Two-dimensional high performance liquid chromatography purification of underivatized urinary prednisone and prednisolone for compound-specific stable carbon isotope analysis.

The gas chromatography-combustion isotope ratio mass spectrometry (GC/C/IRMS) confirmation procedure for prednisone (PS) and prednisolone (PSL) is still a great challenge for the doping control laboratory due to the many structurally similar steroids present in urinary matrices. This study aims to establish an innovative online two-dimensional high performance liquid chromatography (2D-HPLC) purification method for measuring the carbon isotope ratios (CIRs) and achieving the identification of the synthetic forms of these two endogenous anabolic androgenic steroids (EAASs). Initially, the one-dimensional chromatographic column was used to separate and purify endogenous reference compounds (ERCs), and the co-elution fluids containing PS and PSL were switched to a two-dimensional chromatographic column for further purification through an online transfer system. Then the purified compounds were analyzed using GC/C/IRMS after sample pretreatments. The results showed that the minimum detection concentration of PS and PSL reached 30 ng mL-1, and no isotope fractionation occurred during the entire collection and preparation process. This method has been validated with the WADA technical document and showed good sensitivity and selectivity, demonstrating its practical applicability for urine samples in doping control laboratories.

Urinary excretion profile of prednisolone and prednisone after rectal administration: Significance in antidoping analysis.

The rectal administration of glucocorticoids, as well as any injectable, and oral ones, is currently prohibited by the World Anti-Doping Agency when occurs "in competition." A reporting level of 100 ng/ml for prednisolone and 300 ng/ml for prednisone was established to discriminate the allowed and the prohibited administration. Here, the urinary excretion profiles of prednisone and prednisolone were evaluated in five volunteers in therapy with glucocorticoid-based rectal formulations containing prednisone or prednisolone caproate. The urinary levels of the excreted target compounds were determined by liquid chromatography-tandem mass spectrometry (LC-MS/MS) following the procedure validated and currently in use in our laboratory to detect and quantitate glucocorticoids in urine. Predictably, the excretion trend of the analytes of interest were generally comparable with those obtained after oral administration, even if the excretion profile showed a broad interindividual variability, with the absorption rate and the systemic bioavailability after rectal administration being strongly influenced by the type of formulations (suppository or rectal cream, in our case) as well as the physiological conditions of the absorption area. Results showed that the target compounds were detectable for at least 30 h after drug administration. After suppository administration, prednisolone levels reached the maximum after 3 h from drug administration and then dropped below the reporting level after 15-21 h; prednisone reached the maximum after 3 h from drug administration, and then dropped below the reporting level after 12-15 h. After cream administration, both prednisone and prednisolone levels remained in a concentration below the reporting level throughout the entire monitored period.

Elimination profiles of prednisone and prednisolone after different administration routes: Evaluation of the reporting level and washout periods to ensure safe therapeutic administrations.

Prednisolone (PRED) and prednisone (PSONE) are prohibited in sports competitions when administered by systemic routes, and they are allowed by other routes for therapeutic purposes. There is no restriction of use in out-of-competition periods. The present study aimed to evaluate the urinary excretion of PRED, PSONE, and their most important metabolites after systemic and nonsystemic treatments in order to verify the suitability of the current reporting level of 30 ng/ml used to distinguish allowed and prohibited administrations and to establish washout periods for oral treatments performed in out-of-competition periods. PRED was studied after dermatological administration (5 mg/day for 5 days, n = 6 males) and oral administration (5 mg, n = 6 males; 10 mg, n = 2 males). PSONE was studied after oral administration (10 mg, n = 2 males; 30 mg, n = 1 male and 1 female). Concentrations in urine were measured using an LC-MS/MS method. Concentrations after dermatological treatment were low for all metabolites. After oral administration, concentrations were very high during the first 24 h after administration ranging from 1.6 to 2261 ng/ml and from 4.6 to 908 ng/ml for PRED and PSONE, respectively. Concentrations of most of the metabolites measured were lower than 30 ng/ml from 24 h after all oral administrations. New reporting levels are proposed for PRED and PSONE considering data of our study and other information published after nonsystemic administrations of the compounds. Washout periods of at least 24 h are recommended to ensure no false positives when oral treatments need to be performed in out-of-competition periods.

Do dried blood spots (DBS) have the potential to support result management processes in routine sports drug testing?

