AI Article Synopsis
- Microbe-associated infectious diseases pose significant challenges to human health, and diagnosing these diseases is complicated by the lack of specific and reliable methods.
- Systems biology-driven metabolomics offers a promising approach by focusing on microbial functions rather than just phenotypes, enabling better diagnosis and treatment strategies.
- This chapter highlights various microbial metabolomics techniques and their applications in understanding diseases like obesity, UTIs, and hepatitis C, encouraging further research in this field for improved diagnosis and therapeutic solutions.
Article Abstract
Most microbe-associated infectious diseases severely affect human health. However, clinical diagnosis of pathogenic diseases remains challenging due to the lack of specific and highly reliable methods. To better understand the diagnosis, pathogenesis, and treatment of these diseases, systems biology-driven metabolomics goes beyond the annotated phenotype and better targets the functions than conventional approaches. As a novel strategy for analysis of metabolomes in microbes, microbial metabolomics has been recently used to study many diseases, such as obesity, urinary tract infection (UTI), and hepatitis C. In this chapter, we attempt to introduce various microbial metabolomics methods to better interpret the microbial metabolism underlying a diversity of infectious diseases and inspire scientists to pay more attention to microbial metabolomics, enabling broadly and efficiently its translational applications to infectious diseases, from molecular diagnosis to therapeutic discovery.
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| http://dx.doi.org/10.1007/978-3-030-51652-9_7 | DOI Listing |
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