Impedance‐Based DNA Biosensor Employing Molecular Beacon DNA as Probe and Thionine as Charge Neutralizer

In this paper, we present an impedance‐based DNA biosensor using thionine intercalation to amplify DNA hybridization signal. Beacon single‐stranded DNA (ssDNA) probe and mercaptoacetic acid were self‐assembled onto a Au electrode by forming Au? S bonds. These beacon ssDNAs were hybridized with the complementary sequences around the loop structure. Then thionine was intercalated into the double‐stranded DNA (dsDNA) immobilized on the Au electrode surface. Due to the neutralization of the negative charges of dsDNA by the intercalated thionine, the electronic transfer resistance (R_et) of the DNA modified Au electrode was significantly diminished. Herein, the decreased value of R_et resulted from the thionine intercalating into dsDNA was employed as the hybridization signal. SDS was used to reduce the unspecific adsorption between ssDNA and thionine. Several experimental conditions, including the surface coverage of ssDNA probe on Au electrode, the hybridization temperature and time were all optimized. Moreover, the hybridization reactions of the unstructured linear ssDNA probe and the structured beacon ssDNA probe with their complementary sequences were compared in this work. The sensitivity of the presented DNA biosensor highlighted that the intercalation of thionine into dsDNA was an efficient approach to amplify the hybridization signal using impedance detection technique. Additionally, in this DNA biosensing protocol, beacon ssDNA has a good ability to distinguish target DNA sequences. This results in a higher specificity than using traditional unstructured DNA probe.     

Label‐Free and Label Based Electrochemical Detection of Hybridization by Using Methylene Blue and Peptide Nucleic Acid Probes at Chitosan Modified Carbon Paste Electrodes

A chitosan modified carbon paste electrode (ChiCPE) based DNA biosensor for the recognition of calf thymus double stranded DNA (dsDNA), single stranded DNA (ssDNA) and hybridization detection between complementary DNA oligonucleotides is presented. DNA and oligonucleotides were electrostatically attached by using chitosan onto CPE. The amino groups of chitosan formed a strong complex with the phosphate backbone of DNA. The immobilized probe could selectively hybridize with the target DNA to form hybrid on the CPE surface. The detection of hybridization was observed by using the label‐free and label based protocols. The oxidation signals of guanine and adenine greatly decreased when a hybrid was formed on the ChiCPE surface. The changes in the peak currents of methylene blue (MB), an electroactive label, were observed upon hybridization of probe with target. The signals of MB were investigated at dsDNA modified ChiCPE and ssDNA modified ChiCPE and the increased peak currents were observed, in respect to the order of electrodes. The hybridization of peptide nucleic acid (PNA) probes with the DNA target sequences at ChiCPE was also investigated. Performance characteristics of the sensor were described, along with future prospects.     

Determination of DNA Hypermethylation Using Anti‐cancer Drug‐Temozolomide

An electrochemical drug‐DNA biosensor was developed for the detection of interaction between the anti‐cancer drug, Temozolomide (TMZ), and DNA sequences by using Differential Pulse Voltammetry at the graphite electrode surfaces. TMZ is a pro‐drug and an alkylating agent that crosses the blood‐brain barrier, so it is mainly used for brain cancers treatment. In this study, we aim to develop a‐proof‐of‐concept study to investigate the effect of TMZ on formerly methylated DNA sequences since TMZ shows its anti‐cancer activity by methylating the DNA. Interaction between TMZ and DNA causes localized distortion of DNA away from an idealized B‐form, resulting in a wider major groove and greater steric accessibility of functional groups in the base of the groove. According to the results, TMZ behaves as a ‘hybridization indicator’ because of its different electrochemical behavior to different strands of DNA. After interaction with TMZ, hybrid (double stranded DNA‐dsDNA) signals decreased dramatically whereas probe (single stranded DNA‐ssDNA) and control signals remain almost unchanged. The signal differences enabled us to distinguish ssDNA and dsDNA without using a label or tag. It is the first study to demonstrate the interaction between the TMZ and dsDNA created from probe and target. We use specific oligonucleotides sequences instead of using long dsDNA sequences.     

