Analysis of Specific Gene by Integration of Isothermal Amplification and Electrophoresis on Poly(methyl methacrylate) Microchips

Hataoka, Yukari; Zhang, Lihua; Mori, Yasuyohi; Tomita, Norihiro; Notomi, Tsugunori; Baba, Yoshinobu

doi:10.1021/ac035032u

Cited by 83 publications

(58 citation statements)

References 26 publications

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“…To circumvent this challenge, nucleic acid amplifi cation reactions have been developed to operate at reduced or constant temperatures. Loopmediated isothermal amplifi cation (LAMP) uses four specially designed primers and a DNA polymerase to amplify nucleic acids at a constant temperature of ∼ 60 ° C. [ 137 ] LAMP has been integrated onto microfl uidic chips for the analysis of genes [ 138 ] and detection of pathogens. [ 139 ] In self-sustained sequence replication (3SR) [ 140 ] and nucleic acid sequence based amplifi cation (NASBA), [ 141 ] a set of transcription and reverse transcription reactions amplify the nucleic acid.…”

Section: Preconcentration Of Analytesmentioning

confidence: 99%

Microfluidic Chips for Point‐of‐Care Immunodiagnostics

2011

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We might be at the turning point where research in microfluidics undertaken in academia and industrial research laboratories, and substantially sponsored by public grants, may provide a range of portable and networked diagnostic devices. In this Progress Report, an overview on microfluidic devices that may become the next generation of point-of-care (POC) diagnostics is provided. First, we describe gaps and opportunities in medical diagnostics and how microfluidics can address these gaps using the example of immunodiagnostics. Next, we conceptualize how different technologies are converging into working microfluidic POC diagnostics devices. Technologies are explained from the perspective of sample interaction with components of a device. Specifically, we detail materials, surface treatment, sample processing, microfluidic elements (such as valves, pumps, and mixers), receptors, and analytes in the light of various biosensing concepts. Finally, we discuss the integration of components into accurate and reliable devices.

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Section: Preconcentration Of Analytesmentioning

confidence: 99%

Microfluidic Chips for Point‐of‐Care Immunodiagnostics

2011

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Section: Strategies To Miniaturize Isothermal Amplification Reactionsmentioning

confidence: 99%

“…Thus, many microsystems that combined LAMP with different detection methods, newly designed lab-on-chips, microfluidic cartridges and automated techniques were reported. In many studies, the LAMP amplification signals were already detected after 15-40 minutes after the thermal reaction started [50][51][52][53][54].The preferred and the most sensitive method for detection is based on fluorescence (with SYBR green, SYTO green or EvaGreen as fluorescent dyes) that can be detected as early as 15 minutes after the thermal reaction starts. For calcein, a limit of detection (LOD) of about 270 copies/µL was described [55].…”

mentioning

confidence: 99%

Isothermal Amplification and Quantification of Nucleic Acids and its Use in Microsystems

