<i>In vivo</i> Administration of Testosterone Propionate in Cattle Analyzed by High Performance Liquid Chromatography-Tandem Mass Spectrometry: An Enzymatic Hydrolysis Study and Drug Abuse Issues

Rocha, Diego G.; Lana, Mary Ane G.; Faria, Adriana F.; Augusti, Rodinei; Assis, Débora C. S. de

doi:10.21577/0103-5053.20210159

Abstract

This study involved an animal experiment in which testosterone propionate was intramuscularly injected into four steers, and the ensuing urine samples were analyzed using high-performance liquid chromatography-tandem mass spectrometry. The enzymatic hydrolysis conditions were analyzed using analysis of variance (ANOVA) and response surface methodology employing a 3³ Box-Behnken design. A survey study was performed in which 48 urine samples were collected from eight untreated steers to estimate the endogenous levels of testosterone metabolites, and it was found that 17β-testosterone was not detected in the majority of the samples, whereas 17α-testosterone was present in 43 of the 48. Drug abuse was identified within 11 days of 17β-testosterone administration. The ratio between both isomers was also assessed; however, a cut-off limit based on an untreated population could not be estimated due to the absence of the beta isomer. Therefore, there may be a correlation between the exogenous use of testosterone in castrate animals and high levels of 17β-testosterone, although confirmation through further investigation would be required.

Keywords:
testosterone; livestock; animal experimentation; Box-Behnken design

Introduction

Although the use of steroids as growth promoters in foodstuffs is prohibited in the European Union and commercial partners, other countries such as Australia, Canada, New Zealand, and the United States allow their usage for these purposes. To monitor these substances from a surveillance perspective, a range of matrices must be included in regulatory plans, and urine is generally the matrix of choice.¹1 European Commission; Commission Decision of 12 August 2002 implementing Council Directive 96/23/EC Concerning the Performance of Analytical Methods and the Interpretation of Results (2002/657EC); Official Journal of the European Union, 2002, L221, p. 8-36, available at https://eur-lex.europa.eu/legal-content/EN/TXT/HTML/?uri=CELEX:32002D0657&from=EN accessed in November 2021.
https://eur-lex.europa.eu/legal-content/...

2 European Commission; Council Directive 96/23/EC of 29 April 1996 on Measures to Monitor Certain Substances and Residues thereof in Live Animals and Animal Products and Repealing Directives 85/358/EEC and 86/469/EEC and Decisions 89/187/EEC and 91/664/EEC; Official Journal of the European Union, 1996, L125, p. 10-32, available at https://eur-lex.europa.eu/legal-content/EN/TXT/HTML/?uri=CELEX:31996L0023&from=EN accessed in November 2021.
https://eur-lex.europa.eu/legal-content/... -³3 Gonzalez Ronquillo, M.; Angeles Hernandez, J. C.; Food Control 2017, 72, 255.

However, analytical results concerning to the presence of endogenously occurring steroids (boldenone, estradiol, nortestosterone, and testosterone) demand additional strategies such as the use of gas chromatography-combustion-isotope ratio mass spectrometer systems (GC-C-IRMS),⁴4 Janssens, G.; Mangelinckx, S.; Courtheyn, D.; de Kimpe, N.; Matthijs, B.; le Bizec, B.; J. Agric. Food Chem. 2015, 63, 7574. omic approaches,⁵5 van Meulebroek, L.; Wauters, J.; Pomian, B.; Bussche, J. V.; Delahaut, P.; Fichant, E.; Vanhaecke, L.; PLoS One 2018, 13, e0195351.,⁶6 Narduzzi, L.; Dervilly, G.; Marchand, A.; Audran, M.; Le Bizec, B.; Buisson, C.; Drug Test. Anal. 2020, 12, 887. intact steroid ester detection in hair/plasma,⁷7 Toutain, P. L.; Handb. Exp. Pharmacol. 2010, 199, 315.,⁸8 Elmongy, H.; Masquelier, M.; Ericsson, M.; J. Chromatogr. A 2020, 1613. or longitudinal monitoring of biomarkers.⁹9 Kaabia, Z.; Laparre, J.; Cesbron, N.; Le Bizec, B.; Dervilly-Pinel, G.; J. Steroid Biochem. Mol. Biol. 2018, 183, 106.,¹⁰10 Kaabia, Z.; Dervilly-Pinel, G.; Popot, M. A.; Bailly-Chouriberry, L.; Plou, P.; Bonnaire, Y.; Le Bizec, B.; Drug Test. Anal. 2014, 6, 376. As limiting factors, the first alternative has poor sensitivity and high acquisition/maintenance costs, which prevents its widespread use. Omic approaches still lack a legal framework to support a decision-making process regarding non-compliant samples, and the detection of intact steroid esters usually occurs over a short detection window.¹¹11 Narduzzi, L.; Dervilly, G.; Audran, M.; Le Bizec, B.; Buisson, C.; Drug Test. Anal. 2020, 12, 677.,¹²12 Scarth, J. P.; Kay, J.; Teale, P.; Akre, C.; Le Bizec, B.; De Brabander, H. F.; Vanhaecke, L.; Van Ginkel, L.; Points, J.; Drug Test. Anal. 2012, 4, 40. However, biomarkers have been demonstrated to be efficient alternatives, since the concomitant determination of parent drugs and their metabolites frequently leads to improved analytical detection. The steroid 17α-testosterone (αTE) is the main metabolite of 17β-testosterone (βTE) in human and bovine urine and the βTE/αTE ratio (T/E ratio), is widely used in human doping analysis.¹³13 Pozo, O. J.; Marcos, J.; Ventura, R.; Fabregat, A.; Segura, J.; Anal. Bioanal. Chem. 2010, 398, 1759.,¹⁴14 Viljanto, M.; Scarth, J.; Hincks, P.; Hillyer, L.; Cawley, A.; Suann, C.; Noble, G.; Walker, C. J.; Kicman, A. T.; Parkin, M. C.; Drug Test. Anal. 2017, 9, 1328. Exogenous administration of commercial testosterone formulations causes an increased excretion rate of urinary βTE and decreased excretion rate of αTE resulting in an overall increase in the T/E ratio. However, false-negative results should be carefully considered, since individual metabolic patterns may be correlated with abnormal T/E ratios.¹⁵15 Angeletti, R.; Contiero, L.; Gallina, G.; Montesissa, C.; Vet. Res. Commun. 2006, 30, 127.

