Nanoscale affinity chip interface for coupling inhibition SPR immunosensor screening with Nano-LC TOF MS.

The on-line nanoscale coupling of a surface plasmon resonance (SPR)-based inhibition biosensor immunoassay (iBIA) for the screening of low molecular weight molecules with nano-liquid-chromatography electrospray ionization time-of-flight mass spectrometry (nano-LC ESI TOF MS) for identification is described. The interface is based on a reusable recovery chip (RC) that contains a nanoscale biosorbent composed of a hydrogel layer modified with antibodies raised against the analyte featuring the unique possibility of performance characterization using the SPR biosensor. Various hydrogel chemistries were evaluated, and the standard Biacore CM5 chip showed the highest capture capacity in combination with affinity-purified polyclonal antibodies. The procedure has four stages: the samples are prepared (1) and screened using a screening chip (SC) in the iBIA (2). Suspected noncompliant samples as being noncompliant are reinjected over the RC, and the analyte is captured at subnanogram level (3). The captured analyte is released, and the eluate is analyzed with nano-LC ESI TOF MS via a loop-type interface (4). The coupling of the technologies proved effective for screening enrofloxacin, a model compound, in incurred chicken muscle samples followed by identity confirmation in suspected noncompliant samples. Ciprofloxacin, a known metabolite of enrofloxacin, was identified as well in incurred chicken samples. This demonstrates the potential of the technologies coupled by means of a RC for the rapid screening and identification of known as well as unknown compounds. Finally, we demonstrate the feasibility of combining the two biosensor chips (SC and RC) with a robust chip-based nano-LC chip TOF MS system, thus providing a robust alternative triple-chip system.

Estrogenic activity of estradiol and its metabolites in the ER-CALUX assay with human T47D breast cells.

A number of metabolites of 17beta-estradiol were tested for their estrogenic activity using the ER-CA-LUX assay based on the increased expression of luciferase in exposed T47D breast cancer cells. E2beta and estrone showed similar potencies in the test, whereas E2alpha was 100 times less active. Incubation of cells with estrone (0.35 microM) resulted in the formation of E2beta, whereas the reverse reaction was observed for E2beta. The resulting equilibrium may explain the similar estrogenic potency of estrone in the test. The synthetic 17-hydroxy benzoate ester of E2beta was 3 times less active than the parent compound. The 17-hydroxy palmitate and oleate esters of E2beta, were respectively 25 and 200 times less active than the parent compound. The 2-hydroxy metabolites of E2beta and estrone showed a 5,000 to 10,000 fold lower activity. The 4-hydroxy metabolites were more potent than the 2-hydroxy metabolites, showing only a 20-200 times lower activity. The 2- and 4-methoxyesters of estrone were 700 times less active. It is concluded that the estrogenic potency of metabolites formed in cattle after treatment with E2beta, like estrone, E2alpha and especially the esters of E2beta, may be significant with respect to the potential risk of the use of estradiol for growth promotion in domestic animals in certain countries.

Determination of embutramide and pentobarbital in meat and bone meal by gas chromatography-mass spectrometry.

An analytical procedure, consisting of multiple steps, was developed for the analysis of meat and bone meal for two veterinary drugs, embutramide and pentobarbital, used for euthanasia. After a combined extraction, embutramide was converted to its trimethylsilylether derivative and pentobarbital was methylated. Both analytes were determined by gas chromatography-mass spectrometry in the electron impact or chemical ionisation mode. Limits of determination and identification were between 50 and 100 micrograms kg-1 depending on the compound and the ionisation technique applied. Particular attention was focused on the identification of the analytes.

Identification of metabolites of the anabolic steroid methandienone formed by bovine hepatocytes in vitro.

Monolayer cultures of bovine hepatocytes were used to investigate the biotransformation of methandienone in vitro. After incubation of bovine hepatocytes with methandienone, samples were taken at different times. The samples were treated with deconjugation enzymes and extracted with diethyl ether. The metabolites formed were converted to their trimethylsilylether derivatives. By using gas chromatography-mass spectrometry with electron impact and chemical ionisation, several metabolites were identified. After 24 h of incubation with bovine hepatocytes, 83% of the parent compound was converted to its metabolites. The major metabolite found was 6-beta-hydroxymethandienone with a yield of 24%. This compound was identified after comparison with an authentic sample of 6 beta-hydroxymethandienone, which was synthesized chemically.

A fast immunoassay for the screening of beta-agonists in hair.