Investigation of Metal Ion Effect on Specific DNA Sequences and DNA Hybridization

In this article, we investigated the sequence specific interaction of single (ssDNA) and double stranded (dsDNA) with silver ions (Ag⁺) with electrochemical methods. We, for the first time, examined the effect of base sequences, base content and physiochemical properties of different DNA sequences on interaction with Ag⁺ in detail. We used different base contents to show how the composition of nucleic acid influences the electrochemical signals. We first immobilized ssDNA probes on bare graphite electrodes. Then, we showed the sequence effect on oxidation signals of AgDNA complex by sensing Ag⁺ to the probe coated surfaces to interact with different ssDNA sequences. Furthermore, we investigated the effect of Ag⁺ on dsDNA. We measured the oxidation signals obtained from Ag⁺‐ssDNA and Ag⁺‐dsDNA complex at approximately 0.2 V and 1.0 V (vs Ag/AgCl), respectively with Differential Pulse Voltammetry (DPV). We showed that the oxidation signals of the AgDNA complex obtained from dsDNA‐modified electrodes is higher than the electrodes modified with ssDNA. More importantly, we showed that Ag⁺‐ssDNA and Ag⁺ ion‐dsDNA exhibit different electrochemical behaviors.     

Low‐Background,Highly Sensitive DNA Biosensor by Using an Electrically Neutral Cobalt(II) Complex as the Redox Hybridization Indicator

An electrically neutral cobalt complex, [Co(GA)₂(phen)] (GA=glycollic acid, phen=1,10‐phenathroline), was synthesized and its interactions with double‐stranded DNA (dsDNA) were studied by using electrochemical methods on a glassy carbon electrode (GCE). We found that [Co(GA)₂(phen)] could intercalate into the DNA duplex through the planar phen ligand with a high binding constant of 6.2(±0.2)×10⁵ M ^?1. Surface studies showed that the cobalt complex could electrochemically accumulate within the modified dsDNA layer, rather than within the single‐stranded DNA (ssDNA) layer. Based on this feature, the complex was applied as a redox‐active hybridization indicator to detect 18‐base oligonucleotides from the CaMV35S promoter gene. This biosensor presented a very low background signal during hybridization detection and could realize the detection over a wide kinetic range from 1.0×10^?14 M to 1.0×10^?8 M , with a low detection limit of 2.0 fM towards the target sequences. The hybridization selectivity experiments further revealed that the complementary sequence, the one‐base‐mismatched sequence, and the non‐complementary sequence could be well‐distinguished by the cobalt‐complex‐based biosensor.     

Voltammetric Studies on the Recognition of a Copper Complex to Single‐ and Double‐Stranded DNA and Its Application in Gene Biosensor

A mixed‐ligands copper complex [Cu(phendione)(DAP)]SO₄ (phendione=1,10‐phenanthroline‐5,6‐dione, DAP=2,3‐diaminophenazine) was synthesized. Cyclic voltammetry showed that the complex underwent an obvious decrease of redox peak currents and positive shift of formal potential after interaction with double‐stranded DNA (dsDNA), suggesting that the copper complex behaved as a typical metallointercalator for dsDNA, The recognition properties of the copper complex to single‐stranded DNA (ssDNA) and dsDNA were assessed using surface‐based electrochemical methods and the results suggested that the complex had obviously different redox signals at ssDNA and dsDNA modified electrodes. The copper complex was further used as an electroactive indicator for the detection of cauliflower mosaic virus (CaMV) 35S promoter gene.     

