ライフサイエンスコーパス: microreactor

1 molecular reactions in our colliding-droplet microreactor.

2 pillary column functioning as a hydrothermal microreactor.

3 ide droplets, each one acting as an isolated microreactor.

4 m was integrated with an immobilized trypsin microreactor.

5 atile chemical sensor and a highly efficient microreactor.

6 first capillary incorporates an enzyme-based microreactor.

7 eloped capillary sample handling system as a microreactor.

8 protein fraction undergoes digestion in the microreactor.

9 aqueous microcompartments to form primitive microreactors.

10 ments in successful application of enzymatic microreactors.

11 these hollow spheres can be used as template microreactors.

12 ed planar and 3D microfluidic assemblies and microreactors.

13 ed stirred batch reactors or continuous flow microreactors.

14 nts, opening routes to networks of multistep microreactors.

15 which is a crucial challenge when employing microreactors.

16 elivery devices, biosensors and customizable microreactors.

17 (dPCR) in an array of isolated 36-femtoliter microreactors.

18 ) and resealable polydimethylsiloxane (PDMS) microreactors.

19 cules before encapsulating them into droplet microreactors.

20 he residence time of the reactants in a flow microreactor a detailed analysis of the reaction kinetic

21 tions and uses the separation capillary as a microreactor, allowing multiple substrates to be assayed

22 which allow for both fluid flow through the microreactors/analysis chambers and optical access to th

23 that allows for both fluid flow through the microreactors/analysis chambers and optical access to th

24 vels of 1 ppbv have been detected using this microreactor and FTICR-MS system.

25 dic NMR chip hyphenated to a continuous-flow microreactor and is based on the capabilities of the NMR

26 microfluidic devices, lab-on-a-chip, sensor, microreactor and self-cleaning are presented.

27 d. 360 microm) are employed as the digestion microreactor and the nanoelectrospray emitter by immobil

28 The hollow microspheres were used as microreactors and carriers for constructing CaO2 core-me

29 ates fluorophores, which are confined in the microreactors and detected.

30 for the development of diagnostic assays and microreactors and for performing fundamental studies of

31 g poly(ethylene glycol) (PEG) hydrogel-based microreactors and microsensors within microfluidic chann

32 four identically labeled TPLFNs, sealed the microreactors and recorded a fluorescence image after te

33 sis of the chemical composition of levitated microreactors and, thus, paves the way for future contac

34 pported on mesoporous SiO2, packed in a flow microreactor, and activated toward the cascade reaction

35 struction of a UV-Vis spectrophotometer on a microreactor, and demonstrates the online monitoring of

36 The microreactors are completely sealed through the deformat

37 The microreactors are fabricated in silicon and glass using

38 Current applications of droplet microreactors are noted as is reaction acceleration in c

39 ers is measured directly in combinatorial 96-microreactor arrays and polymers produced in a laborator

40 of catalyst selectivity in combinatorial 96-microreactor arrays was performed as a two-wavelength ra

41 e density of active catalyst in a packed-bed microreactor, as well as control over the dynamics of th

42 hydrophilic ZnO nanostructure deposition via microreactor-assisted nanomaterial deposition (MAND) pro

43 The bioactivity of the trypsin-PSG-PEG microreactor at 20 degrees C for the digestion of BAEE w

44 rporates an immobilized alkaline phosphatase microreactor at the distal end of the first capillary an

45 Here, we show that microreactor-based pyrosequencing can detect rare cancer

46 nd kinetic properties of the reaction in the microreactor bed.

47 g of the ensemble average with the "isolated microreactor" benefits of droplet microfluidics.

48 nts, which are then segmented into picoliter microreactors by droplet-based microfluidics.

49 is and detected downstream (18.5 cm from the microreactor) by absorption (254 nm).

50 reparing spatially localized multiple-enzyme microreactors capable of directional synthesis.

51 tail was hydrodynamically pumped through the microreactor channel at different linear velocities rang

52 The approach is based on microreactor chips fabricated from silicon wafers.

53 se high-temperature/high-pressure (high-T/p) microreactor conditions (160-350 degrees C, 90-180 bar)

54 Capillary enzymatic microreactors containing trypsin and endoproteinase LysC

55 are (conventional batch production) and in a microreactor (continuous flow production).

56 A microreactor coupled to an electrochemical flow cell det

57 manipulated individually and act as discrete microreactors, DMF is well suited for microscale sample

58 y described microfluidic chip with enzymatic microreactor (EMR) to a microdialysis probe and evaluate

59 The small volume of the microreactors ensures a compact device with high reactio

60 Levitated drops show potential as microreactors, especially when radicals are present as r

61 reening results were confirmed by industrial microreactor evaluations.

62 The density of the microreactors exceeded 20000/mm(2).

63 A microreactor fabricated from polydimethylsiloxane/glass

64 ng nanoelectrospray mass spectrometry with a microreactor for on-line digestion and fast peptide mass

65 tatic mixer for HDX quenching, a proteolytic microreactor for rapid protein digestion, and on-chip el

66 osslinking agent, producing a very effective microreactor for the detection of glucose.

67 atforms as both a continuous biosensor and a microreactor for the synthesis of high value compounds.

