Doping in horses refers to the administration of prohibited substances or methods to enhance performance or alter behavior during competitions. This practice is a concern in equestrian sports due to its potential impact on animal welfare, fair play, and the integrity of the sport. Substances used in doping can range from stimulants and painkillers to sedatives and anti-inflammatory drugs. Detection methods include blood and urine tests, designed to identify the presence of banned substances or their metabolites. This page compiles peer-reviewed research studies and scholarly articles that explore the detection methods, regulatory frameworks, and ethical considerations associated with doping in equine sports.
CLARKE EG.This research article explores the topic of doping racehorses, looking at the history of the practice, the reasons for it, various methods used, and the substances utilized. It also presents […]
El-Ghaly W, El Kamli T, Gongbe AMA, Zaari Lambarki L, El Hamdani M, Lahkak FE, Al Idrissi N, Benmoussa A, Balouch L, Bakkali F, Saffaj T, Jhilal F.The quantification of banned substances in equine antidoping control, especially in racehorse urine, necessitates robust analytical methods with high detection levels due to the extremely low concentrations of the target substances and the significant impact of minor variations on doping test results. Reliable quantification is important for substances near regulatory thresholds, which, if exceeded, are prohibited. This study presents the development and validation of a bioanalytical UHPLC-HRMS method for quantifying doping substances in equine urine, including diazepam and acepromazine with a...
Viljanto M, Cutler C, Habershon-Butcher J, Hincks P, Scarth J.The use of testosterone in racehorses is predominantly monitored using international urine and plasma concentration-based thresholds and complementary steroid ratios. To date, there has been no published pharmacokinetic study on transdermally applied testosterone products in horses and whether their use could result in adverse analytical findings. Therefore, quantitative analysis of testosterone and epitestosterone in urine and testosterone in plasma samples was performed following a pilot multi-dose transdermal Testogel administration (1 mg/kg once a day for 7 days on clipped skin) to one...
Lai CS, Wong ASY, Wong KS, Wan TSM, Ho ENM.In the screening of prohibited substances (PS) in horse biological samples with gas chromatography/mass spectrometry (GC/MS) and liquid chromatography/mass spectrometry (LC/MS) for doping control, an enormous number of chromatograms are generated. Reviewing these chromatograms to identify suspicious findings requires an extensive manual effort. Recent advancements in Artificial Intelligence (AI) enable its use to classify images into different categories. This can potentially be utilized to perform first-line analysis of chromatograms, which are usually displayed as images, by classifying them...
So YM, Kwok WH, Tang CWY, Wong COL, Wan TSM, Ho ENM.This paper describes the studies of the in vitro biotransformation of nandrolone decanoate and its metabolic fate in equine plasma and urine after intramuscular administration to castrated thoroughbred horses. The in vitro metabolic study was performed using homogenised horse liver, and the more prominent in vitro biotransformation pathways were found to include hydrolysis, reduction, oxidation and sulfation, mainly resulting in seven Phase I metabolites and one Phase II metabolite. The administration study of nandrolone decanoate was carried out using three retired thoroughbred geldings, e...
Furukawa R, Tozaki T, Kawate K, Kikuchi M, Ishige T, Takahashi Y, Fukui E, Kakoi H.Gene doping, which entails the administration of transgenes, poses a serious threat to the integrity of equine sports and also raises both ethical and regulatory concerns. Current methods used for the detection of such doping often necessitate the extraction of DNA from plasma, which can be time-consuming and labour-intensive. To overcome this limitation, we developed a direct chamber digital PCR (cdPCR) method that enables transgene detection in equine plasma without the need for DNA purification. Using the equine erythropoietin (EPO) transgene as a model, we validated the assay by analysing ...
