bioengineering

简明释义

[ˌbaɪəʊˌendʒɪˈnɪərɪŋ][ˌbaɪoʊˌendʒɪˈnɪrɪŋ]

n. 生物工程;[生物物理] 生物工程学

英英释义

Bioengineering is the application of principles of biology and the tools of engineering to create solutions for problems related to living organisms.

生物工程是将生物学原理和工程工具应用于创造与生物体相关的问题解决方案的过程。

单词用法

bioengineering research

生物工程研究

bioengineering ethics

生物工程伦理

bioengineering degree

生物工程学位

bioengineering projects

生物工程项目

bioengineering solutions

生物工程解决方案

advancements in bioengineering

生物工程的进步

bioengineering innovations

生物工程创新

bioengineering challenges

生物工程挑战

bioengineering practices

生物工程实践

bioengineering applications in medicine

生物工程在医学中的应用

同义词

biotechnology

生物技术

Biotechnology is widely used in agriculture to enhance crop yield.

生物技术广泛用于农业,以提高作物产量。

genetic engineering

基因工程

Genetic engineering allows scientists to modify the DNA of organisms.

基因工程使科学家能够修改生物体的DNA。

biomedical engineering

生物医学工程

Biomedical engineering combines principles of engineering and medicine.

生物医学工程结合了工程学和医学的原则。

tissue engineering

组织工程

Tissue engineering aims to regenerate damaged tissues and organs.

组织工程旨在再生受损的组织和器官。

反义词

naturalism

自然主义

Naturalism emphasizes the importance of nature and natural processes.

自然主义强调自然和自然过程的重要性。

organic farming

有机农业

Organic farming avoids synthetic fertilizers and genetically modified organisms.

有机农业避免使用合成肥料和转基因生物。

例句

1.A developmental biologist and tissue engineer, Dr. Mironov, is one of only a few scientists worldwide involved in bioengineering "cultured" meat.

米罗诺夫博士是发展生物学家和组织工程师,是世界上少数的几位参与生物工程“培养”肉类的科学家之一。

2.Two of these bases were major including the much rumored bioengineering facility at Dulce New Mexico.

其中有两个主要基地,包括甚有谣传的位于新墨西哥州杜尔塞(河琉名)的生物工程设施。

3.As management bioengineering subject developed, human beings began to use bioengineering method to research enterprises' management behaviors.

随着管理生物工程学科的兴起,人们开始应用生物工程的方法来研究企业的经营管理行为。

4.Technical principle, research situation and prospect of ion beam bioengineering are discussed in the this paper.

对离子束生物工程的技术原理、研究现状和发展趋势进行了综合评述。

5.Mironov is one of just a handful of scientists around the world who are involved in bioengineering cultured meat.

米罗诺夫是世界上少数几个研究生物工程培养肉的科学家之一。

6.Animalcule fermentation engineering is the foundation of bioengineering as well as modern biology technology and bioengineering industrialization.

微生物发酵工程是生物工程和现代生物技术及其产业化的基础。

7.Mironov is one of only a few scientists worldwide involved in bioengineering cultured meat.

米罗诺夫是世界上为数不多的从事生物工程培养肉的科学家之一。

8.Have fine ESD, dustproof performance, is used in the trades, such as electron, medicine, bioengineering optics, spaceflight, aviation, etc. extensively.

具有优良的防静电、防尘性能,广泛用于电子、医药、生物工程光学、航天、航空等行业。

9.Animalcule fermentation is the basis of bioengineering as well as modern biology technology and bioengineering industrialization.

微生物发酵是生化工程和现代生物技术及其产业化的基础。

10.The application of bioengineering 生物工程 in medicine is revolutionizing patient care.

在医学中应用生物工程 bioengineering 正在彻底改变病人护理。

11.Many universities now offer degrees in bioengineering 生物工程 to prepare students for careers in biotechnology.

许多大学现在提供生物工程 bioengineering 学位,以为学生准备生物技术职业。

12.A breakthrough in bioengineering 生物工程 has led to new treatments for genetic disorders.

生物工程 bioengineering 方面的突破导致了新的遗传疾病治疗方法。

13.The field of bioengineering 生物工程 has made significant advancements in developing artificial organs.

生物工程 bioengineering 领域,人工器官的开发取得了显著进展。

14.Researchers are using bioengineering 生物工程 techniques to create crops that can withstand harsh climates.

