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Metabolon Services Used in Pioneering Multiomic Research on Brain Metabolism and Neurodegenerative Disorders

Ground-breaking investigation leverages Metabolon’s Global Discovery Panel for metabolite genome-wide association study (MGWAS) for cerebrospinal fluid (CSF) and brain metabolite levels as they pertain to neurodegenerative disorders

MORRISVILLE, N.C. – November 12, 2024 – Metabolon, Inc., the global leader in providing metabolomics solutions advancing a wide variety of life science research, diagnostic, therapeutic development, and precision medicine applications, announced its Global Discovery Panel™ was selected for a ground-breaking study, published in Nature Genetics, by Dr. Cruchaga at the Neurogenomics and Informatics Center Washington University School of Medicine at St. Louis and a host of collaborating researchers about brain metabolism and neurodegenerative diseases.

Neurodegenerative diseases such as Alzheimer’s and Parkinson’s disease affect millions of people worldwide.  Alzheimer’s disease impacts an estimated 50 million people globally, and approximately 10 million new cases of dementia are diagnosed each year.  The global cost of Alzheimer’s and other dementias is estimated to be over $1 trillion annually, a number expected to double by 2030 as the world’s population ages. 

Carlos Cruchaga and his team of researchers generated samples collected at the Knight Alzheimer Disease Research Center (Knight ADRC) and other studies in a pioneering multiomic investigation that leveraged advanced genomic and metabolomic research technologies.  These analyses not only identified metabolites associated with several neurodegenerative diseases, but also identified those that are part of causal disease pathways and are druggable targets.  This study organizes the largest CSF cohort ever examined, as CSF makes a useful proxy for understanding brain metabolism.  Metabolon was chosen to provide in-depth metabolomic analysis due to the size and diversity of Metabolon’s industry-leading metabolite library and Metabolon’s high-capacity platform, which can process and analyze thousands of samples in a matter of weeks.

“Our study identified novel genetic associations for metabolites through CSF and brain metabolomics.  Then, we applied novel and powerful statistical approaches to metabolite levels and to traits and diseases, expanding our understanding of health and disease,” said Carlos Cruchaga, Professor of Psychiatry at Washington University School of Medicine in St. Louis.  “This research will potentially lead to new treatments, as well as more accurate tests to determine the potential for and onset of various neurodegenerative disorders.  Metabolon’s industry-leading research capabilities provided a crucial lynchpin in unlocking these novel insights.”

Understanding biological systems requires considering all factors influencing phenotype—genetics, diet, environment, disease, drug exposure, and the microbiome—as each alters metabolite levels,” said Annie Evans, Senior Director and Head of Core Research.  “As a definitive representation of phenotype, metabolomics completes multiomics research solutions by linking gene expression with metabolite function, enhancing researcher confidence in identifying molecular entities and important biochemical pathways.

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About Metabolon 
Metabolon, Inc. is the global leader in metabolomics, with a mission to deliver biochemical data and insights that expand and accelerate the impact of life sciences research and complement other ‘omics’ technologies.  With more than 20 years, 10,000+ projects, 3,000+ publications, and ISO 9001:2015, CLIA, and CAP certifications, Metabolon has developed industry-leading scientific, technology, and bioinformatics techniques.  Metabolon’s Global Discovery Panel is powered by the world’s largest proprietary metabolomics reference library.  Metabolon’s industry-leading data and translational science expertise help customers and partners address some of the most challenging and pressing questions in the life sciences, accelerating research and enhancing development success.  The company offers scalable, customizable multiomics solutions, including metabolomics and lipidomics, that support customer needs from discovery through clinical trials and product life-cycle management.  For more information, please visit www.metabolon.com and follow us on LinkedIn and Twitter.

About Metabolomics
Metabolomics, the large-scale study of all small molecules in a biological system, is the only omics technology that provides a complete current-state functional readout of a biological system.  Metabolomics helps researchers see beyond the genetic variation of individuals, capturing the combined impact of genetic and external factors such as the effect of drugs, diet, lifestyle, and the microbiome on human health. By measuring thousands of discrete chemical signals that form biological pathways in the body, metabolomics can reveal important biomarkers, enabling a better understanding of a drug’s mechanism of action, pharmacodynamics, and safety profile, as well as individual responses to therapy.

Media Inquiries:
siverson@metabolon.com
Sean Iverson
VP, Global Marketing

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References

1. Zgoda-Pols, J.R., et al., Metabolomics analysis reveals elevation of 3-indoxyl sulfate in plasma and brain during chemically-induced acute kidney injury in mice: investigation of nicotinic acid receptor agonists. Toxicol Appl Pharmacol, 2011. 255(1): p. 48-56.

2. Bryant, J.A., et al., The impact of an oral purified microbiome therapeutic on the gastrointestinal microbiome. Nat Med, 2026. 32(1): p. 186-196

3. McGovern, B .H., et al., SER-109, an Investigational Microbiome Drugto Reduce Recurrence After Clostridioides difficile Infection: Lessons Learned From a Phase 2 Trial. Clin Infect Dis, 2021. 72(12): p. 2132-2140.

