Serum androgen levels in elite female athletes.

OBJECTIVE: Prior to the implementation of the blood steroidal module of the Athlete Biological Passport, we measured the serum androgen levels among a large population of high-level female athletes as well as the prevalence of biochemical hyperandrogenism and some disorders of sex development (DSD). METHODS AND RESULTS: In 849 elite female athletes, serum T, dehydroepiandrosterone sulphate, androstenedione, SHBG, and gonadotrophins were measured by liquid chromatography-mass spectrometry high resolution or immunoassay. Free T was calculated. The sampling hour, age, and type of athletic event only had a small influence on T concentration, whereas ethnicity had not. Among the 85.5% that did not use oral contraceptives, 168 of 717 athletes were oligo- or amenorrhoic. The oral contraceptive users showed the lowest serum androgen and gonadotrophin and the highest SHBG concentrations. After having removed five doped athletes and five DSD women from our population, median T and free T values were close to those reported in sedentary young women. The 99th percentile for T concentration was calculated at 3.08 nmol/L, which is below the 10 nmol/L threshold used for competition eligibility of hyperandrogenic women with normal androgen sensitivity. Prevalence of hyperandrogenic 46 XY DSD in our athletic population is approximately 7 per 1000, which is 140 times higher than expected in the general population. CONCLUSION: This is the first study to establish normative serum androgens values in elite female athletes, while taking into account the possible influence of menstrual status, oral contraceptive use, type of athletic event, and ethnicity. These findings should help to develop the blood steroidal module of the Athlete Biological Passport and to refine more evidence-based fair policies and recommendations concerning hyperandrogenism in female athletes.

Testosterone and doping control.

BACKGROUND AND OBJECTIVES: Anabolic steroids are synthetic derivatives of testosterone, modified to enhance its anabolic actions (promotion of protein synthesis and muscle growth). They have numerous side effects, and are on the International Olympic Committee's list of banned substances. Gas chromatography-mass spectrometry allows identification and characterisation of steroids and their metabolites in the urine but may not distinguish between pharmaceutical and natural testosterone. Indirect methods to detect doping include determination of the testosterone/epitestosterone glucuronide ratio with suitable cut-off values. Direct evidence may be obtained with a method based on the determination of the carbon isotope ratio of the urinary steroids. This paper aims to give an overview of the use of anabolic-androgenic steroids in sport and methods used in anti-doping laboratories for their detection in urine, with special emphasis on doping with testosterone. METHODS: Review of the recent literature of anabolic steroid testing, athletic use, and adverse effects of anabolic-androgenic steroids. RESULTS: Procedures used for detection of doping with endogenous steroids are outlined. The World Anti-Doping Agency provided a guide in August 2004 to ensure that laboratories can report, in a uniform way, the presence of abnormal profiles of urinary steroids resulting from the administration of testosterone or its precursors, androstenediol, androstenedione, dehydroepiandrosterone or a testosterone metabolite, dihydrotestosterone, or a masking agent, epitestosterone. CONCLUSIONS: Technology developed for detection of testosterone in urine samples appears suitable when the substance has been administered intramuscularly. Oral administration leads to rapid pharmacokinetics, so urine samples need to be collected in the initial hours after intake. Thus there is a need to find specific biomarkers in urine or plasma to enable detection of long term oral administration of testosterone.

SARM-S4 and metabolites detection in sports drug testing: a case report.

Recently, pharmaceutical industry developed a new class of therapeutics called Selective Androgen Receptor Modulator (SARM) to substitute the synthetic anabolic drugs used in medical treatments. Since the beginning of the anti-doping testing in sports in the 1970s, steroids have been the most frequently detected drugs mainly used for their anabolic properties. The major advantage of SARMs is the reduced androgenic activities which are the main source of side effects following anabolic agents' administration. In 2010, the Swiss laboratory for doping analyses reported the first case of SARMs abuse during in-competition testing. The analytical steps leading to this finding are described in this paper. Screening and confirmation results were obtained based on liquid chromatography tandem mass spectrometry (LC-MS/MS) analyses. Additional information regarding the SARM S-4 metabolism was investigated by ultra high-pressure liquid chromatography coupled to quadrupole time-of-flight mass spectrometer (UHPLC-QTOF-MS).

No variation of physical performance and perceived exertion after adrenal gland stimulation by synthetic ACTH (Synacthen) in cyclists.

