Thanatometabolomics: introducing NMR-based metabolomics to identify metabolic biomarkers of the time of death

Mora-Ortiz, Marina; Trichard, Marianne; Oregioni, Alain; Claus, Sandrine P.

doi:10.1007/s11306-019-1498-1

Cited by 27 publications

(23 citation statements)

References 57 publications

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“…Aliphatic and aromatic regions from urine datasets, where glucose signal is not present, were further studied applying a normalisation under total area (Dieterle et al 2006 ) and interrogated by O-PLS DA model as described above. Metabolite identification was done using Chenomx NMR Suite 8.2 from Chenomx Inc (Edmonton, Canada), online publicly available databases: the Human Metabolome Data Base (HMDB, http://www.hmdb.ca ), the Biological Magnetic Resonance data bank (BMRB, http://www.bmrb.wisc.edu ) and published literature (Claus et al 2011 , 2008 , Mora-Ortiz et al 2019 ). A heatmap was calculated in R using the metabolites relative modulations (i.e.…”

Section: Methodsmentioning

confidence: 99%

“…Systematic metabolomics characterisation of various research models such as rodents, chickens, pigs, humans and horses have been published in the past (Claus et al 2008 ; Le Roy et al 2016 ; Martin et al 2007 ; Merrifield et al 2011 ; Ndagijimana et al 2009 ; Holmes et al 1997 ; Escalona et al 2015 ; Mora-Ortiz et al 2019 ), but to date, a comprehensive metabolic phenotyping of the leptin receptor defective ( db/db ) T2D mouse model: BKS.Cg-Dock7 < m > +/+ Lepr < db >/J is missing. Previous reports have characterised relevant biological matrices such as urine, plasma and kidneys, showing an increase in glucose levels and modulations in the tricarboxylic acid cycle (TCA cycle), branched-chain amino acids (BCAAs) levels, homocysteine-methionine metabolism and ketone and fatty acid metabolism at different stages of the disease.…”

Section: Introductionmentioning

confidence: 99%

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NMR metabolomics identifies over 60 biomarkers associated with Type II Diabetes impairment in db/db mice

et al. 2019

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Introduction The rapid expansion of Type 2 Diabetes (T2D), that currently affects 90% of people suffering from diabetes, urges us to develop a better understanding of the metabolic processes involved in the disease process in order to develop better therapies. The most commonly used model for T2D research is the db/db (BKS.Cg-Dock7 < m > +/+ Lepr < db >/J) mouse model. Yet, a systematic 1 H NMR based metabolomics characterisation of most tissues in this animal model has not been published. Here, we provide a systematic organ-specific metabolomics analysis of this widely employed model using NMR spectroscopy. Objectives The aim of this study was to characterise the metabolic modulations associated with T2D in db/db mice in 18 relevant biological matrices. Methods High-resolution 1 H-NMR and 2D-NMR spectroscopy were applied to 18 biological matrices of 12 db/db mice (WT control n = 6, db/db = 6) aged 22 weeks, when diabetes is fully established. Results 61 metabolites associated with T2D were identified. Kidney, spleen, eye and plasma were the biological matrices carrying the largest metabolomics modulations observed in established T2D, based on the total number of metabolites that showed a statistical difference between the diabetic and control group in each tissue (16 in each case) and the strength of the O-PLS DA model for each tissue. Glucose and glutamate were the most commonly associated metabolites found significantly increased in nine biological matrices. Investigated sections where no increase of glucose was associated with T2D include all intestinal segments (i.e. duodenum, jejunum, ileum and colon). Microbial co-metabolites such as acetate and butyrate, used as carbon sources by the host, were identified in excess in the colonic tissues of diabetic individuals. Conclusions The metabolic biomarkers identified using 1 H NMR-based metabolomics will represent a useful resource to explore metabolic pathways involved in T2D in the db/db mouse model. Electronic supplementary material The online version of this article (10.1007/s11306-019-1548-8) contains supplementary material, which is available to authorized users.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

NMR metabolomics identifies over 60 biomarkers associated with Type II Diabetes impairment in db/db mice

et al. 2019

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“…1 H NMR metabolomics was applied to investigate mice organ (heart, kidney, liver, spleen, skin, and white adipose tissue) samples collected from ten animals at three different PMI (Mora-Ortiz et al 2019 ). Metabolomic alterations were recorded and pairwise Orthogonal Projection to Latent Structure Discriminant Analysis (OPLS-DA) was used to compare two time points for each organ.…”

