CRANFIELD UNIVERSITY MOHAMAD KAMAL ABDUL KADIR DEVELOPMENT OF IMMUNOSENSORS FOR MYCOTOXINS ANALYSIS CRANFIELD HEALTH PhD THESIS Academic Year: 2006 – 2009 Supervisor: Dr. Ibtisam E. Tothill May 2010 i CRANFIELD UNIVERSITY CRANFIELD HEALTH PhD THESIS Academic Year: 2006 – 2009 MOHAMAD KAMAL ABDUL KADIR DEVELOPMENT OF IMMUNOSENSORS FOR MYCOTOXINS ANALYSIS Supervisor: Dr. Ibtisam E. Tothill May 2010 This thesis is submitted in partial fulfilment of the requirements for the degree of Doctor of Philosophy © Cranfield University, 2010. All rights reserved. No part of this publication may be reproduced without the written permission of the copyright owner. ii ABSTRACT Aflatoxin B (AFB ) and fumonisins (Fms) are mycotoxin contaminants found in 1 1 peanuts and corn, respectively, and are known to be immunosuppressive and carcinogenic compounds. Therefore, the development of rapid and sensitive method for detecting these toxins especially for field analysis is required for risk assessment and management. The work presented in this thesis reports on the construction of sensor platforms capable of fulfilling these requirements. The use of, screen-printed thick film electrodes, gold nano-particle application and microelectrodes on a silicone support were investigated as suitable sensor platforms. The development of indirect and direct competitive immunoassay formats for the electrochemical immunosensor construction was undertaken for AFB and Fms determination. 1 A spectrophotometric assay was initially developed as a first step procedure using microtitre plates for immunoreagents concentration and conditions selection before being transferred to the surface of the screen-printed gold electrode (SPGE) and then the microelectrode array (MEA) sensor. Detection was performed by chronoamperometry monitoring the reaction of tetramethylbenzidine (TMB) and hydrogen peroxide (H O ) catalysed by horseradish peroxidase (HRP). The 2 2 performance of screen-printed gold electrode (SPGE) immunosensor was compared to 3,3-dithiodipropionic acid (DTDPA) modified SPGE, immuno gold nano-particle modified SPGE and amine silane modified microelectrode array (MEA). Surface modification of MEA was successfully undertaken using silane and phenylene di- isothiocyanate (PDITC) chemistries for the covalent binding of the recognition system to the silicon surface area of the microelectrode arrays. The immunosensor format was transferred to a gold microelectrode array based on a silicone support for the purpose of signal sensitivity enhancement and miniaturisation for multiplex detection in the prospect of field analysis. The developed of the gold immunosensor achieved a detection limit of 5 ng L-1, 1 ng L-1 and 1 ng L-1 for AFB using indirect assay on DTDPA thiol modified SPGE, 1 immuno gold nano-particle modified SPGE and modified microelectrode array (MEA), respectively. While, the direct competitive method for fumonisins detection iii on the SPGE sensor and modified MEA achieved a limit of detection was 0.5 µg L-1. The sensors were also used for AFB and Fms determination in peanuts and corn 1 samples, respectively, and also validated using a standard HPLC and a commercial ELISA kit. Samples analysis involved the rapid extraction (without clean-up) and pre- treatment using solid phase extraction (clean-up) before measuring using the developed immunosensor platforms. The results achieved were found to be in average 82.7% (without clean-up) and 103.1% (clean-up) using gold-particle SPGE and 85.7% (without clean-up) using MEA for AFB detection in peanut, respectively. While for 1 Fms detection in corn sample was achieved in average of 73.5% (without clean-up) and 98.6% (clean-up) using SPGE and 87.3% (without clean-up) using MEA, respectively. The developed immunosensors (gold particle SPGE, SPGE and MEA) had a satisfactory agreement with HPLC and ELISA kit. The performance of the proposed sensors are highly sensitive and provide analytical system capable of detecting very low level of toxin within the required legislative EU limit of analyses. iv ACKNOWLEDGEMENTS I would like to express my sincere gratitude to my supervisor Dr. Ibtisam E. Tothill for her continue guidance, support and friendship throughout the whole project. The financial support for this research degree is gratefully acknowledged from Malaysian Agricultural Research and Development Institute (MARDI). Special thank to Faridah, which was always there sharing my Cranfield Health experience, also to Yildiz Uludag and all friend for sharing the experience, knowledge and for everything. Thanks. Finally, I would like to thank my wife, Norsuriana Ahmad, for her enormous patience, never ending care and love. Also to all my children, Atie, Rina and Fahiim for their loving support. Without their encouragement and understanding it would have been impossible for me to finish this work. v LIST OF CONTENT CONTENTS PAGE.NO Abstract iii Acknowledgments v Contents vi List of Figures xiv List of Tables xxvi Notation xxviii CHAPTER 1: INTRODUCTION AND LITERATURE REVIEW 1.1 Background 2 1.2 Mycotoxins 4 1.2.1 Aflatoxins 6 1.2.2 Fumonisins 9 1.3 Analytical methods used for aflatoxin and fumonisin analysis 11 1.3.1 Thin Layer Chromatography (TLC) method 14 1.3.2 High Performance Liquid Chromatography (HPLC) method 15 1.4 Immunochemical analysis 16 1.4.1 The antibody (Ig) molecule 17 1.4.1.1 Polyclonal antibody (PAb) 18 1.4.1.2 Monoclonal antibody (MAb) 19 1.4.2 Immunoaffinity column (IAC) 21 1.4.3 Enzyme Linked Immunosorbent Assay (ELISA) 21 1.4.3.1 Competitive immunoassay test 22 1.4.3.2 Detector labels and substrates used in immunoassay 24 1.4.3.3 Data analysis 24 1.5 Immunosensor 26 1.5.1 Background 26 1.5.2 Sensing materials (receptors) 28 1.5.3 Immobilisation (coating) 29 1.5.4 Transducers used in biosensor devices 31 1.6 Electrochemical Immunosensor 34 vi 1.6.1 Electrode systems used for immunosensor fabrication 35 1.6.2 Cyclic voltammetry (CV) 37 1.6.3 Chronoamperometry (CA) 39 1.6.4 Potentiometric detection 40 1.6.5 Amperometric detection 40 1.6.5.1 Hydrogen peroxide and mediators 41 1.6.5.2 A mediator of 3,5,3‘,5‘-tetrametilbenzidine (TMB) 43 1.7 Microsensors 44 1.7.1 Microelectrode arrays design 45 1.7.2 Electrochemical microelectrode arrays application 46 1.8 The functional of nano-particles for a biosensing application 48 1.8.1 Nano-particles for electrochemical immunosensor 48 1.9 Immunosensor for aflatoxin B and fumonisins analysis 50 1 1.10 Aim and objectives 52 1.11 Overall activities for aflatoxin B and fumonisins analysis 55 1 CHAPTER 2: DEVELOPMENT OF ELISA FOR AFLATOXIN B 1 2.1 Introduction 57 2.2 Material and Methods 59 2.2.1 Chemicals and reagents 59 2.2.2 Instrumentations 60 2.2.3 Buffer solutions 60 2.2.4 Blocking solution 61 2.2.5 Standard solution 61 2.2.6 Indirect competitive ELISA 61 2.2.6.1 Optimisation of reagents 62 2.2.6.2 Effect of coating buffers and blocking agents 63 2.2.6.3 Competition assay preparation 63 2.2.6.4 Effect of concentrations of reagents 65 and incubation time for competitive assay development 2.2.7 Direct competitive ELISA 65 2.2.7.1 Optimisation of reagents 65 2.2.7.2 Competition assay preparation 66 vii 2.2.8 Calculation for the sensitivity of the assay 67 2.3 Result and Discussion 68 2.3.1 Indirect ELISA 68 2.3.1.1 Optimisation of anti-AFB antibody 68 1 (monoclonal antibody against AFB ) and 1 AFB -BSA conjugate 1 2.3.1.2 Optimisation of anti-mouse IgG-Horseradish 70 peroxidase conjugates (anti-IgG-HRP) 2.3.1.3 Effect of coating buffer in indirect 72 non-competitive method 2.3.1.4 Blocking agents 