4. Feuerstadt, P., et al., SER-109, an Oral Microbiome Therapy for Recurrent Clostridioides difficile Infection. N Engl J Med, 2022. 386(3): p. 220-229.

5. Hu, Z., et al., Targeted metabolomics reveals novel diagnostic biomarkers for colorectal cancer. Mol Oncol, 2025. 19(6): p. 1737-1750.

6. Butler, F.M., et al., Vegetarian Dietary Patterns and Diet-Related Metabolites Are Associated With Kidney Function in the Adventist Health Study-2 Cohort. J Ren Nutr, 2025.

7. Stanford, J., et al., Metabolomic Profiling and Diet Quality Scoring in a Randomized Crossover Trial of Healthy and Typical Dietary Patterns. Mol Nutr Food Res, 2025 . 69(23): p. e70271.

8. O’Connor, L.E., et al., Metabolomic Profiling of an Ultraprocessed Dietary Pattern in a Domiciled Randomized Controlled Crossover Feeding Trial. J Nutr, 2023. 153(8): p. 2181-2192.

9. Fritsch, D.A., et al., Microbiome function underpins the efficacy of a fiber-supplemented dietary intervention in dogs with chronic large bowel diarrhea. BMC Vet Res, 2022. 18(1): p. 245.

10. Leal, L.N., et al., Preweaning nutrient supply improves lactation productivity and reduces the risk of culling in Holstein cows. J Dairy Sci, 2025. 108(6): p. 5875-5888.

11. Ahsin, M., et al., Soil and pasture health underlie improved beef nutrient density determined by untargeted metabolomics in Southern US grass finished beef systems. NPJ Sci Food, 2025. 9(1): p. 151.

12. Yin, W., et al., Plasma lipid profiling across species for the identification of optimal animal models of human dyslipidemia. J Lipid Res, 2012. 53(1): p. 51-65.

13. Porter, F .D., et al., Cholesterol oxidation products are sensitive and specific blood-based biomarkers for Niemann-Pick C1 disease. Sci Transl Med, 2010. 2(56): p. 56ra81.

14. Needham, B .D., et al., Plasma and Fecal Metabolite Profiles in Autism Spectrum Disorder. Biol Psychiatry, 2021. 89(5): p. 451-462

15. Li, C., et al., Estradiol and mTORC2 cooperate to enhance prostaglandin biosynthesis and tumorigenesis in TSC2-deficient LAM cells. J Exp Med, 2014. 211(1): p. 15-28.

16. Green, P.G., et al., Metabolic flexibility and reverse remodelling of the failing human heart. Eur Heart J, 2025. 46(25): p. 2422-2433.

17. Maekawa, H., et al., SGLT2 inhibition protects kidney function by SAM-dependent epigenetic repression of inflammatory genes under metabolic stress. J Clin Invest, 2025. 135(19).

18. Wu, D., et al., Integrated screens reveal that guanine nucleotide depletion, which is irreversible via targeting IMPDH2, inhibits pancreatic cancer and potentiates KRAS inhibition. Gut, 2026.

19. Schwerdtfeger, L.A., et al., Gut microbiota and metabolites are linked to disease progression in multiple sclerosis. Cell Rep Med, 2025. 6(4): p. 102055.

20. Wu, H., et al., Microbiome-metabolome dynamics associated with impaired glucose control and responses to lifestyle changes. Nat Med, 2025. 31(7): p. 2222-2231.

21. Jacobs, J.P., et al., Cognitive behavioral therapy for irritable bowel syndrome induces bidirectional alterations in the brain-gut-microbiome axis associated with gastrointestinal symptom improvement. Microbiome, 2021. 9(1): p. 236.

22. Pietzner, M., et al., Plasma metabolites to profile pathways in noncommunicable disease multimorbidity. Nat Med, 2021. 27(3): p. 471-479.

23. Faquih, T.O., et al., Robust Metabolomic Age Prediction Based on a Wide Selection of Metabolites. J Gerontol A Biol Sci Med Sci, 2025. 80(3).

24. Scherer, N., et al., Coupling metabolomics and exome sequencing reveals graded effects of rare damaging heterozygous variants on gene function and human traits. Nat Genet, 2025. 57(1): p. 193-205.

25. Holmes, Z.C., et al., Untargeted metabolomic analysis of human milk from healthy mothers reveals drivers of metabolite variability. Sci Rep, 2024. 14(1): p. 20827.

26. Titz, B., et al., Implications of Ocular Confounding Factors for Aqueous Humor Proteomic and Metabolomic Analyses in Retinal Diseases. Transl Vis Sci Technol, 2024. 13(6): p. 17.

27. Bloom, S.M., et al., Cysteine dependence of Lactobacillus iners is a potential therapeutic target for vaginal microbiota modulation. Nat Microbiol, 2022. 7(3): p. 434-450.

28. Leimer, E.M., et al., Lipid profile of human synovial fluid following intra-articular ankle fracture. J Orthop Res, 2017. 35(3): p. 657-666.