Towards Development Of Low Cost Electrochemical Biosensor For Detecting Percentage Glycated Hemoglobin

Siva Rama Krishna, V

01 1900

There is an ever growing demand for low cost biosensors in medical diagnostics. A well known commercially successful example is glucose biosensors which are used to diagonize and monitor diabetes. These biosensors use electrochemical analysis (electro analysis) as transduction mechanism. Electro analytical techniques involve application of electrical stimulus to the chemical/biochemical system under consideration and measurement of electrical response due to the oxidation and reduction reactions that occur because of the stimulus. They offer a lot of advantages in terms of sensitivity, selectivity, cost effectiveness and compatibility towards integration with electronics. Besides glucose, there are several biomolecules of significance for which electro analysis can potentially be used to develop low cost, rapid, easy to use biosensors. One such biomolecule is Glycated Hemoglobin (GHb). It is a post translational, non-enzymatic modification of hemoglobin with glucose and is a very good biomarker that indicates the average value of blood glucose over the past 120 days. It is always expresses as a percentage of total hemoglobin present in blood. Monitoring diabetes based on the value of percentage Glycated hemoglobin is advantageous as it gives an average value of glucose unlike plasma glucose values which vary a lot on a day to day basis depending on the dietary habits and the stress levels of the individual. This thesis is focused on the development of a low coat, easy to use, disposable sensor for measuring percentage Glycated hemoglobin. The first challenge in developing such a sensor is isolation of hemoglobin. Unlike glucose which is present in blood plasma (liquid content of blood), hemoglobin resides inside red blood cells also known as erythrocytes. O isolate hemoglobin, these cells have to be broken or lysed. All the existing approaches rely on mixing blood with lysing reagents to lyse erythrocytes. Ideal biosensors should be devoid of liquid reagents. Keeping this in perspective, in this thesis, this challenge is addressed by developing two entirely buffer/reagentless techniques to lyse erythrocytes and isolate hemoglobin. In the first technique, cellulose acetate membranes are embedded with lysing reagents and are used for lysing reagents and are used for lysing application. In the second techniques, commercially available nylon mesh nets are modified with lysing reagents to lyse and isolate hemoglobin. These membranes or mesh nets can be easily integrated on top of a disposable strip. After isolating hemoglobin, the next challenge is to selectively detect Glycated hemoglobin. Boronic acid conjugates are known to bind Glycated hemoglobin. Using this principle, a new composite is sysnthesized to specifically detect glc\ycated hemoglobin. The composite (GO-APBA) is a result of functionalization of Graphene Oxide (GO) with 3-aminophenylboronic acide (APBA). Detection of Glycated hemoglobin is achieved by modifying screen printed electrode strips with the synthesized compound, thus taking a step forwards achieving the objective. Since Glycated hemoglobin is always expressed as a percentage of hemoglobin, the next challenge is to detect total hemoglobin. In this thesis a low cost way of detecting hemoglobin is achieved by using GO modified or surfactant modified screen printed electrode strips. Furthermore, the potential interferences that blood plasma can cause in these measurements are eliminated with the help of permselective coatings. Thus using the technologies developed in this thesis, measurements of percentage Glycated hemoglobin can be potentially made on handheld electronic devices akin to glucose meters by using just a drop of blood.

Medical Diagnostics

Electrochemical Diagnosis

Biosensors

Glycated Hemoglobin (GHb)

