Ladder-Like DNA Nanostructure-Mediated Cascade Catalytic Nanomachine for Construction of Ultrasensitive Biosensors

Abstract: Herein, a novel two-dimensional ladder-like DNA nanostructure (LDN)-mediated cascade catalytic nanomachine (LDN–CCN) with a higher catalytic efficiency beyond those of a conventional one-dimensional hybrid chain reaction (HCR) nanostructure-mediated CCN was constructed and applied to design an electrochemical biosensing platform with first-rank performance for ultrasensitive detection of target miRNA-21. First, output DNA S1′ and S2′ were produced through the DNAzyme recycle amplification when the target miRNA… Show more

“…32 Furthermore, in order to have better sensitivity to trace targets, some recent electrochemical sensors combine HCR with other nucleic acid amplification technologies. [33][34][35] For example, using target-induced Mg 2+specific DNAzyme amplification in solution, a novel twodimensional ladder-like HCR reaction was designed, which showed higher catalytic efficiency than those of a traditional HCR reaction with a lower detection limit of 48.5 aM miRNA21. 33 In addition, DNA tool enzyme (Nicking endonuclease and polymerase) assisted cascade amplification 34 and CRISPR processing technology 35 could also be combined in the HCR amplification method for dual signal amplified genetic analysis.…”

“…[33][34][35] For example, using target-induced Mg 2+specific DNAzyme amplification in solution, a novel twodimensional ladder-like HCR reaction was designed, which showed higher catalytic efficiency than those of a traditional HCR reaction with a lower detection limit of 48.5 aM miRNA21. 33 In addition, DNA tool enzyme (Nicking endonuclease and polymerase) assisted cascade amplification 34 and CRISPR processing technology 35 could also be combined in the HCR amplification method for dual signal amplified genetic analysis. Besides the solid electrode, using carbon ink screen printing technology, the architecture for DNA strand displacement amplification could also be constructed on microfluidic cloth-based 36 or paper-based analytical devices 37 for point-of-care (POC) diagnosis in resource-limited settings, avoiding the cumbersome chip fabrication and high-cost peripheral facilities.…”

Nucleic acid isothermal amplification-based soft nanoarchitectonics as an emerging electrochemical biosensing platform

“…32 Furthermore, in order to have better sensitivity to trace targets, some recent electrochemical sensors combine HCR with other nucleic acid amplification technologies. [33][34][35] For example, using target-induced Mg 2+specific DNAzyme amplification in solution, a novel twodimensional ladder-like HCR reaction was designed, which showed higher catalytic efficiency than those of a traditional HCR reaction with a lower detection limit of 48.5 aM miRNA21. 33 In addition, DNA tool enzyme (Nicking endonuclease and polymerase) assisted cascade amplification 34 and CRISPR processing technology 35 could also be combined in the HCR amplification method for dual signal amplified genetic analysis.…”

“…[33][34][35] For example, using target-induced Mg 2+specific DNAzyme amplification in solution, a novel twodimensional ladder-like HCR reaction was designed, which showed higher catalytic efficiency than those of a traditional HCR reaction with a lower detection limit of 48.5 aM miRNA21. 33 In addition, DNA tool enzyme (Nicking endonuclease and polymerase) assisted cascade amplification 34 and CRISPR processing technology 35 could also be combined in the HCR amplification method for dual signal amplified genetic analysis. Besides the solid electrode, using carbon ink screen printing technology, the architecture for DNA strand displacement amplification could also be constructed on microfluidic cloth-based 36 or paper-based analytical devices 37 for point-of-care (POC) diagnosis in resource-limited settings, avoiding the cumbersome chip fabrication and high-cost peripheral facilities.…”

Nucleic acid isothermal amplification-based soft nanoarchitectonics as an emerging electrochemical biosensing platform

DNA self-assembled FeNxC nanocatalytic network for ultrasensitive electrochemical detection of microRNA

Minimally invasive electrochemical continuous glucose monitoring sensors: Recent progress and perspective