Synthesis of pyridine-carboxylate derivatives of hydroxysteroids for liquid chromatography-electrospray ionization-mass spectrometry

Synthesis and liquid chromatography-electrospray ionization-mass spectrometric (LC-ESI-MS) behaviors of the picolinoyl, 6-methylpicolinoyl, nicotinoyl, 2-methoxynicotinoyl and isonicotinoyl derivatives of the hydroxysteroids estrone, estradiol, 3beta-hydroxyandrost-5-en-17-one (dehydroepiandrosterone) and testosterone in positive mode were investigated. Each steroid was converted to the corresponding pyridine-carboxylate derivative by the acyl chloride method or the mixed anhydride method using the corresponding free acids and 2-methyl-6-nitrobenzoic anhydride; in each case, the latter method principally gave a better yield. The pyridine-carboxylate derivative of each steroid exhibited a clear single peak in liquid chromatography with a reversed phase column and CH(3)CN-0.1% CH(3)COOH as a mobile phase. The positive-ESI-mass spectra of the picolinoyl, 6-methylpicolinoyl and 2-methoxynicotinoyl derivatives showed a predominance of [M+H](+), whereas [M+H+CH(3)CN](+) was observed with high intensity in the nicotinoyl and isonicotinoyl derivatives. Even in the case of estradiol, with its two hydroxyl groups, a single charged ion of [M+H](+) or [M+H+CH(3)CN](+) was observed in the positive-ESI-mass spectrum of each derivative. The results revealed that picolinoyl derivatization is a simple and versatile method suitable for the sensitive and specific determination of hydroxysteroids by LC-ESI-MS (selected reaction monitoring).     

Estrogen determination using liquid chromatography with precolumn fluorescence labeling

A liquid chromatography procedure is described for the determination of some estrogens using fluorescence detection. The estrogens are labeled by precolumn derivatization with 5-dimethylaminonaphthalene-1-sulfonylchloride (dansyl chloride) and chromatographed on a reversed-phase, C-18 column with a mobile phase consisting of methanol, water, and acetic acid. The eluted analytes are measured with a fluorescence detector using excitation and emission wavelengths of 350 and 540 nm, respectively. The chief advantage of this new procedure is its sensitivity, requiring smaller amounts of sample to detect and quantitate estrogens in biological materials. We could detect less than 400 pg of estriol. With our procedure, this corresponded to about 25 ng in the final reaction mixture, before derivatization. The use of smaller sample volumes could improve this limit. Linearity for dansylated estriol, estrone, and estradiol was excellent over the estrogen range below 100 μg in the sample. This corresponds to approximately 1.7 μg on the column. Within-run precision was better than 5% for the full extraction and derivatization procedure for estriol from pregnancy urine samples. Chromatography is complete within 10 min for dansylated estriol, estrone, and estradiol.     

A novel GC-MS method in urinary estrogen analysis from postmenopausal women with osteoporosis

Estrogen metabolites play important roles in the development of female-related disorders and homeostasis of the bone. To improve detectability, a validated gas chromatography-mass spectrometry (GC-MS) method was conducted with two-phase extractive ethoxycarbonlyation (EOC) and subsequent pentafluoropropionyl (PFP) derivatization was introduced. The resulting samples were separated through a high-temperature MXT-1 column within an 8 min run and were detected in the selected ion monitoring (SIM) mode. The optimized analytical conditions led to good separation with a symmetric peak shape for 19 estrogens as their EOC-PFP derivatives. The limit of quantification (LOQ) was from 0.02 to ～0.1 ng/ml for most estrogens analyzed, except for 2-hydroxyestriol (0.5 ng/ml). The devised method was found to be linear (r2 > 0.995) in the range from the LOQ to 40 ng/ml, whereas the precision (% CV) and accuracy (% bias) ranged from 1.4 to 10.5% and from 91.4 to 108.5%, respectively. The good sensitivity and selectivity of this method even allowed quantification of the estrogen metabolites in urine samples obtained from the postmenopausal female patients with osteoporosis. The present technique can be useful for clinical diagnosis as well as to better understand the pathogenesis of estrogen-related disorders in low-level quantification.     