Veterinary administration of testosterone can be conducted in animals using ear implants through which low doses are continuously released into the bloodstream, or via multiple intramuscular injections. With the latter method, sequenced concentration loops could lead to a cumulative effect (plateau effect).¹⁶16 Waller, C. C.; McLeod, M. D.; Drug Test. Anal. 2017, 9, 1304. Once circulating in the organism, βTE undergoes extensive phase I metabolism (17-oxidation, A-ring reduction, and 3-reduction) mainly in the liver. In phase II metabolism, testosterone is conjugated with glucuronic acid (glucuronidation), and to a lesser extent with 3’-phosphoadenosine 5’-phosphosulfate (PAPS) (sulfoconjugation).¹³13 Pozo, O. J.; Marcos, J.; Ventura, R.; Fabregat, A.; Segura, J.; Anal. Bioanal. Chem. 2010, 398, 1759. Steroid compounds are predominantly excreted in the urine from these reactions as glucuronides or sulfates. Most published protocols use enzymatic hydrolysis for detecting unconjugated steroids in this matrix, such as with β-glucuronidase from bovine liver,¹⁷17 Ferchaud, V.; Courcoux, P.; Le Bizec, B.; Monteau, F.; André, F.; Analyst 2000, 125, 2255. E. coli,¹⁸18 Tamae, D.; Byrns, M.; Marck, B.; Mostaghel, E. A.; Nelson, P. S.; Lange, P.; Lin, D.; Taplin, M. E.; Balk, S.; Ellis, W.; True, L.; Vessella, R.; Montgomery, B.; Blair, I. A.; Penning, T. M.; J. Steroid Biochem. Mol. Biol. 2013, 138, 281. preparations from abalone entrails,¹⁸18 Tamae, D.; Byrns, M.; Marck, B.; Mostaghel, E. A.; Nelson, P. S.; Lange, P.; Lin, D.; Taplin, M. E.; Balk, S.; Ellis, W.; True, L.; Vessella, R.; Montgomery, B.; Blair, I. A.; Penning, T. M.; J. Steroid Biochem. Mol. Biol. 2013, 138, 281.,¹⁹19 Impens, S.; Van Loco, J.; Degroodt, J. M.; De Brabander, H.; Anal. Chim. Acta 2007, 586, 43. and the frequently used Helix pomatia juice, for its activity for both glucuronides and sulfates.¹⁶16 Waller, C. C.; McLeod, M. D.; Drug Test. Anal. 2017, 9, 1304.,²⁰20 Kaklamanos, G.; Theodoridis, G.; Dabalis, T.; J. Chromatogr. B: Anal. Technol. Biomed. Life Sci. 2009, 877, 2330. Usually, pH is maintained at approximately 5.2; however, other reaction conditions are not standardized, since reaction time varies from 2 to 24 h, temperature from 37 to 55 °C, and enzyme volume from 25 to 50 μL.¹²12 Scarth, J. P.; Kay, J.; Teale, P.; Akre, C.; Le Bizec, B.; De Brabander, H. F.; Vanhaecke, L.; Van Ginkel, L.; Points, J.; Drug Test. Anal. 2012, 4, 40.,²¹21 Pizzato, E. C.; Filonzi, M.; da Rosa, H. S.; de Bairros, A. V.; Toxicol. Mech. Methods 2017, 27, 641. The best reaction conditions are generally compound-dependent,¹⁷17 Ferchaud, V.; Courcoux, P.; Le Bizec, B.; Monteau, F.; André, F.; Analyst 2000, 125, 2255. and some glucuronides and sulfates are known to be resistant to enzymatic hydrolysis.²²22 Kotronoulas, A.; Marcos, J.; Segura, J.; Ventura, R.; Joglar, J.; Pozo, O. J.; Anal. Chim. Acta 2015, 895, 35.,²³23 Pedersen, M.; Frandsen, H. L.; Andersen, J. H.; Food Addit. Contam., Part A 2017, 34, 482.

Considering the veterinary use of testosterone, the endogenous origin of βTE and αTE is indisputable. The presence of αTE was observed in the urine of 294 bovines, whereas the detection of βTE was intensified for older bulls, as was the T/E ratio.²⁴24 Snoj, T.; Dolenc, J.; Kobal, S.; Food Addit. Contam., Part A 2014, 31, 614. In the study,²⁴24 Snoj, T.; Dolenc, J.; Kobal, S.; Food Addit. Contam., Part A 2014, 31, 614. no urinary testosterone was found in animals under the age of 5 months, where the limit of quantification (LOQ) for both testosterone metabolites was 2.0 µg mL^-1. In another study,¹⁵15 Angeletti, R.; Contiero, L.; Gallina, G.; Montesissa, C.; Vet. Res. Commun. 2006, 30, 127. testosterone enanthate was intramuscularly administered to 9 calves at the age of 6 months and 12 were kept as a control group. The untreated animals showed variations in the T/E ratio in the range of 8-15 while the treated calves revealed values varying from 12-24. The LOQ for both testosterone metabolites was 0.5 µg L^-1 .The authors¹⁵15 Angeletti, R.; Contiero, L.; Gallina, G.; Montesissa, C.; Vet. Res. Commun. 2006, 30, 127. attributed the high αTE levels to the strong 17α-hydroxysteroid oxidoreductase activity in calves, which catalyzed a rapid conversion of βTE to αTE, masking the effects of the exogenous administration of testosterone. Urine samples of 200 geldings were analyzed by liquid chromatography tandem mass spectrometry (LC-MS/MS) in order to evaluate the T/E ratio in a random population not subject to drug treatment.¹⁴14 Viljanto, M.; Scarth, J.; Hincks, P.; Hillyer, L.; Cawley, A.; Suann, C.; Noble, G.; Walker, C. J.; Kicman, A. T.; Parkin, M. C.; Drug Test. Anal. 2017, 9, 1328. For 15 of the 200 analyzed samples the concentration of βTE exceeded the limit of 15 ng mL^-1 (LOQ = 1.6 µg L^-1), and the T/E ratios were lower than the proposed limit of 5 ng mL^-1. In the same study, two geldings (one 7-year-old and one 10-year-old) were also intramuscularly injected with testosterone propionate (TEP), and the T/E ratio exceeded the proposed limit for all of the collected samples.

The aim of the current study was to determine whether the urinary T/E ratio could be used as an alternative approach to differentiate exogenous testosterone from that endogenously produced in castrate cattle. A survey study was also performed to assess the endogenous concentration values for αTE and βTE in untreated steers. In addition, naturally incurred urine samples were used to determine the extent to which testosterone metabolites were conjugated to glucuronide and sulfate moieties after drug administration. Enzymatic hydrolysis conditions were studied using multivariate analysis and response surface methodology. The detection windows for the exogenous testosterone treatment were assessed for the treated animals in which the concentration of βTE and the calculated T/E ratios were evaluated.

