bioengineered
简明释义
英[ˌbaɪoʊˈɪnʤɪrd]美[ˌbaɪoʊˈɪnʤɪrd]
生物工程(改造)的
英英释义
Referring to organisms or products that have been modified or created using biological engineering techniques, often involving the manipulation of genetic material. | 指通过生物工程技术修改或创造的生物体或产品,通常涉及对遗传材料的操控。 |
单词用法
同义词
| 基因改造的 | Genetically modified organisms (GMOs) are widely used in agriculture. | 转基因生物(GMO)在农业中被广泛使用。 | |
| 生物工程的 | 生物工程产品可以提高农作物产量。 | ||
| 生物操控的 | 合成生物学领域正在快速发展。 | ||
| 合成生物学 | 经过生物操控的农作物已被开发以抵御害虫。 |
反义词
例句
1.The study of tooth regeneration is an interesting topic for domestic and abroad scholars. Making bioengineered teeth is always a hotspot in dental researches.
牙齿再生的研究是国内外学者们十分关注的课题,构建有生物活性的组织工程化牙齿一直是该项研究的热点。
2."The ultimate goal of regenerative therapy is to develop fully functioning bioengineered organs that can replace lost or damaged organs following disease, injury or aging," they wrote.
“再生疗法的最终目标是产生功能齐全的生物工程器官,用于替代因疾病,伤害或老化导致的器官缺失或损坏,”他们写道。
3.This protein structure the bioengineered vein can be used in any human patient because the immunogenic part the cells have been removed "Dahl says."
这些蛋白结构,也就是生物工程血管可以用在任何病人身上,因为具有免疫原性的细胞已经被除掉了。
4.The ultimate goal of regenerative therapy, however, is to develop fully functioning bioengineered organs that can replace lost or damaged organs after disease, injury or aging.
然而,再生性治疗的最终目标是形成具有全部正常功能的生物工程器官来代替病变,损伤衰老后功能不全或缺陷的器官。
5.Now, scientists have demonstrated ready-to-use, bioengineered blood vessels made from human cells.
现在,科学家们已经演示了即用型、由人体细胞制成的生物工程血管。
6."The ultimate goal of regenerative therapy is to develop fully functioning bioengineered organs that can replace lost or damaged organs following disease, injury or aging," they wrote.
“再生疗法的最终目标是产生功能齐全的生物工程器官,用于替代因疾病,伤害或老化导致的器官缺失或损坏,”他们写道。
7.This work represents the first report of a bioengineered version of CD19-L, a recombinant human biotherapeutic agent, targeting CD19-positive leukemic stem cells.
本研究工作为CD19-L的生物工程版本(一种重组的人类生物治疗因子,其靶标为CD19阳性白血病干细胞)的首篇报告。
8.Other deadly organisms exist today which are not natural in origin, but rather have been bioengineered in genetic engineering laboratories located mostly in the United States.
现代存在的其他致命微生物并不源于自然,而大多出与美国的基因生物工程实验室。
9.The study of tooth regeneration is an interesting topic for domestic and abroad scholars, and making bioengineered teeth is always a hotspot in dental researches.
牙齿再生的研究是国内外学者们十分关注的课题,构建有生物活性的组织工程化牙齿一直是该项研究的热点所在。
10.Plantings of cotton bioengineered to produce its own insecticide against bollworms, a major cause of crop failure, sustained little bollworm damage until this year.
经过生物工程改造的棉花种植场可以生产自己的抗棉铃虫杀虫剂,而棉铃虫是造成农作物歉收的主要原因,直到今年,棉铃虫的危害都很小。
11.The bioengineered salmon grows faster than its non-modified counterparts.
这种生物工程三文鱼生长速度比未改良的同类快。
12.Farmers are increasingly adopting bioengineered crops to improve yields.
农民们越来越多地采用生物工程作物以提高产量。
13.Many consumers are concerned about the safety of bioengineered foods.
许多消费者对生物工程食品的安全性表示担忧。
14.The scientists developed a new strain of rice that is bioengineered to resist pests.
科学家们开发了一种新型稻米,该稻米经过生物工程处理,能够抵抗害虫。
15.The bioengineered tomatoes have a longer shelf life than traditional varieties.
