Characterizing the plasma metabolome during 14 days of live‐high, train‐low simulated altitude: A metabolomic approach

Lawler, Nathan G.; Abbiss, Chris R.; Gummer, Joel; Broadhurst, David; Govus, Andrew; Fairchild, Timothy J.; Thompson, Kevin G.; Garvican-Lewis, Laura A; Gore, Christopher J.; Trengove, Robert D.; Peiffer, Jeremiah J.

doi:10.1113/ep087159

Cited by 13 publications

(17 citation statements)

References 32 publications

(59 reference statements)

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“…There are early signs of new ‘-omics’ science in sport [91, 138], but these are a long way from becoming the norm. Similarly, new technology that analyses an athlete’s blood without the need for traditional venepuncture is in existence and could eventually become commonplace in sport.…”

Section: Discussionmentioning

confidence: 99%

Blood Biomarker Profiling and Monitoring for High-Performance Physiology and Nutrition: Current Perspectives, Limitations and Recommendations

2019

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Blood test data were traditionally confined to the clinic for diagnostic purposes, but are now becoming more routinely used in many professional and elite high-performance settings as a physiological profiling and monitoring tool. A wealth of information based on robust research evidence can be gleaned from blood tests, including: the identification of iron, vitamin or energy deficiency; the identification of oxidative stress and inflammation; and the status of red blood cell populations. Serial blood test data can be used to monitor athletes and make inferences about the efficacy of training interventions, nutritional strategies or indeed the capacity to tolerate training load. Via a profiling and monitoring approach, blood biomarker measurement combined with contextual data has the potential to help athletes avoid injury and illness via adjustments to diet, training load and recovery strategies. Since wide inter-individual variability exists in many biomarkers, clinical populationbased reference data can be of limited value in athletes, and statistical methods for longitudinal data are required to identify meaningful changes within an athlete. Data quality is often compromised by poor pre-analytic controls in sport settings. The biotechnology industry is rapidly evolving, providing new technologies and methods, some of which may be well suited to athlete applications in the future. This review provides current perspectives, limitations and recommendations for sports science and sports medicine practitioners using blood profiling and monitoring for nutrition and performance purposes.

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Section: Discussionmentioning

confidence: 99%

Blood Biomarker Profiling and Monitoring for High-Performance Physiology and Nutrition: Current Perspectives, Limitations and Recommendations

2019

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“…Furthermore, we should take into account the fact that a modified metabolic profile could also be the result of specific training (e.g. high altitude training 136 ), specific food supplements, 131 metabolic illnesses, 42 authorized medication, and because athletes participating in different sports have different cardiovascular demands that determine different metabolic profiles 131,137,138 . This fact could mask the markers of effect of the PEDs identified in the research frame.…”

Section: A Metabolomics Approach For Hormone Screening?mentioning

confidence: 99%

A role for metabolomics in the antidoping toolbox?

Narduzzi

Audran²,

Bizec

et al. 2020

Drug Testing and Analysis

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Evidence of the continuous rise of novel doping agents and novel doping strategies calls for the development of more accurate multi‐target screening methods. Direct multi‐target screening approaches are restricted to the targeted substances and their turnover. The development of effective “indirect” screening methods requires a priori a deep understanding of the metabolism of the substance. The biological passport has been demonstrated to be very effective, but it is limited to about 20 indirect parameters. The standard antidoping analytical methods are hence targeted and do not aim directly to identify unknown substances. Also, the detection of doping agents is limited by the excretion of the substance. This study considers metabolomics for the screening of performance enhancing hormone abuse by athletes, based on the following pieces of evidence: (1) hormones have a strong influence on human metabolism, changing several parameters in many tissues, organs, and bio‐fluids; (2) metabolomics has been demonstrated to be a very accurate tool to depict the metabolic status of several organisms, tissues, and for several human diseases, including hormone deficiencies; (3) metabolomics has been demonstrated to be able to distinguish hormone‐treated animals from controls in many species, without the need for a priori knowledge of the metabolism for the specific substance. The literature shows that metabolomics could be an appropriate tool to detect hormone abuse, keeping in mind the strength and the limitation of such an approach.

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“…In this issue of Experimental Physiology , Lawler et al. () characterize changes in the plasma metabolome of endurance‐trained athletes performing LHTL having clocked up to as much as 200 h simulated altitude exposure to 3000 m, to provide important insight into the mechanisms underpinning metabolic adaptation to (albeit normobaric) hypoxia (Lawler et al., ). Given that the respiring mammalian cell has evolved to be dependent entirely on molecular O 2 (because it serves as the terminal electron acceptor in mitochondrial oxidative phosphorylation), a more informed understanding of how we humans adapt (or indeed fail to adapt) to hypoxia is important, not simply from a performance perspective, but equally from a clinical one, because numerous diseases affecting the human circulation are characterized by marked hypoxaemia (Bailey, ).…”

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confidence: 99%

“…Lawler et al. () used liquid chromatography–high‐resolution mass spectrometry, with parts per million mass determination sensitivity. Just wrap your brain around what this means; it is equivalent to detecting one granule of sugar among 273 sugar cubes, a technological marvel in and of itself!…”

mentioning

confidence: 99%