生物工程专业英语翻译(第一篇)改

Abstract:Biological engineering, a relatively young yet rapidly growing field, combines principles from biology, engineering, and computer science to solve complex problems in healthcare, agriculture, and the environment. This interdisciplinary field is at the forefront of technological advancements, offering innovative solutions to some of the most pressing challenges faced by humanity. This paper provides an overview of the field of biological engineering, its history, key areas of research, applications, and future prospects.1. IntroductionThe field of biological engineering emerged in the late 20th century as a response to the increasing need for interdisciplinary approaches to address complex problems in various sectors. By integrating knowledge from biology, engineering, and computer science, biological engineers strive to develop innovative solutions that can improve human health, enhance agricultural productivity, and protect the environment. This field has gained significant attention in recent years, thanks to advancements in biotechnology, genetics, and computational tools.2. History of Biological EngineeringThe roots of biological engineering can be traced back to the early 20th century when scientists began to explore the application of engineering principles to biological systems. The field gained momentum in the 1950s and 1960s with the development of recombinant DNA technology and the establishment of biotechnology companies. Over the years, the field has evolved to encompass a wide range of applications, including medical devices, biofuels, and environmental remediation.3. Key Areas of Research in Biological Engineering3.1 Biomedical EngineeringBiomedical engineering is a major subfield of biological engineeringthat focuses on the application of engineering principles to improve human health. This includes the development of medical devices,diagnostic tools, and therapeutic agents. Some key areas of research in biomedical engineering include:- Tissue engineering: Developing bioartificial tissues and organs for transplantation.- Nanomedicine: Using nanotechnology to deliver drugs and imaging agents directly to diseased cells.- Biocompatibility: Ensuring that medical devices and implants are compatible with the human body.3.2 Biochemical EngineeringBiochemical engineering involves the design and optimization of processes that use biological systems to produce valuable products. This includes the development of industrial fermentation processes, enzyme engineering, and bioreactors. Some key areas of research in biochemical engineering include:- Bioprocessing: Developing efficient and sustainable methods for producing biofuels, pharmaceuticals, and other chemicals.- Enzyme engineering: Improving the properties of enzymes for industrial applications.- Bioreactor design: Optimizing the design of reactors to maximize the production of desired products.3.3 Environmental EngineeringEnvironmental engineering in biological engineering focuses on the development of technologies to protect and restore the environment. This includes the treatment of wastewater, air pollution control, and bioremediation. Some key areas of research in environmental engineering include:- Bioremediation: Using biological agents to clean up contaminated sites.- Wastewater treatment: Developing efficient methods for treating and recycling wastewater.- Air pollution control: Using biological systems to remove pollutants from industrial emissions.4. Applications of Biological Engineering4.1 HealthcareBiological engineering has revolutionized healthcare by developing new treatments, diagnostics, and medical devices. Some notable applications include:- Gene therapy: Using genetic engineering to treat genetic disorders.- Artificial organs: Developing bioartificial organs for transplantation.- Drug delivery systems: Using nanotechnology to deliver drugs directly to diseased cells.4.2 AgricultureBiological engineering has contributed to the development of sustainable agricultural practices that enhance crop yield and reduce environmental impact. Some key applications include:- Genetically modified organisms (GMOs): Developing crops with improved resistance to pests and diseases.- Precision agriculture: Using sensors and data analytics to optimize crop management.- Biopesticides: Developing environmentally friendly alternatives to chemical pesticides.4.3 Environmental ProtectionBiological engineering plays a crucial role in protecting the environment by developing technologies to remediate pollution and reduce waste. Some applications include:- Bioremediation: Using biological agents to clean up oil spills and contaminated sites.- Wastewater treatment: Developing sustainable methods for treating and recycling wastewater.- Air pollution control: Using biological systems to remove pollutants from industrial emissions.5. Future ProspectsThe field of biological engineering is expected to continue growing rapidly in the coming years, driven by technological advancements and increasing demand for sustainable solutions. Some future prospects include:- Development of personalized medicine: Tailoring treatments to individual patients based on their genetic makeup.- Advancements in biofuels: Developing more efficient and sustainable methods for producing biofuels.- Addressing global challenges: Using biological engineering to address issues such as climate change, food security, and water scarcity.6. ConclusionBiological engineering is a dynamic and rapidly evolving field that offers immense potential for solving complex problems in healthcare, agriculture, and the environment. By integrating knowledge from various disciplines, biological engineers are at the forefront of technological innovation, developing innovative solutions that can improve the quality of life for people around the world. As the field continues to grow, it is poised to play an even more significant role in shaping the future of humanity.。