Dried blood spots (DBS) have been considered as complementary matrix in sports drug testing for many years. Especially concerning substances prohibited in-competition only, the added value of DBS collected concomitantly with routine doping control urine samples has been debated, and an increasing potential of DBS has been discussed in the scientific literature. To which extent and under which prerequisites DBS can contribute to enhanced anti-doping efforts is currently evaluated. As a proof-of-principle, two analytical applications, one targeting cocaine/benzoyl ecgonine and the other prednisone/prednisolone, are presented in this perspective to indicate potential added value but also presently existing limitations of the DBS approach.

Carbon isotopic characterization of prednisolone and prednisone pharmaceutical formulations: Implications in antidoping analysis.

Twenty-two pharmaceutical formulations containing prednisolone or prednisone commercially available in Italy, Belgium, Spain, Brazil, and India were analyzed through a specific gas chromatography combustion isotope ratio mass spectrometry (GC-C-IRMS) method. All of them showed typical non-endogenous δ13 C values, except for the Belgian nasal spray, Sofrasolone®, with a less depleted 13 C content (-17.84 ± 0.18‰). Observational studies were performed on two volunteers in therapy with Sofrasolone® to confirm the applicability of the method and to suggest adequate interpretation criteria also in the case of drugs with less negative δ13 C values. Urine samples were collected before, during, and within the 36 hours after the administration of the spray. Both δ13 C values and urinary concentrations of prednisolone and prednisone were evaluated. All samples were subjected to an adequate pre-treatment (enzymatic hydrolysis, liquid/liquid extraction, and two sequential HPLC steps) before injection to the GC-C-IRMS instrument, according to the method recently developed and validated in our laboratory. Pregnanediol (PD), tetrahydro-11-deoxycortisol (THS), and pregnanetriol (PT) were selected as endogenous reference compounds (ERC). The excretion profile was estimated through liquid chromatography coupled to tandem mass spectrometry (LC-MS/MS) method used routinely for the quali-quantitative detection of glucocorticoids. δ13 C values and urinary levels of prednisolone and prednisone were also determined after the intake of one single vial of Sintredius®, a prednisolone oral formulation with a conventional more negative δ13 C value (-29.28 ± 0.25‰). Finally, the potential masking effect that combined therapy with Sofrasolone® and Sintredius® could induce on the IRMS findings was investigated.

Urinary excretion profile of prednisone and prednisolone after different administration routes.

The urinary excretion profile of prednisolone and prednisone after both systemic (i.e., oral) and topical (i.e., ocular and intranasal) administration was studied by liquid chromatography coupled to mass spectrometry, also to select the most appropriate marker(s) of intake for doping control purposes. Urines were collected from ten subjects every 3 h before and after the administration of therapeutic doses of pharmaceutical formulations containing either prednisone or prednisolone. Samples were subjected to enzymatic hydrolysis (performed for the investigation on the glucuronide profile) followed by liquid/liquid extraction with tert-butylmethylether in alkaline conditions. The chromatographic separation was carried out on C18 column, employing as mobile phases ultrapurified water and acetonitrile, both containing 0.1% of formic acid. Detection was achieved using as mass spectrometric analyzer a triple quadrupole, with positive ion electrospray ionization and multiple reaction monitoring as acquisition mode. After both systemic and topical use, the compounds excreted in urine in higher concentration were prednisone, prednisolone and 20ß-dihydro-prednisolone followed by 20α-dihydro-prednisolone and 20α/ß-dihydro-prednisone. All were excreted mainly as unconjugated compounds, with a maximum of excretion in the first 3-9 h after the administration. After systemic use, prednisone and prednisolone were both detectable for at least 24 h in concentrations ranging from 5 to 500 ng/mL and from 5 to 900 ng/mL respectively. Whereas, after topical administration, prednisone and prednisolone were detectable for at least 18 h in concentrations ranging from 5 to 140 ng/mL and from 5 to 50 ng/mL respectively.

Development and validation of a method to confirm the exogenous origin of prednisone and prednisolone by GC-C-IRMS.

Prednisone and prednisolone are two anti-inflammatory steroidal drugs listed by the World Anti-Doping Agency (WADA) within the class of glucocorticoids, which are prohibited "in competition" and when administered systemically. Their presence in collected urine samples may be attributed, if no exogenous administration has occurred, to an in situ microbial formation from endogenous steroids. In this work, a gas chromatography coupled to carbon isotope ratio mass spectrometry (GC-C-IRMS) method was developed and validated to distinguish an exogenous origin from an endogenous one. Eight prednisone/prednisolone pharmaceutical preparations commercially available in Italy were analysed to establish an exogenous δ13 C value reference range (-28.96 ± 0.39‰). No more than 25 mL of urine was processed and no derivatization nor intentional steroids structure modifications were performed before the GC-C-IRMS analysis. A first HPLC purification step was set up to isolate the three endogenous reference compounds (ERCs) selected (tetrahydro-11-deoxycortisol (THS), pregnanediol (PD), and pregnanetriol (PT)), while a second LC purification was necessary to separate prednisone from prednisolone. In the GC-C-IRMS analysis, two different GC run methods were set up to guarantee better sensitivity and selectivity for each compound. Both prednisone and prednisolone showed signals (m/z 44) with amplitudes within the method linearity range to a lower urinary concentration of 20 ng/mL (< WADA reporting level, 30 ng/mL). The method was fully validated according to WADA requirements. As a proof of concept, urine samples collected from two excretion studies in healthy male volunteers, after a prednisone or prednisolone administration, were analysed by the proposed method, demonstrating its applicability for the analysis of real samples.