Label‐Free Detection of Nanomolar Unmodified Single‐ and Double‐Stranded DNA by Using Surface‐Enhanced Raman Spectroscopy on Ag and Au Colloids

Unlabelled single‐ and double‐stranded DNA (ssDNA and dsDNA, respectively) has been detected at concentrations ≥10^?9 M by surface‐enhanced Raman spectroscopy. Under appropriate conditions the sequences spontaneously adsorbed to the surface of both Ag and Au colloids through their nucleobases; this allowed highly reproducible spectra with good signal‐to‐noise ratios to be recorded on completely unmodified samples. This eliminated the need to promote absorption by introducing external linkers, such as thiols. The spectra of model ssDNA sequences contained bands of all the bases present and showed systematic changes when the overall base composition was altered. Initial tests also showed that small but reproducible changes could be detected between oligonucleotides with the same bases arranged in a different order. The spectra of five ssDNA sequences that correspond to different strains of the Escherichia coli bacterium were found to be sufficiently composition‐dependent so that they could be differentiated without the need for any advanced multivariate data analysis techniques.     

An Electrochemical DNA Sensor Based on Electrodepositing Aluminum Ion Films on Stearic Acid‐Modified Carbon Paste Electrode and Its Application for the Detection of Specific Sequences Related to Bar Gene and CP4 Epsps Gene

An electrochemical DNA biosensor was fabricated by immobilizing DNA probe on aluminum ion films that were electrodeposited on the surface of the stearic acid‐modified carbon paste electrode (CPE). DNA immobilization and hybridization were characterized with cyclic voltammetry (CV) by using methylene blue (MB) as indicator. MB has a couple of well‐defined voltammetric redox peaks at the CPE. The currents of redox peaks of MB decreased after depositing aluminum ion films on the CPE (Al(III)/CPE) and increased dramatically after immobilizing DNA probe (ssDNA/Al(III)/CPE). Hybridization of DNA probe led to a marked decrease of the peak currents of MB, which can be used to detect the target single‐stranded DNA. The conditions for the preparation of Al(III)/CPE, and DNA immobilization and hybridization were optimized. The specific sequences related to bar transgene in the transgenic corn and the PCR amplification of CP4 epsps gene from the sample of transgenic roundup ready soybean were detected by differential pulse voltammetry (DPV) with this new electrochemical DNA biosensor. The difference between the peak currents of MB at ssDNA/Al(III)/CPE and that at hybridization DNA modified electrode (dsDNA/Al(III)/CPE) was applied to determine the specific sequence related to the target bar gene with the dynamic range comprised between 1.0×10^?7 mol/L to 1.0×10^?4 mol/L. A detection limit of 2.25×10^?8 mol/L of oligonucleotides can be estimated.     

5‐(Pyren‐1‐yl)uracil as a Base‐Discriminating Fluorescent Nucleobase in Pyrrolidinyl Peptide Nucleic Acids

A pyrene‐labeled uridine (U^Py) monomer for a pyrrolidinyl peptide nucleic acid with an alternating proline/2‐aminocyclopentanecarboxylic acid backbone (acpcPNA) was synthesized and incorporated into the PNA. The U^Py base in acpcPNA could specifically recognize the base A in its complementary DNA strand as determined by thermal denaturation (T_m) experiments. The fluorescence of the U^Py‐containing single‐stranded acpcPNA was very weak in aqueous buffer. In the presence of a complementary DNA target, the fluorescence was enhanced significantly (2.7–41.9 folds, depending on sequences). The fluorescence enhancement was specific to the pairing between U^Py and dA, making the U^Py‐modified acpcPNA useful as a hybridization‐responsive fluorescence probe for DNA‐sequence determination.     

Direct Detection of DNA and DNA‐Ligand Interaction by Impedance Spectroscopy

In this work we present an impedimetric detection system for DNA‐ligand interactions. The sensor system consists of thiol‐modified single‐stranded DNA chemisorbed to gold. Impedance measurements in the presence of the redox system ferri‐/ferrocyanide show an increase in charge transfer resistance (R_ct) after hybridisation of a complementary target. Different amounts of capture strands, used for gold electrode modification, result in surface coverages between 3 and 15 pmol/cm² ssDNA. The relative change in R_ct upon hybridisation increases with increasing amount of capture probe on the electrode from 1.5‐ to 4.5‐fold. Impedimetric detection of binding events of a metal‐intercalator ([Ru(phen)₃]²⁺) and a groove binder (spermine) to double‐stranded DNA is demonstrated. Binding of [Ru(phen)₃]²⁺ and spermine exhibits a decrease in charge transfer resistance. Here, the ligand’s interaction leads to electrostatic shielding of the negatively charged DNA backbone. The impedance changes have been evaluated in dependence on the concentration of both DNA binders. Furthermore, the association of a single‐stranded binding protein (SSBP) is found to cause an increase in charge transfer resistance only when incubated with single‐stranded DNA. The specific binding of an anti‐dsDNA antibody to the dsDNA‐modified electrode surface decreases in contrast the interfacial impedance.     

