Selected papers from “L’innovazione scientifica per la nutrizione”, 15th October, 2015, Lodi (MI), Italy 1 

HAF © 2013 

Vol. II, No. 2s  ISSN: 2283-3927 

Figure 1 – Chemical structures of the considered molecules. 

   

 

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Introduction 

The Council Directive 96/23/CE allows the therapeutic use of the glucocorticoids prednisolone, 

methylprednisolone, betamethasone and dexamethasone, and the  Commission Regulation No 37/2010/EU sets the 

maximum residue limits (MRLs) in bovine liver, muscle, fat and milk. However, their possible use as growth 

promoters is well known, due to e.g. their ability to increase weight gain or their synergistic activity with β-agonists. 

No MRLs are for urine so their presence at 

any concentration should not be allowed. 

In the last noughties, the frequency of 

detection of prednisolone in cow urine, 

especially in samples collected at the 

slaughterhouse, raised in Italy. The 

possibility of an endogenous production 

of prednisolone after stress events as the 

slaughtering was demonstrated (Pompa 

et al. 2011) on cows and its presence in 

bovine urine was shown to be related to a 

state of stress in the animals both at farm 

and slaughterhouse (Dusi et al. 2012; 

Bertocchi et al. 2013). The hypothesis that a 

contamination could lead to the presence 

of prednisolone in urine because of a likely 

microbiological dehydrogenase activity on 

cortisol was also shown in bovine (Arioli et al. 2010) and human (Bredehöft et al. 2012). 

In this study, saponins and sapogenins with steroidal nucleus were analogously considered as possible cause of 

the neo-formation of prednisolone in the faeces-contaminated urine and in feed. Attention has been focused on  

α-solanine, a saponin contained in the Solanaceae, and diosgenin, an important starting material to obtain steroidal 

drugs such as cortisol, testosterone, estradiol, contained in many herbaceous plants as Dioscoraceae (Figure 1). 

Material and Methods 

Sample preparation - 500 mg of faeces or feed from the market were suspended in 500 mL of 0.9% NaCl, and 

gently mixed for a whole night. Three aliquots of 40 mL were collected from each suspension. An aliquot was 

spiked (100 ng/mL) with diosgenin, one with α-solanine and one was the control. At the times: t = 0; 1; 2; 4; 8; 24; 48 

and 72h, 1 mL was collected, heated at 80 °C (15 min), fortified with the Internal Standard (Prednisolone d6, 10 

ng/mL) and centrifuged at 3000xg (10 min). A 200 µL supernatant was collected and analysed. 

 

 

KEYWORDS 

Saponins; sapogenins; 

prednisolone neoformation; 

faeces; feed 
 

CORRESPONDING AUTHOR 

Francesco Arioli, 

francesco arioli@unimi.it  

 

JOURNAL HOME PAGE 

riviste.unimi.it/index.php/haf 

Are saponins and sapogenins precursors 

of prednisolone? Preliminary results 

G.F. Labella
1
, L.M. Chiesa

2
, S. Panseri

2
, F. Arioli

1
 

1 Department of Health, Animal Science and Food Safety, Università degli 
Studi di Milano, Italy. 

2 Department of Veterinary Science and Public Health, Università degli Studi 
di Milano, Italy. 

 

Article 



Selected papers from “L’innovazione scientifica per la nutrizione”, 15th October, 2015, Lodi (MI), Italy  2 

HAF © 2013 

Vol. II, No. 2s  ISSN: 2283-3927 

Sample analyses - HPLC-MSn was made with a LCQ DECA XP ion trap mass spectrometer equipped with a pump 

and an autosampler LC Surveyor (ThermoFinnigan, San Jose, CA, USA). The column was a 100mm×2.1mm id, 3µm 

Allure Biphenyl (Restek, Bellefonte, PA, USA). The mobile phase consisted of an aqueous solution of formic acid 0.1% 

(A) and methanol (B). A gradient was used: 40% eluent A and 60% eluent B from 0 to 15 min and 100% eluent B from 

20 to 40 min. The acquisition was in the Electrospray Ionization (ESI) in the (+) mode for α-solanine and diosgenin, in 

the (-) mode for prednisolone. The data acquisition software was Xcalibur® by ThermoFinnigan. The Limit of 

Detection (LOD) were from 0.6 to 4 ng/mL, the Limit of Quantification (LOQ) were from 1 to 10 ng/mL. 

Results  

Diosgenin and α-solanine underwent a transformation in faeces. Their concentrations decreased over time. 

From t = 48h diosgenin was not detected while α-solanine was detected at a concentration lower than 30% of the 

initial one. After 72h also α-solanine was not detectable. The faecal suspension spiked with diosgenin, at t = 8h 

showed the presence of prednisolone at the concentration of 7.1 ng/mL (Figure 2). In the sample of faeces spiked 

with α-solanine, cortisol was detected at t = 24h with a concentration of 6.6 ng/mL (Figure 3). In the feed solanine 

did not transform while diosgenin steadily decreased to the 15% of the initial concentration. No corticosteroids were 

detected. In the control samples, no transformations were observed. 

 

Discussion and Conclusions 

The presence of corticosteroids in two faecal suspensions could show that the neo formation of prednisolone 

and cortisol from diosgenin and α-solanine, even if sporadic, may be possible. 

It could be conceivable that the transformation event likely occurs in the presence of certain microorganisms, 

and is apparently random, as faeces are highly non homogeneous both in their rough composition and in the 

microflora present. Further studies are ongoing to investigate these preliminary conclusions. 

References 

Arioli F., Fidani M., Casati A., Fracchiolla M.L., Pompa G. (2010). Investigation on possible transformations of cortisol, cortisone and cortisol 
glucuronide in bovine faecal matter using liquid chromatography-mass spectrometry, Steroids, 75, 350–354.  

Bertocchi L., Dusi G., Ghidelli V., Hathaway T., Nassuato C., Casati A., Fidani M., Pompa G., Arioli F. (2013), Investigation on the origin of 
prednisolone in urine and adrenal glands of cows, Food Addi. Contam., Part A, 30, 1055-1062.  

Bredehöft M., Baginski R., Parr M.K., Thevis M., Schänzer W. (2012) Investigations of the microbial transformation of cortisol to prednisolone in 
urine samples. J. . Steroid Biochem. Mol. Biol., 129, 54–60. 

Dusi G., Arioli F., Ghidelli V., Casati A., Hathaway T., Pompa G., Bertocchi L. (2012) Investigations on the origin of prednisolone in cow urine “Euro 
Residue VII – Conference on Residues of Veterinary Drugs in Food” - 14-16 May 2012, Egmond aan Zee,The Netherlands. 

Pompa G., Arioli F., Casati A., Fidani M., Bertocchi L., Dusi G. (2011) Investigation of the origin of prednisolone in cow urine. Steroids, 76, 104–110.  

Figure 2 - Prednisolone neoformation in diosgenin-spiked 

faecal suspension. 

 

Figure 3 - Cortisol neoformation in α-solanine-spiked 

faecal suspension.