ライフサイエンスコーパス: microcantilever

1 f nerve agents, were detected using a SiO(2) microcantilever.

2 detected by monitoring the deflection of the microcantilever.

3 inguish among eight Salmonella serovars on a microcantilever.

4 ls by using infrared (IR)-sensitive hydrogel microcantilevers.

5 and cardiac microtissues constrained between microcantilevers.

6 actuation of arrays of 3D microtissues using microcantilevers.

7 suring animal stiffness using piezoresistive microcantilevers.

8 c supported bilayer were also observed using microcantilevers.

9 Gold coated microcantilever, 250 microm long and 50 microm wide, wit

10 The peptide-functionalized microcantilever allowed efficient capture and detection

11 ick monolayers on substrates such as silicon microcantilevers and elastomer sheets, creating bio-hybr

12 ties and structure, we deform capsules using microcantilevers and use finite element modeling to desc

13 Here, we introduce a genome-scale microcantilever- and RNAi-based approach to phenotype th

14 This novel microcantilever aptasensor has potential for development

15 thylene glycol) diacrylate (PEG-DA) hydrogel microcantilevers are fabricated by ultraviolet (UV) curi

16 phase-contrast images in liquids using soft microcantilevers are often maps of short-range conservat

17 dard, packed-column gas chromatograph with a microcantilever array (MCA) is demonstrated for enhanced

18 comprises a microfluidic spray nozzle and a microcantilever array operated in dynamic mode within a

19 A microcantilever array sensor with cantilevers differenti

20 se of a peptide moiety in conjunction with a microcantilever array system to selectively detect CTCs

21 Microcantilever arrays are driven by a piezoelectric ele

22 were also performed before and after dipping microcantilever arrays into a static B. subtilis solutio

23 as obtained by subsequent examination of the microcantilever arrays under a dark-field microscope.

24 chnique readily lends itself to formation of microcantilever arrays, what has remained unclear is the

25 ease in frequency for binding-peptide-coated microcantilevers as compared to that for control peptide

26 A microcantilever based method for fluid viscosity and mas

27 luids is required for optimal performance of microcantilever-based biosensors.

28 ilevers could potentially be used to prepare microcantilever-based chemical and biological sensors wh

29 This microcantilever-based DNA sensor offers a detection sens

30 (PCR) of cholera toxin gene, ctxA gene, and microcantilever-based DNA sensor to improve the sensitiv

31 With a simple and versatile microcantilever-based force measurement technique, we ha

32 of DNA mismatches using an elegantly simple microcantilever-based optical deflection assay, without

33 Microcantilever-based sensors comprise an emerging class

34 Combined with phage-derived peptides, this microcantilever-based technique provides a novel biosens

35 molecular binding occurs on one surface of a microcantilever beam, intermolecular nanomechanics bend

36 ucleotides that are grafted on one side of a microcantilever beam.

37 An array of flexible microcantilever beams, each coated on one side with a mo

38 We report the use of free-standing microcantilever beams, which have been used as an ultras

39 e have gained a great amount of knowledge in microcantilever bending due to surface stress changes, w

40 onto the surface of the microcantilever, the microcantilever bends due to the induced compressive or

41 Therefore, the microcantilever biosensing technique provides a potentia

42 The microcantilever biosensor was approved for the detection

43 an electrical detection of a piezoresistive microcantilever biosensor.

44 ification of the hydration induced stress on microcantilever biosensors functionalized with oligonucl

45 The results of the present piezoresistive microcantilever biosensors showed a solid correlation of

46 This label-free, electrically measured microcantilever can be miniaturized in order to be porta

47 Dynamic responses of the PEG-DA microcantilever can be obtained in a range of IR wavelen

48 te that properly designed and functionalized microcantilevers can be used to construct economical, fa

49 sensing technologies such as SAW devices and microcantilevers can compete with state-of-the art devic

50 The peptide-ligand-functionalized microcantilever chip was mounted onto a fluid cell fille

51 ssembled monolayer was prepared on a silicon microcantilever coated with a thin layer of gold on one

52 race amounts of Hg2+ are detected by using a microcantilever coated with gold.

53 Such hydrogel-coated microcantilevers could potentially be used to prepare mi

54 The microcantilever deflection as a function of the concentr

55 The microcantilever deflection increased as the concentratio

56 ction-induced bending and the correlation of microcantilever deflection with the HF concentration are

57 ate (PETN), located 4 m away from the PEG-DA microcantilever detector.

58 Microcantilever devices with aptamers as recognition ele

59 The resonance frequency of a PEG-DA microcantilever exhibits high thermal sensitivity due to

60 This new method of using microcantilevers for detecting and quantifying the surfa

61 tetraalkylammonium salts were used to modify microcantilevers for measurements of the concentration o

62 o stretch/unstretch actuations, as probed by microcantilever force sensors, was dominated by cellular

63 A sensing microcantilever, functionalized with a breast cancer spe

64 During the past decade, however, microcantilevers have been increasingly used as transduc

65 The dual-channel microcantilevers have demonstrated much superior sensing

66 We report on novel microcantilever heater sensors with separate AlGaN/GaN h

67 simultaneous operation of an array of these microcantilever heaters in multiple sensing modalities.

