Electrochemical DNA biosensor based on gold nanorods for detecting hepatitis B virus

Shakoori, Zahra; Salimian, Samaneh; Kharrazi, Sharmin; Adabi, Mahdi; Saber, Reza

doi:10.1007/s00216-014-8303-9

Cited by 72 publications

(19 citation statements)

References 24 publications

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“…These CHIT‐CNF modified electodes presented some important advantages such as, being cost‐effective, easy‐to use, and not requiring any time consuming modification step, or any sophisticated instruments with a special training. Consequently, it is indicating that the CHIT‐CNF matrix can be used as a selective and sensitive platform for monitoring of indicator‐free DNA hybridization without using any external electroactive indicators, such as methylene blue , or daunomycin , ferrocenecarboxylic acid , [Co(phen) 3 ] 3+ . This advanced biosensor technology can be further used in the application of detection of genetic, or inherited diseases based on PCR samples, and monitoring of protein, toxins, drugs.…”

Section: Discussionmentioning

confidence: 99%

Chitosan‐carbon Nanofiber Modified Single‐use Graphite Electrodes Developed for Electrochemical Detection of DNA Hybridization Related to Hepatitis B Virus

Ekşin

Erdem

2016

Electroanalysis

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1IntroductionHepatitis Bv irus (HBV) infection is am ajor worldwide public health problem with acute and chronic clinical consequences.H BV is one of the causative agents of viral hepatitis,t hat may lead to chronic hepatitis, cirrhosis, and primaryl iver cancer. Accordingt ot he WHO,m ore than 240 million people have chronic (long-term) liver infections and moret han 780 000 people die every year due to the consequences of Hepatitis B[ 1].T he goal of antiviral therapyofchronic hepatitis Bisthe sustained suppression or loss of detectable HBV DNAi ns erum, which is detected by nucleic acid amplification and hybridization techniques [2].T hereh as been ag rowing interest for fast, reliable and ultrasensitive biosensors for detection of trace amounts of DNA [ 3].E lectrochemical detection systemsa re amendablet om iniaturization using well established microfabrication techniques.Among the availablet echniques, electrochemical based biosensors have been one of the mosts uccessful ones that are offering less expensive,f aster,s impler, portable,a ccurate,f lexible for multiplexing and label free detectiono f aw ide range of proteins,n ucleic acids,e nzymes and other biomolecules.I na ddition, they are promising candidate for advanced biosensor platform [4,5].A fter the implementation of single and multi-walled carbonn anotubes (CNTs)[ 6],c arbonn anofibers (CNFs) [7,8],g raphene [9],g old nanowires,n anostructures [10] and other inorganic wires [11] to sensort echnologyh ave tremendously improved the sensitivity and detection limits for proteins and nucleic acids etc. [12].T he constructedb iosensors can be employed with conventional electrochemical techniques;s uch as cyclic voltammetry( CV) [13],d ifferential pulse voltammetry (DPV)[ 14],a nd electrochemicali mpendence spectroscopy (EIS) [14-17].Among carbon nanomaterials,C NFs have excellent conductive and structural properties.C NFs with ah igh aspect ratio have advantages in both electricalc onductivity and providing as pecific surface area [18].C NFs are extremely attractive for development of novel sensor surfaces,a st hey provide such properties as high surface area, non-toxicity,a cceptable biocompatibility [19][20][21][22]. In addition,C NF is produced 100 timesl ower in cost than single walled carbon nanotubes [ 23].Chitosan (CHIT), ap olysaccharide,i st he N-deacetylated derivative of chitin,w hich has ah igh content of hydroxyl and amino groups alongits chains [24].I thas been widely used for the development of biosensors due to its properties;m echanical strength,p ore size,b iocompatibility,e xcellent membrane-forming ability,i on-transport and ion-exchange [25,26].Abstract:C hitosan (CHIT) and carbon nanofiber( CNF) modified pencil graphite electrodes (PGEs) were developed for the first time in the presents tudy for enhanced monitoring of DNAh ybridization.C HIT-CNF modified PGE, CHIT modified PGE and unmodified PGE were firstly characterized by scanninge lectronem icroscopy (SEM),a nd the electrochemical behaviour of each electrode was investigated b...