Direct Electrochemical Oxidation of DNA on Polycrystalline Gold Electrodes

Electrochemical CV and SWV studies were performed with double stranded DNA from salmon testes (dsDNA) and single stranded DNAs, containing 25 nucleotides (ssDNA) directly adsorbed at polycrystalline Au electrodes. A distinct oxidation peak at +730 mV (SWV, scan rate 0.248 V s^?1) or at +730 – +780 mV (CV, scan rate from 0.3 to 1 V s^?1) was obtained with DNA‐modified Au electrodes after a time‐dependent prepolarization step at a positive potential value, i.e., at +500 mV (vs. Ag|AgCl), performed with the DNA‐modified Au electrodes dipped in a blank buffer solution. No electrochemical activity was detected when ssDNA, containing no guanines, was used for adsorptive modification of the Au electrodes. Electrochemical impedance measurements registered a possible reorganization of the adsorbed DNA layer in the course of the prepolarization, accompanied by decreasing in‐phase impedance. The results enable us to relate the oxidation process observed at the DNA‐modified Au electrodes with the oxidation of guanine residues in DNA.     

Rapid and sensitive DNA target detection using enzyme amplified electrochemical detection based on microchip

A rapid and sensitive DNA targets detection using enzyme amplified electrochemical detection (ED) based on microchip was described. We employed a biotin‐modified DNA, which reacted with avidin‐conjugated horseradish peroxidase (avidin–HRP) to obtain the HRP‐labeled DNA probe and hybridized with its complementary target. After hybridization, the mixture containing dsDNA‐HRP, excess ssDNA‐HRP, and remaining avidin–HRP was separated by MCE. The separations were performed at a separation voltage of +1.6 kV and were completed in less than 100 s. The HRP was used as catalytic labels to catalyze H₂O₂/o‐aminophenol reaction. Target DNA could be detected by the HRP‐catalyzed reduction with ED. With this protocol, the limits of quantification for the hybridization assay of 21‐ and 39‐mer DNA fragments were of 8×10^?12 M and 1.2×10^?11 M, respectively. The proposed method has been applied satisfactorily in the analysis of Escherichia coli genomic DNA. We selected the detection of PCR amplifications from the gene of E. coli to test the real applicability of our method. By using an asymmetric PCR protocol, we obtained ssDNA targets of 148 bp that could be directly hybridized by the single‐stranded probe and detected with ED.     

Rolling‐Circle Amplification Detection of Thrombin Using Surface‐Enhanced Raman Spectroscopy with Core‐Shell Nanoparticle Probe

An ultrasensitive surface‐enhanced Raman spectroscopy (SERS) sensor based on rolling‐circle amplification (RCA)‐increased “hot‐spot” was developed for the detection of thrombin. The sensor contains a SERS gold nanoparticle@Raman label@SiO₂ core‐shell nanoparticle probe in which the Raman reporter molecules are sandwiched between a gold nanoparticle core and a thin silica shell by a layer‐by‐layer method. Thrombin aptamer sequences were immobilized onto the magnetic beads (MBs) through hybridization with their complementary strand. In the presence of thrombin, the aptamer sequence was released; this allowed the remaining single‐stranded DNA (ssDNA) to act as primer and initiate in situ RCA reaction to produce long ssDNAs. Then, a large number of SERS probes were attached on the long ssDNA templates, causing thousands of SERS probes to be involved in each biomolecular recognition event. This SERS method achieved the detection of thrombin in the range from 1.0×10^?12 to 1.0×10^?8 M and a detection limit of 4.2×10^?13 M , and showed good performance in real serum samples.     

