biogenetic

简明释义

[ˌbaɪəʊdʒəˈnetɪk][baɪoʊdʒeˈnetɪk]

adj. 生物起源的;生物发生的

英英释义

Relating to the production of living organisms from other living organisms, often involving genetic manipulation.

与通过其他生物体产生生物体有关,通常涉及基因操作。

单词用法

biogenetic materials

生物遗传材料

biogenetic modifications

生物遗传修饰

biogenetic diversity

生物遗传多样性

biogenetic technology

生物遗传技术

biogenetic inheritance

生物遗传继承

biogenetic traits

生物遗传特征

同义词

genetic

遗传的

genetic engineering is a biogenetic process

基因工程是一个生物遗传过程

biological

生物的

the biological factors influence health

生物因素影响健康

hereditary

遗传性的

hereditary traits are passed from parents to offspring

遗传特征从父母传给后代

evolutionary

进化的

evolutionary biology studies the origin of species

进化生物学研究物种的起源

反义词

abiotic

非生物的

Abiotic factors such as temperature and sunlight play a crucial role in ecosystem dynamics.

非生物因素如温度和阳光在生态系统动态中起着关键作用。

non-genetic

非遗传的

Non-genetic traits can be influenced by environmental factors rather than inherited.

非遗传特征可以受到环境因素的影响,而不是遗传的。

例句

1.The bacteria related to the biogenetic karstification have been found in many samples of gypsum.

在所研究的样品中,都检测到这些可发生生物岩溶作用的菌类。

2.The most common biogenetic minerals are carbonates, sulfides and iron oxides.

最普遍的生物成因矿物有碳酸盐、硫化物和铁的氧化物。

3.The sample analysis showed that the nature gas at this area belonged to methane biogenetic gas.

气样组分分析表明,该区天然气属甲烷型生物成因气。

4.The bacteria related to the biogenetic karstification have been found in many samples of gypsum.

在所研究的样品中,都检测到这些可发生生物岩溶作用的菌类。

5.Understanding biogenetic 生物遗传的 principles is essential for developing personalized medicine.

理解生物遗传的原则对于开发个性化医学至关重要。

6.Advances in biogenetic 生物遗传的 engineering have led to new treatments for genetic disorders.

生物遗传的工程技术的进步导致了针对遗传疾病的新治疗方法。

7.The biogenetic 生物遗传的 modifications in crops can enhance their resistance to pests.

作物中的生物遗传的改良可以增强它们对害虫的抵抗力。

8.The biogenetic 生物遗传的 research aims to uncover the secrets of DNA.

这项生物遗传的研究旨在揭示DNA的秘密。

9.The researchers are studying the biogenetic 生物遗传的 factors that influence human health.

研究人员正在研究影响人类健康的生物遗传的因素。

作文

In recent years, the field of science has made tremendous advancements, especially in genetics and biotechnology. One of the most fascinating areas of study is that of biogenetic (生物遗传的) engineering, which focuses on the manipulation of living organisms' genetic material to achieve desired traits and characteristics. This innovative approach has opened up new possibilities in medicine, agriculture, and environmental conservation.The concept of biogenetic (生物遗传的) engineering is rooted in the understanding of DNA, the fundamental building block of life. Scientists have learned how to edit genes using techniques such as CRISPR-Cas9, which allows for precise modifications to an organism's genome. This technology has the potential to eradicate genetic disorders, enhance crop resilience, and even combat climate change by creating organisms that can thrive in extreme conditions.In medicine, biogenetic (生物遗传的) engineering has revolutionized the way we approach disease treatment. For instance, gene therapy offers hope for patients suffering from hereditary diseases like cystic fibrosis or sickle cell anemia. By directly correcting defective genes, researchers aim to provide long-lasting cures rather than temporary relief. Moreover, the development of personalized medicine, which tailors treatments based on an individual’s genetic makeup, is a direct result of advancements in biogenetic (生物遗传的) research.Agriculture is another field where biogenetic (生物遗传的) engineering has made significant strides. Genetically modified organisms (GMOs) have been developed to resist pests, tolerate harsh environmental conditions, and improve nutritional content. These innovations are crucial in addressing global food security challenges, especially as the world’s population continues to grow. However, the use of GMOs remains a contentious issue, with debates surrounding their safety and ethical implications.Furthermore, biogenetic (生物遗传的) engineering plays a vital role in environmental conservation efforts. Scientists are exploring ways to engineer microorganisms that can break down pollutants or absorb excess carbon dioxide from the atmosphere. Such applications could mitigate the effects of climate change and help restore damaged ecosystems. The potential benefits of biogenetic (生物遗传的) solutions in this regard are immense, yet they also raise questions about unintended consequences and ecological balance.Despite the promising prospects of biogenetic (生物遗传的) engineering, it is essential to approach this field with caution. Ethical considerations must be at the forefront of discussions, particularly concerning the manipulation of human genes. Issues such as designer babies and the potential for genetic discrimination pose significant moral dilemmas that society must address. Regulatory frameworks will need to evolve to ensure that biogenetic (生物遗传的) technologies are used responsibly and equitably.In conclusion, the advancements in biogenetic (生物遗传的) engineering present both exciting opportunities and formidable challenges. As we continue to explore the depths of genetic science, it is imperative that we balance innovation with ethical responsibility. By fostering open dialogues among scientists, ethicists, policymakers, and the public, we can harness the power of biogenetic (生物遗传的) technologies to improve lives while safeguarding our shared future.