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Section: Discussionmentioning

confidence: 99%

Chitosan‐carbon Nanofiber Modified Single‐use Graphite Electrodes Developed for Electrochemical Detection of DNA Hybridization Related to Hepatitis B Virus

Ekşin

Erdem

2016

Electroanalysis

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“…The sequence of oligonucleotides was selected using basic local alignment search tool (BLAST) to have the least similarity to the human serum genome. To select these types of the DNA oligonucleotides, their spatial symmetry and thermodynamical aspects, which prevents them from screwing or bending when immobilized to the surface, were significant parameters, [18].…”

Section: The Fabrication Of Te-doped Zno Nwsmentioning

confidence: 99%

The highly sensitive impedimetric biosensor in label free approach for hepatitis B virus DNA detection based on tellurium doped ZnO nanowires

et al. 2019

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The highly sensitive impedimetric biosensor in label free approach for hepatitis B virus DNA (HPV DNA) detection based on tellurium doped ZnO nanowires was fabricated. The NWs were grown by hybrid thin film oxidation in the physical vapor deposition (PVD) mechanism. The morphology characterization of the synthesized NWs was performed by field emission scanning electron microscopy (FESEM) and the images demonstrated that the diameter and the length of the materialized NWs were around 50 nm and several micrometers, respectively. The high-resolution transmission electron microscopy (HRTEM) image indicated that the fabricated NWs were crystalline and their phase characterization was validated by the X-ray diffraction pattern (XRD pattern). The single-stranded DNA (ss DNA) probe was immobilized on the surface of the Te-ZnO NWs. The electrochemical impedance spectra (EIS) measurements showed high response sensitivity after hybridization with complementary oligonucleotides. The biosensor could distinguish complementary target from non-complementary and mismatch oligonucleotides. The HBV biosensor could respond to complementary target in the concentrations range from 1 pM to 1 μM. The limit of detection (LOD) of the biosensor was 0.1 pM. The stability of the HBV DNA biosensor was investigated and biosensor could show 95% of its initial responses after 8 weeks maintenance.

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“…Several nanostructured materials have been explored for the biomedical applications. The most commonly studied materials are based on carbon, silica, and metals in different shapes (i.e., spheres, tubes, and rods) (Adabi et al 2011, Ketabchi et al 2016, Shakoori et al 2015, Tavakol et al 2014. The toxicity and biocompatibility of these materials depends on several factors such as the size, surface area, functional groups, concentration, and dosage (Foldvari and Bagonluri 2008).…”

Section: Introductionmentioning

confidence: 99%

Biocompatibility and nanostructured materials: applications in nanomedicine

Adabi

Naghibzadeh²,

Adabi

et al. 2016

Artificial Cells, Nanomedicine, and Biotechnology

Self Cite

179

101

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There has been huge interest in applications of nanomaterials in biomedical science, including diagnosis, drug delivery, and development of human organs. Number of these nanomaterials has been already studied in human or at pre-clinical trial. There is a growing concern on potential toxicity and adverse effects of nanomaterials on human health, including lack of standard method of assessment of toxicology of these materials. Our investigation indicated that the bare and small nanoparticle have higher toxicity than modified and bulk materials, respectively. In addition, spherical nanoparticles have less toxicity than rod nanoparticles due to immune response of body.

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Electrochemical DNA biosensor based on gold nanorods for detecting hepatitis B virus

Cited by 72 publications

References 24 publications

Chitosan‐carbon Nanofiber Modified Single‐use Graphite Electrodes Developed for Electrochemical Detection of DNA Hybridization Related to Hepatitis B Virus

Chitosan‐carbon Nanofiber Modified Single‐use Graphite Electrodes Developed for Electrochemical Detection of DNA Hybridization Related to Hepatitis B Virus

The highly sensitive impedimetric biosensor in label free approach for hepatitis B virus DNA detection based on tellurium doped ZnO nanowires

Biocompatibility and nanostructured materials: applications in nanomedicine

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