disorders. They can also be used to guide medical devices, such as magnetic nanoparticles, to targeted areas of the body.
Another area where biomagnetism is used is in environmental sensing. Magnetic sensors can be used to detect the presence of pollutants in the environment, such as toxic substances and radioactive materials. This technology can be used to monitor environmental conditions and protect public health.
Biomagnetism is also used in animal tracking and navigation. Animals such as birds and fish use magnetic fields to orient themselves and navigate through their habitat. By studying these magnetic fields, we can learn more about the behavior and ecology of these animals.
In conclusion, biomagnetism is a rapidly growing field with many potential applications. It has the potential to revolutionize medical diagnosis and treatment, environmental monitoring, animal tracking, and more. However, further research is needed to fully understand its potential and develop practical applications.
范文:
Title: Biomagnetism: A New Frontier in Life Science
In recent years, biomagnetism has emerged as a rapidly growing field that holds great promise for the future. This interdisciplinary field bridges the gap between biology and magnetism, exploring the magnetic properties of living organisms and their role in various aspects of life.
One of the most exciting areas where biomagnetism is already making a difference is in medical diagnosis and treatment. Magnetic fields have been used to detect and diagnose various diseases, such as cancer and neurological disorders, with increasing accuracy and precision. Moreover, magnetic nanoparticles have been developed as targeted drug delivery systems that can improve patient outcomes and reduce side effects.
Environmental sensing is another rapidly growing area where biomagnetism is making a difference. Magnetic sensors can detect pollutants in the environment, such as toxic substances and radioactive materials, with increasing sensitivity and accuracy. This technology has the potential to revolutionize environmental monitoring and help safeguard public health.
Moreover, biomagnetism is also being used in animal tracking and navigation. Animals use magnetic fields to orient themselves and navigate through their habitat, and biomagnetism can provide valuable insights into their behavior and ecology.
In conclusion, biomagnetism holds tremendous potential for the future of science and medicine. With further research and development, this field has the potential to revolutionize our understanding of life and improve our lives in countless ways.
