A Label-Free Electrochemical Biosensing Approach for Modern Diagnostics Using Screen-Printed Electrodes

Grewal, Rehmat

January 2024

Electrochemical biosensors are renowned for their ability to detect a wide range of analytes in biological fluids for clinical diagnosis. The implementation of biomarkers in electrochemical biosensors for clinical diagnosis is essential for the specific and accurate diagnosis of the disease with high sensitivity and selectivity. Therefore, this thesis evaluates the challenges pertaining to the stability, reproducibility, and obtaining a low limit of detection for the internal/external biomarkers associated with two distinct electrochemical biosensors. The first study tackles the challenge of detecting low analyte concentrations in a label-free biosensor. It introduces an innovative label-free electrochemical biosensing method for the detection of glycosylated hemoglobin (HbA1c) and C-reactive protein (CRP) to predict Coronary Heart Disease (CHD) progression using tailored redox probes, proposing a dual biomarker biosensing platform for future research. Calibration curves reveal an LOD of 5 mg/mL in PBS (8) FeCN (II) and 6 mg/mL in SB for a linear range of 0 – 30 mg/mL of HbA1c. Similarly, an LOD of 0.007 mg/mL and 0.008 mg/mL in PBS (7.4) PcA-NO2 and SB, respectively, is reported for a linear range of 0 – 0.05 mg/mL of CRP. The second study focuses on stabilizing a biomolecule-free sensor for the ultra-low detection of Δ9-tetrahydrocannabinol (THC) in roadside testing. Pre-depositing THC, an external biomarker for drug-impaired driving, onto the biosensor's working electrode enhances its interaction with analytes. However, THC's oxidative nature compromises sensor stability during manufacturing. Consequently, optimal electrode storage conditions were explored, indicating frozen storage as ideal for up to six months, effectively preventing THC oxidation at -18°C, while degradation occurs at 4°C. Modified electrodes stored under optimal conditions exhibit improved calibration curves when exposed to various THC samples. / Thesis / Master of Applied Science (MASc) / An electrochemical biosensor is a sensing device with the ability to detect biological species via the transduction of a specific biological event into electrochemical signals. These sensors are extremely useful for the detection of analytes in biological fluids for clinical diagnostics, to determine the presence or absence of diseases. This manuscript addresses the challenges associated with the stability, reproducibility, and the low limits of detection associated with screen-printed carbon electrodes used in electrochemical biosensing. Subsequently, due to the strong correlation between glycated hemoglobin (HbA1c) and C-reactive protein (CRP) to connote the risk of contracting coronary heart disease (CHD), the manuscript presents a novel label-free electrochemical biosensing method for the detection of HbA1c and CRP with low detection limits. Secondly, the manuscript identifies ambient storage conditions for the long-term stability of a biomolecule-free sensing device for the roadside detection of ultra-low concentrations of Δ9-tetrahydrocannabinol (THC).

Electrochemical

Label-free

Modern Diagnostics

Differential Pulse Voltammetry

Glycated Hemoglobin (HbA1c)

C-Reactive Protein (CRP)

Δ9-tetrahydrocannabinol (THC)

Square Wave Voltammetry

Coronary Heart Disease (CHD)

Stability

Diagnostic Accuracy of Protein Glycation Sites in Long-Term Controlled Patients with Type 2 Diabetes Mellitus and Their Prognostic Potential for Early Diagnosis

Spiller, Sandro, Li, Yichao, Blüher, Matthias, Welch, Lonnie, Hoffmann, Ralf

06 April 2023

Current screening tests for type 2 diabetes mellitus (T2DM) identify less than 50% of undiagnosed T2DM patients and provide no information about how the disease will develop in prediabetic patients. Here, twenty-nine protein glycation sites were quantified after tryptic digestion of plasma samples at the peptide level using tandem mass spectrometry and isotope-labelled peptides as internal standard. The glycation degrees were determined in three groups, i.e., 48 patients with a duration of T2DM exceeding ten years, 48 non-diabetic individuals matched for gender, BMI, and age, and 20 prediabetic men. In long-term controlled diabetic patients, 27 glycated peptides were detected at significantly higher levels, providing moderate diagnostic accuracies (ACCs) from 61 to 79%, allowing a subgrouping of patients in three distinct clusters. Moreover, a feature set of one glycated peptides and six established clinical parameters provided an ACC of 95%. The same number of clusters was identified in prediabetic males (ACC of 95%) using a set of eight glycation sites (mostly from serum albumin). All patients present in one cluster showed progression of prediabetic state or advanced towards diabetes in the following five years. Overall, the studied glycation sites appear to be promising biomarkers for subgrouping prediabetic patients to estimate their risk for the development of T2DM.

