genotypical

简明释义

英[ˌdʒɛnəʊˈtɪpɪkəl]美[ˌdʒɛnəˈtɪpɪkəl]

adj. 遗传型的

英英释义

单词用法

同义词

反义词

例句

1.Objective: to study the genotypical polymorphism of CYP2C19, a cytochrome oxidase, in Chinese healthy and hyperthyroid populations.

目的：考察中国健康人群和甲亢患者细胞色素氧化酶cyp2c19遗传多态性的相关性。

2.Objective: to study the genotypical polymorphism of CYP2C19, a cytochrome oxidase, in Chinese healthy and hyperthyroid populations.

目的：考察中国健康人群和甲亢患者细胞色素氧化酶cyp2c19遗传多态性的相关性。

3.The researchers aimed to compare the genotypical 基因型的 differences between the two species.

研究人员旨在比较这两个物种之间的基因型的差异。

4.Understanding the genotypical 基因型的 variations can help in developing targeted therapies.

理解基因型的变异可以帮助开发针对性的治疗方案。

5.The experiment focused on the genotypical 基因型的 expression of certain traits in plants.

实验集中于植物某些性状的基因型的表现。

6.In this study, we will analyze the genotypical 基因型的 makeup of the population.

在这项研究中，我们将分析该人群的基因型的构成。

7.The genotypical 基因型的 assessment revealed significant insights into disease resistance.

对基因型的评估揭示了对疾病抵抗的重要见解。

作文

In the field of genetics, the concept of genotypical traits plays a crucial role in understanding how organisms inherit characteristics from their ancestors. The term genotypical refers to the genetic constitution of an individual, specifically the alleles they possess for a particular gene. This genetic makeup is fundamental in determining not only the physical appearance of an organism but also its behavior, physiology, and overall health. For instance, when studying plants, researchers often look at the genotypical variations to understand how certain traits, such as drought resistance or disease susceptibility, are inherited and expressed. The importance of genotypical analysis extends beyond basic biology; it has significant implications in agriculture, medicine, and conservation. In agriculture, understanding the genotypical differences among crop varieties can lead to better yields and more resilient food sources. Farmers can select seeds with favorable genotypical traits that are better suited to their local environments, thereby increasing productivity and sustainability. In medicine, knowledge of a patient’s genotypical information can inform treatment plans, particularly in the realm of personalized medicine. By analyzing an individual’s genotypical makeup, healthcare providers can predict how that person will respond to certain medications or therapies. This approach minimizes adverse effects and maximizes the effectiveness of treatments, leading to better patient outcomes. Moreover, conservation efforts benefit greatly from understanding the genotypical diversity within species. Conservation biologists study the genotypical variations among populations to ensure genetic diversity is maintained. This diversity is crucial for the adaptability and resilience of species in changing environments. When a population lacks genotypical diversity, it becomes more vulnerable to diseases and environmental changes, which can lead to extinction. However, the study of genotypical traits is not without its challenges. One major issue is the complexity of gene interactions. Many traits are influenced by multiple genes, and the environment can also play a significant role in how these traits are expressed. This means that identifying a single genotypical trait does not provide a complete picture of an organism's capabilities or limitations. Researchers must consider both the genotypical and environmental factors to gain a comprehensive understanding of biological systems. Furthermore, ethical considerations arise when manipulating genotypical traits, particularly in humans and other animals. Genetic engineering and gene editing technologies, such as CRISPR, allow scientists to alter genotypical traits, raising questions about the implications of such modifications. Society must grapple with the moral and ethical ramifications of altering the genetic makeup of living beings. In conclusion, the study of genotypical traits is essential for advancements in various fields, including agriculture, medicine, and conservation. Understanding an organism's genotypical constitution allows scientists and practitioners to make informed decisions that can enhance productivity, improve health outcomes, and preserve biodiversity. As we continue to explore the complexities of genetics, it is vital to approach the subject with both curiosity and caution, recognizing the profound impact our understanding of genotypical traits can have on the future of life on Earth.

在遗传学领域，genotypical 特征的概念在理解生物如何从祖先那里继承特征方面起着至关重要的作用。术语 genotypical 指的是个体的遗传构成，特别是他们在特定基因上所拥有的等位基因。这种遗传构成在决定生物的外貌、行为、生理和整体健康方面是基础性的。例如，在研究植物时，研究人员通常会观察 genotypical 变异，以了解某些特征（如抗旱性或抗病性）是如何遗传和表现的。 genotypical 分析的重要性超越了基础生物学；它在农业、医学和保护方面具有重要意义。在农业中，了解作物品种之间的 genotypical 差异可以导致更好的产量和更具韧性的食品来源。农民可以选择具有有利 genotypical 特征的种子，这些特征更适合他们的本地环境，从而提高生产力和可持续性。 在医学中，了解患者的 genotypical 信息可以为治疗计划提供指导，特别是在个性化医学领域。通过分析个体的 genotypical 构成，医疗提供者可以预测该人对某些药物或治疗的反应。这种方法最小化了不良反应，并最大化了治疗效果，从而改善了患者的健康结果。 此外，保护工作也因了解物种内部的 genotypical 多样性而大大受益。保护生物学家研究种群之间的 genotypical 变异，以确保保持遗传多样性。这种多样性对于物种在变化环境中的适应能力和韧性至关重要。当一个种群缺乏 genotypical 多样性时，它就会变得更容易受到疾病和环境变化的影响，这可能导致灭绝。 然而，genotypical 特征的研究并非没有挑战。一个主要问题是基因相互作用的复杂性。许多特征受到多个基因的影响，环境也可以在这些特征的表现中发挥重要作用。这意味着识别单一的 genotypical 特征并不能提供生物能力或限制的完整图景。研究人员必须考虑 genotypical 和环境因素，以全面了解生物系统。 此外，当操纵 genotypical 特征时，会出现伦理问题，特别是在涉及人类和其他动物时。基因工程和基因编辑技术（如CRISPR）使科学家能够改变 genotypical 特征，引发了关于这种修改的影响的问题。社会必须面对改变生物遗传构成的道德和伦理后果。 总之，genotypical 特征的研究对于农业、医学和保护等多个领域的进步至关重要。了解生物的 genotypical 构成使科学家和从业者能够做出明智的决策，从而增强生产力、改善健康结果和保护生物多样性。随着我们继续探索遗传学的复杂性，重要的是以好奇心和谨慎的态度来对待这一主题，认识到我们对 genotypical 特征的理解对地球生命未来的深远影响。