Immunoaffinity chromatography for the sample pretreatment of Taxus plant and cell extracts prior to analysis of taxanes by high-performance liquid chromatography.

The application of immunoaffinity chromatography for the purification of Taxus plant and cell extracts prior to the HPLC analysis is described. Polyclonal antibodies raised against 10-deacetylbaccatin III (10-DAB III), paclitaxel's main precursor in plant, were characterised by enzymed-linked immunosorbent assay. Immunoglobulins from selected antisera were immobilised on CNBr-activated Sepharose 4B. The immunoaffinity column was used for the purification of plant and plant cell culture extracts prior to their analysis by HPLC. Immunoaffinity chromatography enabled the selective concentration of taxoids and enhanced sample clean-up.

Direct biosensor immunoassays for the detection of nonmilk proteins in milk powder.

The low prices of some nonmilk proteins make them attractive as potential adulterants in dairy products. An optical biosensor (BIACORE 3000) was used to develop a direct and combined biosensor immunoassay (BIA) for the simultaneous detection of soy, pea, and soluble wheat proteins in milk powders. Affinity-purified polyclonal antibodies raised against the three protein sources were immobilized in different flow channels (Fcs) on the biosensor chip (CM5). Dissolved milk powders were injected (20 microL injections at 20 microL min(-1)) through the serially connected Fcs, and the antibody-bound plant proteins were detected directly. The total run time between samples, including a regeneration step with 5 microL of 10 mM HCl, was 5 min. The limits of detection in milk powder were below 0.1% of plant protein in the total milk protein content. The antibodies also recognized some proteins from other plant sources, which made this BIA even more suitable as a broad screening assay for nonmilk proteins.

Immunochemical detection of aminoglycosides in milk and kidney.

In 1996, the European Union established provisional maximum residue limits (MRL) for gentamicin, neomycin, streptomycin and dihydrostreptomycin in milk and tissue (0.1-5 mg kg-1). For the detection of these four aminoglycosides, three enzyme linked immunosorbent assays (ELISA) for applications in milk and kidney were developed. The screening of defatted and diluted milk resulted in limits of determination (LDM) of < 0.01 mg l-1. Kidney samples were deproteinized with a trichloroacetic acid solution (3%) and after filtration and the addition of buffer, aliquots were used in the ELISA. The LDM of the four aminoglycosides in kidney were < 0.05 mg kg-1. The ELISA were found suitable for the semi-quantitative screening of milk and kidney for the presence of the four aminoglycosides far below the MRL levels. In randomly taken milk samples (n = 776) and in kidneys derived from healthy pigs (n = 124), the aminoglycoside residues found were far below their established MRL. In eight out of the 94 kidney samples obtained from diseased animals after emergency slaughter, aminoglycoside residues were above the MRL.

Development of a one step strip test for the detection of sulfadimidine residues.

The one step strip test described is a competitive immunoassay in which the detector reagent consists of colloidal gold particles coated with affinity purified polyclonal anti-sulfadimidine (SDD) antibodies. The capture reagent in the assay is an SDD-ovalbumin conjugate which is immobilised on the lateral flow membrane of the test device. In the test procedure, 150 microliters (four drops) of a liquid sample (buffer, urine or milk) are brought into the sample well of the test device and allowed to migrate over the membrane. The more analyte present in the sample, the more effectively it will compete with the SDD immobilised on the membrane for binding to the limited amount of antibodies of the detector reagent. A sufficient amount of SDD in the sample will therefore prevent the binding of the detector reagent to the SDD immobilised on the membrane. Therefore, a positive sample will not show a test line in the read-out zone. With spiked buffer or calf urine this was obtained at a level of > 10 ng ml-1 of SDD and with spiked (diluted) fresh cow milk at a level > 20 ng ml-1 of SDD. At these levels, the test is applicable only as a qualitative assay. The presence or absence of a test line indicates lower or higher levels of SDD, respectively. The major advantages of the one step strip test are that results can be obtained within 10 min and that all reagents are included in the test device.

Application of an enzyme immunoassay for the determination of sulphamethazine (sulphadimidine) residues in swine urine and plasma and their use as predictors of the level in edible tissue.

The potential of an enzyme immunoassay (EIA) with high cross-reactivity towards the major metabolite (N4-acetyl-sulphamethazine) of sulphamethazine was tested for screening fluids and tissues. Healthy pigs were given 20 mg sulphamethazine per kg body weight per day in their drinking water for 2 days. Groups of four pigs were slaughtered after 3, 4 and 7 days withdrawal. The results were compared with liquid chromatographic analysis for urine, plasma, kidney, liver, gluteal muscle and diaphragm. In general, concentrations found by the EIA were higher than those found by liquid chromatography (LC) because sulphamethazine metabolites were detected by the EIA and not by LC. Using the EIA for the detection of sulphamethazine and the major metabolite in urine and plasma, predictive relationships (tissue-fluid ratios) for the concentration of the parent drug in tissue, determined by LC, were calculated. The tissue-plasma ratios for muscle, liver and kidney were 0.1, 0.2 and 0.1, respectively. The tissue-urine ratios for muscle, liver and kidney were 0.02, 0.03 and 0.03, respectively. Owing to the higher concentration of the parent drug in both fluids, the presence of the major metabolite in urine and the sensitivity of the EIA, tissue can be screened for low concentrations of sulphamethazine.

Development of a tube enzyme immunoassay for "on-site' screening of urine samples in the presence of beta-agonists.

An on-site screening test for the detection of beta-agonistic drugs in urine was developed. The test is based on the principle of an enzyme immunoassay in polystyrene tubes. Results can be obtained by visual interpretation or by measurement with a differential photometer. The total time required to perform the test for a set of samples (five samples+one cut-off standard) is about 20 min (visual interpretation) with an additional 2 min for an instrumental interpretation. Owing to its speed and simplicity, the test can be performed in slaughter- and farmhouses. In the tube test, a mixture of antibodies raised against clenbuterol and salbutamol is used, which makes this test sensitive towards a range of beta-agonists (multi-test). In this study, the test was applied to the screening of 269 bovine urine samples. Bovine urine samples with a level of 3 ng ml-1 of clenbuterol and higher were found positive with this on-site test. Owing to fewer matrix effects, a lower level (1 ng ml-1) could be detected in calf urine. The detection of positive samples at the place of sampling can result in more effective control of the illegal use of beta-agonists.

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.