Corticosteroids in liver and urine in Sicilian cattle by a LC-MS/MS method.

The presence of corticosteroid residues was assessed in urine and liver samples from livestock of Sicily. A total of 630 bovine samples were collected from farms and slaughterhouses. The samples were analysed using solid-phase extraction (SPE) coupled with ultra-performance liquid chromatography tandem mass spectrometry (UHPLC-MS/MS). All the corticosteroids found were under the maximum residue limit imposed by Commission Regulation (EC) 37/2010. About 4% of liver samples showed dexamethasone levels above the limit of detection (LOD), with a mean of 1.5 ± 0.2 µg kg-1. Betamethasone was found only in seven liver samples, with a mean of 1.6 ± 0.1 µg kg-1. Furthermore, prednisolone and prednisone were found only in urine and liver samples from slaughterhouse, probably related to the high rate of stress for bovines. These results suggest good control practices adopted by Sicilian farms, able to ensure the quality of food products.

Determination of prednisolone and prednisone in plasma, whole blood, urine, and bound-to-plasma proteins by high-performance liquid chromatography.

A high-performance liquid chromatographic technique for the simultaneous determination of prednisolone and prednisone in human plasma, whole blood, urine, and bound-to-plasma proteins, using betamethasone as internal standard, is presented. Liquid-liquid extraction is used for whole blood samples, and solid phase extraction is used for plasma, urine, and proteins bound to plasma. The accuracy, precision, specificity, linearity, and repeatability meet the requirements of current recommendations in bioanalytical method validation. The method is suitable for high altitude pharmacokinetic studies, in which the quantitation of drugs in those fluids is required. The results from healthy volunteers are presented.

Suitability of bovine bile compared to urine for detection of free, sulfate and glucuronate boldenone, androstadienedione, cortisol, cortisone, prednisolone, prednisone and dexamethasone by LC-MS/MS.

The administration of boldenone and androstadienedione to cattle is forbidden in the European Union, while prednisolone is permitted for therapeutic purposes. They are pseudoendogenous substances (endogenously produced under certain circumstances). The commonly used matrices in control analyses are urine or liver. With the aim of improving the residue controls, we previously validated a method for steroid analysis in bile. We now compare urine (a 'classic' matrix) to bile, both collected at the slaughterhouse, to understand whether the detection of steroids in the latter is easier. With the aim of having clearer results, we tested the presence of the synthetic corticosteroid dexamethasone. The results show that bile does not substantially improve the detection of boldenone, or its conjugates, prednisolone and prednisone. Dexamethasone, instead, was found in 10 out of 53 bovine bile samples, but only in one urine sample from the same animals. Bile could constitute a novel matrix for the analysis of residues in food-producing animals, and possibly not only of synthetic corticosteroids.

Renal inactivation, mineralocorticoid generation, and 11beta-hydroxysteroid dehydrogenase inhibition ameliorate the antimineralocorticoid effect of progesterone in vivo.

Progesterone (P) is a strong mineralocorticoid receptor (MR) antagonist in vitro. The high P concentrations seen in normal pregnancy only moderately increase renin and aldosterone concentrations. In previous in vitro studies we hypothesized that this may be explained by intrarenal conversion of P to less potent metabolites. To investigate the in vivo anti-MR potency of P, we performed an infusion study in patients with adrenal insufficiency (n = 8). They omitted 9alpha-fluorocortisol for 4 d and hydrocortisone for 0.5 d before a continuous iv infusion of aldosterone for 8.5 h, with an additional iv P infusion commenced at 4 h. During aldosterone infusions the initially elevated urinary sodium to potassium ratio decreased significantly. Despite the 1000-fold excess of P over aldosterone, the urinary sodium to potassium ratio and urinary sodium excretion increased only slightly after 3 h of P infusion. We detected inhibition of renal 11beta-hydroxysteroid dehydrogenase type 2 by P, thus giving cortisol/prednisolone access to the MR. Urinary and plasma concentrations of 17alpha-hydroxyprogesterone, a major metabolite of renal P metabolism, and those of serum androstenedione and deoxycorticosterone, a mineralocorticoid itself, increased significantly during P infusion. This supports the hypothesis of an effective protection of the MR from P by efficient extraadrenal downstream conversion of P.