Electrochemical Biosensors

Erythrocytes - Lysis

Glycated Hemoglobin - Biosensors

Glycated Hemoglobin Sensor

Pathology

Electrochemical Biosensors based on Novel Receptors for Diabetes Management

Kumar, Vinay

January 2016

To address the challenge of accurate, low cost and robust biosensors for diabetes management and early detection of diabetes complications, we have developed novel, robust sensing chemistry (or receptors) for electrochemical POC biosensors. The biosensors have been developed for the bio-markers associated with diabetes management such as glycated haemoglobin (HbA1c), glycated albumin, glucose, biomarkers associated with diabetes complications such as microalbuminuria, urine creatinine and albumin-to-creatinine ratio (ACR) and biomarkers associated with anaemia and malnutrition conditions such as haemoglobin and serum albumin. For haemoglobin detection, a new POC bio sensing technique has been developed based on Aza-heterocyclic chemicals. The repeatability and accuracy of the biosensor have been tested on real pathology samples. The glycated form of haemoglobin, called glycated haemoglobin or HbA1c, is the gold standard test in diabetes management as it gives the 90-days average blood glucose value. We demonstrate a simple method for electrochemical detection of HbA1c by combining bosonic affinity principle along with aza-heterocyclic receptors. The technique has been verified on the real clinical patient samples. Albumin is the most abundant protein in the human blood. Human serum albumin (HSA) is either alone or an associative biomarker in several chronic diseases like necrosis, nephrosis, hepatitis, malnutrition, arthritis, immune disorders, cancer, diabetes and in some severe infections. In pathology laboratories, the serum albumin is usually tested on serum samples and not in whole blood samples. Since albumin is not a metalloproteinase, it is very difficult to develop electrochemical POC biosensor. We have developed a novel technique for the electrochemical detection of serum albumin in whole blood samples, by exploiting its binding property with redox active copper salts. The accuracy of technique has been verified on both real human blood plasma as well as whole blood samples. Glycated albumin, which is the glycated form of serum albumin, is emerging as a novel biomarker for diabetes management, as it gives the average blood glucose value of 15-20 days. It is also extremely useful in chronic kidney disease patients and patients with hemoglobinopathies where HbA1c can give the erroneous results. By combining the copper chemistry along with bosonic affinity principle, we present the first ever demonstration of glycated albumin sensing. Instant blood glucose monitoring is an integral part of diabetes management. Most of the glucometers available in the market are based on glucose oxidase enzyme. We have demonstrated a low cost non-enzymatic electrochemical technique for blood glucose detection using alkaline methylene blue chemistry. The accuracy of the technique has been verified on real human blood plasma samples. Glucometer is one of the most easily available POC biosensor and a useful tool for diabetes population. India has second largest diabetes population in the world. To analyse the accuracy of the POC glucometers which are available in Indian market, a comprehensive study was conducted. The results were compared with clinical accuracy guidelines using exhaustive statistical analysis techniques. The shortcomings of the commercial glucometers are elucidated, regarding different international standards. Diabetic nephropathy is one of the major diabetes complications and is the primary cause of chronic kidney disease (CKD). The presence of albumin in urine is a well-established biomarker for the early detection of diabetic nephropathy. We have developed a technique for electrochemical detection of microalbuminuria for point of care applications by exploring the binding property of human albumin with electrochemically active molecules like copper and hemin. Methylene blue mediated sensing technique has also been proposed. Urine Albumin-to creatinine ratio (ACR) is another variant of the microalbumuria test that can be done any time and does not suffer from the dilution factor of urine. Iron binding property of creatinine is exploited to develop creatinine biosensor, thus enabling POC ACR tests.

Electrochemical Biosensors

Targeted Biomarkers

Hemoglogin Electrochemical Detection

Blood Glucose Electrochemical Detection

Electrochemical Point of Care Biosensors

Electrochemical Glucose Biosensors

Blood Glucose

Nano Science and Engineering

Microsystème pour la nanomédecine : application aux maladies nosocomiales et à la détection des agents pathogènes / Microsystem for Nanomedicine : Application to nosocomial diseases and detection of pathogens

