Maria G.E.G. Bremer

Label-Free and Multiplex Detection of Antibiotic Residues in Milk Using Imaging Surface Plasmon Resonance-Based Immunosensor

Monitoring of antimicrobial drug residues in foods relies greatly on the availability of adequate analytical techniques. Currently, there is a need for a high-throughput screening method with a broad-spectrum detection range. This paper describes the development of a microarray biosensor, based on an imaging surface plasmon resonance (iSPR) platform, for quantitative and simultaneous immunodetection of different antibiotic residues in milk. Model compounds from four major antibiotic families: aminoglycosides (Neomycin, Gentamicin, Kanamycin, and Streptomycin), sulfonamides (Sulfamethazine), fenicols (Chloramphenicol), and fluoroquinolones (Enrofloxacin) were detected using a single sensor chip. By multiplexing seven immunoassays in a competitive format, we were able to measure all the target compounds at parts per billion (ppb) levels in buffer and in 10x-diluted milk. The assays for Neomycin, Kanamycin, Streptomycin, Enrofloxacin, and Sulfamethazine were sensitive enough for milk control at maximum residue levels as established in the European Union. The overall performance of the biosensor was determined to be comparable to that of conventional four-channel surface plasmon resonance (SPR)-based biosensors, in terms of assay sensitivity and robustness. Combining the advantages of a SPR sensor and a microarray, utilization of the biosensor described here offers a promising alternative to the existing methods and is highly relevant for multianalyte food profiling.

Hyaluronan-coated nanoparticles: The influence of the molecular weight on CD44-hyaluronan interactions and on the immune response

Hyaluronan (HA), a naturally occurring glycosaminoglycan, exerts different biological functions depending on its molecular weight ranging from 4000-10M Da. While high Mw HA (HMw-HA) is considered as anti-inflammatory, low Mw HA (LMw-HA) has been reported to activate an innate immune response. In addition, opposing effects on cell proliferation mediated by the HA receptor CD44, have also been reported for high and low Mw HA. We have previously demonstrated that HMw-HA can be covalently attached to the surface of lipid nanoparticles (NPs), endowing the carriers with long circulation and active targeting towards HA-receptors (CD44 and CD168) highly expressed on tumors. Here we present a small library of HA-coated NPs distinguished only by the Mw of their surface anchored HA ranging from 6.4 kDa to 1500 kDa. All types of NPs exerted no effect on macrophages, T cells and ovarian cancer cells proliferation. In addition, no induction of cytokines or complement activation was observed. The affinity towards the CD44 receptor was found to be solely controlled by the Mw of the NPs surface-bound HA, from extremely low binding for LMw-HA to binding with high affinity for HMw-HA. These findings have major implications for the use of HA in nanomedicine as LMw-HA surface modified-NPs could be a viable option for the replacement of polyethylene glycol (PEG) when passive delivery is required, lacking adverse effects such as complement activation and cytokine induction, while HMw-HA-coated NPs could be used for active targeting to CD44 overexpressing tumors and aberrantly activated leukocytes in inflammation.

Structural changes of IgG induced by heat treatment and by adsorption onto a hydrophobic Teflon surface studied by circular dichroism spectroscopy

Thermal denaturation of mouse monoclonal immunoglobulin G (isotype 1), as well as structural rearrangements resulting from adsorption on a hydrophobic Teflon surface, are studied by circular dichroism spectroscopy. Both heat-induced and adsorption-induced denaturation do not lead to complete unfolding into an extended polypeptide chain, but leave a significant part of the IgG molecule in a globular or corpuscular form. Heating dissolved IgG causes a decrease of the fractions of beta-sheet and beta-turn conformations, whereas those of random coil and, to a lesser extent, alpha-helix increase. Adsorption enhances the formation of alpha-helices and random coils, but the beta-sheet content is strongly reduced. Heating adsorbed IgG results in a gradual break-down of the alpha-helix and beta-turn contents, and a concomitant formation of beta-sheet structures. Thus, the structural changes in IgG caused by heating and by adsorption, respectively, are very different. However, after heating, the structure of adsorbed IgG approaches the structure of thermally denatured IgG in solution.

