genetic
简明释义
adj. 基因的,遗传学的;有共同起源的
英英释义
与基因或遗传有关的。 | |
与某事物的起源或发展有关的。 |
单词用法
遗传算法 | |
遗传工程 |
同义词
| 遗传的 | 遗传性疾病 | ||
| 继承的 | 继承特征 | ||
| 基因组的 | 基因组研究 | ||
| 基于DNA的 | 基于DNA的技术 |
反义词
| 环境的 | 环境因素在健康中起着重要作用。 | ||
| 后天获得的 | 后天获得的特征可以受到生活方式选择的影响。 |
例句
1.Eye colour shows more than your genetic inheritance.
眼睛的颜色显示的不只是你基因的遗传特征。
2.Scientists have made genetic modifications to cotton to increase its resistance to insect pests.
科学家对棉花进行了基因改造,以增强其对害虫的抵抗力。
3.DNA carries the genetic blueprint which tells any organism how to build itself.
脱氧核糖核酸带有决定有机体形成方式的遗传型板。
4.Cystic fibrosis is the most common fatal genetic disease in the United States.
囊肿性纤维化在美国是最常见的致命性遗传疾病。
5.Scientists provided the key to understanding the genetic code that determines every bodily feature.
科学家们提供了线索来了解决定每个身体特征的遗传密码。
6.In January 2008, Isabelle was diagnosed with a genetic blood disorder.
2008年1月,伊莎贝尔被诊断出患有遗传性血液疾病。
7.In January 2008 Isabelle was diagnosed with a genetic blood disorder.
2008年1月,伊莎贝尔被诊断出患有遗传性血液疾病。
8.Forslan's object is to gather as great a diversity of genetic material as possible.
福斯兰的目标是尽可能收集各种不同的基因物质。
9.The genetic 遗传的 testing revealed that she had a higher risk for breast cancer.
这项遗传的测试显示她患乳腺癌的风险更高。
10.Understanding genetic 遗传的 inheritance patterns can help predict health issues in families.
了解遗传的遗传模式可以帮助预测家庭健康问题。
11.Researchers are studying the role of genetic 遗传的 factors in the development of certain diseases.
研究人员正在研究某些疾病发展中遗传的因素的作用。
12.Scientists are exploring how genetic 遗传的 modifications can improve crop yields.
科学家们正在探索如何通过遗传的修改来提高作物产量。
13.He has a genetic 遗传的 disorder that affects his ability to process information.
他有一种影响信息处理能力的遗传的疾病。
作文
The concept of genetic inheritance has fascinated scientists and the general public alike for many years. At its core, genetic refers to the study of genes, heredity, and genetic variation in living organisms. This field of study is crucial for understanding how traits are passed from parents to offspring and how these traits can evolve over generations. The implications of genetic research are vast, influencing areas such as medicine, agriculture, and even conservation efforts.One of the most significant breakthroughs in genetic science was the discovery of DNA's structure by James Watson and Francis Crick in 1953. This revelation opened up new avenues for exploring how genetic information is stored and transmitted. With the mapping of the human genome completed in 2003, researchers gained unprecedented insight into our genetic makeup. This knowledge has paved the way for advancements in personalized medicine, where treatments can be tailored to an individual's genetic profile.Moreover, genetic engineering has emerged as a powerful tool that allows scientists to modify the DNA of organisms. This technology has led to the development of genetically modified organisms (GMOs), which have been used to increase crop yields and resistance to pests. While GMOs hold great promise for addressing food security, they also raise ethical questions about the manipulation of natural processes.In addition to agriculture, genetic research plays a pivotal role in understanding and treating diseases. Many conditions, such as cystic fibrosis and certain types of cancer, have a genetic component. By studying the genetic basis of these diseases, scientists hope to develop targeted therapies that can improve patient outcomes. For instance, gene therapy aims to correct defective genes responsible for disease development, offering potential cures for previously untreatable conditions.However, the implications of genetic research extend beyond health and agriculture. Issues such as privacy and discrimination based on genetic information have emerged as significant concerns. As we learn more about our genetic predispositions, there is a risk that individuals could face discrimination in employment or insurance based on their genetic makeup. Therefore, it is essential to establish ethical guidelines and legal protections to ensure that genetic information is used responsibly.Furthermore, the study of genetic diversity is critical for conservation efforts. Understanding the genetic variability within endangered species can help conservationists develop strategies to preserve biodiversity. By maintaining a healthy genetic pool, we can enhance the resilience of species against environmental changes and diseases.In conclusion, the field of genetic research holds immense potential for improving our lives. From advancing medical treatments to enhancing agricultural productivity, the applications of genetic science are far-reaching. However, with these advancements come ethical considerations that must be addressed. As we continue to explore the mysteries of our genetic code, it is vital to balance innovation with responsibility, ensuring that the benefits of genetic research are realized while safeguarding individual rights and the environment.
遗传学的概念多年来一直吸引着科学家和公众的关注。其核心是,genetic(遗传的)指的是对基因、遗传和生物体内遗传变异的研究。这一研究领域对于理解特征如何从父母传递给后代,以及这些特征如何在几代人中演变至关重要。genetic(遗传的)研究的影响深远,影响着医学、农业,甚至保护工作。在遗传学科学中,最显著的突破之一是詹姆斯·沃森和弗朗西斯·克里克在1953年发现DNA结构。这一发现为探索遗传信息的存储和传递开辟了新途径。随着人类基因组的绘制于2003年完成,研究人员获得了对我们genetic(遗传的)构成前所未有的洞察。这一知识为个性化医学的进步铺平了道路,使得治疗可以根据个体的genetic(遗传的)特征进行定制。此外,genetic(遗传的)工程作为一种强大的工具,使科学家能够修改生物体的DNA。这项技术导致了转基因生物(GMO)的发展,这些生物已被用于提高作物产量和抵抗害虫。虽然转基因生物在解决粮食安全问题上具有巨大潜力,但它们也引发了关于自然过程操控的伦理问题。除了农业,genetic(遗传的)研究在理解和治疗疾病方面也发挥着关键作用。许多疾病,如囊性纤维化和某些类型的癌症,都具有genetic(遗传的)成分。通过研究这些疾病的genetic(遗传的)基础,科学家希望开发出能够改善患者预后的靶向疗法。例如,基因治疗旨在修正导致疾病发展的缺陷基因,为以前无法治愈的疾病提供潜在的治疗方案。然而,genetic(遗传的)研究的影响超越了健康和农业。基于genetic(遗传的)信息的隐私和歧视等问题已成为重要关注点。随着我们对自身genetic(遗传的)倾向的了解加深,个人可能面临因其genetic(遗传的)构成而在就业或保险方面受到歧视的风险。因此,建立伦理指南和法律保护至关重要,以确保genetic(遗传的)信息的负责任使用。此外,genetic(遗传的)多样性的研究对于保护工作至关重要。理解濒危物种内的genetic(遗传的)变异性可以帮助保护主义者制定保护生物多样性的策略。通过维持健康的genetic(遗传的)基因库,我们可以增强物种对环境变化和疾病的抵御能力。总之,genetic(遗传的)研究领域对改善我们的生活具有巨大的潜力。从推进医疗治疗到提高农业生产力,genetic(遗传的)科学的应用范围广泛。然而,随着这些进展而来的伦理考虑必须得到解决。在我们继续探索genetic(遗传的)密码的奥秘时,平衡创新与责任至关重要,确保genetic(遗传的)研究的好处得以实现,同时保护个人权利和环境。