Kahlouche, Karima

19 December 2018

Ce travail a pour objet l’étude et le développement d’un capteur électrochimique pour la détection sélective quantitative des analytes biologiques à l’échelle nano. Il se divise en deux parties après une présentation de l’état de l’art sur les maladies nosocomiales et les capteurs électrochimiques. Tout d’abord, nous avons développé un protocole spécifique qui repose sur la fonctionnalisation localisée de la microélectrode de travail par dépôt électrophorétique d'oxyde de graphène réduit/polyéthylènimine (rGO/PEI) pour amplifier le signal de détection. Le microsystème réalisé en salle blanche, a été exploité avec succès pour la détection sélective de la dopamine avec une limite de détection de 50 nM.Ensuite, nous avons utilisé la même plateforme constituée d’électrodes de plus grande taille (mm) pour la réalisation d’un capteur immunologique. Il a démontré son efficacité, de manière spécifique et sélective, pour discriminer la souche sauvage E. Coli UTI89 de UTI89 Δfim (sans opéron), avec une limite de détection de 10 cfu mL−1. En outre, le concept d’utilisation d’une électrode modifiée par rGO/PEI par la modification covalente avec des anticorps pathogènes est général. Il peut être facilement adapté à toute autre espèce pathogène, rendant l’approche générique. Le capteur a donc abouti à des résultats intéressants en milieu aqueux, sérique et urinaire, ce qui est essentiel pour son utilisation potentielle pour le diagnostic clinique des maladies pathogènes. / The purpose of this work concerns the study and development of an electrochemical sensor for both quantitative and selective detection of biological analytes at the nanoscale. It is divided into two parts after a presentation of the state of the art on nosocomial diseases and electrochemical sensors. First, we have developed a specific protocol based on the localized functionalization of the working microelectrode by electrophoretic deposition. The strategy is based on the localizedfunctionalization of the working microelectrode by electrophoretic deposition of reduced graphène oxide / polyethyleneimine (rGO / PEI) to amplify the detection signal. The microsystem built in a clean room has been successfully tested for the selective detection of dopamine with a detection limit of 50 nM. In addition, the microsystem showed good performance in detecting dopamine levels.Then, we have also used the same electrode platform at a larger scale (mm) for the specific and selective detection of the immunological sensor which has demonstrated its effectiveness in distinguishing the UTI89 E. Coli wild-type strain of UTI89 Δfim (without operon), with a detection limit of 10. cfu mL-1. In addition, the concept of rGO / PEI modified electrode by covalent modification with pathogenic antibodies is general and can be easily transposed to any other pathogenic species, making the approach very versatile and generic.The sensor works in aqueous, serum and urinary media, which is essential for its potential use in clinical diagnosis of pathogenic diseases.

Microelctriodes

Fonctionnalisation

Eléctrochimie

Biodetection

Infections nosocomiales

Oxyde de graphène réduit

Biocapteurs électrochimiques

Dépôt électrophorétique

Dopamine

Anticorps anti-fimbrial E. Coli

Biodection

Functionnalisation

Electrochemistry

Nosocomial infections

Electrochemical biosensors

Reduced graphène oxide

Electrophoretic deposition

Dopamine

Anti- fimbrial E. Coli antibodies.

660.6

Development of electrochemical ZnSe Quantam dots biosensors for low-level detection of 17β-Estradiol estrogenic endocrine disrupting compound

Jijana, Abongile Nwabisa

January 2010

<p>The main thesis hub was on development of two electrochemical biosensors for the determination of 17&beta / -estradiol: an estrogenic endocrine disrupting compound. Endocronology have significantly shown that the endocrine disruptors contribute tremendously to health problems encountered by living species today, problems such as breast cancer, reproductive abnormalities, a decline in male population most significant to aquatic vertebrates, reduced fertility and other infinite abnormalities recurring in the reproductive system of mostly male species. The first biosensor developed for the detection of 17&beta / -estradiol endocrine disrupting compound / consisted of an electro-active polymeric 3-mercaptoprorionic acid capped zinc selenide quantum dots cross linked to horseradish peroxidase (HRP) enzyme as a bio-recognition element. The second biosensor developed was comprised of cysteamine self assembled to gold electrode, with 3-mercaptopropionic acid capped zinc selenide quantum dots cross linked to cytochrome P450-3A4 (CYP3A4) enzyme in the presence of 1-ethyl-3-(3- dimethylaminopropyl)carbodiimide hydrochloride and succinimide.</p>