Experimental

Standards

Epitestosterone (αTE) was acquired from Dr. Ehrenstopher (Augsburg, Germany); 17β-testosterone (βTE) was purchased from LGC Standards (Augsburg, Germany); 17α-methyltestosterone-d₃ (MTT-d₃) was obtained from Creative Proteomics (New York, USA) and 19-nortestosterone-d₃ was obtained from Cambridge Isotope Laboratories (Andover, USA).

Individual stock solutions and internal standards were prepared at an average concentration of 100 μg mL^-1 in methanol (J.T. Baker, Center Valley, USA). Working solutions were prepared by mixing the individual stock solutions and diluting them to obtain the final concentration of 0.07 μg mL^-1 for both αTE and βTE. The internal standards 17α-methyltestosterone-d₃ (MTT-d₃) and 17β-nortestosterone-d₃ (NOR-d₃) were prepared at concentrations of 0.10, 0.40 μg mL^-1, respectively.

Chemicals

All reagents were of analytical grade. Anhydrous sodium acetate was acquired from Vetec (Rio de Janeiro, Brazil). The enzyme β-glucuronidase derived from Helix pomatia, type HP-2, activity ≥ 100,000 units mL^-1, tris-hydroxymethyl aminomethane, and the solid phase extraction (SPE) column HLB (hydrophilic lipophilic balanced, 200 mg, 6 mL) were purchased from Sigma-Aldrich (St. Louis, USA). The SPE column amino (500 mg, 3 mL) was acquired from Agilent Technologies (Waldbronn, Germany). The high-performance liquid chromatography (HPLC) grade solvents acetone, methanol, and tert-butyl methyl ether were purchased from J.T. Baker (Center Valley, USA). Sodium acetate buffer (0.2 mol L^-1) was prepared by dissolving 16.4 g of anhydrous sodium acetate in 1000 mL ultrapure water; thereafter, the pH was adjusted to 5.2 by adding acetic acid (Sigma-Aldrich, St. Louis, USA). Ultrapure water was generated by Gehaka Master Sigma 100 (Gehaka, São Paulo, Brazil).

Equipment

High-performance liquid chromatography-tandem mass spectrometry (HPLC-MS/MS) analysis was performed using an Agilent Technologies 1200 series liquid chromatography system equipped with an autosampler and a quaternary pump (Agilent Technologies, Santa Clara, USA) coupled to a triple quadrupole mass spectrometer (API 5000, Applied Biosystems, Foster City, USA). Separation was achieved on a Poroshell 120 EC-C18 column (50 × 3.0 mm, 2.7 μm) (Agilent Technologies, Santa Clara, USA). The flow rate used was 0.700 mL min^-1 and the column temperature was set at 40 °C. A gradient elution programmer was used with solvent A (ultrapure water) and solvent B (methanol) as follows: from 0 to 0.5 min the percentage of B was held at 60% and linearly increased to 80% at 2.0 min; from 2.0 to 2.1 min this percentage linearly increased to 100%, which was maintained until 2.5 min, and from 2.5 to 4.00 linearly decreased to 60%. From 4.0 to 6.0 min, the B percentage was held constant at 60%, and the injection volume was 10 µL. Detection was performed in selected reaction monitoring (SRM) mode. Instrumental control and data treatment were performed using Analyst 1.5.1 software (AB Sciex, Framingham, USA). The data acquisition used for the HPLC-MS/MS analysis is presented in Table 1.

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Table 1
Data acquisition used to detect the testosterone metabolites and the internal standards by the selected reaction monitoring (SRM) mode

Sample extraction

Urine samples were analyzed using an in-house ISO/IEC/17025:2017²⁵25 ABNT NBR ISO/IEC 17025:2017: Requisitos Gerais para a Competência de Laboratórios de Ensaio e Calibração, ABNT: Rio de Janeiro, 2005. accredited method that is regularly used in Brazil for the routine monitoring of bovine urine samples for 17 growth promoters as well as αTE and βTE. The extraction procedure was executed as follows: after the samples were thawed at room temperature, 100 µL of the internal standard working solution, 2 mL of sodium acetate buffer (2 mol L^-1, pH = 5.2) and 25 μL of Helix pomatia juice were added to 5.0 mL of urine and incubated at 37 °C for 16 h. Thereafter, 4 mL of tris-hydroxymethyl aminomethane solution (2 mol L^-1, pH = 9.5) were added, and two consecutive liquid-liquid extractions with diethyl ether were performed. After evaporation, the residue was reconstituted with 4 mL of water/methanol (2:1 v/v). The clean-up was performed using SPE with HLB and amino cartridges coupled. The former was pre-conditioned with 5 mL of methanol and 5 mL of acetone, and HLB with 5 mL of methanol and 5 mL of water. After elution with 5 mL of acetone and evaporation, the residue was reconstituted to 500 μL, and 10 μL of the reconstituted residue was injected into the HPLC-MS/MS system. Together with the analyzed samples, matrix-matched calibration curves were prepared by adjusting the working solution at the beginning of the extraction procedure to obtain the following concentration values for αTE and βTE: 0.50, 0.75, 1.00, 1.25, 1.50, and 2.00 μg L^-1. The validated limits of detection and quantification were 0.25 and 0.50 μg L^-1, respectively.

Enzymatic hydrolysis study

The evaluation of the extent of chemical conjugation of the studied analytes to glucuronide and sulfate moieties was performed using Helix pomatia juice. For the treated group, four samples collected from each animal were combined to make 5 mL of urine. Six replicates were prepared, three of which were enzymatically digested for 16 h at 37.5 °C with 50 µL of the enzyme preparation. The estimated percentage of the unconjugated fraction (P) was calculated by monitoring the unconjugated steroids (αTE and βTE). Analytical curves were prepared using the hydrolysis reaction, to allow for the referencing of 100% of the set of samples subjected to Helix pomatia deconjugation. The corresponding P (%) value was then obtained as a direct proportion of the obtained concentration values for the samples for which hydrolysis was not executed. The Student’s t-value for comparison of means between the two sets was also calculated. A Box-Behnken design was used to assess the best reaction conditions for each analyte. The following factors were evaluated: enzyme volume (-1): 10, (0): 50, (1): 100 µL; reaction time (-1): 1.5; (0): 16; (1): 24 h; and reaction temperature (-1): room temperature; (0): 37; (1): 55 °C. The calculated concentration values were statistically evaluated using analysis of variance (ANOVA)²⁶26 Rocha, D. G.; Santos, F. A.; Augusti, R.; Faria, A. F.; J. Braz. Chem. Soc. 2016, 27, 221. in Microsoft Excel 2010^® software.²⁷27 Gates III, W. H.; Allen, P. G.; Microsoft Excel software; Microsoft Corporation, Redmond, Washington, United States, 2010.