There is anecdotal evidence that athletes use the banned substance Synacthen because of its perceived benefit with its associated rise in cortisol. To test the performance-enhancing effects of Synacthen, eight trained cyclists completed two, 2-day exercise sessions separated by 7-10 days. On the first day of each 2-day exercise session, subjects received either Synacthen (0.25 mg, TX) or placebo (PLA) injection. Performance was assessed by a 20-km time trial (TT) after a 90-min fatigue period on day 1 and without the fatiguing protocol on day 2. Plasma androgens and ACTH concentrations were measured during the exercise bouts as well as the rate of perceived exertion (RPE). Spot urines were analyzed for androgens and glucocorticoids quantification. Basal plasma hormones did not differ significantly between PLA and TX groups before and 24 h after the IM injection (P > 0.05). After TX injection, ACTH peaked at 30 min and hormone profiles were significantly different compared to the PLA trial (P < 0.001). RPE increased significantly in both groups as the exercise sessions progressed (P < 0.001) but was not influenced by treatment. The time to completion of the TT was not affected on both days by Synacthen treatment. In the present study, a single IM injection of synthetic ACTH did not improve either acute or subsequent cycling performance and did not influence perceived exertion. The investigated urinary hormones did not vary after treatment, reinforcing the difficulty for ACTH abuse detection.

Effects of high-intensity exercises on 13C-nandrolone excretion in trained athletes.

OBJECTIVE: Nandrolone is an anabolic steroid widely used in several sports. The numerous nandrolone positive cases in the recent years (International Olympic Committee statistics) led to several studies in the antidoping field. Nevertheless, essential questions pertaining to nandrolone endogenous production, the effects of physical exercise on the excretion of nandrolone metabolites, and contamination from nutritional supplements must still be addressed. The purpose of this study was to evaluate the influence of exhaustive exercises on 19-norandrosterone (19-NA) and 19-noretiocholanolone (19-NE) urinary excretion rates after administration of labeled nandrolone. SETTING AND PARTICIPANTS: A total of 34 healthy male Caucasian volunteers from the Institute of Sports Sciences and Physical Education (University of Lausanne) applied to participate in the study. All subjects were free from any physical drug addiction and were instructed strictly to avoid any nutritional supplement or steroid before and during the study. The participants were randomly dispatched in 2 groups in a double-blind way: a placebo group and a group treated with C-labeled nandrolone. MAIN OUTCOME MEASUREMENTS: The urinary concentrations of the 2 main nandrolone metabolites, 19-NA and 19-NE, were measured using gas chromatography coupled with mass spectrometry. In addition, clinical parameters such as creatinine, total protein, and beta2-microglobuline levels were determined using immunologic assays. RESULTS: After an oral ingestion of a 25 mg 3,4-C2-nandrolone dose, followed by a second identical dose 24 hours later, 19-NA and 19-NE could be detected in the urine for a period of 6 days after the initial intake. Despite several interesting observations, the measurements were very scattered and did not appear to be significantly influenced by exercise sessions in the athlete population. CONCLUSIONS: The results of this study suggest that physical exercise cannot be considered as a reliable parameter that systematically affects nandrolone metabolite concentrations in the urine.

Production endogène de Nortestostérone chez l'homme et influence de l'activité physique et du régime alimentaire