Electrochemical biosensors

Cytochrome P450-3A4 (CYP3A4)

Horseradish peroxidase (HRP)

ZnSe quantum dots

Conducting polymers

Cyclic voltammetry (CV)

Differential-pulse voltammetry (DPV)

17β- estradiol

17α-ethnylestradiol

Michaelis Menten constant

Hydroxylation.

Development of electrochemical ZnSe Quantam dots biosensors for low-level detection of 17β-Estradiol estrogenic endocrine disrupting compound

Jijana, Abongile Nwabisa

January 2010

<p>The main thesis hub was on development of two electrochemical biosensors for the determination of 17&beta / -estradiol: an estrogenic endocrine disrupting compound. Endocronology have significantly shown that the endocrine disruptors contribute tremendously to health problems encountered by living species today, problems such as breast cancer, reproductive abnormalities, a decline in male population most significant to aquatic vertebrates, reduced fertility and other infinite abnormalities recurring in the reproductive system of mostly male species. The first biosensor developed for the detection of 17&beta / -estradiol endocrine disrupting compound / consisted of an electro-active polymeric 3-mercaptoprorionic acid capped zinc selenide quantum dots cross linked to horseradish peroxidase (HRP) enzyme as a bio-recognition element. The second biosensor developed was comprised of cysteamine self assembled to gold electrode, with 3-mercaptopropionic acid capped zinc selenide quantum dots cross linked to cytochrome P450-3A4 (CYP3A4) enzyme in the presence of 1-ethyl-3-(3- dimethylaminopropyl)carbodiimide hydrochloride and succinimide.</p>

Electrochemical biosensors

Cytochrome P450-3A4 (CYP3A4)

Horseradish peroxidase (HRP)

ZnSe quantum dots

Conducting polymers

Cyclic voltammetry (CV)

Differential-pulse voltammetry (DPV)

17β- estradiol

17α-ethnylestradiol

Michaelis Menten constant

Hydroxylation.

Development of electrochemical ZnSe Quantam dots biosensors for low-level detection of 17β-Estradiol estrogenic endocrine disrupting compound

Jijana, Abongile Nwabisa

January 2010

Magister Scientiae - MSc / The main thesis hub was on development of two electrochemical biosensors for the determination of 17β-estradiol-estradiol: an estrogenic endocrine disrupting compound. Endocronology have significantly shown that the endocrine disruptors contribute tremendously to health problems encountered by living species today, problems such as breast cancer, reproductive abnormalities, a decline in male population most significant to aquatic vertebrates, reduced fertility and other infinite abnormalities recurring in the reproductive system of mostly male species. The first biosensor developed for the detection of 17β-estradiol-estradiol endocrine disrupting compound; consisted of an electro-active polymeric 3-mercaptoprorionic acid capped zinc selenide quantum dots cross linked to horseradish peroxidase (HRP) enzyme as a bio-recognition element. The second biosensor developed was comprised of cysteamine self assembled to gold electrode, with 3-mercaptopropionic acid capped zinc selenide quantum dots cross linked to cytochrome P450-3A4 (CYP3A4) enzyme in the presence of 1-ethyl-3-(3- dimethylaminopropyl)carbodiimide hydrochloride and succinimide. / South Africa

Electrochemical biosensors

Cytochrome P450-3A4 (CYP3A4)

Horseradish peroxidase (HRP)

ZnSe quantum dots

Conducting polymers

Cyclic voltammetry (CV)

Differential-pulse voltammetry (DPV)

17- estradiol

17α-ethnylestradiol

Michaelis Menten constant

Hydroxylation