Hair has been shown to be an excellent site for the accumulation of clenbuterol residues. Compared with other matrices, hair sampling is very easy and this might result in large numbers of samples. In this study, a simple digestion-extraction procedure was combined with a sensitive clenbuterol ELISA, which resulted in an easy screening procedure suitable for the detection of at least four beta-agonists. Hair from untreated cows (n = 40) resulted in low blank levels (0.9 +/- 0.7 and 0.5 +/- 0.2 ng g-1 for black and white hair, respectively). The detection limits for clenbuterol, bromobuterol, mapenterol and mabuterol were determined as 1-1.5 ng g-1 for white and 3-4 ng g-1 for black hair. The accumulation of mabuterol and mapenterol in black and white hair from treated calves was demonstrated by GC-MS. The screening assay is not suitable for the detection of cimbuterol (owing to the low extraction efficiency) and for salbutamol and terbutaline (owing to the low cross-reactivity of the antibodies used for the ELISA and the low extraction efficiency). Black hair samples from cows treated with clenbuterol were still found to be positive (> 5 ng g-1) at 23 weeks after treatment. The fast screening procedure is a powerful means to detect and track the illegal use of clenbuterol, bromobuterol, mabuterol and mapenterol in animal production.

Determination of anabolic esters in oily formulations and plasma in husbandry using high-performance liquid chromatography and gas chromatography-mass selective detection.

Two different analytical methods are described for the analysis of anabolic steroid esters in oily formulations for veterinary use and animal plasma samples, respectively. For the determination of anabolic steroid esters in oily formulations (at mg kg-1 levels) a reversed-phase high-performance liquid chromatographic method with gradient elution is described. Gradient elution is performed owing to the relatively large variations in polarity of the investigated anabolic steroid esters. For the analysis of anabolic steroid esters in plasma (at ng ml-1 levels) two different strategies are applied. After solid-phase extraction, the plasma samples are introduced into the high-performance liquid chromatography (HPLC) system where the obtained fractions are then analysed by using gas chromatography-mass selective detection (GC-MSD). An alternative method is direct analysis of plasma samples after solid-phase extraction by using GC-MSD without any further clean-up procedure. Prior to GC-MSD the samples are derivatized to corresponding trifluoroacyl (TFA) derivatives. The calibration graph for HPLC is rectilinear over the range 25-150 ng ml-1 plasma and the analytical recoveries for medroxyprogesterone acetate (MPA) and testosterone propionate (TP) are more than 95%. The detection limits for both analytes in GC-MS are 2.5 ng ml-1 plasma for MPA and 0.5 ng ml-1 plasma for TP with an acceptable signal-to-noise ratio (calculated for the derivatized relative molecular mass). In the analysis of plasma obtained from animal experiments concentrations of 6.5 ng ml-1 are found for MPA by using GC-MSD and 5.0 ng ml-1 are found for nortestosterone laurate (NL) by using HPLC.

Determination of fenoterol and ractopamine in urine by enzyme immunoassay.

Fenoterol and ractopamine are phenethanolamines with beta-adrenergic agonist activity. An enzyme immunoassay (EIA) for these compounds was developed using antibodies raised in a New Zealand white rabbit against fenoterol-bovine serum albumin and fenoterol coupled to horseradish peroxidase (HRP). The calibration graphs of fenoterol and ractopamine showed linearity over the concentration ranges 0.1-5 and 0.2-25 ng ml-1, respectively. Isoxsuprine showed a cross-reactivity of 0.7% while the cross-reactivity of other beta-agonists was < 0.1%. The screening assay was used to detect fenoterol in urine samples obtained from an animal experiment in which male calves were treated with fenoterol (100 micrograms of fenoterol per kg of bodymass per meal for a period of four weeks). Using a direct method, without sample preparation, fenoterol concentrations ranged from 22 to 210 ng ml-1. The mean concentration of fenoterol after extraction in isobutanol was 3.5 times lower compared with the direct method. On applying enzymic hydrolysis in combination with isobutanol extraction, the mean concentration was eight times higher than that obtained when using extraction only. Gas chromatography-mass spectrometry (GC-MS) analysis confirmed the presence of fenoterol in most of these samples. However, probably owing to the absence of a proper GC-MS internal standard, the correlation between GC-MS and EIA concentrations was low (r = 0.7976). In general, the concentrations found by the EIA are much higher than those found by GC-MS, which might be caused by the presence of metabolites detected with the EIA. Fenoterol is excreted in urine mostly (about 85%) as glucuronidated-sulfated conjugate. The antibodies partly recognize the conjugated fenoterol, which makes it possible to use a direct screening assay. In blank calf urine the detection limits, mean background +3 times the standard deviation, are 1.3 (fenoterol) and 2.6 ng ml-1 (ractopamine). In bovine urine, however, owing to matrix effects, the detection limits are 20 times higher.