RESUME Depuis les années 1980, les stéroïdes androgéniques anabolisants (SAA) sont restés les produits dopants les plus utilisés par les sportifs. Les propriétés principales attribuées à ces substances sont une augmentation de la masse et de la force musculaire ainsi qu'une agressivité supérieure pouvant s'avérer bénéfique lors des entraînements ou des compétitions. En plus de cette "tradition" liée à la consommation des SAA, une autre problématique est apparue dans le monde antidopage suite à la fulgurante expansion de l'utilisation des compléments alimentaires par les athlètes professionnels et amateurs. Dès la fin des années 1990, une recrudescence de cas positifs de dopage aux SAA a été attribuée à la contamination des compléments alimentaires par des composés anabolisants tels que la testostérone ou la nandrolone ou par des prohormones se situant en amont dans le métabolisme de certains SAA et conduisant à la présence, dans les urines, de traces de substances interdites par l'Agence Mondiale Antidopage (AMA). Afin de mettre en garde les autorités antidopage ainsi que les athlètes quant aux problèmes liés aux compléments alimentaires, le Laboratoire Suisse d'Analyse du Dopage (LAD) a décidé d'étudier de manière plus précise la composition d'une centaine de produits accessibles en Suisse par l'intermédiaire d'internet. Cette étude a permis de mettre en évidence un taux de non conformité des produits avoisinant les 20%, avec une contamination plus importante des produits contenant des hormones ou des prohormones. La consommation de doses journalières recommandées des produits contaminés a mené à la détection dans les urines de la présence de substances interdites par l'AMA. Ces résultats confirment ainsi que l'usage de compléments alimentaires peut s'avérer dangereuse dans le cadre de contrôles antidopage et que les effets sur l'état physique et mental des athlètes peuvent dépasser les effets désirés et être dramatiques pour la poursuite d'une carrière sportive. D'autre part, cela démontre que l'alimentation peut mener à la présence urinaire de substances proscrites telles que les métabolites de la nandrolone, la 19-norandrostéreone (19-NA) et la 19-norétiocholanolone (19-NE). Afin de démontrer un effet potentiel de l'exercice physique sur l'excrétion urinaire des métabolites de la nandrolone, une première étude clinique a été réalisée avec 34 volontaires. Deux doses orales de nandrolone marquée avec deux atomes de C13 ont été administrées aux sujets. Les urines ont été récoltées durant les 5 jours suivant les prises orales (études d'excrétion) ainsi qu'avant et après les 8 séances d'entraînements du protocole. Les analyses des études d'excrétion ont permis d'établir une variabilité intra- et inter-individuelle du métabolisme et de la pharmacocinétique de la 19-NA et de la 19-NE. En dépit de la rapide élimination urinaire des métabolites de la nandrolone C13, les analyses des échantillons prélevés avant et après les différents efforts n'ont pas révélé une influence nette de l'exercice physique sur les concentrations urinaires de la 19-NA et 19-NE. Une seconde étude clinique a été effectuée, avec la participation de 30 volontaires. Il s'agissait de déterminer si la consommation de multiples doses orales d'un décanoate de testostérone, de 19-norandrostenedione (un précurseur de la nandrolone) ou de placebo durant un mois, pouvait avoir des effets bénéfiques sur la récupération et la performance physique. En parallèle, les sujets étaient soumis à un entrainement d'endurance intense et individualisé. Divers paramètres physiologiques ont été étudiés dans le sérum et les urines afin de mettre en évidence une meilleure récupération de l'organisme. Aucun de ses paramètres n'a permis de conclure que la consommation orale de SAA est favorable pour optimaliser les capacités de récupération des athlètes. De plus, les performances physiques ont été évaluées avant et après l'entraînement et le traitement. Aucune différence significative n'a été démontrée entre les trois groupes de volontaires. L'état psychologique des volontaires a été évalué à l'aide de questionnaires (short Profile of Mood State, sPOMS) remplis à trois reprises au cours du protocole. De manière générale, l'évolution observée est une augmentation de la fatigue avec une diminution de la vigueur. Des analyses statistiques ont révélé que des prises orales de testostérone, et dans une moindre mesure de 19-norandrostenedione, ont une légère influence sur cette évolution générale en diminuant les effets de l'entrainement sur le profil psychologique. Les urines récoltées durant le protocole ont été analysées par GC/C/IRMS et GCMS afin de détecter les variations des concentrations des hormones liées au métabolisme de la testostérone. Les résultats ont démontré une variabilité interindividuelle du métabolisme de la testostérone qui implique que les critères de positivité imposés par l'AMA ne sont pas forcément valables pour tous les individus. La détection de la 19-NA et de la 19-NE, issus du métabolisme in vivo de la 19norandrostenedione, a confirmé les résultats obtenus sur la pharmacocinétique et le métabolisme de la nandrolone C13 obtenus lors de la première étude clinique. Ce travail a permis de clarifier certains points en lien avec l'abus de la nandrolone dans le sport et notamment par rapport à la consommation de compléments alimentaires. Les deux études cliniques n'ont pas véritablement apporté les réponses souhaitées aux hypothèses de départ. Cependant certains aspects intéressants en relation avec le métabolisme des SAA ont été découverts et pourront peut-être permettre à la lutte antidopage d'évoluer vers une meilleure efficacité. SUMMARY Since 1980's, anabolic androgenic steroids (AAS) are still the most used doping agents in sports. The main properties attributed to these substances are an increase of muscle mass and strength and also a higher aggressiveness that could be beneficial during trainings and competitions. In addition to this "tradition" linked to the AAS intake, another problematics has raised in the antidoping field. Indeed, nutritional supplements have been more and more used by professional and amateur athletes. Since the end of the 1990's, an outburst of positive doping cases with AAS has been attributed to nutritional supplements contaminations with anabolic compounds like testosterone or nandrolone or with prohormones located above in the metabolism of some AAS and prompting urinary traces of forbidden compounds by the World Antidoping Agency (WADA). In order to inform the antidoping authorities and the athletes about the problems linked to the nutritional supplements, the Swiss Laboratory for Doping Analyses (LAD) decided to investigate more precisely the composition of about hundred products accessible in Switzerland through different web sites. This study showed that about 20% of the products were not conformed to the composition announced by the manufacturers. The oral intake of daily recommended doses of the contaminated products revealed the presence in urines of forbidden substances by the WADA. Hence, these results confirm that the use of nutritional supplements can lead to adverse analytical findings in antidoping controls and that the effects on athletes' physical and mental state could be different from the ones desired and could be dramatic for the continuation of an athlete's career. Moreover, this demonstrates that the diet can lead to the presence in urines of proscribed substances like nandrolone metabolites, i.e. 19-norandrosterone (19-NA) and 19-noretiocholanolone (19-NE). To put forward a potential effect of physical exercise on urinary nandrolone metabolites excretion rate, a first clinical study was done with 34 volunteers. Two oral doses of nandrolone labelled with two C13 atoms were administered to the subjects. The urines were collected during the 5 days following the treatment (excretion studies) and before and after the 8 exercise sessions of the protocol. The analyses of excretion studies revealed an intra- and inter-individual variability of the metabolism and the pharmacokinetics of 19-NA and 19-NE. In spite of the rapid urinary elimination of the nandrolone C13 metabolites, the analyses of the urine samples gathered before and after efforts did not show a clear influence of physical exercise on the urinary 19-NA and 19-NE concentrations. A second clinical study was done with the participation of 30 volunteers. The main aim was to determine if multiple oral doses of testosterone undecanoate, 19-norandrostenedione (a nandrolone precursor) or placebo during one month, could have beneficial effects on recovery and physical performance. Meanwhile, the individuals had to follow an intense and personalized endurance training program. Several physiological parameters were investigated in serum and urines in order to demonstrate a better organism's recovery. None of these parameters lead to the conclusion that oral intake of AAS is useful to optimise the recovery capacities of athletes. In addition, physical performances were evaluated before and after the training and treatment month. No significant difference was shown between the three volunteers groups. The psychological state of the volunteers was assessed through questionnaires (short Profile of Mood State, sP4MS) filled three times during the protocol. The global evolution is an increase of fatigue with an decrease of vigour. Statistical analyses revealed that the oral intake of testosterone, and to a lesser extent of 19= norandrostenedione, have a small influence on this general evolution in decreasing the effect of training on the psychological profile. The urines collected during the protocol were analysed by GC/C/IRMS and GCMS to detect concentrations variations of hormones related to the testosterone metabolism. The results revealed an interindividual variability of testosterone metabolism which implies that the guidance concerning endogenous steroids prescribed by the WADA are not uniformly valid for all individuals. Detection of 19-NA and 19-NE, coming from the in vivo metabolism of 19norandrostenedione, confirmed the results previously obtained on the pharamcokinetics and metabolism of the nandrolone C13 in the first clinical study. This work allowed to clarify some aspects linked to nandrolone abuse in sports and noteworthy related to nutritional supplements intake. The two clinical studies did not really bring plain answers to the basal hypotheses but some interesting aspects in relation with AAS metabolism were put forth and would perhaps allow an evolution of a more effective fight against doping.