Food Allergens Profiling with an Imaging Surface Plasmon Resonance-Based Biosensor

Food allergy is a growing health concern, which currently affects approximately 4% of adults and 8% of infants. For consumer protection purposes, food producers are required by law to disclose on the product label whether a major allergen is used during the production process. The commonly employed monitoring methods are highly laborious, time-consuming, and often expensive when screening for multiple allergens. Here, we utilize imaging surface plasmon resonance (iSPR) in combination with antibody array for rapid, quantitative, and multianalyte food allergens detection. We demonstrate how the use of this technology provides a complete allergen profile within short measurement time and with adequate sensitivity. The successful applicability of this approach is demonstrated by analyzing cookies and dark chocolate products from different manufacturers. Hazelnut content of the tested food products is also determined by enzyme linked immunosorbent assay and is found to correlate well with the hazelnut content determined by iSPR. This newly developed method opens the door to automated and high-throughput allergen analysis, ultimately aiming at providing the consumer with safer food.

Untargeted LC-Q-TOF mass spectrometry method for the detection of adulterations in skimmed-milk powder

A nontargeted protein identification method was developed to screen for adulterations in skimmed-milk powder (SMP). There are indications of falsified SMP content due to the addition of plant proteins. To demonstrate the reliability and accuracy of the developed comparative LC-MS method using a quadrupole TOF MS instrument, adulterated SMP samples were prepared by the addition of protein isolates of soy and pea to skimmed-milk before pasteurisation and evaporation. The comparative LC-MS approach enabled unequivocal discrimination of those SMP samples containing soy and pea protein from nonadulterated SMP. To identify the source of (plant) proteins present in the adulterated SMP, data-dependent LC-MS/MS was used in combination with an include list of differential peptides. Numerous peptides originating from the major seed proteins of soy (glycinin, beta-conglycin) and pea (legumin, vicilin) could be identified in this way.

Development of a biosensor microarray towards food screening using imaging surface plasmon resonance

In this study we examined the possibilities of implementing direct and competitive immunoassay formats for small and large molecule detection on a microarray, using IBIS imaging surface plasmon resonance (iSPR) system. First, IBIS iSPR optics performance was evaluated. Using a glycerol calibration curve on underivatized surface we observed high baseline variability, but uniform and robust sensitivity between hundred regions of interest. Further on, a direct immunoassay for bovine IgG detection and a competitive immunoassay for gentamicin and neomycin were developed. The direct immunoassay for bovine IgG detection in a microarray format showed poor sensitivity in comparison to the assay performed in Biacore 3000, due to low immobilization efficiency on spots. The competitive immunoassay for parallel gentamicin and neomycin detection in a microarray format displayed sensitivity in the ngmL(-1) range, comparable with the sensitivity achieved in Biacore 3000 and in the range of maximum residue limits in milk, established in the European Union. We expect that, utilization of the IBIS iSPR system for food analysis, by screening high and low molecular weight compounds, will allow rapid and simultaneous detection of various ingredients and contaminants, providing the end-user with a detailed food profile. However, assay transfer from conventional SPR biosensors to the imaging microarray platform also presents new challenges, such as sufficient immobilization on spots, that must be addressed in future studies.

Multiple Protein Biomarker Assessment for Recombinant Bovine Somatotropin (rbST) Abuse in Cattle

Biomarker profiling, as a rapid screening approach for detection of hormone abuse, requires well selected candidate biomarkers and a thorough in vivo biomarker evaluation as previously done for detection of growth hormone doping in athletes. The bovine equivalent of growth hormone, called recombinant bovine somatotropin (rbST) is (il)legally administered to enhance milk production in dairy cows. In this study, first a generic sample pre-treatment and 4-plex flow cytometric immunoassay (FCIA) were developed for simultaneous measurement of four candidate biomarkers selected from literature: insulin-like growth factor 1 (IGF-1), its binding protein 2 (IGFBP2), osteocalcin and endogenously produced antibodies against rbST. Next, bovine serum samples from two extensive controlled rbST animal treatment studies were used for in vivo validation and biomarker evaluation. Finally, advanced statistic tools were tested for the assessment of biomarker combination quality aiming to correctly identify rbST-treated animals. The statistical prediction tool k-nearest neighbours using a combination of the biomarkers osteocalcin and endogenously produced antibodies against rbST proved to be very reliable and correctly predicted 95% of the treated samples starting from the second rbST injection until the end of the treatment period and even thereafter. With the same biomarker combination, only 12% of untreated animals appeared false-positive. This reliability meets the requirements of Commission Decision 2002/657/EC for screening methods in veterinary control. From the results of this multidisciplinary study, it is concluded that the osteocalcin – anti-rbST-antibodies combination represent fit-for-purpose biomarkers for screening of rbST abuse in dairy cattle and can be reliably measured in both the developed 4-plex FCIA as well as in a cost-effective 2-plex microsphere-based binding assay. This screening method can be incorporated in routine veterinary monitoring programmes: in the European Union for detection of rbST abuse and in the control of rbST-free dairy farms in the United States of America and other countries.

