Application of an asymmetric helical tube reactor for fast identification of gene transcripts of pathogenic viruses by micro flow-through PCR

Hartung, Regina; Brösing, Andreas; Sczcepankiewicz, G.; Liebert, Uwe G.; Häfner, Norman; Dürst, Matthias; Felbel, Jana; Laßner, Dirk; Köhler, J. Michael

doi:10.1007/s10544-008-9280-6

Cited by 29 publications

(31 citation statements)

References 24 publications

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“…This disadvantage could be avoided by spiral-like arrangements [53]. An asymmetrical helical tube reactor was developed in order to realize optimal conditions of thermocycling with sufficient time for efficient elongation and a minimal thermal stress for the PCR mix during the denaturation phases [37]. The helical coiled microtube follows the periphery of a cylindric core and forms 42 loops of equal total length and constant length of the three temperature sections in each loop (Fig.…”

Section: An Asymmetric Helical Tube Reactor For Virus Diagnosticsmentioning

confidence: 99%

“…7.10a). The heating cylinder consists of three copper sections which are equipped with electrical heaters [37] and resistive temperature sensors for precise temperature control. The three sections can be heated individually in order to realize up to three different temperatures as required for denaturation, annealing, and primer extension.…”

Section: An Asymmetric Helical Tube Reactor For Virus Diagnosticsmentioning

confidence: 99%

“…7.11a). The complete microcontinuous-flow RT-PCR arrangement was applied for the detection of virus gene expression [37].…”

Section: Micro Continuous Rt-pcr For Detection Of Hpv 16 and Measles mentioning

confidence: 99%

“…So, it can be applied, for example, for the implementation of PCR [34][35][36] and for the detection of virus transcripts by a RT-PCR [37]. In the following, principles of the handling and characterization of microfluid segments and the application of the technique for the detection of infective viruses will be explained and challenges for the future development of microsegmented flow devices to systems for handling of chemical and biological information will be discussed.…”

Section: Introductionmentioning

confidence: 99%

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Droplet-Based Microfluidics as a Biomimetic Principle: From PCR-Based Virus Diagnostics to a General Concept for Handling of Biomolecular Information

Köhler

2012

Microdroplet Technology

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The ability of lithographic fabrication of microchannels for fluid transport on the one hand and the continuously decreasing critical dimensions during the development of microlithography over the last decades generated high expectations on the progress of automated processing of small amounts of substances. In particular, it was expected that large numbers of well distinguished chemical entities-atoms, molecules, nano particles-could become manipulated highly parallel and with high speed. This hope was fed by the imagination of an analogy between the electron transport in integrated circuits and the transport of chemical objects inside microfluidic networks. The experiences of the last both decades had shown that such ideas of a complete analogy are not realistic. The progress of handling of substance-coupled information is much slower as the progress of hard ware development in the electronic devices. But, beside this general disappointment, microfluidics is still promising the arise and growth-up of very important new strategies for organizing chemical systems at the microscale and for supplying functional interfaces between the complex information inside the world of molecules and particles on the one hand and electronic systems on the other hand.Whereas clouds of electrons are manipulated in digital electronic devices, clouds of molecules are transported through microchannels by a convective flow. But, the special conditions in microfluidics cause low Reynolds numbers which reflect the small ratio of channel diameter and volume flow rate to the viscous forces. The microfluidic conditions cause always a laminary structure of flow with steep flow velocity gradients and results in to very high fluidic dispersion of concentration signals if homogeneous fluids are applied. So, the principle high potential of J.M. K€ ohler

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Section: An Asymmetric Helical Tube Reactor For Virus Diagnosticsmentioning

confidence: 99%

Section: An Asymmetric Helical Tube Reactor For Virus Diagnosticsmentioning

confidence: 99%

“…7.11a). The complete microcontinuous-flow RT-PCR arrangement was applied for the detection of virus gene expression [37].…”

Section: Micro Continuous Rt-pcr For Detection Of Hpv 16 and Measles mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Droplet-Based Microfluidics as a Biomimetic Principle: From PCR-Based Virus Diagnostics to a General Concept for Handling of Biomolecular Information

Köhler

2012

Microdroplet Technology

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“…The mixture is kept static, and the temperature of the reaction chamber is cycled [2]. Some researchers have examined the continuous flow PCR (CFPCR) devices, and the reaction mixture moves through one or several different isothermal regions repetitively in a microchannel or tube [3]. There are three main construction types of the CFPCR reactors: unidirectional, closed-loop and oscillatory reactors.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Thermal Performance in a Bidirectional Thermocycler by Including Thermal Contact Characteristics

Chen

et al. 2014

Micromachines

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This paper illustrates an application of a technique for predicting the thermal characteristics of a bidirectional thermocycling device for polymerase chain reaction (PCR). The micromilling chamber is oscillated by a servo motor and contacted with different isothermal heating blocks to successfully amplify the DNA templates. Because a comprehensive database of contact resistance factors does not exist, it causes researchers to not take thermal contact resistance into consideration at all. We are motivated to accurately determine the thermal characteristics of the reaction chamber with thermal contact effects existing between the heater surface and the chamber surface. Numerical results show that the thermal contact effects between the heating blocks and the reaction chamber dominate the temperature variations and the ramping rates inside the PCR chamber. However, the influences of various temperatures of the ambient conditions on the sample temperature during three PCR steps can be negligible. The experimental temperature profiles are compared well with the numerical simulations by considering the thermal contact conductance coefficient which is empirical by the experimental fitting. To take thermal contact conductance coefficients into consideration in the thermal simulation is recommended to predict a reasonable temperature profile of the reaction chamber during various thermal cycling processes. Finally, the PCR experiments present that Hygromycin B DNA templates are amplified successfully. Furthermore, our group is the first group to OPEN ACCESS Micromachines 2014, 5 1446 introduce the thermal contact effect into theoretical study that has been applied to the design of a PCR device, and to perform the PCR process in a bidirectional thermocycler.

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DNA Analysis in Droplet‐Based Microfluidic Devices

Ozdemir

Zhang

2011

Molecular Analysis and Genome Discovery

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Application of an asymmetric helical tube reactor for fast identification of gene transcripts of pathogenic viruses by micro flow-through PCR

Cited by 29 publications

References 24 publications

Droplet-Based Microfluidics as a Biomimetic Principle: From PCR-Based Virus Diagnostics to a General Concept for Handling of Biomolecular Information

Droplet-Based Microfluidics as a Biomimetic Principle: From PCR-Based Virus Diagnostics to a General Concept for Handling of Biomolecular Information

Analysis of Thermal Performance in a Bidirectional Thermocycler by Including Thermal Contact Characteristics

DNA Analysis in Droplet‐Based Microfluidic Devices

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