Time for change: a roadmap to guide the implementation of the World Anti-Doping Code 2015

A medical and scientific multidisciplinary consensus meeting was held from 29 to 30 November 2013 on Anti-Doping in Sport at the Home of FIFA in Zurich, Switzerland, to create a roadmap for the implementation of the 2015 World Anti-Doping Code. The consensus statement and accompanying papers set out the priorities for the antidoping community in research, science and medicine. The participants achieved consensus on a strategy for the implementation of the 2015 World Anti-Doping Code. Key components of this strategy include: (1) sport-specific risk assessment, (2) prevalence measurement, (3) sport-specific test distribution plans, (4) storage and reanalysis, (5) analytical challenges, (6) forensic intelligence, (7) psychological approach to optimise the most deterrent effect, (8) the Athlete Biological Passport (ABP) and confounding factors, (9) data management system (Anti-Doping Administration & Management System (ADAMS), (10) education, (11) research needs and necessary advances, (12) inadvertent doping and (13) management and ethics: biological data. True implementation of the 2015 World Anti-Doping Code will depend largely on the ability to align thinking around these core concepts and strategies. FIFA, jointly with all other engaged International Federations of sports (Ifs), the International Olympic Committee (IOC) and World Anti-Doping Agency (WADA), are ideally placed to lead transformational change with the unwavering support of the wider antidoping community. The outcome of the consensus meeting was the creation of the ad hoc Working Group charged with the responsibility of moving this agenda forward.