Nanotechnology has emerged as a boon to the society with immense potential in varied area of research and our day-to-day life. The application of nanotechnology for the advancement of biosensor leads to an efficient n...Nanotechnology has emerged as a boon to the society with immense potential in varied area of research and our day-to-day life. The application of nanotechnology for the advancement of biosensor leads to an efficient nanobiosensor with miniature structure as compared to conventional biosensors. Nanobiosensors can be effectively used for sensing a wide variety of fertilizers, herbicide, pesticide, insecticide, pathogens, moisture, and soil pH. Taken together, proper and controlled use of nanobiosensor can support sustainable agriculture for enhancing crop productivity.展开更多
A wavelength-dependent three-dimensional(3D)superlocalization imaging method on gold nanoislands(GNIs)chip was developed as a supersensitive single-molecule thyroid-stimulating hormone(TSH)nanobiosensor.Scattered and ...A wavelength-dependent three-dimensional(3D)superlocalization imaging method on gold nanoislands(GNIs)chip was developed as a supersensitive single-molecule thyroid-stimulating hormone(TSH)nanobiosensor.Scattered and fluorescent signals from gold nanoislands on the substrate and quantum dots(QDs)nanoprobes were simultaneously isolated and acquired within an evanescent field layer generated by total internal reflection(TIR)of incident light using a dual-view device.The 3D TIR fluorescence images of TSH-bound QDs on the GNIs were obtained using z-axis optical sectioning at 10nm intervals before/after immunoreaction to identify the optimal conditions for detection.The localized centroid position of QD nanoprobes and GNI were distinguished at a subdiffraction limit resolution using 3D Gaussian fitting to the point spread function.The QD TSH nanobiosensor using wavelength-dependent 3D TIR fluorescence-based single-molecule localization microscopy(3D TIRF-SLM)imaging technique showed an excellent detection limit of 90 yoctomoles(~54 molecules)and a wide linear dynamic range of 1.14 zmol/L-100 pmol/L for TSH.The detection sensitivity was about 4.4×10^(9)times higher than conventional enzyme-linked immunosorbent assay and could successfully quantify TSH in human serum.The wavelength-dependent 3D TIRF-SLM technique may emerge as a reliable platform for ultrahigh-sensitive nanobiosensors at the single-molecule level and early diagnosis with quantification of disease-related ultra-tracebiomolecules.展开更多
This paper describes theoretical steps to develop an optical nanobiosensor using bacteriorhodopsin (BR) as the biomembrane and Single-Walled Carbon NanoTube (SWCNT) as the scaffold. Bacteriorhodopsin is a retinal ...This paper describes theoretical steps to develop an optical nanobiosensor using bacteriorhodopsin (BR) as the biomembrane and Single-Walled Carbon NanoTube (SWCNT) as the scaffold. Bacteriorhodopsin is a retinal protein used by archaea that come under the family of halobacteria. This retinal protein acts as a proton pump and resulting proton gradient is used to change the voltage that pass across the drain and source. The biosensor contains nano ISFET where the channel is made of a carbon nanotube for the conduction of current. The gate is replaced by bacteriorhodopsin biomembrane. Bacteriorhodopsin can be used as a molecular-level ultra fast bi-stable red / green photo switch for making 3D optical molecular memories that reliably store data with 10,000 molecules/bit. The molecules switch in femtoseconds. Biomembrane will sense 510 nm and 650 nm wavelength of light and the sensing voltage can be used to convert the data into digital signals. This molecular level memory device can be used for ‘Read-Write' operations. The sensor performance will also be ultra fast since it uses photons for the data storage, which are much faster than electrons used in normal memory devices, and the 3D storage capacity is much higher maximum of 10^13/cm^2.展开更多