info:eu-repo/classification/ddc/610

ddc:610

Neue biosensorische Prinzipien für die Hämoglobin-A1c Bestimmung

Stöllner, Daniela

January 2002

Hämoglobin-A1c (HbA1c) ist ein Hämoglobin (Hb)-Subtypus, der durch nicht-enzymatische Glykierung des N-terminalen Valinrestes der Hämoglobin-beta-Kette entsteht. Das gemessene Verhältnis von HbA1c zum Gesamt-Hämoglobin (5-20 % bei Diabetikern) repräsentiert den Mittelwert der Blutglucosekonzentration über einen zweimonatigen Zeitraum und stellt zur Beurteilung der diabetischen Stoffwechsellage eine Ergänzung zur Akutkontrolle der Glukosekonzentration dar.<br /> Ziel der vorliegenden Arbeit war es, einen amperometrischen Biosensor für die Bestimmung des medizinisch relevanten Parameters HbA1c zu entwickeln. Durch Selektion geeigneter Bioerkennungselemente und deren Immobilisierung unter Erhalt der Bindungsfunktion für die Zielmoleküle Hämoglobin bzw. HbA1c wurden spezifische, hochaffine und regenerationsstabile Sensoroberflächen geschaffen. Für die Entwicklung des HbA1c-Biosensors wurden zwei Konzepte - Enzymsensor und Immunosensor - miteinander verglichen. <br /> Die enzymatische Umsetzung von HbA1c erfolgte mit der Fructosylamin Oxidase (FAO) aus Pichia pastoris N 1-1 unter Freisetzung von H2O2, welches sowohl optisch über eine Indikatorreaktion als auch elektrochemisch nach Einschluss der FAO in PVA-SbQ und Fixierung des Immobilisats vor einer H2O2-Elektrode nachgewiesen wurde. Die Kalibration des Enzymsensors mit der HbA1c-Modellsubstanz Fructosyl-Valin ergab Nachweisgrenzen, die ausserhalb des physiologisch relevanten HbA1c-Konzentrationsbereich lagen. Aus der Umsetzung von glykierten Peptiden mit einer nicht HbA1c analogen Aminosäurensequenz, z.B. Fructosyl-Valin-Glycin wurde zudem eine geringe HbA1c-Spezifität abgeleitet.<br /> Für den Immunosensor wurden zwei heterogene Immunoassay-Formate unter Verwendung von hochaffinen und spezifischen Antikörpern in Kombination mit Glucose Oxidase (GOD) als Markerenzym zum Nachweis von HbA1c untersucht. Beim indirekt-kompetitiven Immunoassay wurde anstelle des kompletten HbA1c-Moleküls das glykierte Pentapeptid Fructosyl-Valin-Histidin-Leucin-Threonin-Prolin (glkPP) als Kompetitor und Affinitätsligand immobilisiert und so eine regenerierfähige Oberfläche geschaffen. Beim Sandwich-Immunoassay wurde im ersten Schritt Gesamt-Hämoglobin an die mit Haptoglobin (Hp) modifizierte Festphase angereichert und im zweiten Schritt der gebundene HbA1c-Anteil nachgewiesen. <br /> Für die Konstruktion des HbA1c-Immunosensors wurden Affinitätsmatrizen durch Modifizierung von Cellulose-Dialysemembranen mit glkPP bzw. Hp hergestellt. Grundlegend studiert wurde die Aktivierung der Cellulose-Membranen mit 1,1'-Carbonyldiimidazol (CDI) und 1-Cyano-4-dimethylaminopyridintetrafluoroborat (CDAP) als Aktivierungsagenzien. Eine gerichtete Immobilisierung der Liganden wurde realisiert, indem glkPP über dessen C-Terminus (einzige Carboxylatgruppe) und Hp über dessen periodat-oxidiertem Kohlenhydratrest an die amino- oder hydrazidfunktionalisierte Membranen kovalent gekoppelt wurden. <br /> Mit dem Einsatz der glkPP- und Hp-modifizierten Membranen in der elektrochemischen Messzelle war erstmalig der biosensorische Nachweis von HbA1c möglich. Als Transduktor diente eine Pt-Elektrode, an der das von der GOD generierte H2O2 umgesetzt und ein mit der HbA1c-Konzentration korrelierendes Stromsignal erzeugt wurde. Die Immunosensoren zeigten Ansprechzeiten von 3 s. Mit dem Immunosensor auf Basis des indirekt-kompetitiven Testprinzips wurde eine Kalibrationskurve für HbA1c im Bereich von 0,25-30 &#181;g/ml (3,9-465 nM, CV 3-9 %) mit Assayzeiten von 60 min und mit dem Immunosensor im Sandwich-Format eine Kalibrationskurve im Bereich von 0,5-5 &#181;g/ml (7,8-78 nM; 5-50 % HbA1c vom Gesamt-Hb, CV 6-10 %, 3 h) aufgenommen. / Hemoglobin-A1c (HbA1c) is a hemoglobin subtype formed by non-enzymatic reaction of glucose with the N-terminus of the beta-polypeptide