Section: Metabolome Modifications After Deathmentioning

confidence: 99%

“…, Heart, Kidney, Liver, Serum, Skin, Spleen, Plasma, Urine, VH, WAT Human, Calf, Goat, Mice, SheepLocci et al (2014Locci et al ( , 2019,Snytnikova et al (2017a, b),Jawor et al 2019, andMora-Ortiz et al 2019 Alanine Cornea, Kidney, Plasma, Spleen, Serum, Skin, Urine, VH, WAT Human, Calf, Goat, MiceLocci et al (2014),Rosa et al (2015),Snytnikova et al (2017aSnytnikova et al ( , 2017b, Jawor et al(2019), and Mora-Ortiz et al (2019) Ascorbate AH, Cornea, Kidney, Serum, Spleen, Urine, VH Human, Calf, Goat, Mice, Sheep Locci et al (2014, 2019), Snytnikova et al (2017a, b), Jawor et al (2019), and Mora-Ortiz et al (2019) BCAA AH, Cornea, Heart, Kidney, Liver, Plasma, Serum, Spleen, Urine, VH, WAT Human, Calf, Goat, Mice, Sheep Locci et al (2014, 2019), Snytnikova et al (2017a, 2017b), Jawor et al (2019), Mora-Ortiz et al (2019) Betaine Kidney, AH, VH, Serum, Urine Human, Calf, Goat, Mice, Sheep Locci et al (2014, 2019) Snytnikova et al (2017a), Jawor et al (2019), and Mora-Ortiz et al (2019) Carnitine Cornea, Heart, Serum Human, Mice Snytnikova et al (2017a, b) and Mora-Ortiz et al (2019) Creatine AH, Cornea, Heart, Kidney, Liver, Plasma, Skin, Serum, Spleen, Urine, WAT, VH Human, Calf, Goat, Mice, Sheep Locci et al (2014, 2019), Rosa et al (2015), Snytnikova et al (2017b), Jawor et al (2019), and Mora-Ortiz et al (2019) Creatinine Cornea, AH, Plasma, Serum, Urine Human, Calf, Sheep, Snytnikova et al (2017a, 2017b), Jawor et al (2019), and Locci et al (2019) Choline AH, Cornea, Heart, Kidney, Plasma, Serum, Spleen, Urine, VH Human, Calf, Goat, Mice, Rabbit, Sheep Locci et al (2014, 2019), Rosa et al (2015), Zelentsova et al (2016), Snytnikova et al (2017a, b), Jawor et al (2019), and Mora-Ortiz et al (2019) Formate Cornea, Spleen, AH, Plasma, Urine Human, Calf, Mice, Sheep Snytnikova et al (2017a, b), Jawor et al (2019), Locci et al (2019), and Mora-Ortiz et al (2019) Glucose Heart, Kidney, Liver, Plasma, Skin, Spleen, Urine, VH, WAT Calf, Goat, Mice Locci et al (2014), Rosa et al (2015), Jawor et al (2019), and Mora-Ortiz et al (2019) Glutamate AH, Heart, Kidney, Liver, Plasma, Serum, Skin, Spleen, VH, WAT Human, Calf, Mice, Rabbit, Sheep Zelentsova et al (2016), Snytnikova et al (2017a), Jawor et al (2019), Locci et al 2019, and Mora-Ortiz et al (2019) Glutamine Heart, Plasma, Serum, Spleen, Urine, VH Human, Calf, Goat, Mice Locci et al (2014), Snytnikova et al (2017a), Mora-Ortiz et al (2019), and Jawor et al (2019) Glycerol AH, Cornea, Heart, Serum, Spleen, VH Human, Goat, Mice, Rabbit Locci et al (2014), Zelentsova et al (2016), Snytnikova et al (2017a, b), and Mora-Ortiz et al (2019) Glycine AH, Cornea, Serum, VH Human, Rabbit Zelentsova et al (2016), and Snytnikova et al (2017a, b) 3-OH-butyrate AH, Urine, VH Calf, Goat, Sheep Rosa et al (2015), Jawor et al (2019), and Locci et al (2019) Histidine Kidney, Serum, Urine Human, Calf, Mice Snytnikova et al (2017a), Mora-Ortiz et al (2019), and Jawor et al (2019) Hypoxanthine AH, Cornea, Heart, Serum, Urine, VH Human, Calf, Goat, Mice, Rabbit, Sheep Rosa et al (2015), Zelentsova et al (2016), Snytnikova et al (2017a, b), Jawor et al (2019), Mora-Ortiz et al (2019), and Locci et al (2019) Lactate AH, Cornea, Heart, Kidney, Plasma, Serum,...…”

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confidence: 99%

Forensic NMR metabolomics: one more arrow in the quiver

et al. 2020

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Introduction NMR metabolomics is increasingly used in forensics, due to the possibility of investigating both endogenous metabolic profiles and exogenous molecules that may help to describe metabolic patterns and their modifications associated to specific conditions of forensic interest. Objectives The aim of this work was to review the recent literature and depict the information provided by NMR metabolomics. Attention has been devoted to the identification of peculiar metabolic signatures and specific ante-mortem and post-mortem profiles or biomarkers related to different conditions of forensic concern, such as the identification of biological traces, the estimation of the time since death, and the exposure to drugs of abuse. Results and Conclusion The results of the described studies highlight how forensics can benefit from NMR metabolomics by gaining additional information that may help to shed light in several forensic issues that still deserve to be further elucidated.

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“…The H-NMR can be utilized to put the complete structure of the metabolite together using the components of the spectra like signals, chemical shift, and integration and splitting patterns. The C-NMR spectroscopy abolishes some structures that can be possible if we use H-NMR spectrumFigure 4[14].…”

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confidence: 99%