68 pendent mass-transfer resistances when using microreactors for calculating kinetic rate constants.

69 spread use and application of merged droplet microreactors for monitoring chemical reactions.

70 a number of applications, including that of microreactors for organic reactions.

71 The technique involves the use of microreactors for small-volume PCR and for dye-terminato

72 e have examples of phase-separated attoliter microreactors: for sonochemistry, it is a hot gas inside

73 lications in microelectromechanical sensing, microreactors, gene delivery, drug loading and DNA seque

74 An electrochemical flow microreactor has been designed and manufactured to impro

75 oth a solid-phase extractor and an enzymatic microreactor have been prepared, and their operation has

76 Enzymatic microreactors have been prepared in capillaries and on m

77 In the past decade microreactors have emerged as a compelling technology fo

78 The microreactors have thousands of micropillars in microflu

79 The protein sample was loaded onto the microreactor in an acidic buffer.

80 n methods has led to drops being proposed as microreactors in many applications of biology and chemis

81 hways for the synthesis of active functional microreactors in the range from hundreds of nanometers t

82 that such domains act as fluid and permeable microreactors in which the order-stabilized molecular co

83 for lignin depolymerization in a continuous microreactor is a superior approach for the generation o

84 However, the microreactor is also significantly different from tradit

85 The microreactor is designed to facilitate the in situ cryst

86 A pepsin microreactor is incorporated into the distal end of this

87 he ability for blood detoxification of these microreactors is demonstrated.

88 phase oxidation chemistry in continuous-flow microreactors is given.

89 use simultaneous real-time monitoring of all microreactors is not required.

90 onvert red blood cells (RBCs) into efficient microreactors is reported.

91 The use of a photo microreactor led to a significant improvement with respe

92 d that 97 ng of trypsin is bound to the 1-cm microreactor located at the entrance of capillary column

93 ations for channel-free microfluidics, smart microreactors, microengines, and so on.

94 TAML activators are localized in the aqueous microreactors of reverse micelles where water is present

95 The proteolytic activity of the enzymatic microreactor on chip was demonstrated at different flow

96 d are increasingly being used as biochemical microreactors operating in physiological environments.

97 or using an acoustically levitated drop as a microreactor, particularly for studying kinetics.

98 portantly, useful data are acquired from the microreactor platform in specific isothermal and nonisot

99 a high-temperature (240-300 degrees C) glass microreactor produced high-quality CdSe nanocrystals, as

100 The microreactor provided a very convenient means for runnin

101 ous-flow liquid phase oxidation chemistry in microreactors receives a lot of attention as the reactor

102 Continuous-flow photochemistry in microreactors receives a lot of attention from researche

103 d activated carbonyls in a single continuous microreactor sequence is described.

104 S), allows the samples to be loaded into all microreactors simultaneously.

105 An automated, silicon-based microreactor system has been developed for rapid, low-vo

106 el cellulose nanofirbril aerogel-based W/O/W microreactor system that can be used for fast and high e

107 s use of inline IR analysis and an automated microreactor system, which allowed for rapid and tight c

108 amount of external waste water to form W/O/W microreactor system.

109 Microreactor technology has shown potential for optimizi

110 roplets containing alkali propiolates act as microreactors that confine the thermal decomposition of

111 In the microreactor, the reaction could be carried out safely w

112 r a reaction by using droplets (or plugs) as microreactors, the composition of the droplets must be i

113 rt we review the operation of segmented flow microreactors, their application to the controlled synth

114 We immobilized primed DNA templates in the microreactors, then sequentially introduced one of the f

115 d enzyme can be cleaned easily, enabling the microreactor to be reused for nanoelectrospray.

116 R) geometry is integrated with silicon-based microreactors to allow detection of a wide range of chem

117 The synthesis incorporates three sequential microreactors to produce 1,2,4-oxadiazoles in approximat

118 The ability to multiplex Leidenfrost microreactors, to extract product into an immiscible sol

119 ds, packing the microbeads into a chip-based microreactor (volume approximately 1.0 nL), and flowing

120 Our experimental indicates the novel microreactor was able to extract 93% phenol and 82% Cu(2

121 The excellent performance of the monolithic microreactor was also demonstrated with the digestion of

122 A microreactor was applied to produce ortho-substituted [(

123 orm employing immobilized sortase A within a microreactor was developed that permits efficient sortag

124 of a multistep catalytic reaction in a flow microreactor was performed with a spatial resolution of

125 ilica hybrid strong cation exchange monolith microreactor was synthesized and coupled to a linear pol

126 c fields via a trio of 3-D electrodes in the microreactor, we are able to precisely direct the transp

127 We have developed an automated quench-flow microreactor which interfaces directly to an electrospra

128 iotinylated DNA capture probes into the bead-microreactors, which are derivatized in each case with a

129 Microreactors, which initially targeted DNA-based reacti

130 nt of trypsin, thereby creating an enzymatic microreactor with high proteolytic activity.

131 dducts and unreacted ATM are eluted from the microreactor with less than 40 muL of methanol and direc

132 ntegrating a continuous-flow capillary-based microreactor with ultra-high-pressure liquid chromatogra

133 nanoflowerssupported on cellulose paper (the microreactor zone) coupled to 3,3',5,5'-tetramethylbenzi