Survey study and detection window evaluation

An in vivo study was performed on four crossbred steers treated with TEP (Androgenol^®, Hertape Calier, Juatuba, Brazil) in two consecutive doses of 0.2 mg kg^-1. Urine samples were collected by spontaneous urination of the confined animals on the following days for the treated animals: -5, -4, 0 (just before drug administration), 0 + 6 h, 1, 1 + 6 h, 2, 3, 3 + 6 h, 4, 5, 7, 9, 11, and 14. A second set of four steers (C1-C4) was maintained without any drug treatment during the experiment, and urine samples were collected on days -5, -4, 1, 9, and 14. The samples were centrifuged for 30 min at 2700 g and transferred to 50 mL plastic tubes, which were stored at -80 °C for a maximum period of 10 days before extraction. This procedure was performed after approval by the Ethical Committee on Animal Experimentation of the Federal University of Minas Gerais, Brazil, according to protocol No. 111/2019.

Results and Discussion

Matrix-matched calibration curves were employed for the validated method, in which the analytical standards were adjusted at the beginning of the extraction procedure to obtain the following concentration levels: 0.70, 1.05, 1.40, 1.75, 2.10, and 2.80 µg L^-1. After method validation, the accuracy levels were 76.5 and 86.4%, and the coefficients of variation under intermediate precision conditions were 22.6 and 15.8% for αTE and βTE, respectively, which corresponds to adequate performance according to the adopted validation guide.¹1 European Commission; Commission Decision of 12 August 2002 implementing Council Directive 96/23/EC Concerning the Performance of Analytical Methods and the Interpretation of Results (2002/657EC); Official Journal of the European Union, 2002, L221, p. 8-36, available at https://eur-lex.europa.eu/legal-content/EN/TXT/HTML/?uri=CELEX:32002D0657&from=EN accessed in November 2021.
https://eur-lex.europa.eu/legal-content/... The calculated decision limits (CCα) were 0.22 µg L^-1 for αTE and 0.23 µg L^-1 for βTE, and the detection capabilities (CCβ) were 0.48 µg L^-1 for αTE and 0.53 µg L^-1 for βTE.

Enzymatic hydrolysis study

Considering that phase II reactions such as glucuronidation and sulfation play an important role in the excretion metabolism of veterinary drugs in urine,²¹21 Pizzato, E. C.; Filonzi, M.; da Rosa, H. S.; de Bairros, A. V.; Toxicol. Mech. Methods 2017, 27, 641.,²³23 Pedersen, M.; Frandsen, H. L.; Andersen, J. H.; Food Addit. Contam., Part A 2017, 34, 482. the extent to which they are chemically bound is important for quantification purposes. Therefore, the use of naturally produced samples for the study of conjugation reactions is highly desirable, since the use of synthetic standards may not perfectly mimic the biological distribution of the conjugate species. The frequently performed hydrolysis conditions reported in the literature were initially used to assess its influence on the deconjugation reaction in urine (i.e., 16 h, 37 °C, 50 µL for urine).¹²12 Scarth, J. P.; Kay, J.; Teale, P.; Akre, C.; Le Bizec, B.; De Brabander, H. F.; Vanhaecke, L.; Van Ginkel, L.; Points, J.; Drug Test. Anal. 2012, 4, 40.,¹⁶16 Waller, C. C.; McLeod, M. D.; Drug Test. Anal. 2017, 9, 1304.,²¹21 Pizzato, E. C.; Filonzi, M.; da Rosa, H. S.; de Bairros, A. V.; Toxicol. Mech. Methods 2017, 27, 641. Table 2 presents the concentration values for αTE and βTE obtained from urine samples that were subjected to the hydrolysis reaction, together with the estimated percentage of the unconjugated fraction for both analytes.

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Table 2
Enzymatic hydrolysis evaluation of the testosterone metabolites in bovine urine

The concentration values of αTE and βTE were significantly lower in the absence of the hydrolysis reaction (13.4-15.5%), and the calculated t values at the 95% confidence level were greater than the critical value (t_{(0.05; 4)} = 2.77). Therefore, the hydrolysis reaction had a significant influence on the analysis of unconjugated testosterone metabolites in bovine urine. Therefore, a Box-Behnken design was used to study the influence of each reaction condition on the analytical responses of βTE and αTE (Table 2). The Box-Behnken design is a second-order multivariate design based on a three-level incomplete factorial design with no axial points, which permits the assessment of the critical factors that significantly affect the analytical responses using a reduced number of experiments.²⁸28 Montgomery, D. C.; Design and Analysis of Experiments, 4th ed.; Willey: New York, USA, 1997. The evaluated factors and the obtained concentration values for each test are presented in Table 3.

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Table 3
Calculated concentrations for 17α-testosterone (αTE) and 17β-testosterone (βTE) obtained from the 3³ Box-Behnken Design for the enzymatic hydrolysis evaluation

The quality of the adjustments was evaluated by ANOVA, in which the respective mean square values for lack of fit and pure error were divided to obtain a calculated F-value. The response surfaces obtained for αTE and βTE are shown in Figure 1.

Figure 1
Response surfaces obtained for αTE and βTE from a 3³ Box-Behnken design for the evaluation of the enzymatic hydrolysis conditions using Helix pomatia.