研究人员正在使用生物工程 bioengineering 技术来创造能够抵御恶劣气候的农作物。

作文

Bioengineering, or 生物工程, is a multidisciplinary field that applies principles of biology and engineering to create solutions for various challenges in healthcare, agriculture, and environmental sustainability. This innovative discipline has gained significant attention in recent years due to its potential to revolutionize the way we approach some of the most pressing issues facing humanity today. From developing new medical therapies to enhancing crop yields, 生物工程 plays a crucial role in improving our quality of life and safeguarding our planet. One of the most notable applications of bioengineering is in the realm of medicine. Scientists and engineers work together to design and produce biopharmaceuticals, which are drugs derived from biological sources. These medications can target specific diseases more effectively than traditional pharmaceuticals, leading to better patient outcomes. For instance, monoclonal antibodies, a type of biopharmaceutical, have been instrumental in treating conditions like cancer and autoimmune disorders. The ability to manipulate biological systems at the molecular level is a hallmark of 生物工程, making it a powerful tool in modern medicine.In addition to healthcare, bioengineering is making strides in agriculture. Genetic engineering techniques allow scientists to modify crops to be more resistant to pests, diseases, and environmental stresses. This not only increases food security but also reduces the need for chemical pesticides, which can harm ecosystems. For example, genetically modified organisms (GMOs) such as Bt cotton and Roundup Ready soybeans have been developed to withstand specific threats while maintaining high yield levels. These advancements in agricultural 生物工程 contribute to sustainable farming practices, helping to feed a growing global population.Furthermore, bioengineering has significant implications for environmental conservation. Bioremediation, a process that uses living organisms to clean up contaminated environments, is an area where 生物工程 is particularly impactful. By harnessing the natural abilities of certain microbes, scientists can develop strategies to detoxify polluted soils and water bodies. This not only restores ecosystems but also promotes biodiversity, ensuring that future generations inherit a healthier planet.Despite its many benefits, bioengineering also raises ethical and safety concerns. The manipulation of genetic material and the creation of GMOs have sparked debates about potential risks to human health and the environment. Regulatory frameworks are essential to ensure that 生物工程 practices are conducted safely and responsibly. Public engagement and education are also critical in addressing misconceptions and fostering informed discussions about the implications of this technology.In conclusion, bioengineering is a transformative field that holds immense promise for advancing healthcare, enhancing agricultural productivity, and promoting environmental sustainability. As we continue to explore the possibilities within 生物工程, it is imperative that we approach this powerful tool with caution and responsibility, ensuring that its applications benefit society as a whole. By embracing innovation while prioritizing ethics and safety, we can harness the full potential of bioengineering to create a better future for all.

生物工程是一个多学科领域,应用生物学和工程学的原则,为医疗保健、农业和环境可持续性等各种挑战创造解决方案。由于其在应对当今人类面临的一些最紧迫问题方面的潜力,这一创新学科近年来引起了广泛关注。从开发新的医疗疗法到提高作物产量,生物工程在改善我们的生活质量和保护地球方面发挥着至关重要的作用。生物工程最显著的应用之一是在医学领域。科学家和工程师共同合作,设计和生产生物制药,即源自生物来源的药物。这些药物可以比传统药物更有效地针对特定疾病,从而改善患者的治疗效果。例如,单克隆抗体作为一种生物制药,在治疗癌症和自身免疫性疾病方面发挥了重要作用。在分子层面上操纵生物系统的能力是生物工程的一个标志,使其成为现代医学中的强大工具。除了医疗保健,生物工程在农业方面也取得了进展。基因工程技术使科学家能够修改作物,使其更能抵御害虫、疾病和环境压力。这不仅增加了粮食安全,还减少了对化学杀虫剂的需求,这些杀虫剂可能会对生态系统造成伤害。例如,转基因生物(GMO)如Bt棉花和抗草甘膦大豆已经被开发出来,以抵御特定威胁,同时保持高产量水平。这些农业生物工程的进展有助于可持续农业实践,帮助养活不断增长的全球人口。此外,生物工程对环境保护也具有重要意义。生物修复是一种利用生物体清理污染环境的过程,这是生物工程特别有影响力的领域之一。通过利用某些微生物的自然能力,科学家可以制定策略来净化被污染的土壤和水体。这不仅恢复了生态系统,还促进了生物多样性,确保未来几代人继承一个更健康的地球。尽管生物工程有许多好处,但它也引发了伦理和安全方面的担忧。基因材料的操纵和转基因生物的创造引发了关于对人类健康和环境潜在风险的辩论。监管框架对于确保生物工程实践的安全和负责任的进行至关重要。公众参与和教育在解决误解和促进对这一技术影响的知情讨论方面也至关重要。总之,生物工程是一个具有变革潜力的领域,为推动医疗保健、提高农业生产力和促进环境可持续性提供了巨大希望。随着我们继续探索生物工程的可能性,我们必须以谨慎和负责任的态度对待这一强大工具,确保其应用惠及整个社会。通过拥抱创新,同时优先考虑伦理和安全,我们可以充分利用生物工程的潜力,为所有人创造一个更美好的未来。