Resumen de Bottom-up surface engineering for the construction of (bio) sensoring systems: design strategies and analytical applications

Hossam Metwally Ahmed Nassef

• Specifically outlining the work achieved in this PhD thesis, the work is organised into separate articles that have been published, submitted or are under preparation for submission.Chapter 1 is an introduction, in which the state of the art and objectives are presented. In Chapters 2-4, different potential mediators that could be used for the catalytic interaction with the enzymatic product o-AP were evaluated and due to their well characterized properties, hydrazine, NADH and ascorbic acid were selected for further study. Hydrazine is used as an antioxidant and reducing agent; NADH plays an important rule in oxidoreductases and dehydrogenase systems and ascorbic acid (vitamin C) is an antioxidant whose detection is important in clinical and food applications. The electrocatalytic properties of o-aminophenol films grafted on glassy carbon surfaces have been employed for the electrochemical evaluation of hydrazine, NADH and ascorbic acid, to select the most relevant as a recycling mediator in the planned signal amplification strategy. To evaluate the best mediator, the reaction kinetics between mediators and the o-AP/o-QI were extensively studied using different techniques such as cyclic voltammetry, hydrodynamic voltammetry, double potential step chronoamperometry, and double potential step chronocoulometry. Of them, ascorbic acid was selected as the mediator for regeneration of the o-AP film and substrate recycling. We had thus demonstrated an interesting catalytic system for the oxidation of ascorbic acid, which is stable, sensitive and reproducible, and we decided to explore this system for clinical and food applications. In the first application, we targeted the determination of uric acid (UA) in the presence of ascorbic acid (AA), which commonly co-exist in biological fluids of humans, mainly in blood and urine (Chapter 4). In Chapters 5 and 6, the selective electrocatalytic properties of the grafted o-AP film toward ascorbic acid were also applied to its detection in real samples of fruits and vegetables using disposable one-shot screen printed electrodes. The o-AP modified screen printed electrodes showed high catalytic responses toward the electrocatalytic oxidation of ascorbic acid. The o-AP SPE sensor exhibited high sensitivity and selectivity toward ascorbic acid with excellent storage and operational stability, as well as a quantitatively reproducible analytical performance. In the second part of the thesis, different surface engineering strategies of antibody immobilization for immunosensor construction using a linker or via direct attachment onto a Au surface using a strategy of self assembly were evaluated and compared. An alternative strategy explored was the direct anchoring of the antibody with or without a linker via the electrochemical reduction of their diazonium cations.In Chapter 7, a comparison between these different surface chemistries methodologies for the construction of immunosensors towards the model analyte of coeliac toxic gliadin was carried out. Firstly, the self-assembled monolayer approach was evaluated based on the modification of gold surfaces with two bipodal carboxylic acid terminated thiols (thioctic acid and a benzyl alcohol disubstituted thiol, DT2). A stable SAM of DT2 was rapidly immobilized (3 h) on Au as compared with thioctic acid (100 h), although both surface chemistries resulted in highly sensitive electrochemical immunosensors for gliadin detection using an anti-gliadin antibody (CDC5), with detection limits of 11.6 and 5.5 ng/mL, respectively. The developed immunosensors were then applied to the detection of gliadin in commercial gluten-free and gluten-containing food products, showing an excellent correlation when compared to results obtained with ELISA. In Chapter 8, another approach was explored to further improve immunosensor sensitivity and stability and furthermore to reduce the time necessary for sensor preparation was investigated looking at the direct attachment of the SATA modified full length antibody, and their F(ab) fragments onto Au electrodes. Spontaneously adsorbed SAMs of Fab-SH and CDC5-SH onto Au were rapidly formed in less than 15 minutes. The amperometric immunosensors based on Fab fragments exhibited a vastly improved detection limit as compared to the thiolated antibody with a highly sensitive response toward gliadin detection (LOD, 3.29 ng/ml for amperometric detection and 0.42 g/ml for labelless (impedimetric) detection). Moreover, the self-assembled monolayer of F(ab) fragments was extremely stable with almost no loss in response after 60 days storage at 4oC.In Chapter 9, an alternative surface chemistry approach was explored for the modification of Au electrodes via electrochemical and spontaneous reduction of diazonium cations of a conjugate prepared from the monoclonal full length anti-gliadin antibody (CDC5) and the linker 3,5-bis(aminophenoxy)benzoic acid (DAPBA). Cylic voltammetry was chosen for surface modification via applying three potential cycles, but it was observed that an extensive washing process was necessary after each potential cycle to remove the non-specifically adsorbed molecules or formed multilayers. The affinity of the immobilized antibody toward gliadin was studied using EIS and amperometry. The modified CDC5-DAPBA surface showed a reasonable amperometric response after incubation with 5 g/ml gliadin, and exhibited excellent specificity with no response observed in the absence of the analyte.In Chapter 10, general conclusions and future work are presented. From the different surface chemistry strategies evaluated in this work we can conclude that the best approach is the immunosensor based on the spontaneous adsorption of thiolated F(ab) fragments on gold. This surface is easy and fast to prepare, very stable and sensitive and can be stored for long times in the appropriate conditions without lost of affinity. A good alternative to this approach seems to be the electrodeposition of antibody-diazonium conjugates, although further work is needed in order to optimize this system.Overall, this work has contributed significantly to the vision we have for an immunosensor that avoids washes and reagent addition, where we have selected an excellent mediator for co-encapsulation with alkaline phosphatase enzymes within liposome reporter molecules, for regeneration of surface immobilised substrate following enzymatic dephosporylation, facilitating substrate recycling and increase in sensitivity and reduction in detection limit. Furthermore, we have selected an optimum surface chemistry for co-immobilisation of capture antibody molecules and enzyme substrate via the formation of self-assembled monolayers of antibody fragments on gold surfaces. Future work will focus on combining the selected mediator and surface chemistry into a sandwich immunosensor with a target sensitive liposome reporter molecule, to demonstrate a reagentless, washless ultrasesensitive immunosensing platform.