Abstract
Immunosensor sensitivity and stability depend on a number of parameters such as the orientation, the surface density, and the antigen-binding efficiency of antibodies following their immobilization onto functionalized surfaces. A number of techniques have been developed to improve the performance of an immunosensor that targets one or both of the parameters mentioned above. Herein, two widely employed techniques are compared for the first time, which do not require any complex engineering of neither the antibodies nor the surfaces onto which the former get immobilized. To optimize the different surface functionalization protocols and compare their efficiency, a model antibody-antigen system was employed that resembles the complex matrices immunosensors are frequently faced with in real conditions. The obtained results reveal that protein A/G is much more efficient in increasing antibody loading onto the surfaces in comparison to boronate ester chemistry. Despite the fact, therefore, that both contribute towards the orientation-specific immobilization of antibodies and hence enhance their antigen-binding efficiency, it is the increased antibody surface density attained with the use of protein A/G that plays a critical role in achieving maximal antigen recognition.
Highlights
Ιmmunosensors are affinity-based assays that feature prominently as effective tools for the quantification of the amount of antibodies or antigens in complex samples
That both contribute towards the orientation-specific immobilization of antibodies and enhance their antigen-binding efficiency, it is the increased antibody surface density attained with the use of protein A/G that plays a critical role in achieving maximal antigen recognition
Despite having optimized antibody immobilization onto GOPTS-aminophenyl-boronic acid- (APBA-)modified surfaces, the reversibility of boronate ester chemistry could compromise the stability of the antibody-decorated surface
Summary
Ιmmunosensors are affinity-based assays that feature prominently as effective tools for the quantification of the amount of antibodies or antigens in complex samples Of whether it is the antibody or the antigen that is immobilized on the transducer surface, the strong binding forces that develop allow the detection of the target analyte with high sensitivity and specificity [1], making them very attractive for applications in a diverse range of fields such as food safety [2, 3], medical diagnostics [4, 5], and environmental monitoring [6, 7]. As far as the latter is concerned, carbon nanotubes, noble metal nanoparticles, polymers, quantum dots, and graphene are some of the numerous nanomaterials that have been applied in the design of an immunosensor to amplify signal detection, enrich and concentrate trace analytes, and immobilize the recognition elements with enhanced stability [9,10,11,12].
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