Facile and ultrasensitive detection of Pb^(2+)in water for remote or resource-limited environments remains challenging.DNAzyme-based colorimetric nanobiosensors have been extensively studied to regulate the assembly o...Facile and ultrasensitive detection of Pb^(2+)in water for remote or resource-limited environments remains challenging.DNAzyme-based colorimetric nanobiosensors have been extensively studied to regulate the assembly of functionalized gold nanoparticles(AuNPs).However,these nanobiosensors have been criticized for their low sensitivity owing to the difficulty of dissociating DNAzyme embedded in AuNP aggregates.To address this issue,we rationally designed a DNAzyme by introducing an adenine-cytosine(A-C)mismatch to strengthen the disassembly of DNAzyme-linked nanostructures.As proof of concept,a“turn on”colorimetric nanobiosensor integrated with mismatched DNAzyme and functionalized AuNPs was first developed for Pb^(2+)detection.Under the optimal detection conditions,the obtained typical calibration curve shows a detection limit of 8.6 nmol/L,with an approximately 11-fold sensitivity improvement in Pb^(2+)detection compared with unmismatched DNAzyme,and a linear response range from 10 to 300 nmol/L.This nanobiosensor demonstrated robust selectivity and satisfactory recovery rates between 86.5%and 106.4%for Pb^(2+)in spiked environmental water samples.Additionally,the detection process is user-friendly and can be completed within 30 min,requiring only a simple water sample addition step.Considering the extensive applications of DNAzyme in conjunction with nanoparticles,this study provides a valuable reference for designing other DNAzyme-powered nanoparticle assemblies in biosensing systems.展开更多
The detection of circulating tumor DNA(ctDNA)with high sensitivity and specificity is crucial for the early diagnosis and monitoring of tumors,as well as for drug therapy.In this study,a simple and highly sensitive bi...The detection of circulating tumor DNA(ctDNA)with high sensitivity and specificity is crucial for the early diagnosis and monitoring of tumors,as well as for drug therapy.In this study,a simple and highly sensitive biosensor was specifically designed for the identification of targeted ctDNA.For the first time,a three-dimensional polyvinylidene fluoride-graphene oxide-chitosan(PVDF/CS/GO)nanofiber mesh was fabricated on a polydimethylsiloxane(PDMS)micropillar substrate using electrospinning technology,and the nanofibers were functionalized with peptide nucleic acids probe-gold nanoparticle(PNA-AuNP)complexes,which served as affinity molecules for detecting the methylation of the E542K variant of the phosphatidylinositol-4,5-bisphosphate 3-kinase catalytic subunit α(PIK3CA)gene in the peripheral blood of cancer patients.Additionally,an anti-5-Methylcytosine monoclonal antibody-multi-walled carbon nanotubes-COOH complex(Anti-5-mC-MWCNTs-COOH)complex was incubated to result in significantly amplified electrochemical signals for the accurate quantification of the E542K variant of the PIK3CA gene.Detectable signal responses were observed only when both molecules were simultaneously present,greatly enhancing the accuracy of the analysis.The biosensor exhibits high capture sensitivity for the methylation level of the E542K variant of the PIK3CA gene across a concentration range of 50 to 10000 fmol/L,with the lowest detection limit of 10 fmol/L.The ctDNA nanobiosensor has been shown to be both feasible and valuable for quantifying ctDNA concentrations in clinical blood samples.Consequently,this 3D nanofiber biosensor shows significant potential for clinical applications in cancer diagnosis and personalized medical treatments.展开更多
Nano-sized bacterial pores were inserted into a lipid membrane as a nanobiosensor for the detection of single peptide molecules. Due to the intrinsic properties of single-channel conductance, the transit of individual...Nano-sized bacterial pores were inserted into a lipid membrane as a nanobiosensor for the detection of single peptide molecules. Due to the intrinsic properties of single-channel conductance, the transit of individual molecules through the pore can be studied. The analysis of both the blockage current and duration is able to provide specific structural information and allows the detection of specific peptides in bulk mixtures.展开更多
Various nanobiosensors composed of biomaterials and nanomaterials have been developed,due to their demonstrated advantage of showing high performance.Among various biomaterials for biological recognition elements of t...Various nanobiosensors composed of biomaterials and nanomaterials have been developed,due to their demonstrated advantage of showing high performance.Among various biomaterials for biological recognition elements of the nanobiosensor,sensory receptors,such as olfactory and taste receptors,are promising biomaterials for developing nanobiosensors,because of their high selectivity to target molecules.Field-effect transistors(FET)with nanomaterials such as carbon nanotube(CNT),graphene,and conducting polymer nanotube(CPNT),can be combined with the biomaterials to enhance the sensitivity of nanobiosensors.Recently,many efforts have been made to develop nanobiosensors using biomaterials,such as olfactory receptors and taste receptors for detecting various smells and tastes.This review focuses on the biomaterials and nanomaterials used in nanobiosensor systems and studies of various types of nanobiosensor platforms that utilize olfactory receptors and taste receptors which could be applied to a wide range of industrial fields,including the food and beverage industry,environmental monitoring,the biomedical field,and anti-terrorism.展开更多