73 2.3.2 Assay optimisation with free AFB 76 1 2.3.2.1 Effect of the sample volume on the assay 76 2.3.2.2 Effect of incubation times in the competition steps 77 2.3.2.3 Effect of different concentration of 79 anti-aflatoxin B antibody (MAbAFB ) 1 1 2.3.2.4 Effect of different concentration of anti-IgG-HRP 81 2.3.3 Direct ELISA format 83 2.3.3.1 Optimisation of MAbAFB and AFB -HRP 83 1 1 without free AFB 1 2.3.3.2 Optimisation of anti-IgG (mouse) 85 unconjugated without free AFB 1 2.3.3.3 Calibration curve of AFB 87 1 2.3.4 Sensitivity of the immunoassay development 89 2.4 Conclusions 90 CHAPTER 3: DEVELOPMENT OF ELECTROCHEMICAL IMMUNOSENSOR USING GOLD WORKING ELECTRODE FOR AFB 1 DETECTION 3.1 Introduction 92 3.1.1 Electrochemical immunosensor 92 3.1.2 Immuno gold nano-particle application 93 3.2 Materials and Methods 93 3.2.1 Chemicals and reagents 93 viii 3.2.2 Buffer and solution 94 3.2.3 Apparatus 95 3.2.4 Screen-Printed Gold Electrode (SPGE) 95 3.2.4.1 Preparation of SPGE fabricated in house 95 3.2.5 Electrochemical Measurement 97 3.2.5.1 Voltammetric studies for characterisation of SPGE 98 3.2.5.2 Surface characterisation of screen-printed gold electrode 99 with SEM 3.2.5.3 Electrochemical study of TMB/ H O / HRP 100 2 2 3.2.6 Electrochemical immunosensor development for competitive 100 assay of AFB 1 3.2.6.1 Optimisation of antibody and HRP conjugate 101 3.2.6.2 Physical adsorption procedure for competitive assay 101 3.2.6.3 Thiol self assembled monolayer (SAM) modification 102 of the gold surface 3.2.7 Electrochemical immuno gold nano-particle sensor detection 103 3.2.7.1 Self Assembled Monolayer (SAM) on gold working 103 electrode (SPGE) 3.2.7.2 Optimisation and preparation of immuno gold 103 nano-particle conjugated HRP 3.2.7.3 Indirect competitive assay using immuno gold 104 nano-particles-HRP 3.2.8 Sample analysis 105 3.2.8.1 Sample extraction for immunoassay analysis 105 3.2.8.2 Sample extraction for immunoassay and HPLC 106 3.3 Results and Discussion 107 3.3.1 Characterisation of screen-printed gold electrode by 107 cyclic voltammetry 3.3.2 Surface characterisation of SPGE using SEM 110 3.3.3 Cyclic voltammetry of 3,3‘5,5‘-tetramethylbenzidine 110 (TMB) as an electron shuttle 3.3.4 Chronoamperometry study of enzyme activity using TMB/H O 114 2 2 3.3.5 Potential determination 115 3.3.6 Optimisation of TMB and hydrogen peroxide concentrations 117 ix 3.3.7 Optimisation of reagents concentrations 117 3.3.7.1 Optimisation of monoclonal antibody against AFB 119 1 3.3.7.2 Optimisation of HRP conjugate 120 3.3.8 Development of competitive assay on SPGE (ERCON) 121 3.3.8.1 Passive adsorption immobilisation 121 3.3.9 Development of Competitive assay on SPGE DuPont 124 3.3.9.1 Characterisation of the formation of thiols monolayer 124 3.3.9.2 Passive adsorption and covalent immobilisation 127 calibration curve 3.3.10 Application of gold nano-particle to enhance the 131 sensor response 3.3.10.1 Formation of immuno gold nano-particle for 131 signal amplification 3.3.10.2 Electrochemical characterisation of the electrode 132 with nano-particle 3.3.10.3 Optimisation of immuno gold nano-particle sensor 135 3.3.10.4 Competitive assay using immuno gold nano-particle 136 3.3.11 AFB detection in peanuts 141 1 3.3.11.1 Competitive method of detection used with sample matrix 141 3.3.11.2 Sample analysis 143 3.4 Conclusions 146 CHAPTER 4: DEVELOPMENT OF ELECTROCHEMICAL IMMUNOSENSOR FOR FUMONISINS ANALYSIS 4.1 Introduction 149 4.2 Materials and Methods 150 4.2.1 Chemicals and reagents 150 4.2.2 Buffer Solutions 151 4.2.3 Apparatus 151 4.2.4 Preparation of stock solutions 151 4.2.5 Preparation of Standard solution 152 4.2.6 Spectrophotometric ELISA for fumonisins analysis 152 4.2.6.1 Optimisation by ELISA Procedure (Checkerboard method) 152 x