Comparison of dextran-coated charcoal and ammonium sulfate in the radioimmunoassay of estrogens

A comparison was made between the use of ammonium sulfate (AS) and Dextran coated charcoal (DCC) to separate free and antibody-bound estrogens in the RIA of estrone and estradiol in serum. Under the conditions tested, AS yielded values which were approximately twice those obtained using DCC. This difference was found for both estrogens, using male and female serum and regardless of whether the estrogens were separated from one another by means of the Girard reagent or TLC. There was no significant difference in the sensitivity, accuracy or usable range of the standard curve or in the water-blank for the two procedures.     

Stable isotope-coded quaternization for comparative quantification of estrogen metabolites by high-performance liquid chromatography-electrospray ionization mass spectrometry

A fast and sensitive LC-ESI-MS method is described for the comparative quantification of 16 estrogen metabolites based on the derivatization of estrogens with a novel derivatizing reagent, N-methyl-nicotinic acid N-hydroxysuccinimide ester (C1-NA-NHS). The process introduces a quaternary amine to the analytes, making the analytes permanently charged regardless of the pH of the high-performance liquid chromatography (HPLC) mobile phase. This quaternization resulted in a highly efficient separation of 16 estrogen metabolites in 7 min at a detection level below 1 ng/mL. By using a deuterated derivatizing reagent (C1-d(3)-NA-NHS), a complete set of deuterated standards was utilized and used as internal standards in a comparative quantification and recovery study, demonstrating acceptable results over a wide concentration range. A pooled breast cancer serum sample was analyzed using the described method, and 15 estrogens were detected in the range of 80-530 pg/mL.     

A non-chromatographic radioimmunoassay of estrone and estradiol-17beta serum

A sensitive and efficient non-chromatographic procedure employing the Girard reagent and solvent-partitioning has been developed for the accurate radioimmunoassay (RIA) of estrone (E1) and estradiol-17β(E2) in a single 1.0 ml specimen of male or female serum. Using standard curves which permitted the discrimination of zero from 0.75–1.5 pg (p=0.05), the following mean procedural blanks (pg ± S.D.) were determined (1.0 ml water, n= 24): estrone, 2. 1 ± 1.1 (range 0–4.1); estradiol 1.0± 1.1 (range 0–3.6).A comparison of RIA of estrogens (1) in serum after separation by the Girard procedure and by TLC yielded correlation coefficients of 0.99 and 0.98 for E1 and E2 respectively. The following results (pg/ml ± S.D.) were obtained on RIA of E1 and E2 in 12 different 1.0 ml specimens of male and female serum using the Girard procedure: male. E1 (32.0 ± 9.2), E2 (24.1 ± 10.9); female, E1 (108.5 ± 60.8), E2 (126.4 ± 63.2).The intra-assay variability (c.v.) was found to be 12.6% for E1 and 9.4% for E2. The interassay variability was 14.2% for both estrogens.Twenty-four assays of E1 and E2 can be completed by one person in 2 working days.     

Biotransformation and bioconcentration of steroid estrogens by Chlorella vulgaris

The biotransformation and bioconcentration of natural and synthetic steroid estrogens by Chlorella vulgaris were investigated by using batch-shaking experiments with incubation for 48 h in the light or dark. Estradiol and estrone were interconvertible in both light and dark conditions; however, this biotransformation showed a preference for estrone. In the light, 50% estradiol was further metabolized to an unknown product. Apart from biotransformation, estrone, as well as hydroxyestrone, estriol, and ethinylestradiol, was relatively stable in the algal culture, whereas estradiol valerate was hydrolyzed to estradiol and then to estrone within 3 h of incubation. All of the tested estrogens exhibited a degree of partitioning to C. vulgaris; however, the concentrations of estriol, hydroxyestrone, ethinylestradiol, and estradiol valerate were always below the quantification limits. For estradiol and estrone, the partitioning of these estrogens in the algal extracts to the filtrates was <6% of the total amount present. The average concentration factor for estrone was ca. 27; however, the concentration factor for estradiol was not reported since no equilibrium was reached between the aqueous solution and that within the cells due to continuing biotransformation.     