这些生物工程番茄比传统品种具有更长的保质期。
作文
In recent years, the term bioengineered has gained significant attention in both scientific and public discussions. The concept of bioengineered organisms refers to those that have been genetically modified through various biotechnological methods to exhibit desired traits or characteristics. This can include anything from crops that are resistant to pests to animals that grow faster than their natural counterparts. The implications of bioengineered products are vast and multifaceted, influencing agriculture, medicine, and environmental sustainability.One of the most prominent applications of bioengineered technology is in agriculture. Farmers face numerous challenges, such as climate change, pest infestations, and soil degradation. To combat these issues, scientists have developed bioengineered crops that can withstand harsh conditions and require fewer chemical inputs. For example, bioengineered corn and soybeans are designed to resist specific herbicides, allowing farmers to control weeds more effectively without harming the crops. This innovation not only increases crop yields but also reduces the environmental impact of farming practices.Moreover, bioengineered crops can also be fortified with essential nutrients, addressing food security and nutritional deficiencies in populations around the world. Golden Rice, a bioengineered variety enriched with vitamin A, aims to combat blindness and other health issues in regions where rice is a staple food. By enhancing the nutritional profile of staple crops, bioengineered foods can play a crucial role in improving public health.In addition to agriculture, the field of medicine has also benefited from bioengineered technologies. One notable example is the production of insulin for diabetes treatment. Traditionally, insulin was extracted from animal pancreases, but with the advent of genetic engineering, scientists can now produce human insulin using bioengineered bacteria. This method is not only more efficient but also reduces the risk of allergic reactions associated with animal-derived insulin.Furthermore, bioengineered therapies, such as gene editing techniques like CRISPR, hold the potential to treat genetic disorders by correcting defective genes. These advancements could revolutionize the way we approach healthcare, offering hope for diseases that were previously deemed untreatable.Despite the numerous benefits of bioengineered organisms, there are also concerns surrounding their use. Critics argue that bioengineered products may pose risks to human health and the environment. There are fears about the long-term effects of consuming bioengineered foods and the potential for unintended consequences on ecosystems. Additionally, the ethical implications of manipulating the genetic makeup of living organisms raise questions about the limits of scientific intervention in nature.Public perception of bioengineered products varies widely, often influenced by cultural beliefs, personal values, and levels of understanding about biotechnology. Education and transparent communication are essential in addressing these concerns and fostering informed discussions about the role of bioengineered technologies in society.In conclusion, the term bioengineered encompasses a wide range of applications that have the potential to address some of the most pressing challenges facing humanity today. From enhancing agricultural productivity to advancing medical treatments, bioengineered technologies offer innovative solutions. However, it is crucial to balance these advancements with ethical considerations and public awareness to ensure that the benefits of bioengineered products are realized without compromising health or environmental integrity.
近年来,术语生物工程在科学和公众讨论中获得了显著关注。生物工程有机体的概念是指通过各种生物技术方法基因改造,以表现出所需的特征或特性。这可以包括从抗虫害的农作物到生长速度比其自然同类更快的动物。生物工程产品的影响广泛而复杂,影响农业、医学和环境可持续性。生物工程技术最显著的应用之一是在农业中。农民面临着诸多挑战,例如气候变化、虫害和土壤退化。为了应对这些问题,科学家们开发了能够抵御恶劣条件并减少化学投入的生物工程作物。例如,生物工程玉米和大豆被设计成抗特定除草剂,使农民能够更有效地控制杂草,而不会伤害作物。这一创新不仅提高了作物产量,还减少了农业实践对环境的影响。此外,生物工程作物还可以强化必需营养素,解决全球人口的粮食安全和营养不足问题。金米(Golden Rice)是一种富含维生素A的生物工程品种,旨在解决稻米作为主食的地区的失明和其他健康问题。通过增强主食作物的营养成分,生物工程食品在改善公共健康方面发挥着至关重要的作用。除了农业,医学领域也受益于生物工程技术。一个显著的例子是糖尿病治疗中胰岛素的生产。传统上,胰岛素是从动物胰腺提取的,但随着基因工程的出现,科学家们现在可以利用生物工程细菌生产人胰岛素。这种方法不仅更高效,而且减少了与动物来源的胰岛素相关的过敏反应风险。此外,生物工程疗法,如CRISPR等基因编辑技术,具有通过修正缺陷基因来治疗遗传疾病的潜力。这些进展可能会彻底改变我们对医疗保健的看法,为以前被认为无法治愈的疾病带来希望。尽管生物工程有机体的众多好处,但其使用也存在一些担忧。批评者认为,生物工程产品可能对人类健康和环境构成风险。人们担心消费生物工程食品的长期影响以及对生态系统的潜在意外后果。此外,操控生物体遗传构成的伦理问题引发了关于科学干预自然的界限的质疑。公众对生物工程产品的看法差异很大,通常受到文化信仰、个人价值观和对生物技术理解程度的影响。教育和透明的沟通在解决这些担忧和促进有关生物工程技术在社会中作用的知情讨论方面至关重要。总之,术语生物工程涵盖了一系列应用,有潜力解决当今人类面临的一些最紧迫的挑战。从提高农业生产力到推进医学治疗,生物工程技术提供了创新的解决方案。然而,平衡这些进步与伦理考量和公众意识是至关重要的,以确保实现生物工程产品的益处,而不危害健康或环境的完整性。