The emerging nanotechnology has opened novel opportunities to explore analytical applications of the fabricated nano-sized materials. Recent advances in nano-biotechnology have made it possible to realize a variety of...The emerging nanotechnology has opened novel opportunities to explore analytical applications of the fabricated nano-sized materials. Recent advances in nano-biotechnology have made it possible to realize a variety of enzyme electrodes suitable for sensing application. In coating miniaturized electrodes with biocatalysts, undoubtedly the most of the potential deposition processes suffer from the difficulty in depositing process and reproducible coatings of the active enzyme on the miniature transducer element. The promising prospects can concern to the obtaining of thin protein layers by using, i.e. electrochemical deposition, electrophoretic deposition as well as monolayer methods (Langmuir-Blodgett procedure, Layer-by-Layer—LbL). Many aspects dealing with deposition of enzyme by techniques employing electric field are considered, including surface charge of enzyme, and its migration under applied electric filed. The using of nanoscale materials (i.e. nanoparticles, nanowires, nanorods) for electrochemical biosensing has seen also explosive increase in recent years following the discovery of nanotubes. These structures offer a promise in the development of biosensing, facilitating the great improvement of the selectivity and sensitivity of the current methods. Finally, the perspectives in the further exploration of nanoscaled sensors are discussed.展开更多
文摘Nanotechnology has emerged as a boon to the society with immense potential in varied area of research and our day-to-day life. The application of nanotechnology for the advancement of biosensor leads to an efficient nanobiosensor with miniature structure as compared to conventional biosensors. Nanobiosensors can be effectively used for sensing a wide variety of fertilizers, herbicide, pesticide, insecticide, pathogens, moisture, and soil pH. Taken together, proper and controlled use of nanobiosensor can support sustainable agriculture for enhancing crop productivity.
基金supported by the National Research Foundation of Korea(NRF)grant funded by the Korea government(MSIT)(Nos.2019R1A2C2002556 and 2020R1C1C1009668)supported by Nano-Material Technology Development Program through the NRF funded by the Ministry of Science,ICT and Future Planning(No.2009-0082580).
文摘A wavelength-dependent three-dimensional(3D)superlocalization imaging method on gold nanoislands(GNIs)chip was developed as a supersensitive single-molecule thyroid-stimulating hormone(TSH)nanobiosensor.Scattered and fluorescent signals from gold nanoislands on the substrate and quantum dots(QDs)nanoprobes were simultaneously isolated and acquired within an evanescent field layer generated by total internal reflection(TIR)of incident light using a dual-view device.The 3D TIR fluorescence images of TSH-bound QDs on the GNIs were obtained using z-axis optical sectioning at 10nm intervals before/after immunoreaction to identify the optimal conditions for detection.The localized centroid position of QD nanoprobes and GNI were distinguished at a subdiffraction limit resolution using 3D Gaussian fitting to the point spread function.The QD TSH nanobiosensor using wavelength-dependent 3D TIR fluorescence-based single-molecule localization microscopy(3D TIRF-SLM)imaging technique showed an excellent detection limit of 90 yoctomoles(~54 molecules)and a wide linear dynamic range of 1.14 zmol/L-100 pmol/L for TSH.The detection sensitivity was about 4.4×10^(9)times higher than conventional enzyme-linked immunosorbent assay and could successfully quantify TSH in human serum.The wavelength-dependent 3D TIRF-SLM technique may emerge as a reliable platform for ultrahigh-sensitive nanobiosensors at the single-molecule level and early diagnosis with quantification of disease-related ultra-tracebiomolecules.