Determination of 8-iso-prostaglandin F(2alpha) in exhaled breath condensate using combination of immunoseparation and LC-ESI-MS/MS

Rapid and precise method for the determination of 8-iso-prostaglandin F(2alpha), an essential marker of the oxidative stress, in exhaled breath condensate (EBC) was developed. The protocol consisted of stable isotope dilution, immunoseparation combined with selective and sensitive LC-ESI-MS/MS operated in multiple reaction monitoring (MRM) mode. The imprecision of the developed method was below 8.8%, the parameter of mean inaccuracy was determined as <9.6% (0-250pg of 8-iso-prostaglandin F(2alpha)/ml EBC). The limit of detection (LOD) was 1 pg/ml EBC and limit of quantification (LOQ) 5 pg/ml EBC. A significant difference in 8-iso-prostaglandin F(2alpha) content between the group of asbestosis patients and healthy volunteers was found.     

Biotransformation and Bioconcentration of Steroid Estrogens by Chlorella vulgaris

The biotransformation and bioconcentration of natural and synthetic steroid estrogens by Chlorella vulgaris were investigated by using batch-shaking experiments with incubation for 48 h in the light or dark. Estradiol and estrone were interconvertible in both light and dark conditions; however, this biotransformation showed a preference for estrone. In the light, 50% estradiol was further metabolized to an unknown product. Apart from biotransformation, estrone, as well as hydroxyestrone, estriol, and ethinylestradiol, was relatively stable in the algal culture, whereas estradiol valerate was hydrolyzed to estradiol and then to estrone within 3 h of incubation. All of the tested estrogens exhibited a degree of partitioning to C. vulgaris; however, the concentrations of estriol, hydroxyestrone, ethinylestradiol, and estradiol valerate were always below the quantification limits. For estradiol and estrone, the partitioning of these estrogens in the algal extracts to the filtrates was <6% of the total amount present. The average concentration factor for estrone was ca. 27; however, the concentration factor for estradiol was not reported since no equilibrium was reached between the aqueous solution and that within the cells due to continuing biotransformation.     

Analysis of steroidal estrogens as pyridine-3-sulfonyl derivatives by liquid chromatography electrospray tandem mass spectrometry

Sulfonyl chlorides substituted with functional groups having high proton affinity can serve as derivatization reagents to enhance the sensitivity for steroidal estrogens in liquid chromatography electrospray ionization tandem mass spectrometry (LC-ESI-MS/MS). The most commonly used reagent for derivatization of estrogens for LC-ESI-MS/MS is dansyl chloride. In this study, we compared dansyl chloride, 1,2-dimethylimidazole-4-sulfonyl (DMIS) chloride, pyridine-3-sulfonyl (PS) chloride, and 4-(1H-pyrazol-1-yl)benzenesulfonyl (PBS) chloride for derivatization of 17beta-estradiol (E2) prior to LC-ESI-MS/MS. The product ion spectra of the dansyl and DMIS derivatives were dominated by ions representing derivatization reagent moieties. In contrast, the product ion spectrum of the PS derivative of E2 and, to a lesser extent, the PBS derivative, showed analyte-specific fragment ions. Derivatization with PS chloride was therefore chosen for further investigation. The product ion spectrum of the PS derivative of E2 showed intense ions at m/z 272, assigned to the radical E2 cation, and at m/z 350, attributed to the loss of SO(2) from the [M+H](+) ion. Third-stage mass spectrometry of the PS derivative of E2 with isolation and collisional activation of the m/z 272 ion resulted in steroid C and D ring cleavages analogous to those observed in electron ionization mass spectrometry. The product ion spectra of the PS derivatives of estrone, 17alpha-ethinylestradiol, equilin, and equilenin showed similar estrogen-specific ions. Using derivatization with PS chloride, we developed an LC-ESI-MS/MS method with multiple reaction monitoring of primary and confirmatory precursor-to-product ion transitions for the determination of E2 in serum.     