Electrochemical DNA Biosensor Based on Partially Reduced Graphene Oxide Modified Carbon Ionic Liquid Electrode for the Detection of Transgenic Soybean A2704‐12 Gene Sequence

In this work a partially reduced graphene oxide (p‐RGO) modified carbon ionic liquid electrode (CILE) was prepared as the platform to fabricate an electrochemical DNA sensor, which was used for the sensitive detection of target ssDNA sequence related to transgenic soybean A2704‐12 sequence. The CILE was fabricated by using 1‐butylpyridinium hexafluorophosphate as the binder and then p‐RGO was deposited on the surface of CILE by controlling the electroreduction conditions. NH₂ modified ssDNA probe sequences were immobilized on the electrode surface via covalent bonds between the unreduced oxygen groups on the p‐RGO surface and the amine group at the 5′‐end of ssDNA, which was denoted as ssDNA/p‐RGO/CILE and further used to hybridize with the target ssDNA sequence. Methylene blue (MB) was used as electrochemical indicator to monitor the DNA hybridization. The reduction peak current of MB after hybridization was proportional to the concentration of target A2704‐12 ssDNA sequences in the range from 1.0×10^?12 to 1.0×10^?6 mol/L with a detection limit of 2.9×10^?13 mol/L (3σ). The electrochemical DNA biosensor was further used for the detection of PCR products of transgenic soybean with satisfactory results.     

Supramolecular Reassembly of Self‐Exfoliated Ionic Covalent Organic Nanosheets for Label‐Free Detection of Double‐Stranded DNA

Ionic covalent organic nanosheets (iCONs), a member of the two‐dimensional (2D) nanomaterials family, offer a unique functional platform for a wide range of applications. Herein, we explore the potential of an ethidium bromide (EB)‐based covalent organic framework ( EB‐TFP ) that self‐exfoliates in water resulting in 2D ionic covalent organic nanosheets ( EB‐TFP‐iCONs ) for the selective detection of double‐stranded DNA (dsDNA). In an aqueous medium, the self‐exfoliated EB‐TFP‐iCONs reassemble in the presence of dsDNA resulting in hybrid EB‐TFP‐iCONs‐DNA crystalline nanosheets with enhanced fluorescence at 600 nm. Detailed steady‐state and time‐resolved emission studies revealed that the reassembly phenomenon was highly selective for dsDNA when compared to single‐stranded DNA (ssDNA), which allowed us to use the EB‐TFP‐iCONs as a 2D fluorescent platform for the label‐free detection of complementary DNA strands.     

Single‐Walled Carbon Nanotubes Modified Gold Electrodes as an Impedimetric DNA Sensor

A gold surface modified with a self‐assembled monolayer of 11‐amino‐1‐undecanethiol (AUT) was used for the covalent immobilization of oxidized single‐walled carbon nanotubes (SWNTs). The as‐described SWNTs‐modified substrate was subsequently used to attach single‐stranded deoxyribonucleic acid (ssDNA) used as a substrate for DNA hybridization. Electrochemical impedance spectroscopy measurements were performed to follow the DNA hybridization process by using the redox couple [Fe(CN)₆]^3−/4− as a marker ion. Specifically, changes in charge transfer resistance obtained from the Nyquist plots were used as the sensing parameter of DNA hybridization. The substrate sensitivity towards changes in target DNA concentration, its selectivity toward different DNA sequences and its reusability are successfully demonstrated in this report.     