The statistical models did not present evidence of lack of fit at the 95% confidence level, since the calculated F values (9.84 for αTE and 15.09 for βTE) were lower than F_{critical(0.05;3;2)} = 19.16. The respective equations to describe the concentration values (C) related to the studied factors volume (V), temperature (T), and time (t) are represented in equations 1 and 2:

(1)

\begin{aligned} C_{α T E} = (2.79 \pm 0.06) + (0.88 \pm 0.04) V + (0.91 \pm 0.04) t - \\ (0.22 \pm 0.04) T - (0.26 \pm 0.06) V^{2} - (1.00 \pm 0.06) t^{2} - \\ (0.69 \pm 0.06) T^{2} + (0.55 \pm 0.06) V T - (0.31 \pm 0.06) t T \end{aligned}

(2)

\begin{aligned} C_{β T E} = (1.71 \pm 0.04) + (0.30 \pm 0.02) V + (0.19 \pm 0.02) t - \\ (0.21 \pm 0.03) t^{2} - (0.16 \pm 0.06) T^{2} + (0.24 \pm 0.03) V T \end{aligned}

Temperature had the least influence on the curvature of the obtained response surfaces. In contrast, volume and time significantly influenced the deconjugation process in such a way that the maximum values were located around the greater factors (24 h and 100 μL). However, the central point condition (50 µL, 16 h, and 37 °C), which require a lower enzyme volume and a faster reaction, did not lead to significantly lower concentration values; therefore, this combination is an option for use on a routine basis, whereas the experiments using 10 µL of enzyme and 1.5 h exhibited poorer performance and thereby should be avoided.

Survey study and detection window evaluation

The endogenous levels of αTE and βTE were assessed by analyzing urine samples collected from the treated group before drug administration, and for the control group throughout the experiment. Table 4 presents the estimated concentration values obtained for both isomers, in which the treated animals were denoted as T1-T4, and the untreated animals as C1-C4. The alpha epimer αTE was observed at greater intensities than βTE for all of the collected urine samples, which corroborates the literature,¹⁵15 Angeletti, R.; Contiero, L.; Gallina, G.; Montesissa, C.; Vet. Res. Commun. 2006, 30, 127. although βTE was not detected in the vast majority of urine samples collected from the untreated steers, probably because of their castrate condition. The methods reported in the literature describe endogenous testosterone as dependent on the animal age and gender,¹⁴14 Viljanto, M.; Scarth, J.; Hincks, P.; Hillyer, L.; Cawley, A.; Suann, C.; Noble, G.; Walker, C. J.; Kicman, A. T.; Parkin, M. C.; Drug Test. Anal. 2017, 9, 1328.,¹⁵15 Angeletti, R.; Contiero, L.; Gallina, G.; Montesissa, C.; Vet. Res. Commun. 2006, 30, 127.,²⁴24 Snoj, T.; Dolenc, J.; Kobal, S.; Food Addit. Contam., Part A 2014, 31, 614. and an aim of this work was to establish that animal castration should also be evaluated when dealing with testosterone monitoring. Here, the calculation of the T/E ratio to assess a cut-off limit for a control group of animals was not possible, and most of the concentrations obtained for both isomers were lower than the validated LOQ (0.50 µg mL^-1), which is equal or inferior to other reported limits found in the literature.¹⁴14 Viljanto, M.; Scarth, J.; Hincks, P.; Hillyer, L.; Cawley, A.; Suann, C.; Noble, G.; Walker, C. J.; Kicman, A. T.; Parkin, M. C.; Drug Test. Anal. 2017, 9, 1328.,¹⁵15 Angeletti, R.; Contiero, L.; Gallina, G.; Montesissa, C.; Vet. Res. Commun. 2006, 30, 127.,²⁴24 Snoj, T.; Dolenc, J.; Kobal, S.; Food Addit. Contam., Part A 2014, 31, 614. However, it should be noted that the method validation and applicability were developed in the frame of the European Decision 657/2002/EC,¹1 European Commission; Commission Decision of 12 August 2002 implementing Council Directive 96/23/EC Concerning the Performance of Analytical Methods and the Interpretation of Results (2002/657EC); Official Journal of the European Union, 2002, L221, p. 8-36, available at https://eur-lex.europa.eu/legal-content/EN/TXT/HTML/?uri=CELEX:32002D0657&from=EN accessed in November 2021.
https://eur-lex.europa.eu/legal-content/... which recommends that any result above the CCα of the method should be reported for prohibited drugs. According to this regulation, the CCα is used to define the limit above which it can be concluded that a sample contains the analyte, with an error probability of α equal to 1% (probability of false non-compliant decision) for prohibited drugs. This means that CCα is the lowest concentration level at which a method can discriminate whether the identified analyte is present. CCβ is the lowest concentration of a compound that may be detected, identified, and quantified in a sample, with an error probability of β equal to 5% (probability of false-compliant results). Therefore, since this work deals with the detection of hormone abuse, the concentration values above the respective CCα values for αTE and βTE, 0.22 and 0.23 µg L^-1, were reported as estimated concentration values.

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Table 4
Detection of the metabolites 17α-testosterone (αTE) and 17β-testosterone (βTE) in urine samples of untreated steers

As for the monitoring of both testosterone isomers after drug administration, Figure 2 shows the extracted ion chromatograms for αTE and βTE from day 0-14 after testosterone treatment for T1.

Figure 2
Extracted ion chromatograms (quantitative and qualitative ion transitions) related to the variation on the intensities between βTE (bTE) and αTE (aTE) for the animal T1 at (a) day 0; (b) day 0 + 6 h; (c) day 11, and (d) day 14.

βTE was rapidly observed after 6 h of drug administration, and its analytical signal was detected for 11 days. For the other three animals, a similar pattern was observed, in which the detection windows for βTE were 7 days for T2 and T4, and 11 days for T3. Figure 3 shows the calculated βTE concentrations and T/E ratios obtained from the urine samples. The concentration values for each sample are presented in Table S1 (Supplementary Information section).

Figure 3
Calculated βTE concentrations (a) and T/E ratios (b) in urine for the four steers subjected to the testosterone treatment.

A period of 3 days occurred between the application of the testosterone formulation and a decay to lower levels, which is in agreement with the package leaflet instructions. Although βTE was not detected before drug administration, illegal treatment could not be attributed to the treated samples due to the known endogenous nature of this compound. Therefore, the applicability of the T/E ratio was evaluated to characterize the exogenous use, in which higher oscillations over the treatment were observed for T2 and T4 (Figure 2). However, for T1, the drug treatment did not significantly alter this value over the study period, even after the second dose was administered on day 3. It should be noted that for most of the reported studies, the T/E ratios were greater than 1 for treated animals, with cut-off limits in the range of 4 to 6. However, these ratios were calculated when high βTE concentrations were obtained (around 15 ppb), which did not occur in any of the samples in this work.¹⁴14 Viljanto, M.; Scarth, J.; Hincks, P.; Hillyer, L.; Cawley, A.; Suann, C.; Noble, G.; Walker, C. J.; Kicman, A. T.; Parkin, M. C.; Drug Test. Anal. 2017, 9, 1328.,¹⁶16 Waller, C. C.; McLeod, M. D.; Drug Test. Anal. 2017, 9, 1304.