LC–MS/MS coupled with immunoaffinity extraction for determination of estrone, 17β-estradiol and estrone 3-sulfate in human plasma

Determination of estrogens in plasma is important in evaluation of effects of some anticancer drugs, such as aromatase inhibitors. However, as reported previously, high performance liquid chromatography–radio immunoassay (HPLC–RIA) and liquid chromatography–tandem mass spectrometry (LC–MS/MS) with chemical derivatization require complicated sample preparation. In this study, a highly sensitive and simple method for determination of estrone (E1), 17β-estradiol (E2) and estrone 3-sulfate (E1S) in human plasma has been developed. Following diethylether extraction from plasma, analytes were purified by immunosorbents and then determined by LC–MS/MS using electrospray ionization (ESI). Immunosorbents were prepared by immobilization of specific antibodies raised against each analyte onto solid support. Use of selective immunosorbents in sample preparation removed interference in plasma samples that would cause ionization suppression, and markedly improved the sensitivity of LC–MS/MS for these analytes, without derivatization. Calibration curves of each analyte showed good linearity and reproducibility over the range of 0.05–50 pg/injection for E1, 0.2–50 pg/injection for E2 and 0.05–300 pg/injection for E1S, respectively. The mean values of lower limits of quantification (LLOQ) in human plasma corrected by recovery of deuterated estrogens (internal standard, I.S.) were 0.1892 pg/mL for E1, 0.7064 pg/mL for E2 and 0.3333 pg/mL for E1S, respectively. These LLOQ values were comparable to those previous reported using HPLC–RIA and LC–MS/MS. Using this method, the normal levels of three estrogens in healthy female plasma (n = 5) were determined. The mean values of E1, E2 and E1S were 38.0 pg/mL (range 24.8–53.0), 34.3 pg/mL (22.6–46.6) and 786 pg/mL (163–2080), respectively. The immunoaffinity LC–MS/MS described here allows sensitive and accurate quantification of E1, E2 and E1S without laborious sample preparation.     

Highly sensitive quantification of 7alpha-hydroxy-4-cholesten-3-one in human serum by LC-ESI-MS/MS

We describe a highly sensitive and specific method for the quantification of serum 7alpha-hydroxy-4-cholesten-3-one (C4), which has been used as a biomarker for bile acid biosynthesis. This method is based upon a stable isotope dilution technique by liquid chromatography-tandem mass spectrometry (LC-MS/MS). C4 was extracted from human serum (2-50 mul) by a salting-out procedure, derivatized into the picolinoyl ester (C4-7alpha-picolinate), and then purified using a disposable C(18) cartridge. The resulting picolinoyl ester derivative of C4 was quantified by LC-MS/MS using the electrospray ionization mode. The detection limit of the C4 picolinoyl ester was found to be 100 fg (signal-to-noise ratio = 10), which was approximately 1,000 times more sensitive than the detection limit of C4 with a conventional HPLC-ultraviolet method. The relative standard deviations between sample preparations and between measurements by our method were calculated to be 5.7% and 3.9%, respectively, by one-way layout analysis. The recovery experiments were performed using serum spiked with 20.0-60.0 ng/ml C4 and were validated by a polynomial equation. The results showed that the estimated concentration with 95% confidence limit was 23.1 +/- 2.8 ng/ml, which coincided completely with the observed X(0) +/- SD = 23.3 +/- 1.0 ng/ml with a mean recovery of 93.4%. This method provides highly reliable and reproducible results for the quantification of C4, especially in small volumes of blood samples.     