Evaluating the Performance of Gluten ELISA Test Kits: The Numbers Do Not Tell the Tale

A wide variety of enzyme-linked immunosorbent assays (ELISAs) are commercially available for gluten detection in food, including new formats and assays with antibodies against relevant gluten epitopes. Nevertheless, problems persist to accurately determine the gluten content of products. In this study, the performance of a set of 14 ELISA kits for gluten detection, representative of the current ELISA methods available on the market, was evaluated. These tests were used to determine gluten content in a series of relevant food matrices varying in complexity. Our results show that, currently, there is no single ELISA method that can accurately detect and quantify gluten in all different matrices. This includes the current type I method R5 as recommended by Codex Alimentarius. We conclude that further improvements are urgently needed and recommend focusing on competitive formats, improving extraction methods, and the detection of relevant gluten peptides (in order of priority).

Development of a flow cytometric immunoassay for recombinant bovine somatotropin-induced antibodies in serum of dairy cows.

Administration of recombinant bovine somatotropin (rbST) to enhance milk production in dairy cows is banned within the European Union. Therefore, methods for pinpointing rbST abuse are required. Due to the problematic detection of rbST itself in serum, methods are also focused on detecting changes in rbST-related biomarkers. In this study, a fast and easy-to-perform microsphere-based flow cytometric immunoassay (FCIA) for detection of rbST-induced antibodies in serum was developed. Until now, detection of rbST-induced antibodies was also problematic due to non-specific binding of serum proteins resulting in a high rate of false positive results. Therefore, five different sample preparation methods, i.e. dilution, octanoic acid precipitation, filtration, protein G purification, and a previously described generic FCIA sample preparation were critically compared to overcome non-specific binding to the microspheres. Only the generic FCIA sample pretreatment was effective in reducing non-specific binding. As a result, an absolute decision level for detecting rbST antibodies in serum of dairy cows was determined and its applicability was demonstrated. In accordance with biological expectations from literature, rbST antibodies were induced in three out of four rbST-treated dairy cows. These rbST-induced antibodies were successfully detected for up to 4 weeks after the last rbST treatment, whereas no false positive results were obtained for 27 untreated dairy cows. This is the first method, able to overcome the interference of serum proteins and therefore, can be applied with high confidence for screening unknown herds of cattle for rbST antibodies, an important biomarker for pinpointing at rbST abuse in cattle.

Multiplex ready flow cytometric immunoassay for total insulin like growth factor 1 in serum of cattle

The European Union has banned the use of recombinant bovine somatotropins (rbST, growth hormones) to increase milk yield in dairy cattle. As direct detection of rbST in serum is problematic, methods based on the detection of changes in multiple rbST-dependent biomarkers have high potential for monitoring rbST abuse. In this study immunoassays were developed for total insulin-like growth factor 1 (IGF-1) in cow sera. Ultimately aiming at combination with other rbST-dependent biomarker assays two multiplex formats were studied and compared critically, a multi-channel surface plasmon resonance (SPR)-based biosensor and flow cytometry combined with color encoded microbeads. Moreover, a new dedicated sample pretreatment was developed for the dissociation of complexed IGF-1 in serum, while keeping other biomarkers in solution. Compared to the SPR biosensor immunoassay, the flow cytometric immunoassay (FCIA) was more sensitive, less antibody-consuming and less vulnerable to necessary but interfering reagents from the sample treatment. In an initial in-house validation study the developed FCIA showed to be fast, specific, robust, and a high repeatability and reliability, and generated realistic IGF-1 values for bovine serum, without compromising the potential for simultaneous detection of other biomarkers. Due to the xMAP technology, in which 100 different bead sets can be measured simultaneously, the total IGF-1 assay can easily be extended with other immunoassays for candidate biomarkers. Preliminary results about a FCIA for IGF-1 multiplexing with insulin-like growth factor binding protein 2 (IGFBP2) are presented which strongly supported both the FCIA multiplex format as well as the generic nature of the developed sample pretreatment.