Electrochemical Quantitative Analysis of Nucleic Acids Using β‐Cyclodextrin Modified Gold Electrode

We present an electrochemical biosensor for the analysis of nucleic acids upon hybridization on the β‐cyclodextrin (β‐CD)‐modified gold electrode. The strategy is based on the following: The 5’‐ferrocene‐labeled single stranded capture probe DNA (5’‐fc‐ss‐DNA) was incorporated into the cavity of thiolated β‐CD which was immobilized on the surface of gold electrode. After hybridization of complementary target DNA, hybridized double stranded DNA (ds‐DNA) was released from the cavity of β‐CD. The difference of electrochemical properties on the modified gold electrode was characterized by cyclic voltametry and surface plasmon resonance. We successfully applied this method to the investigation of the sensor responses due to hybridization on various concentrations of applied target DNA. As a result, the label‐free electrochemical DNA sensor can detect the target DNA with a detection limit of 1.08 nM. Finally, our method does not require either hybridization indicators or other signalling molecules such as DNA intercalaters which most of electrochemical hybridization detection systems require.     

New Electroactive Hybridization Indicators 2‐Phthalimido‐N‐Substitutedphenylethanesulfonamide Derivatives for Biosensor Applications: Ring Substituent Effect on Interaction between Compound and DNA

In this work, an electrochemical DNA‐based sensor was developed for the detection of the interaction between the anticonvulsant compounds 2‐phthalimido‐N‐substituted phenylethanesulfonamides (PMPES‐derivatives) and 24‐mer short DNA sequences by using differential pulse voltammetry (DPV) based on both compound and guanine oxidation signals at the renewable carbon graphite electrode (CGE) surface. The influence of compounds on DNA showed differences depending on the nature and position of the substituent on the N‐phenyl ring. Compounds bearing 3‐methoxy, 4‐chloro and 2,6‐dimethyl substituents bind to single stranded probe DNA more strongly than the other derivatives of PMPES. Thus, these compounds were evaluated for use as an electrochemical hybridization label (indicator).     

Coordination Polymer Nanobelts as an Effective Sensing Platform for Fluorescence‐enhanced Nucleic Acid Detection

In this communication, the application of coordination polymer nanobelts (CPNs) assembled from H₂PtCl₆ and 3,3′,5,5′‐tetramethylbenzidine (TMB) are explored as an effective fluorescent sensing platform for nucleic acid detection for the first time. The suggested method has a high selectivity down to single‐base mismatch. DNA detection is accomplished by the following two steps: (1) CPN binds fluorecent dye‐labeled single‐stranded DNA (ssDNA) probe via both electrostatic attraction and π‐π stacking interactions between unpaired DNA bases and CPN. As a result, the fluorescent dye is brought into close proximity to CPN and substantial fluorescence quenching occurs due to photoinduced electron transfer from the nitrogen atom in CPN to the excited fluorophore. (2) The hybridization of adsorbed ssDNA probe with its target generates a double stranded DNA (dsDNA). The duplex cannot be adsorbed by CPN due to its rigid conformation and the absence of unpaired DNA bases, leading to an obvious fluorescence enhancement.

     

An Electrochemical Aptasensor for Detection of Thrombin based on Target Protein‐induced Strand Displacement

A sensitive electrochemical aptasensor for detection of thrombin based on target protein‐induced strand displacement is presented. For this proposed aptasensor, dsDNA which was prepared by the hybridization reaction of the immobilized probe ssDNA (IP) containing thiol group and thrombin aptamer base sequence was initially immobilized on the Au electrode by self‐assembling via Au? S bind, and a single DNA labeled with CdS nanoparticles (DP‐CdS) was used as a detection probe. When the so prepared dsDNA modified Au electrode was immersed into a solution containing target protein and DP‐CdS, the aptamer in the dsDNA preferred to form G‐quarter structure with the present target protein resulting that the dsDNA sequence released one single strand and returned to IP strand which consequently hybridized with DP‐CdS. After dissolving the captured CdS particles from the electrode, a mercury‐film electrode was used for electrochemical detection of these Cd²⁺ ions which offered sensitive electrochemical signal transduction. The peak current of Cd²⁺ ions had a good linear relationship with the thrombin concentration in the range of 2.3×10^?9–2.3×10^?12 mol/L and the detection limit was 4.3×10^?13 mol/L of thrombin. The detection was also specific for thrombin without being affected by the coexistence of other proteins, such as BSA and lysozyme.