metabolomics

简明释义

英[mɪtæˌbəˈlɒmɪks]美[metæˈbɑːləmɪks]

代谢组学

英英释义

单词用法

同义词

反义词

例句

1.Metabolomics can provide very specific Pointers as to what is going wrong and new ways of intervening.

新陈代谢可以为身体提供很多的详细指标，像哪里出问题了和阻止问题的新方法。

2.From microbial product exploitation to metabolic engineering application, microbial metabolomics has become the focus of research.

从微生物产品开发到代谢工程的应用，微生物代谢组学已成为研究热点。

3.Annual Plant Reviews, Volume 43, Biology Of Plant Metabolomics ( Annual Plant Reviews )

年度植物评论，43卷，植物代谢组学生物学。

4.Different substances and different metabolic pathways between the three syndromes of MS could be identified with metabolomics technology.

而且MS三个中医证型之间也存在着不同的物质代谢或代谢网络的改变。

5.We also cover some fundamental issues related to biological sequence analyses, transcriptome analyses, computational proteomics, computational metabolomics, bio-ontologies, and biological databases.

我们也涵盖了与生物学序列分析、转录组分析、计算蛋白质组学、计算代谢组学、生物-本体论及生物学数据库相关的一些基本问题。

6.This article reviews Metabolomics about its definition and feature, study method, application and so on.

文章从代谢组学的定义及特点、研究方法、应用等方面予以阐述。

7.Metabolomics is a new science and technology, which it refers to a holistic analytical approach to all the low molecular weight metabolites in an organism or a cell.

代谢组学是对某一生物或细胞所有低分子量代谢产物进行定性和定量分析的一门新学科。

8.Researchers are using metabolomics to identify biomarkers for early disease detection.

研究人员正在利用代谢组学识别早期疾病检测的生物标志物。

9.The study of metabolomics can provide insights into how diet affects health.

对代谢组学的研究可以提供饮食如何影响健康的见解。

10.In cancer research, metabolomics is helping scientists understand tumor metabolism.

在癌症研究中，代谢组学正在帮助科学家理解肿瘤代谢。

11.By analyzing blood samples, metabolomics can reveal metabolic disorders.

通过分析血液样本，代谢组学可以揭示代谢紊乱。

12.Pharmaceutical companies are increasingly adopting metabolomics to improve drug development.

制药公司越来越多地采用代谢组学来改善药物开发。

作文

In recent years, the field of science has made significant strides in understanding the complex biochemical processes that occur within living organisms. One of the most exciting areas of research is known as metabolomics, which refers to the comprehensive study of metabolites in biological systems. Metabolites are small molecules that are the end products of cellular processes, and they play crucial roles in metabolism, signaling, and regulation within cells.The importance of metabolomics lies in its ability to provide insights into the physiological state of an organism. By analyzing the profiles of metabolites present in a sample, researchers can gain valuable information about how an organism responds to various environmental factors, diseases, or treatments. This approach is particularly beneficial in fields such as personalized medicine, where understanding an individual’s unique metabolic profile can lead to more effective and tailored therapeutic strategies.One of the key techniques used in metabolomics is mass spectrometry, which allows scientists to identify and quantify metabolites with high sensitivity and specificity. Coupled with advanced statistical analysis and bioinformatics, mass spectrometry enables researchers to interpret complex data sets and draw meaningful conclusions about metabolic changes associated with different conditions.For example, in cancer research, metabolomics has been instrumental in identifying specific metabolic signatures that distinguish tumor cells from normal cells. By understanding these differences, researchers can develop new diagnostic tools and therapeutic targets that are based on the unique metabolic pathways active in cancer cells. Similarly, in the field of nutrition, metabolomics can help elucidate how dietary components influence metabolic health, providing insights into the relationship between diet and chronic diseases such as obesity and diabetes.Despite its potential, metabolomics faces several challenges. One major hurdle is the complexity of the metabolome, which consists of thousands of metabolites that can vary widely between individuals and even within the same individual over time. Additionally, the dynamic nature of metabolism means that metabolite levels can change rapidly in response to various stimuli, making it difficult to obtain a stable snapshot of an organism's metabolic state.To overcome these challenges, researchers are continually refining their methodologies and developing new technologies that enhance the sensitivity and accuracy of metabolomics studies. Collaborative efforts across disciplines, including chemistry, biology, and computational science, are essential for advancing this field and unlocking the full potential of metabolic analysis.In conclusion, metabolomics represents a powerful tool for understanding the intricate biochemical networks that govern life. As research continues to evolve, the insights gained from metabolomics will undoubtedly contribute to advancements in health care, agriculture, and environmental science. By harnessing the power of metabolite profiling, scientists can pave the way for innovative solutions to some of the most pressing challenges facing humanity today.

近年来，科学领域在理解生物体内发生的复杂生化过程方面取得了显著进展。一个令人兴奋的研究领域被称为代谢组学，它指的是对生物系统中代谢物的全面研究。代谢物是细胞过程的最终产物，是小分子，在细胞内的代谢、信号传递和调节中发挥着至关重要的作用。代谢组学的重要性在于它能够提供有关生物体生理状态的见解。通过分析样本中存在的代谢物谱，研究人员可以获得有关生物体如何响应各种环境因素、疾病或治疗的宝贵信息。这种方法在个性化医学等领域尤其有益，因为了解个体独特的代谢特征可以导致更有效和量身定制的治疗策略。代谢组学中使用的一项关键技术是质谱法，它允许科学家以高灵敏度和特异性识别和定量代谢物。结合先进的统计分析和生物信息学，质谱法使研究人员能够解释复杂的数据集，并得出关于与不同条件相关的代谢变化的有意义结论。例如，在癌症研究中，代谢组学在识别区分肿瘤细胞和正常细胞的特定代谢特征方面发挥了重要作用。通过理解这些差异，研究人员可以开发基于癌细胞活跃的独特代谢途径的新诊断工具和治疗靶点。类似地，在营养学领域，代谢组学可以帮助阐明膳食成分如何影响代谢健康，为饮食与慢性疾病（如肥胖和糖尿病）之间的关系提供见解。尽管潜力巨大，代谢组学仍面临一些挑战。一个主要障碍是代谢组的复杂性，它由数千种代谢物组成，这些代谢物在个体之间以及同一个体在不同时间之间可能差异很大。此外，代谢的动态特性意味着代谢物水平可以迅速响应各种刺激而变化，这使得获得生物体代谢状态的稳定快照变得困难。为了克服这些挑战，研究人员不断改进他们的方法，并开发新技术，以增强代谢组学研究的灵敏度和准确性。跨学科的协作努力，包括化学、生物学和计算科学，对于推动这一领域的发展并释放代谢分析的全部潜力至关重要。总之，代谢组学代表了一种强大的工具，用于理解支配生命的复杂生化网络。随着研究的不断发展，从代谢组学获得的见解无疑将促进医疗保健、农业和环境科学的进步。通过利用代谢物分析的力量，科学家们可以为应对当今人类面临的一些最紧迫的挑战铺平道路。