As an outcome of this study, it can be seen that the T/E ratio could be useful for sample treatment classification in castrate cattle, since high values are suggestive of exogenous treatment, whereas low or non-existent values of βTE were detected in the untreated castrated animals. The decision limit for this analyte was equal to 0.23 μg mL^-1, which indicated that the endogenous concentrations should be lower than this value. The method described in this article was developed for use in a surveillance program by the Ministry of Agriculture, Livestock, and Supply of Brazil for the monitoring of prohibited veterinary drugs. Thus, the identification of high levels of 17β-testosterone in urine samples collected from castrated cattle can be classified as suspicious with regard to non-compliance with growth promoter regulations. Since the exogenous use would still be inconclusive, the laboratory report could contain this information, with an additional request for forensic work, such as in loco farm/slaughterhouse inspections. This work could be executed through interviews, searches for used packages, package inserts and syringes, or by other strategies to trace/prevent drug abuse.

Conclusions

In this study, naturally incurred urine samples containing testosterone propionate metabolites were obtained for an animal experiment involving castrate cattle, which is a condition particularly common in livestock. It could be observed that βTE and αTE were predominantly present in conjugate forms in urine. The enzymatic hydrolysis reaction was studied using response surface methodology, in which a central point condition led to satisfactory performance. Few samples collected from untreated animals exhibited detectable βTE signals, which were observed in the treated group up to 11 days after drug administration. In contrast, αTE was detected in most of the control animals and all of the treated steers. Considering that the beta isomer was observed only after drug treatment, high levels of this analyte could be related to possible drug abuse in castrate cattle. The application of the T/E ratio between both testosterone isomers was also studied; however, the absence of βTE for the control group halted the establishment of a cut-off level based on an untreated population. To the best of our knowledge, this is the first time that this ratio has been evaluated for castrate cattle.

Supplementary Information

Supplementary information (Table S1) is available free of charge at http://jbcs.sbq.org.br as PDF file.

Acknowledgments

The authors would like to acknowledge the Fundação de Amparo à Pesquisa do Estado de Minas Gerais (process: CAG-APQ-01049-15) and the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) for financial support. The authors are grateful to Laboratório Federal de Defesa Agropecuária (LFDA-MG), at the Ministério da Agricultura, Pecuária e Abastecimento (MAPA) of Brazil, for providing its infrastructure and supplies for the development of this work. The authors also thank the assistance of the Postgraduate Collegiate in Animal Science at the Universidade Federal de Minas Gerais (UFMG) for providing the funds for the publication of the article.

References

¹
European Commission; Commission Decision of 12 August 2002 implementing Council Directive 96/23/EC Concerning the Performance of Analytical Methods and the Interpretation of Results (2002/657EC); Official Journal of the European Union, 2002, L221, p. 8-36, available at https://eur-lex.europa.eu/legal-content/EN/TXT/HTML/?uri=CELEX:32002D0657&from=EN accessed in November 2021.
» https://eur-lex.europa.eu/legal-content/EN/TXT/HTML/?uri=CELEX:32002D0657&from=EN
²
European Commission; Council Directive 96/23/EC of 29 April 1996 on Measures to Monitor Certain Substances and Residues thereof in Live Animals and Animal Products and Repealing Directives 85/358/EEC and 86/469/EEC and Decisions 89/187/EEC and 91/664/EEC; Official Journal of the European Union, 1996, L125, p. 10-32, available at https://eur-lex.europa.eu/legal-content/EN/TXT/HTML/?uri=CELEX:31996L0023&from=EN accessed in November 2021.
» https://eur-lex.europa.eu/legal-content/EN/TXT/HTML/?uri=CELEX:31996L0023&from=EN
³
Gonzalez Ronquillo, M.; Angeles Hernandez, J. C.; Food Control 2017, 72, 255.
⁴
Janssens, G.; Mangelinckx, S.; Courtheyn, D.; de Kimpe, N.; Matthijs, B.; le Bizec, B.; J. Agric. Food Chem. 2015, 63, 7574.
⁵
van Meulebroek, L.; Wauters, J.; Pomian, B.; Bussche, J. V.; Delahaut, P.; Fichant, E.; Vanhaecke, L.; PLoS One 2018, 13, e0195351.
⁶
Narduzzi, L.; Dervilly, G.; Marchand, A.; Audran, M.; Le Bizec, B.; Buisson, C.; Drug Test. Anal 2020, 12, 887.
⁷
Toutain, P. L.; Handb. Exp. Pharmacol 2010, 199, 315.
⁸
Elmongy, H.; Masquelier, M.; Ericsson, M.; J. Chromatogr. A 2020, 1613.
⁹
Kaabia, Z.; Laparre, J.; Cesbron, N.; Le Bizec, B.; Dervilly-Pinel, G.; J. Steroid Biochem. Mol. Biol 2018, 183, 106.
¹⁰
Kaabia, Z.; Dervilly-Pinel, G.; Popot, M. A.; Bailly-Chouriberry, L.; Plou, P.; Bonnaire, Y.; Le Bizec, B.; Drug Test. Anal. 2014, 6, 376.
¹¹
Narduzzi, L.; Dervilly, G.; Audran, M.; Le Bizec, B.; Buisson, C.; Drug Test. Anal. 2020, 12, 677.
¹²
Scarth, J. P.; Kay, J.; Teale, P.; Akre, C.; Le Bizec, B.; De Brabander, H. F.; Vanhaecke, L.; Van Ginkel, L.; Points, J.; Drug Test. Anal. 2012, 4, 40.
¹³
Pozo, O. J.; Marcos, J.; Ventura, R.; Fabregat, A.; Segura, J.; Anal. Bioanal. Chem. 2010, 398, 1759.
¹⁴
Viljanto, M.; Scarth, J.; Hincks, P.; Hillyer, L.; Cawley, A.; Suann, C.; Noble, G.; Walker, C. J.; Kicman, A. T.; Parkin, M. C.; Drug Test. Anal 2017, 9, 1328.
¹⁵
Angeletti, R.; Contiero, L.; Gallina, G.; Montesissa, C.; Vet. Res. Commun. 2006, 30, 127.
¹⁶
Waller, C. C.; McLeod, M. D.; Drug Test. Anal 2017, 9, 1304.
¹⁷
Ferchaud, V.; Courcoux, P.; Le Bizec, B.; Monteau, F.; André, F.; Analyst 2000, 125, 2255.
¹⁸
Tamae, D.; Byrns, M.; Marck, B.; Mostaghel, E. A.; Nelson, P. S.; Lange, P.; Lin, D.; Taplin, M. E.; Balk, S.; Ellis, W.; True, L.; Vessella, R.; Montgomery, B.; Blair, I. A.; Penning, T. M.; J. Steroid Biochem. Mol. Biol. 2013, 138, 281.
¹⁹
Impens, S.; Van Loco, J.; Degroodt, J. M.; De Brabander, H.; Anal. Chim. Acta 2007, 586, 43.
²⁰
Kaklamanos, G.; Theodoridis, G.; Dabalis, T.; J. Chromatogr. B: Anal. Technol. Biomed. Life Sci. 2009, 877, 2330.
²¹
Pizzato, E. C.; Filonzi, M.; da Rosa, H. S.; de Bairros, A. V.; Toxicol. Mech. Methods 2017, 27, 641.
²²
Kotronoulas, A.; Marcos, J.; Segura, J.; Ventura, R.; Joglar, J.; Pozo, O. J.; Anal. Chim. Acta 2015, 895, 35.
²³
Pedersen, M.; Frandsen, H. L.; Andersen, J. H.; Food Addit. Contam., Part A 2017, 34, 482.
²⁴
Snoj, T.; Dolenc, J.; Kobal, S.; Food Addit. Contam., Part A 2014, 31, 614.
²⁵
ABNT NBR ISO/IEC 17025:2017: Requisitos Gerais para a Competência de Laboratórios de Ensaio e Calibração, ABNT: Rio de Janeiro, 2005.
²⁶
Rocha, D. G.; Santos, F. A.; Augusti, R.; Faria, A. F.; J. Braz. Chem. Soc 2016, 27, 221.
²⁷
Gates III, W. H.; Allen, P. G.; Microsoft Excel software; Microsoft Corporation, Redmond, Washington, United States, 2010.
²⁸
Montgomery, D. C.; Design and Analysis of Experiments, 4^th ed.; Willey: New York, USA, 1997.

