It’s getting hairy – External contamination may affect the validity of hair cortisol as an indicator of stress in pigs and cattle

•External factors can influence hair cortisol concentrations (HCCs).•Contamination is a confounding factor on HCC in pigs and cattle.•Cortisol in urine causes a concentration-dependent increase in HCC.•Repeated treatment with water leads to wash-out of cortisol from porcine hair. Hair cortisol concentration (HCC) is increasingly used for the assessment of enhanced hypothalamic–pituitary-adrenal (HPA) axis activity, e.g., caused by repeated or long-term stressful conditions or pathologies. However, there is still a lack of knowledge regarding the mechanisms and sources of cortisol incorporation into the hair and possible confounding factors, especially in non-human animals. Farm animals are usually kept under confined housing conditions, have close contact with each other and with soiled environments and may thus be exposed to contamination with urine, feces and saliva, which are known to contain substantial concentrations of cortisol or its metabolites. Therefore, the aim of our study was to investigate the impact of contamination with urine, feces and saliva on the cortisol concentration in the hair of pigs and cattle. In an in vitro experiment, hair strands of 12 pigs and 12 cattle were repeatedly contaminated with urine and saliva, containing either low or high cortisol concentrations, or with the feces of the respective species and were compared with hair treated with water or untreated hair. Contamination was performed over 20 days for two hours daily. Thereafter, all samples were washed, ground, extracted and analyzed for HCCs following the same protocol. Our results showed that contamination with urine caused a considerable and concentration-dependent increase in HCCs in both species. Saliva had a comparable effect only in cattle. In addition, the treatment with water led to a reduction in the cortisol concentration of porcine hair, whereas contamination with feces caused an increase in HCC only in cattle. Our findings provide evidence that contamination of hair with cortisol-containing body fluids causes incorporation of cortisol into the hair shaft, probably via diffusion depending on the concentration gradient. In that case, cortisol in hair derived from contamination cannot be distinguished from cortisol originating from blood. Thus, contamination may affect the validity of hair cortisol as an indicator of HPA axis activity and cannot be prevented by decontamination protocols prior to analysis.