Impact of ketoconazole on the metabolism of prednisolone.

The impact of ketoconazole (200 mg for 7 days) on the kinetics of oral prednisone and intravenous prednisolone and on the apparent activity of the 6 beta-hydroxylase was investigated in 10 healthy volunteers. The ratio of urinary 6 beta-OH-cortisol/17-OH-corticosteroids declined by greater than 50% and the urinary excretion of 6 beta-OH-prednisolone decreased more than twofold in all subjects. The decline of the activity of the 6 beta-hydroxylase was associated with impaired metabolic and renal clearances of total and unbound prednisolone. The ratios of the AUCs of prednisolone/prednisone after oral prednisone and intravenous prednisolone were independent of the administration of ketoconazole, suggesting that the enzymes responsible for the interconversion of prednisolone in equilibrium prednisone were not affected by ketoconazole. Thus ketoconazole inhibits 6 beta-hydroxylase and increases the exposure of the body to the biologically active unbound prednisolone after oral prednisone or intravenous prednisolone.

Effects of cimetidine and ranitidine on the conversion of prednisone to prednisolone.

Prednisone is a glucocorticoid that must be converted in vivo to prednisolone for pharmacologic activity. We examined the effects of the H2-receptor antagonists cimetidine and ranitidine on the time course of plasma prednisolone concentrations after an oral dose of prednisone. Nine healthy men received each of three oral treatments in a double-blind, balanced, crossover manner: cimetidine (300 mg every 6 hours), ranitidine (150 mg twice a day), or placebo for 4 days, with prednisone (40 mg) taken also on day 4. Serial blood and urine samples were collected for 30 hours after prednisone dosing. Prednisone and prednisolone plasma and urine concentrations were analyzed by HPLC. No differences were found between treatments in the maximum prednisolone plasma concentration, t1/2, apparent volume of distribution, and AUC. Cimetidine reduced the mean (+/- SD) ratio of prednisone dose to the plasma prednisolone AUC (16.6 +/- 2.9 L/hr) below that ratio after ranitidine (19.2 +/- 4.2 L/hr) and placebo (19.3 +/- 2.8 L/hr), and resulted in the lowest fractional excretion of prednisolone in the urine (5.2% +/- 2.2%, 9.8% +/- 4.5%, and 12.4% +/- 4.9%, respectively). The minor alterations in prednisolone kinetics during concomitant cimetidine dosing are not likely to induce clinically significant alterations in steroid effect.

A field survey on the presence of prednisolone and prednisone in urine samples from untreated cows.

Prednisolone is a synthetic glucocorticoid widely employed in bovine clinical practice that may also be used illegally as a growth promoter. Recent in vitro and in vivo studies lend support to the hypothesis that prednisolone could be synthesised from cortisol in untreated cattle subjected to stressful events. To verify such a hypothesis, a field survey was conducted on urine samples collected from 131 guaranteed untreated cows and analysed for the presence of prednisolone and prednisone - in some instances also for cortisol and cortisone - with a validated LC/MS-MS method. None of the examined samples exhibited either prednisolone levels higher than the CCα limit (around 0.70 µg l⁻¹) or prednisone, being therefore officially compliant for both analytes. Trace amounts of prednisolone, approximately estimated in the range 0.1-0.3 µg l⁻¹ were found in only seven samples from cows also showing urinary cortisol and cortisone levels higher than those detected in negative specimens, as the result of a probable stress condition.

Prednisolone and prednisone neo-formation in bovine urine after sampling.

The rise in the frequency of detecting prednisolone in bovine urine from northern Italy has come into focus of attention in recent years. The possibility that neo-formation of prednisolone or that prednisone may occur in urine after collection of samples was therefore investigated. Cow urine collected for official routine controls in Lombardy containing more than 80 ng/ml cortisol, and prednisolone and prednisone below the decision limit (CCα) of the method (0.4 and 0.5 ng/ml, respectively) was used. The C1-2 dehydrogenation of naturally present cortisol and cortisone was checked by incubating urine, both contaminated and uncontaminated with faeces, at 37°C and by collecting samples at 0, 1, 2, 4, 6 and 24 h. The influence of Helix pomatia juice was also investigated in order to determine whether deconjugation could influence the reliability of the results. All samples were analysed by HPLC-MS3 for the presence of cortisol, cortisone, prednisolone and prednisone in negative electrospray ionisation mode, utilising the consecutive reaction monitoring of product ions derived from the formate molecular adduct ([M+HCOO]-). The observed neo-formation of prednisolone shows that inappropriate temperatures in sample storage and processing can result in an incorrect accusation of non-compliance. The faecal contamination of urine, performed with the aim to mimic a collection conducted without the necessary care, moreover, evoked a high increase in prednisolone concentration in two out of seven animals. Moreover, H. pomatia juice had no significant effect on the prednisolone concentration, indicating that this corticosteroid is present in its free form in cow urine.

