OBJECTIVE: A supervised multivariate model to classify the metabolome alterations between autistic spectrum disorders (ASD) patients and controls, siblings of autistic patients, has been realized and used to realize a network model of the ASD patients' metabolome. METHODS: In our experiment we propose a quantification of urinary metabolites with the Mass Spectroscopy technique couple to Gas Chromatography. A multivariate model has been used to extrapolate the variables of importance for a network model of interaction between metabolites. In this way we are able to propose a network-based approach to ASD description. RESULTS: Children with autistic disease composing our studied population showed elevated concentration of several organic acids and sugars. Interactions among diet, intestinal flora and genes may explain such findings. Among them, the 3-(3-hydroxyphenyl)-3-hydroxypropanoic acid has been previously described as altered in autistic subjects. Other metabolites increased are 3,4-dihydroxybutyric acid, glycolic acid and glycine, cis-aconitic acid; phenylalanine, tyrosine, p-hydroxyphenylacetic acid, and homovanillic acid are all involved in the tyrosine pathway leading to neurotransmitter cathecolamine. CONCLUSION: GC-MS-based metabolomic analysis of the urinary metabolome suggests to have the required sensitivity and specificity to gain insight into ASD phenotypes and aid a personalized network-based medicine approach.
OBJECTIVE: A supervised multivariate model to classify the metabolome alterations between autistic spectrum disorders (ASD) patients and controls, siblings of autisticpatients, has been realized and used to realize a network model of the ASDpatients' metabolome. METHODS: In our experiment we propose a quantification of urinary metabolites with the Mass Spectroscopy technique couple to Gas Chromatography. A multivariate model has been used to extrapolate the variables of importance for a network model of interaction between metabolites. In this way we are able to propose a network-based approach to ASD description. RESULTS:Children with autistic disease composing our studied population showed elevated concentration of several organic acids and sugars. Interactions among diet, intestinal flora and genes may explain such findings. Among them, the 3-(3-hydroxyphenyl)-3-hydroxypropanoic acid has been previously described as altered in autistic subjects. Other metabolites increased are 3,4-dihydroxybutyric acid, glycolic acid and glycine, cis-aconitic acid; phenylalanine, tyrosine, p-hydroxyphenylacetic acid, and homovanillic acid are all involved in the tyrosine pathway leading to neurotransmitter cathecolamine. CONCLUSION: GC-MS-based metabolomic analysis of the urinary metabolome suggests to have the required sensitivity and specificity to gain insight into ASD phenotypes and aid a personalized network-based medicine approach.
Authors: O D Rangel-Huerta; A Gomez-Fernández; M J de la Torre-Aguilar; A Gil; J L Perez-Navero; K Flores-Rojas; P Martín-Borreguero; M Gil-Campos Journal: Metabolomics Date: 2019-06-27 Impact factor: 4.290
Authors: Brittany D Needham; Mark D Adame; Gloria Serena; Destanie R Rose; Gregory M Preston; Mary C Conrad; A Stewart Campbell; David H Donabedian; Alessio Fasano; Paul Ashwood; Sarkis K Mazmanian Journal: Biol Psychiatry Date: 2020-10-10 Impact factor: 13.382
Authors: Sergio Modafferi; Xiali Zhong; Andre Kleensang; Yohei Murata; Francesca Fagiani; David Pamies; Helena T Hogberg; Vittorio Calabrese; Herbert Lachman; Thomas Hartung; Lena Smirnova Journal: Environ Health Perspect Date: 2021-07-14 Impact factor: 9.031