Steroid levels after intramuscular injection of radioactive estradiol-17beta, estrone, progesterone and testosterone in the bovine

Eight 2 year old Hereford cows from days 8 to 12 of the estrous cycle were injected intramuscularly with 5 ml of corn oil containing 5 mg of estradiol-17beta (two cows), estrone (two cows), progesterone (two cows) or testosterone (two cows). Each cow treated with estradiol received 494 microc of estradiol-17beta-6, 7 H3 and each cow treated with estrone received 492 microc of estrone-6, 7 H3. Each cow treated with progesterone or testosterone received 400 muc of H3 compound labeled in the 7 position. Total urine was collected by urethral catheterization of the cows treated with estrogens. Blood samples for plasma and serum were collected via jugular cannulae. Blood and urine samples from estrogen-treated cows were collected hourly for the first 24 hr, at 2 hr intervals for the next 26 hr, at 4 hr intervals for the next 12 hr and at 12 hr intervals until background was reached. Blood samples were collected hourly from 1 to 8 hr after injection from progesterone or testosterone-treated cows. Plasma and serum levels of radioactive estradiol-17beta, estrone, progesterone and testosterone were similar. Blood levels of radioactivity peaked at 2 hr post-injection in cows receiving estradiol-17beta and at 3 hr in cows receiving estrone. Blood levels of labeled estradiol-17beta and estrone were nondetectable by 54 hr and 83 hr, respectively. Peak urinary excretion of radioactivity was reached at 7 hr for estradiol-17beta and at 14 hr for estrone and nondetectable levels were reached by 95 hr for estradiol-17beta and 14 hr for estrone. At these times, 15.5% of the total dose of radioactive estradiol-17beta and 17.5% of the injected estrone had been excreted in the urine. Peak blood and urinary excretion levels were reached earlier for radioactive estradiol-17beta than for estrone, and excretion of estradiol-17beta was completed more rapidly. No difference was found in plasma and serum levels for any steroid studies; thus, endogenous steroid titers in blood plasma and serum are not different in the cow.     

Effects of serum proteins on estrogen action in the perfused rat liver

To determine the effects of serum proteins on the biologic activity of estrogens, we perfused isolated livers from ovariectomized female rats with oxygenated Krebs-Henseleit-bicarbonate buffer (KHBB), with and without 4% human serum albumin (4% HSA), with and without added estrogens, or with charcoal-stripped human serum (CSHS) with and without added estradiol. At the end of the perfusions, the cytosolic and nuclear estrogen receptors were measured by an exchange assay. When added to KHBB, estradiol 10(-9) or 10(-8) M or estrone 10(-8) M did not cause any significant increase in the percent of receptors measured in the nucleus. When the livers were perfused with KHBB containing 4% HSA and estradiol 10(-9) to 10(-7) M or estrone 10(-8) M, there was an increase in nuclear receptors. Perfusion with estradiol 10(-8) M in CSHS resulted in significantly less receptor in the nucleus than after estradiol in KHBB plus 4% HSA. We conclude that the presence of 4% HSA in the perfusion medium increases the biologic activity of estradiol and estrone on the isolated rat liver, and this increase is inhibited in the presence of sex hormone-binding globulin. The exact mechanism by which HSA increases the biologic activity is uncertain, but may be due in part to better diffusion of estrogen through the liver.     

Analysis of estrogens in serum and plasma from postmenopausal women: Past present,and future