生物工程(生物技术)专业英语翻译Lesson One（4学时）Inside the Living Cell: Structure andFunction of Internal Cell Parts教学目的：使学生掌握细胞的组成结构（各种细胞器以及它们在细胞中的位置），Cytoplasm: The Dynamic, Mobile Factory细胞质：动力工厂Most of the properties we associate with life are properties of the cytoplasm. Much of the mass of a cell consists of this semifluid substance, which is bounded on the outside by the plasma membrane. Organelles are suspended within it, supported by the filamentous network of the cytoskeleton. Dissolved in the cytoplasmic fluid are nutrients, ions, soluble proteins, and other materials needed for cell functioning.生命的大部分特征表现在细胞质的特征上。

细胞质大部分由半流体物质组成，并由细胞膜（原生质膜）包被。

细胞器悬浮在其中，并由丝状的细胞骨架支撑。

细胞质中溶解了大量的营养物质，离子，可溶蛋白以及维持细胞生理需求的其它物质。

2The Nucleus: Information Central（细胞核：信息中心）The eukaryotic cell nucleus is the largest organelle and houses the genetic material (DNA) on chromosomes. (In prokaryotes the hereditary material is found in the nucleoid.) The nucleus also contains one or two organelles-the nucleoli-that play a role in cell division. A pore-perforated sac called the nuclear envelope separates the nucleus and its contents from the cytoplasm. Small molecules can pass through the nuclear envelope, but larger molecules such as mRNA and ribosomes must enter and exit via the pores.真核细胞的细胞核是最大的细胞器，细胞核对染色体组有保护作用（原核细胞的遗传物质存在于拟核中）。

1 Unit 1 Biomedical Engineering Lesson 1A History of Biomedical EngineeringIn its broadest sense，biomedical engineering has been with us for centuries，perhaps even thousands of years。

In 2000，German archeologists uncover a 3，000—year—old mummy from Thebes with a wooden prosthetic tied to its foot to serve as a big toe。

Researchers said the wear on the bottom surface suggests that it could be the oldest known limb prosthesis. Egyptians also used hollow reeds to look and listen to the internal goings on of the human anatomy. In 1816, modesty prevented French physician Rene Laennec from placing his ear next to a young woman's bare chest，so he rolled up a newspaper and listened through it，triggering the idea for his invention that led to today’s ubiquitous stethoscope.广义上来说，生物医学工程与我们已经几个世纪以来，甚至数千年.2000年,德国考古学家发现一个3000岁高龄的木乃伊从底比斯木制假肢与作为大脚趾的脚。

Beijing University of Chemical Technology 化学工业出版社• Exercise for Chapter 1Line 1-10, P. 1生物工程是属于应用生物科学和技术的一个领域，它包含生物或其亚细胞组分在制造业、服务业和环境管理等方面的应用。

生物工程利用细菌，酵母，真菌，植物细胞或培养的哺乳动物细胞作为工业加工的组分。

只有将微生物学、生物化学、遗传学、分子生物学、化学和化学工程等多种学科和技术结合起来，生物工程的应用才能获得成功。

Biotechnology is an area of applied bioscience and technology which involves the practical application of biological organisms,or their subcellular components to manufacturing and service industries and to environmental management.Biotechnology utilizes bacteria,yeasts，fungi，algae，plant cells or cultured mammalian cells as constituents of industrial processes.Successful application of biotechnology will result only from the integration of a multiplicity of scientific disciplines and technologies,including microbiology,biochemistry,genetics,molecular biology,chemistry and chemical and process engineering.line3 ---line7, P.6生物科学和生物工程之间有一个很明显的区别。