Tröger¹,

Niemann²,

Gärtig³

et al. 2015

J Nanomed Nanotechnol

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Nucleic acid amplification technologies (NAATs) offer the most sensitive tests in the clinical laboratory. These techniques are used as a powerful tool for screening and diagnosis of infectious diseases. Isothermal methods, as an alternative to polymerase chain reaction (PCR), require no thermocycling machine and can mostly be performed with reduced time, high throughput, and accurate and reliable results.However, current molecular diagnostic approaches generally need manual analysis by qualified and experienced personal which is a highly complex, time-consuming and labor-intensive task. Thus, the demand for simpler, miniaturized systems and assays for pathogen detection is steadily increasing. Microfluidic platforms and lab-on-a-chip devices have many advantages such as small sample volume, portability and rapid detection time and enable point-of-care diagnosis.In this article, we review several isothermal amplification methods and their implementation in microsystems in relation to quantification of nucleic acids. miniaturized systems can be diverse. The majority of publications are focussed on clinical diagnostics including foodborne organisms for environmental monitoring [10][11][12]. In case of an infectious disease, cultivation and phenotypic characterization are still the standard methods of microbiologists which need days up to weeks to obtain a diagnostic result. Hence, scientists started to make use of nucleic acid amplification methods to accelerate the analysis. The most widespread and well known technique for this purpose is the polymerase chain reaction (PCR) [10,13], which exploits the activity of the DNA polymerase. The method is based on a thermal cycling process consisting of repeated cycles of heating and cooling steps allowing for DNA melting, sequence specific primer binding and enzymatic amplification of the target nucleic acid. The quantitative assessment of target copies is possible by using a real-time PCR approach, where a concentration dependent signal (e.g. fluorescence) increases over time [14]. The latter enables the user to easily assess the pathogen load of patient samples [15][16][17][18]. Since the first example of a PCR on a miniaturized system in 1994 [19,20], numerous devices were presented, which integrate not just the amplification, but also sample preparation and detection steps [9,[21][22][23][24][25][26][27][28]. Just a few of those microsystems have reached the market so far, but some have shown a fascinating potential to replace the classical laboratory-oriented state-of-the art [29][30][31][32][33]. setups has been shown to obtain a similar result [34]. A smaller heat capacity allows for rapid changes in temperature beneficial for the PCR time as well as a higher parallelism of multiple genetic samples [34].However, a major drawback of the integration of PCR to microsystems is the necessity of sophisticated instrumentation. The reaction requires a thermal cycling instrumentation, space and considerable expertise [35]. Therefore, isothermal reactions for the ta...

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“…Numerous capillary electrophoresis (CE)-and microchip capillary electrophoresis (MCE)-based approaches have been tested and validated for DNA sequencing [1,2], genotyping [3,4], mutation analysis [5,6], characterization of single nucleotide polymorphisms (SNPs) [7,8], forensic human identification [9,10], diagnosis of diseases [11,12], and other applications [13,14]. When compared to slab-gel electrophoresis, these techniques provide the advantages of comparable resolving power, rapidity, high throughout, minute sample requirement, and ease of integration [10,15,16]. Using these techniques, small separation channels/capillaries are often filled with polymer solutions that are advantageous over cross-linked gels, including relatively low viscosity, ease of preparation, and flexibility.…”

Section: Introductionmentioning

confidence: 99%

Nanomaterials and chip‐based nanostructures for capillary electrophoretic separations of DNA

Lin

Huang

2005

Electrophoresis

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Capillary electrophoresis (CE) and microchip capillary electrophoresis (MCE) using polymer solutions are two of the most powerful techniques for the analysis of DNA. Problems, such as the difficulty of filling polymer solution to small separation channels, recovering DNA, and narrow separation size ranges, have put a pressure on developing new techniques for DNA analysis. In this review, we deal with DNA separation using chip-based nanostructures and nanomaterials in CE and MCE. On the basis of the dependence of the mobility of DNA molecules on the size and shape of nanostructures, several unique chip-based devices have been developed for the separation of DNA, particularly for long DNA molecules. Unlike conventional CE and MCE methods, sieving matrices are not required when using nanostructures. Filling extremely low-viscosity nanomaterials in the presence and absence of polymer solutions to small separation channels is an alternative for the separations of DNA from several base pairs (bp) to tens kbp. The advantages and shortages of the use of nanostructured devices and nanomaterials for DNA separation are carefully addressed with respect to speed, resolution, reproducibility, costs, and operation.

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Analysis of Specific Gene by Integration of Isothermal Amplification and Electrophoresis on Poly(methyl methacrylate) Microchips

Cited by 83 publications

References 26 publications

Microfluidic Chips for Point‐of‐Care Immunodiagnostics

Microfluidic Chips for Point‐of‐Care Immunodiagnostics

Isothermal Amplification and Quantification of Nucleic Acids and its Use in Microsystems

Nanomaterials and chip‐based nanostructures for capillary electrophoretic separations of DNA

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