Edited by

Editors handled this article: Eduardo Carasek and Emanuel Carrilho (Associate)

Publication Dates

Publication in this collection
18 Mar 2022
Date of issue
2022

History

Received
25 Apr 2021
Accepted
23 Nov 2021

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
European Commission; Commission Decision of 12 August 2002 implementing Council Directive 96/23/EC Concerning the Performance of Analytical Methods and the Interpretation of Results (2002/657EC); Official Journal of the European Union, 2002, L221, p. 8-36, available at https://eur-lex.europa.eu/legal-content/EN/TXT/HTML/?uri=CELEX:32002D0657&from=EN accessed in November 2021.
» https://eur-lex.europa.eu/legal-content/EN/TXT/HTML/?uri=CELEX:32002D0657&from=EN

[2] ²
European Commission; Council Directive 96/23/EC of 29 April 1996 on Measures to Monitor Certain Substances and Residues thereof in Live Animals and Animal Products and Repealing Directives 85/358/EEC and 86/469/EEC and Decisions 89/187/EEC and 91/664/EEC; Official Journal of the European Union, 1996, L125, p. 10-32, available at https://eur-lex.europa.eu/legal-content/EN/TXT/HTML/?uri=CELEX:31996L0023&from=EN accessed in November 2021.
» https://eur-lex.europa.eu/legal-content/EN/TXT/HTML/?uri=CELEX:31996L0023&from=EN

[3] ³
Gonzalez Ronquillo, M.; Angeles Hernandez, J. C.; Food Control 2017, 72, 255.

[4] ⁴
Janssens, G.; Mangelinckx, S.; Courtheyn, D.; de Kimpe, N.; Matthijs, B.; le Bizec, B.; J. Agric. Food Chem. 2015, 63, 7574.

[5] ⁵
van Meulebroek, L.; Wauters, J.; Pomian, B.; Bussche, J. V.; Delahaut, P.; Fichant, E.; Vanhaecke, L.; PLoS One 2018, 13, e0195351.

[6] ⁶
Narduzzi, L.; Dervilly, G.; Marchand, A.; Audran, M.; Le Bizec, B.; Buisson, C.; Drug Test. Anal 2020, 12, 887.

[7] ⁷
Toutain, P. L.; Handb. Exp. Pharmacol 2010, 199, 315.

[8] ⁸
Elmongy, H.; Masquelier, M.; Ericsson, M.; J. Chromatogr. A 2020, 1613.

[9] ⁹
Kaabia, Z.; Laparre, J.; Cesbron, N.; Le Bizec, B.; Dervilly-Pinel, G.; J. Steroid Biochem. Mol. Biol 2018, 183, 106.

[10] ¹⁰
Kaabia, Z.; Dervilly-Pinel, G.; Popot, M. A.; Bailly-Chouriberry, L.; Plou, P.; Bonnaire, Y.; Le Bizec, B.; Drug Test. Anal. 2014, 6, 376.

[11] ¹¹
Narduzzi, L.; Dervilly, G.; Audran, M.; Le Bizec, B.; Buisson, C.; Drug Test. Anal. 2020, 12, 677.

[12] ¹²
Scarth, J. P.; Kay, J.; Teale, P.; Akre, C.; Le Bizec, B.; De Brabander, H. F.; Vanhaecke, L.; Van Ginkel, L.; Points, J.; Drug Test. Anal. 2012, 4, 40.

[13] ¹³
Pozo, O. J.; Marcos, J.; Ventura, R.; Fabregat, A.; Segura, J.; Anal. Bioanal. Chem. 2010, 398, 1759.

[14] ¹⁴
Viljanto, M.; Scarth, J.; Hincks, P.; Hillyer, L.; Cawley, A.; Suann, C.; Noble, G.; Walker, C. J.; Kicman, A. T.; Parkin, M. C.; Drug Test. Anal 2017, 9, 1328.

[15] ¹⁵
Angeletti, R.; Contiero, L.; Gallina, G.; Montesissa, C.; Vet. Res. Commun. 2006, 30, 127.

[16] ¹⁶
Waller, C. C.; McLeod, M. D.; Drug Test. Anal 2017, 9, 1304.

[17] ¹⁷
Ferchaud, V.; Courcoux, P.; Le Bizec, B.; Monteau, F.; André, F.; Analyst 2000, 125, 2255.