Simultaneous voltammetric determination of prednisone and prednisolone in human body fluids.

A sensitive, rapid and reliable electrochemical method based on voltammetry at single wall carbon nanotube (SWNT) modified edge plane pyrolytic graphite electrode (EPPGE) is proposed for the simultaneous determination of prednisolone and prednisone in human body fluids and pharmaceutical preparations. The electrochemical response of both the drugs was evaluated by osteryoung square wave voltammetry (OSWV) in phosphate buffer medium of pH 7.2. The modified electrode exhibited good electrocatalytic properties towards prednisone and prednisolone reduction with a peak potential of approximately -1230 and approximately -1332 mV respectively. The concentration versus peak current plots were linear for both the analytes in the range 0.01-100 microM and the detection limit (3 sigma/slope) observed for prednisone and prednisolone were 0.45 x 10(-8), 0.90 x 10(-8)M, respectively. The results of the quantitative estimation of prednisone and prednisolone in biological fluids were also compared with HPLC and the results were in good agreement.

Characterization of prednisone, prednisolone and their metabolites by gas chromatography-mass spectrometry.

Human urinary metabolites of the synthetic corticosteroids prednisone and prednisolone were detected in the course of gas chromatographic steroid profiling as methoxime-trimethylsilyl derivatives. Metabolites were provisionaly identified by combined gas chromatography-mass spectrometry. The major metabolites were 11-keto/11-hydroxy conversion products, 20-hydroxy and 4,5-dihydro analogues of the parent drugs. Cortisone, 6-hydroxy and fully saturated A-ring compounds were minor metabolites. Retention indices and mass spectral data are presented.

Prednisolone metabolism and excretion in the isolated perfused rat kidney.

The isolated perfused rat kidney was used to identify factors responsible for the renal elimination of prednisolone (Pn). Pn was recirculated at initial concentrations varying from 100 to 1000 ng/ml for 90 min. Perfusate and urine samples were assayed for Pn and prednisone by HPLC. Protein binding of Pn was measured by using 3H-Pn and equilibrium dialysis at 37 degrees C. There were no significant differences in perfusate flow, glomerular filtration rate, urine flow, or sodium excretion between control and steroid experiments. Partial metabolism of Pn to prednisone occurred in all studies. The total kidney clearance (CIT) of Pn ranged from 0.39 to 1.24 ml/min/100 g of rat body weight with approximately half of the Pn dose unaccountable for as either Pn or prednisone. The apparent percentage of the Pn dose excreted unchanged in the urine ranged from 1.9 to 6.4% and was not related to Pn dose. The apparent urinary clearances of Pn and its metabolite, prednisone, normalized for inulin clearance (fractional excretion) were variable with means of 0.068 and 0.095, respectively. The fractional excretions of Pn and prednisone were related to the fraction of filtered water excreted but not to perfusate concentration. Thus, the extent of urinary clearance of these corticosteroids is related to glomerular filtration and passive tubular reabsorption. The perfused rat kidney reflects the urinary and renal metabolic clearance of Pn without the complication of dose-dependent disposition.

Simultaneous measurement of prednisone, prednisolone and 6 beta-hydroxyprednisolone in urine by high-performance liquid chromatography coupled with a radioactivity detector.

We describe the first method of routine measurement of prednisone, prednisolone and 6 beta-hydroxyprednisolone concomitantly in urine. Urine (3 ml) is extracted with ethyl acetate, washed with base and separated by high-performance liquid chromatography on a silica column with a solvent system of hexane--diethyl ether--ethanol--tetrahydrofuran--glacial acetic acid (59.9:31:2.3:6.5:0.3, v/v). The steroids are detected at 254 nm. Because no conventional internal standard was found, 6 beta-[3H]hydroxycortisol and [3H]prednisolone are added to urine prior to extraction; 3H is monitored by a radioactivity detector coupled with the chromatograph. The assay exhibits linearity from 200 to 7500 ng and an inter-day variability of less than 11.4% (C.V.).