生物学英语中英对照1. 遗传学 Genetics基因 Gene染色体 Chromosome遗传变异 Genetic variation2. 细胞生物学 Cell Biology细胞 Cell细胞核 Nucleus细胞膜 Cell membrane3. 生态学 Ecology生态系统 Ecosystem生物多样性 Biodiversity生物群落 Biome4. 分子生物学 Molecular Biology蛋白质 Protein核酸 Nucleic acid酶 Enzyme5. 发育生物学 Developmental Biology胚胎发育 Embryonic development细胞分化 Cell differentiation形态发生 Morphogenesis6. 植物学 Botany叶绿体 Chloroplast光合作用 Photosynthesis根系 Root system7. 动物学 Zoology器官 Organ组织 Tissue神经系统 Nervous system8. 微生物学 Microbiology细菌 Bacteria病毒 Virus真菌 Fungus9. 生物化学 Biochemistry代谢 MetabolismATP（三磷酸腺苷） ATP (Adenosine Triphosphate)酶促反应 Enzymatic reaction10. 生理学 Physiology心脏 Heart肺 Lung肝脏 Liver生物学英语中英对照（续）11. 进化生物学 Evolutionary Biology自然选择 Natural selection物种形成 Speciation进化树 Evolutionary tree12. 行为生物学 Behavioral Biology繁殖行为 Reproductive behavior领域行为 Territorial behavior社会行为 Social behavior13. 神经生物学 Neurobiology神经元 Neuron突触 Synapse神经递质 Neurotransmitter14. 免疫学 Immunology抗体 Antibody免疫系统 Immune system炎症 Inflammation15. 营养学 Nutrition蛋白质 Protein碳水化合物 Carbohydrate脂肪 Fat16. 遗传工程 Genetic Engineering基因克隆 Gene cloning基因编辑 Gene editing转基因技术 Genetic modification 17. 生态遗传学 Ecological Genetics种群 Population环境适应性 Environmental adaptation遗传漂变 Genetic drift18. 生物信息学 Bioinformatics基因组学 Genomics蛋白质组学 Proteomics生物数据挖掘 Bioinformatics data mining19. 生物统计学 Biostatistics实验设计 Experimental design数据分析 Data analysis显著性检验 Significance test20. 环境生物学 Environmental Biology环境污染 Environmental pollution生态修复 Ecological restoration生物降解 Biodegradation这份生物学英语中英对照文档旨在帮助您更全面地了解生物学领域的专业术语。

1、Once a suitable organism is found, conventional breeding and mutagenesismethods are used where possible to induce genetic changes that may produce even more of the desired product.一旦筛选到了合适的生物体，就尽可能地应用传统育种及诱变方法来使生物体发生遗传变化，从而产生更多的目标产物。

2、Thus, totally new capabilities can be engineered and microorganisms in particularand plant and animal cells to a lesser extent may be made to produce substances beyond their naturally endowed genetic capabilities通过这种方法就可以设计出全新的性能，并且,可以主要应用微生物和相对较少的动植物细胞来生产某些物质，它们的性质是那些本来正常遗传所不具备的。

3、Thus, resistance to viral infection and increased genetic stability may beincorporated into organisms that lack them, the formation of harmful by-products can be reduced or eliminated and objectionable odours, colours or slime products can be removed这样，对那些遗传稳定性不高，易遭受病毒感染的生物体来说，就可以提高抵抗力和稳定性，同时，有害副产品的形成也可以减少或消除，并且，那些具有令人讨厌的颜色、气味或粘质的产品也可以除掉。