文摘This paper describes theoretical steps to develop an optical nanobiosensor using bacteriorhodopsin (BR) as the biomembrane and Single-Walled Carbon NanoTube (SWCNT) as the scaffold. Bacteriorhodopsin is a retinal protein used by archaea that come under the family of halobacteria. This retinal protein acts as a proton pump and resulting proton gradient is used to change the voltage that pass across the drain and source. The biosensor contains nano ISFET where the channel is made of a carbon nanotube for the conduction of current. The gate is replaced by bacteriorhodopsin biomembrane. Bacteriorhodopsin can be used as a molecular-level ultra fast bi-stable red / green photo switch for making 3D optical molecular memories that reliably store data with 10,000 molecules/bit. The molecules switch in femtoseconds. Biomembrane will sense 510 nm and 650 nm wavelength of light and the sensing voltage can be used to convert the data into digital signals. This molecular level memory device can be used for ‘Read-Write' operations. The sensor performance will also be ultra fast since it uses photons for the data storage, which are much faster than electrons used in normal memory devices, and the 3D storage capacity is much higher maximum of 10^13/cm^2.
基金supported by the Basic Research Project of Shanxi Province,China(202203021222086)the start-up foundation of Taiyuan University of Technology,China(RY2400000583).
文摘Facile and ultrasensitive detection of Pb^(2+)in water for remote or resource-limited environments remains challenging.DNAzyme-based colorimetric nanobiosensors have been extensively studied to regulate the assembly of functionalized gold nanoparticles(AuNPs).However,these nanobiosensors have been criticized for their low sensitivity owing to the difficulty of dissociating DNAzyme embedded in AuNP aggregates.To address this issue,we rationally designed a DNAzyme by introducing an adenine-cytosine(A-C)mismatch to strengthen the disassembly of DNAzyme-linked nanostructures.As proof of concept,a“turn on”colorimetric nanobiosensor integrated with mismatched DNAzyme and functionalized AuNPs was first developed for Pb^(2+)detection.Under the optimal detection conditions,the obtained typical calibration curve shows a detection limit of 8.6 nmol/L,with an approximately 11-fold sensitivity improvement in Pb^(2+)detection compared with unmismatched DNAzyme,and a linear response range from 10 to 300 nmol/L.This nanobiosensor demonstrated robust selectivity and satisfactory recovery rates between 86.5%and 106.4%for Pb^(2+)in spiked environmental water samples.Additionally,the detection process is user-friendly and can be completed within 30 min,requiring only a simple water sample addition step.Considering the extensive applications of DNAzyme in conjunction with nanoparticles,this study provides a valuable reference for designing other DNAzyme-powered nanoparticle assemblies in biosensing systems.