Previous studies have shown that the selection of women who are at high breast cancer risk for treatment with chemoprevention agents leads to an enhanced benefit/risk ratio. However, further efforts to implement this strategy will require the development of new models to predict the breast cancer risk of particular individuals. Postmenopausal women with elevated plasma or serum estrogens are at increased risk for breast cancer. Therefore, the roles of various enzymes involved in the biosynthesis of estrogens in postmenopausal women have been reviewed in detail. In addition, the potential genotoxic and/or proliferative effects of the different estrogen metabolites as risk factors in the etiology of breast cancer have been examined. Unfortunately, much of the current bioanalytical methodology employed for the analysis of plasma and serum estrogens has proved to be problematic. Major advances in risk assessment would be possible if reliable methodology were available to quantify estradiol and its major metabolites in the plasma or serum of postmenopausal women. High performance liquid chromatography (HPLC) coupled with radioimmunoassay (RIA) currently provides the most sensitive and best validated immunoassay method for the analysis of estrone and estradiol in serum samples from postmenopausal women. However, inter-individual differences in specificity observed with many other immunoassays have caused significant problems when interpreting epidemiologic studies of breast cancer. It is almost impossible to overcome the inherent assay problems involved in using RIA-based methodology, particularly for multiple estrogens. For reliable measurements of multiple estrogens in plasma or serum, it will be necessary to employ stable isotope dilution methodology in combination with liquid chromatography–tandem mass spectrometry (LC–MS/MS). Extremely high sensitivity can be obtained with pre-ionized estrogen derivatives when employed in combination with a modern triple quadrupole mass spectrometer and nanoflow LC. Using [¹³C₆]-estrone as the internal standard it has proved possible to analyze estrone as its pre-ionized Girard T (GT) derivative in sub-fg (low amol) amounts on column. This suggests that in the future it will be possible to routinely conduct LC–MS assays of multiple estrogen metabolites in serum and plasma at even lower concentrations than the current lower limit of quantitation of 0.4 pg/mL (1.6 pmol/L). The ease with which the pre-ionization derivatization strategy can be implemented will make it possible to readily introduce high sensitivity stable isotope dilution methodology in laboratories that are currently employing LC–MS/MS methodology. This will help conserve important plasma and serum samples as it will be possible to conduct high sensitivity analyses using low sample volumes.     

Lipid peroxidation at various estradiol concentrations in human circulation during ovarian stimulation with exogenous gonadotropins.

The aim of our study was to investigate the correlation between serum malondialdehyde levels and serum estradiol concentrations in healthy human female subjects. Nine hundred and fifty-five blood samples, from infertile women undergoing controlled ovarian hyperstimulation treatment with recombinant follicle-stimulating hormone, were collected for estradiol and malondialdehyde measurements. Five groups were formed according to serum estradiol levels: Group I (< 50 pg/ml), group II (50 - 299 pg/ml), group III (300-999 pg/ml), group IV (1000-1999 pg/ml) and group V (> or = 2000 pg/ml). One-way analysis of variance was used for comparisons. Mean malondialdehyde concentrations were 1.74 +/- 0.24 mmol/ml (group I), 1.53 +/- 0.20 mmol/ml (group II), 1.69 +/- 0.24 mmol/ml (group III), 1.77 +/- 0.21 mmol/ml (group IV) and 1.86 +/- 0.20 mmol/ml (group V), respectively. Mean serum malondialdehyde level at physiological estradiol concentrations (50-199 pg/ml, group II) was significantly (p < 0.01) lower than the mean malondialdehyde levels in other groups. Mean malondialdehyde concentrations among the remaining groups did not significantly differ. Our findings suggest that in vivo lipid peroxidation might be increased when circulating estradiol concentrations are below (< 50 pg/ml) or above (> 300 pg/ml) the physiological limits. High blood estradiol levels in human female subjects during ovarian stimulation with exogenous gonadotropins could be associated with increased serum malondialdehyde concentrations.     

Bioluminescence: an improvement in the enzymatic assay of dehydroepiandrosterone sulfate in biological fluids

Dehydroepiandrosterone sulfate (DHEAS) determination in biological fluids was carried out by enzymatic hydrolysis and conversion into estrogens [estrone (E1) and estradiol (E2)] by the multienzyme system of human placental microsomes. The enzymatic complex consists of sulfatase, 3 beta-hydroxysteroid oxido reductase and 5en----4en isomerase which converts DHEAS into androstenedione (A); the latter component is further converted into estrogens by the aromatase. The resulting estrogens were determined from the NADH formed by the transhydrogenation reactions of human placental dehydrogenase. NADH was measured by bioluminescence. As little as 4 pg was assayable by this rapid enzymatic method, with a coefficient of variation of 8%. The results are in good agreement with radioimmunoassay and the method is suitable for routine use.     

Steroid metabolism in the gonads of a patient with testicular feminization. II. Metabolism of c19- and c18-steroids in vitro.