chains. As it reflects the glycemic status of diabetics over the preceding 8-12 weeks, the determination of HbA1c has become an established procedure in the management of diabetes mellitus. It is measured as the percentage of total hemoglobin. Up to 5 % HbA1c are considered as normal whereas in diabetic subjects it could be elevated from 5-20 %. In addition to amperometric biosensors for glucose self monitoring which have been successfully applied in diabetes management, biosensors for HbA1c would be an useful supplement for a comprehensive diabetes control. <br /> <br /> Objective of this work was to develop and compare amperometric biosensors for determination of HbA1c based on enzymatic and immunochemical methods. <br /> <br /> For the enzyme based HbA1c assay a novel fructosamine oxidase (FAO) derived from marine yeast Pichia pastoris, strain N1-1 was utilized. It recognizes and oxidatively degrades fructosyl-valine (FV) which corresponds to the glycated N-terminus of the beta-chain of HbA1c and therefore is regarded as a model compound for HbA1c. Hydrogen peroxide which is liberated by the FAO during FV conversion was indicated optically in a horseradish peroxidase (POD) coupled reaction and electrochemically. For the biosensor the FAO was embedded in polyvinyl alcohol-stylbazole (PVA-SbQ) and fixed it in front of a Pt-electrode. So far, the measuring range of FV did not cover the clinically relevant range of HbA1c. Low specificity was assumed since enzyme activity also was obtained with glycated peptides, e.g. fructosyl-valine-glycine, not corresponding to the glycated N-terminus of the hemoglobin-beta-chain.<br /> <br /> For the immunosensor two immunoassays formats - heterogeneous sandwich and heterogeneous competitive - were tested. The assays were designed as follows: The competitive immunoassay was based on the immobilized synthetic glycated pentapeptide fructosyl-valine-histidine-leucine-threonine-proline (glkPP) utilized as HbA1c analogue. The peptide has an amino acid sequence corresponding to the N-terminus of the hemoglobin beta-chains and is capable for competition together with the HbA1c of the sample for the amount of a glucose oxidase (GOD)-labelled anti-HbA1c antibody. In the sandwich-type assay haptoglobin (Hp), a natural hemoglobin binding molecule with antibody characteristic properties, was used as bioreceptor for enrichment of total hemoglobin onto the surface. In a subsequent step the HbA1c fraction was quantified by a GOD-labelled HbA1c specific antibody. <br /> <br /> Cellulose dialysis membrane was used as the solid support for immobilization of Hp and glkPP near the sensor surface. For activation of the membrane two reagents, 1,1&prime;-carbonyldiimidazole (CDI) and 1-cyano-4-dimethylamino pyridinium tetrafluoroborate (CDAP), were compared with respect to the degree of activation and coupling efficiency. Site-directed immobilization of Hp and glkPP was achieved by coupling Hp via its carbohydrate residue and glkPP via its C-terminus to the activated membrane using a bis-amine or bis-hydrazide spacer. <br /> <br /> The affinity membranes were placed in front of a modified Clark-type hydrogen peroxide electrode in an electrochemical measuring cell and HbA1c analysis was carried out within the stirred cell. Detection of the bound GOD-label was achieved by measurement of the electrocatalytic oxidation of hydrogen peroxide at +600 mV vs. Ag/AgCl. The indication was done in only 3 s. For the competitive principle a typical inhibition curve with a linear range between 0,25-30 &#181;g/ml (3,9-465 nM, CV 3-9 %, 60 min per sample) HbA1c was obtained. Due to the high functional stability of the peptide multiple regeneration of the affinity surface was possible without loss of binding capacity. With the sandwich assay configuration the clinically relevant range could easily be covered (calibration curve: 5-50 % HbA1c corresponding to 7,8-78 nM, CV 6-10 %, 3 h per sample).