基金Funded by the National Natural Science Foundation of China(No.11804121)Special Funds for Central Guiding Local Scientific and Technological Development Project(No.2016ZYYD049)。
文摘The detection of circulating tumor DNA(ctDNA)with high sensitivity and specificity is crucial for the early diagnosis and monitoring of tumors,as well as for drug therapy.In this study,a simple and highly sensitive biosensor was specifically designed for the identification of targeted ctDNA.For the first time,a three-dimensional polyvinylidene fluoride-graphene oxide-chitosan(PVDF/CS/GO)nanofiber mesh was fabricated on a polydimethylsiloxane(PDMS)micropillar substrate using electrospinning technology,and the nanofibers were functionalized with peptide nucleic acids probe-gold nanoparticle(PNA-AuNP)complexes,which served as affinity molecules for detecting the methylation of the E542K variant of the phosphatidylinositol-4,5-bisphosphate 3-kinase catalytic subunit α(PIK3CA)gene in the peripheral blood of cancer patients.Additionally,an anti-5-Methylcytosine monoclonal antibody-multi-walled carbon nanotubes-COOH complex(Anti-5-mC-MWCNTs-COOH)complex was incubated to result in significantly amplified electrochemical signals for the accurate quantification of the E542K variant of the PIK3CA gene.Detectable signal responses were observed only when both molecules were simultaneously present,greatly enhancing the accuracy of the analysis.The biosensor exhibits high capture sensitivity for the methylation level of the E542K variant of the PIK3CA gene across a concentration range of 50 to 10000 fmol/L,with the lowest detection limit of 10 fmol/L.The ctDNA nanobiosensor has been shown to be both feasible and valuable for quantifying ctDNA concentrations in clinical blood samples.Consequently,this 3D nanofiber biosensor shows significant potential for clinical applications in cancer diagnosis and personalized medical treatments.
基金Supported by the National Natural Science Foundation of China (Grant No. 20875030) the Shuguang Project of Shanghai (Grant No. 07SG36)
文摘Nano-sized bacterial pores were inserted into a lipid membrane as a nanobiosensor for the detection of single peptide molecules. Due to the intrinsic properties of single-channel conductance, the transit of individual molecules through the pore can be studied. The analysis of both the blockage current and duration is able to provide specific structural information and allows the detection of specific peptides in bulk mixtures.
文摘Various nanobiosensors composed of biomaterials and nanomaterials have been developed,due to their demonstrated advantage of showing high performance.Among various biomaterials for biological recognition elements of the nanobiosensor,sensory receptors,such as olfactory and taste receptors,are promising biomaterials for developing nanobiosensors,because of their high selectivity to target molecules.Field-effect transistors(FET)with nanomaterials such as carbon nanotube(CNT),graphene,and conducting polymer nanotube(CPNT),can be combined with the biomaterials to enhance the sensitivity of nanobiosensors.Recently,many efforts have been made to develop nanobiosensors using biomaterials,such as olfactory receptors and taste receptors for detecting various smells and tastes.This review focuses on the biomaterials and nanomaterials used in nanobiosensor systems and studies of various types of nanobiosensor platforms that utilize olfactory receptors and taste receptors which could be applied to a wide range of industrial fields,including the food and beverage industry,environmental monitoring,the biomedical field,and anti-terrorism.
基金Authors are gratefully acknowledged for financial support of NCN-Grant no.2012/05/B/ST5/00749Wrocław University of Technology.
文摘The emerging nanotechnology has opened novel opportunities to explore analytical applications of the fabricated nano-sized materials. Recent advances in nano-biotechnology have made it possible to realize a variety of enzyme electrodes suitable for sensing application. In coating miniaturized electrodes with biocatalysts, undoubtedly the most of the potential deposition processes suffer from the difficulty in depositing process and reproducible coatings of the active enzyme on the miniature transducer element. The promising prospects can concern to the obtaining of thin protein layers by using, i.e. electrochemical deposition, electrophoretic deposition as well as monolayer methods (Langmuir-Blodgett procedure, Layer-by-Layer—LbL). Many aspects dealing with deposition of enzyme by techniques employing electric field are considered, including surface charge of enzyme, and its migration under applied electric filed. The using of nanoscale materials (i.e. nanoparticles, nanowires, nanorods) for electrochemical biosensing has seen also explosive increase in recent years following the discovery of nanotubes. These structures offer a promise in the development of biosensing, facilitating the great improvement of the selectivity and sensitivity of the current methods. Finally, the perspectives in the further exploration of nanoscaled sensors are discussed.