[18] ¹⁸
Tamae, D.; Byrns, M.; Marck, B.; Mostaghel, E. A.; Nelson, P. S.; Lange, P.; Lin, D.; Taplin, M. E.; Balk, S.; Ellis, W.; True, L.; Vessella, R.; Montgomery, B.; Blair, I. A.; Penning, T. M.; J. Steroid Biochem. Mol. Biol. 2013, 138, 281.

[19] ¹⁹
Impens, S.; Van Loco, J.; Degroodt, J. M.; De Brabander, H.; Anal. Chim. Acta 2007, 586, 43.

[20] ²⁰
Kaklamanos, G.; Theodoridis, G.; Dabalis, T.; J. Chromatogr. B: Anal. Technol. Biomed. Life Sci. 2009, 877, 2330.

[21] ²¹
Pizzato, E. C.; Filonzi, M.; da Rosa, H. S.; de Bairros, A. V.; Toxicol. Mech. Methods 2017, 27, 641.

[22] ²²
Kotronoulas, A.; Marcos, J.; Segura, J.; Ventura, R.; Joglar, J.; Pozo, O. J.; Anal. Chim. Acta 2015, 895, 35.

[23] ²³
Pedersen, M.; Frandsen, H. L.; Andersen, J. H.; Food Addit. Contam., Part A 2017, 34, 482.

[24] ²⁴
Snoj, T.; Dolenc, J.; Kobal, S.; Food Addit. Contam., Part A 2014, 31, 614.

[25] ²⁵
ABNT NBR ISO/IEC 17025:2017: Requisitos Gerais para a Competência de Laboratórios de Ensaio e Calibração, ABNT: Rio de Janeiro, 2005.

[26] ²⁶
Rocha, D. G.; Santos, F. A.; Augusti, R.; Faria, A. F.; J. Braz. Chem. Soc 2016, 27, 221.

[27] ²⁷
Gates III, W. H.; Allen, P. G.; Microsoft Excel software; Microsoft Corporation, Redmond, Washington, United States, 2010.

[28] ²⁸
Montgomery, D. C.; Design and Analysis of Experiments, 4^th ed.; Willey: New York, USA, 1997.

Analyte	IS	Q1	Q3	Ion ratio / %	DP / V	CE / V	CXP / V
αTE	NTT-d₃	289.2	97.0^a a Quantitative diagnostic ions;	-	56	33	18
αTE	NTT-d₃	289.2	109.0	91.2	56	35	10
βTE	MTT-d₃	289.2	97.1^a a Quantitative diagnostic ions;	-	60	37	12
βTE	MTT-d₃	289.2	109.1	93.3	60	35	12
MTT-d₃	-	306.3	97.0^b b internal standard diagnostic ions. IS: internal standard; Q1: parent ion; Q3: product ion; DP: declustering potential; CE: collision energy; CXP: collision cell exit potential; αTE: epitestosterone; βTE: 17α-testosterone; MTT-d3:17α-methyltestosterone-d3; NTT-d3: 19-nortestosterone- d3.	-	111	39	20
NTT-d₃	-	278.5	109.1^b b internal standard diagnostic ions. IS: internal standard; Q1: parent ion; Q3: product ion; DP: declustering potential; CE: collision energy; CXP: collision cell exit potential; αTE: epitestosterone; βTE: 17α-testosterone; MTT-d3:17α-methyltestosterone-d3; NTT-d3: 19-nortestosterone- d3.	-	85	36	18

Analyte	C^a a C: calculated concentration obtained with no hydrolysis reaction; / (µg L^-1)	C^b b C: calculated concentration obtained after hydrolysis; P: estimated percentage of the unconjugated fraction; αTE: 17α-testosterone; βTE: 17β-testosterone. / (µg L^-1)	P / %	Student t-value
αTE	0.42 (± 0.01)	2.73 (± 0.03)	15.5	121.1
βTE	0.22 (± 0.03)	1.64 (± 0.14)	13.4	12.4

Experiment	Enzyme volume	Reaction time	Reaction temperature	Concentration / (µg L^-1)
Experiment	Enzyme volume	Reaction time	Reaction temperature	αTE	βTE
1	-1	-1	0	0.27	1.01
2	1	-1	0	0.65	1.49
3	-1	1	0	1.30	1.47
4	1	1	0	3.90	1.65
5	-1	0	-1	1.18	1.37
6	1	0	-1	2.97	1.75
7	-1	0	1	0.46	0.68
8	1	0	1	2.75	2.04
9	0	-1	-1	0.26	1.11
10	0	1	-1	2.36	1.48
11	0	-1	1	0.46	1.13
12	0	1	1	1.33	1.63
13	0	0	0	2.66	1.73
14	0	0	0	2.86	1.76
15	0	0	0	2.85	1.64

Collection day	βTE / (µg mL^-1)
Collection day	T1	T2	T3	T4	C1	C2	C3	C4
-5	0.26	ND	ND	0.34^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.49^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.58	ND	ND
-4	ND	ND	ND	ND	0.45^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	ND	ND	ND
0	ND	ND	ND	0.52	ND	0.70	ND	ND
1	-	-	-	-	ND	ND	ND	0.29^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.
9	-	-	-	-	ND	ND	0.29^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	ND
14	-	-	-	-	ND	ND	0.43^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	ND
	αTE / (µg mL^-1)
	T1	T2	T3	T4	C1	C2	C3	C4
-5	0.43^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.34^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.25^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.29^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.45^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	ND	0.70	0.43^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.
-4	0.38^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.28^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.35^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.26^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.49^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.29^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.56	0.33^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.
0	0.32^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.30^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.36^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.36^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.47^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.33^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.46^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.47^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.
1	0.41^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.39^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.24^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	ND	0.41^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	ND	0.54	0.51
9	0.48^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.31^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.27^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	ND	0.22^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	ND	0.50	0.42^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.
14	0.37^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.43^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.29^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.28^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.30^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.31^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.	0.62	0.36^a a Estimated concentration values lower than LOQ but greater than CCα. ND: no detection; αTE: 17α-testosterone; βTE: 17β-testosterone.

Brasil

Brasil

In vivo Administration of Testosterone Propionate in Cattle Analyzed by High Performance Liquid Chromatography-Tandem Mass Spectrometry: An Enzymatic Hydrolysis Study and Drug Abuse Issues

Abstract

Introduction

Experimental

Standards

Chemicals

Equipment

Sample extraction

Enzymatic hydrolysis study

Survey study and detection window evaluation

Results and Discussion

Enzymatic hydrolysis study

Survey study and detection window evaluation

Conclusions

Supplementary Information

Acknowledgments

References

Edited by

Publication Dates

History