Life sciences

Análise do papel da metformina na via insulínica, não-insulínica e inflamatória

Peixoto, Leonardo Gomes

28 July 2015

Fundação de Amparo a Pesquisa do Estado de Minas Gerais / Doutor em Genética e Bioquímica / CHAPTER II: Purpose: We performed a meta-analysis of randomized trials to assess the effect of metformin on inflammatory markers and metabolic parameters in subjects with diabetes. Methods: We performed comprehensive searches on NCBI, Cochrane, Science Direct databases from 1966 to Jun of 2015. We included randomized trials of at least 4 weeks duration that compared groups with diabetes before and after the treatment with metformin or metformin plus other drugs, and evaluated body mass index, blood glucose, HbA1c and inflammatory parameters such as C-reactive protein, tumor necrosis factor and adiponectin. Results: Pooled results of the 26 trials, with 1760 participants at the end of treatment reduce BMI in 0.9% p=0,0043, as well as, decrease of blood glucose level [SMD -0,411 mg/dL, 95%CI -0,463 to -0,369, I2= 56.62%], HbA1c [SMD -0.479%, 95%CI -0,568 to -0,390, I2= 55.02%], CRP levels [SMD -0,274mg/dL, 95%CI -0,419 to -0,129, I2= 72.78%], TNFα concentration [SMD -0,103pg/ml, 95%CI -0,514 to 0,309, I2= 87.67%] and increase of adiponectin [SMD 0,171μg/ml, 95%CI 0,098 to 0,440, I2= 81.09%] compared with pretreatment. Conclusion: The long-treatment with metformin monotherapy or metformin plus other drugs improves metabolic parameters and induced changes in inflammatory markers in diabetic subject. CHAPTER III: Background: Metformin increases insulin sensitivity by decreasing hepatic glucose production and increasing glucose disposal in skeletal muscle. However, modulation of inflammatory response and CaMKKβ/AMPK/Myosin V activation in gastrocnemius muscle by metformin treatment has not been demonstrated in hypoinsulinemic diabetic rats. Objective: The present study investigated how the metformin improve insulin sensitivity in skeletal muscle of hypoinsulinemic diabetic rats. Methods: Diabetes was induced by streptozotocin (45 mg/kg, intraperitoneally) 10 days prior treatments. On 11th day, diabetic rats were treated with metformin (500 mg/kg, oral gavage), insulin (2U at 08:00 h and 4U at 17:00 h, subcutaneously) or untreated. After 20 days, glycemia was measured and insulin sensitivity was determined by KITT. Serum Insulin, GLUT4, IRSthr, inflammatory markers (NF-κB, IκB, TNF-α and p-JNK) and CAMKK, AMPK and Myosin V in gastrocnemius muscle were determined by ELISA. Results: As expected, insulin and metformin improved the insulin sensitivity. Besides, metformin treatment promoted reduction in inflammatory response mediated by NF-κB, IκB, TNF-α and p-JNK, and that was accompanied by increased CaMKKβ/AMPK/Myosin V/GLUT4 pathway activity in gastrocnemius muscle of diabetic rats. Conclusion: Our findings suggest that metformin induces significant reductions in several inflammatory markers in skeletal muscle of diabetic rats. Metformin-induced increase in CaMKKβ/AMPK/Myosin V/GLUT4 pathway activity was associated with higher insulin sensitivity. CHAPTER IV: Diabetes is characterized by a proinflammatory state which can activate TLR2 and TLR4, and these receptors could induce NF-κB and JNK activation in skeletal muscle. In this study, we investigated the inflammatory and apoptotic signaling pathways triggered by TLRs/NF-κB and JNK activation in skeletal muscle of diabetic rats treated with metformin before and after an insulin tolerance test. Metformin treatment decreased p-JNK and NF-κB, and increased IκB concentrations. This attenuation leads to a decrease of TNFα and CXCL1/KC, and an increase of p-AMPK, BAX and Bcl2 concentration. Furthermore, KITT revealed an improvement of the insulin sensitivity in the diabetic rats treated with metformin. In addition, metformin was not capable of attenuating the changes in the inflammatory pathway triggered by insulin injection as the increase of TNFα and TLR4 in metformin treated rats, and IκB, CXCL1/KC, TNFα and p-AMPK increase in the untreated group. Taken together, these results point out that metformin may attenuate the activation of the inflammatory pathway TLRs/NF-κB/TNFα/CXCL1/KC and the apoptotic signaling BAX/Bcl2/p-JNK, which could be accompanied by a reduction of the inflammatory damage caused by hyperglycemia and an improvement of insulin sensitivity in diabetic rats.

C-reactive proteins

Tumor necrosis factor (TNFα

Adiponectin

Blood glucose level

Glycated hemoglobin (HbA1c)

Inflammatory pathway

Insulin sensitivity

Insulin pathway

Hypoinsulinemic rat

Insulin resitance

Toll like receptor

NF-κ

B/Iκ

B pathway

skeletal muscle

Músculo esquelético

Sensibilidade insulínica

Captação de glicose

CNPQ::CIENCIAS BIOLOGICAS::GENETICA