The metabolism of C19- and C18-steroids, in particular, the aromatization of androstenedione and testosterone, the interconversion of androgens to estrogens and the 5alpha-reductase activity of a right abdominal (r) and a left inguinal (l) testis of a patient with testicular feminization, are reported. Aromatization and 5alpha-reductase activity were also evaluated in tissue from the left ductus diferens (ld). The following results were obtained: 1. aromatization of androstenedione to estrone 2.52% (r), 0.02% (l), 0.94% (ld); 2. aromatization of testosterone to estradiol 0.58% (r), 2.88% (l); 3. conversion of androstenedione to testosterone 95.65% (r), 98.07% (l); 4. conversion of testosterone to androstenedione 33.14% (r), 53.65% (l); 5. conversion of estrone to estradiol85.29% (r), 100% (l), 6. conversion of estradiol to estrone 33.12% (r), 32.33% (l); 7.5alpha-reduction of testosterone to 5alpha-dihydrotestosterone 12.01% (r), 13.64% (l) and 4.10% (ld). A lack of 5alpha-reductase activity was not found in the tissues examined as stated in the literature. Estrogen production in these testes was demonstrated by the aromatization of androstenedione and testosterone to estrone and estradiol and is reflected in the difference of the estradiol concentration measured in spermatic and peripheral blood of the same patient (168 versus 33 pg/ml).     

Estrogens and prostaglandin F2alpha in the semen and blood plasma of stallions

A study was performed to determine the levels of estrogens and prostaglandin F(2)alpha in the stallion ejaculate. Simultaneous semen and blood plasma samples were collected from 19 stallions, 2 weeks apart, during the breeding season. Although not statistically different, the total mean estrogen content tended to be higher in seminal plasma (4447 pg/ml) than in blood (2497 pg/ml). A tendency was found for higher mean estrone sulphate concentrations than for total free steroid in both seminal (4116.1 vs 330.5 pg/ml) and blood plasma (2447.1 vs 49.5 pm/ml). Mean concentrations of estrone in ejaculate and blood plasma were 257.1 +/- 267.0 (SD) and 9.5 +/- 5.4 pg/ml, respectively. Estradiol-17beta concentrations were 73.4 +/- 87.4 and 40.0 +/- 27.6 pg/ml in ejaculates and blood plasma, respectively. Mean PGF(2)alpha concentrations tended to be much higher than total estrogens (1106.8 +/- 1636.4, SD, vs approximately 260 ng/ejaculate, respectively). To our knowledge this is the first report of PGF(2)alpha and estrogen concentrations in the stallion ejaculate.     

Simultaneous determination of norethindrone and ethinyl estradiol in human plasma by high performance liquid chromatography with tandem mass spectrometry--experiences on developing a highly selective method using derivatization reagent for enhancing sensitivity

In the present work, for the first time, a liquid chromatographic method with tandem mass spectrometric detection (LC-MS/MS) for the simultaneous analysis of norethindrone, and ethinyl estradiol, was developed and validated over the concentration range of 50-10000pg/ml and 2.5-500pg/ml, respectively, using 0.5 ml of plasma sample. Norethindrone, ethinyl estradiol, and their internal standards norethindrone-(13)C2, and ethinyl estradiol-d4, were extracted from human plasma matrix with n-butyl chloride. After evaporation of the organic solvent, the extract was derivatized with dansyl chloride and the mixture was injected onto the LC-MS/MS system. The gradient chromatographic elution was achieved on a Genesis RP-18 (50 mm x 4.6 mm, 3 microm) column with mobile phase consisted of acetonitrile, water and formic acid. The flow rate was 1.0 ml/min and the total run time was 5.0 min. Important parameters such as sensitivity, linearity, matrix effect, reproducibility, stability, carry-over and recovery were investigated during the validation. The inter-day precision and accuracy of the quality control samples at low, medium and high concentration levels were <6.8% relative standard deviation (RSD) and 4.4% relative error (RE) for norethindrone, and 4.2% RSD and 5.9% RE for ethinyl estradiol, respectively. Chromatographic conditions were optimized to separate analytes of interest from the potential interference peaks, arising from the derivatization. This method could be used for pharmacokinetic and drug-drug interaction studies in human subjects.