68 ctor of a dynamically driven, polymer-coated microcantilever in a viscous liquid medium have been obt

69 MC), we observe a compressive bending of the microcantilever, indicating adsorption to the SLB.

70 Overall, the PEG-DA microcantilever is a promising candidate for further exp

71 expensive, compact methodology that employs microcantilever (MC) arrays for sensitive nanomechanical

72 Novel nanostructured microcantilever (MC) surfaces were developed by modifyin

73 e demonstrate the use of a sensitive silicon microcantilever (MC) system with a porous silicon oxide

74 We report the use of microcantilevers (MCs) for the detection of three retino

75 Nanomechanical Si microcantilevers (MCs) functionalized by a film of tetra

76 monolayers (SAMs) functionalized on silicon microcantilevers (MCs) with gold nanostructured surfaces

77 es caused when common proteins interact with microcantilevers (MCs) with nanostructured (roughened) g

78 detection of trace amounts of CrO4(2-) using microcantilevers modified with a self-assembled monolaye

79 Microcantilevers modified with a self-assembled monolaye

80 As an example, we report here that microcantilevers of different geometries have been used

81 ystal microbalance, atomic force microscope, microcantilever, or other tools that measure the concent

82 erogeneous immunoassay at an allergen-coated microcantilever platform.

83 reports on the development of piezoresistive microcantilevers (PMCs) to investigate their potential u

84 d as a biorecognition element coupled to the microcantilever probe from atomic force microscope thus

85 oscopy (dAFM) in liquids where low-stiffness microcantilever probes are often used for nanoscale imag

86 By monitoring the deflection of the microcantilevers, real-time free energy changes in the S

87 of the work is devoted to show the effect on microcantilever resonance frequency of the composition o

88 Our tool based on microcantilever resonator arrays has shown to be capable

89 We show the feasibility of using microcantilever resonator arrays to effectively identify

90 low concentrations of multiple mycotoxins by microcantilever resonator arrays.

91 xin detection, based on antibody-immobilized microcantilever resonators, a promising label free biose

92 a-estradiol in serum by antibody-immobilized microcantilever resonators, an innovative biosensing pla

93 acid derivative, gold-coated piezoresistive microcantilevers responsive to analytes having vicinal c

94 that the nanomechanical fluctuations of the microcantilever sensor are sensitive enough to detect th

95 We report a novel enzyme-based microcantilever sensor by using layer-by-layer nanoassem

96 The developed highly specific microcantilever sensor has a response time of approximat

97 The membrane-coated microcantilever sensor is capable of characterizing the

98 The microcantilever sensor operated in fluctuation mode was

99 Microcantilever sensor technology has been steadily grow

100 A differential interferometer-based microcantilever sensor was developed with the aptamer as

101 echanical fluctuation based highly sensitive microcantilever sensor, which is capable of characterizi

102 We will also discuss our perspectives on microcantilever sensors based on surface stress changes.

103 s in the liquid stream on the performance of microcantilever sensors operated in both deflection and

104 charged metal cations to the surface of the microcantilever sensors produces surface stress that cau

105 In this paper we explore the use of microcantilever sensors to quantify surfactants' effects

106 tress changes, which is a unique property of microcantilever sensors, we are still in the early stage

107 s: solid-supported lipid bilayers (SLBs) and microcantilever sensors.

108 sequently the sensitivity and reliability of microcantilever sensors.

109 surface chemistries of surface-stress-based microcantilever sensors.

110 Microcantilever stress measurements are examined to cont

111 When immobilized on gold microcantilever surface, the cyclic peptide was able to

112 mobilization of glucose oxidase (GOx) onto a microcantilever surface.

113 rating a thin film of the MOF HKUST-1 with a microcantilever surface.

114 niformly through picoliter droplets onto the microcantilever surface; the micrometer-scale drops evap

115 ress, which is caused by interactions on the microcantilever surfaces, would improve the S/N ratio an

116 h and nanostructured (dealloyed) gold-coated microcantilever surfaces.

117 A microcantilever technique was used to apply force to rec

118 Here, with the microcantilever technique, where latex beads affixed on

119 ction field effect transistor-integrated GaN microcantilever that utilizes piezoelectric polarization

120 ave incorporated these heterostructures into microcantilevers that are actuated with extremely low dr

121 Here we introduce ion beam-sculpted microcantilevers that enable precise force-feedback-cont

122 of DNA self-assembled monolayers anchored to microcantilevers that occur as a consequence of the hybr

123 As molecules adsorb onto the surface of the microcantilever, the microcantilever bends due to the in

124 ce coated with target chemical onto a PEG-DA microcantilever, the resonance frequency of the cantilev

125 Coupled with a reference microcantilever, this approach enables detection of acti

126 We report the use of an array of microcantilevers to measure the specific binding of Salm

127 We report the use of lipid membrane-coated microcantilevers to probe the interactions between phosp

128 yl] diethylenetriamine (DETA) and fabricated microcantilevers to promote the differentiation of disso

129 These microcantilevers undergo bending deflection upon exposur

130 The enzyme-functionalized microcantilever undergoes bending due to a change in sur

131 The microcantilever undergoes bending due to accumulation of

132 The microcantilever undergoes bending due to sorption of CrO

133 The microcantilever underwent bending due to the reaction of

134 A glucose oxidase (GOx) functionalized microcantilever underwent bending when it was exposed to

135 epared on the silicon dioxide surface of the microcantilevers using a vesicle fusion method.

136 urface functionalization or treatment, these microcantilevers utilize the strong surface polarization

137 The anchor design principle was extended to microcantilevers via finite element simulations, which c

138 of detection for PETN trace using the PEG-DA microcantilever was 40 ng/cm(2).

139 The miniaturized piezoresistive microcantilever was fabricated by micro-electro-mechanic

140 Microcantilevers were used to simultaneously constrain t

141 We use microcantilevers which are coated with lipid membranes t

142 tte to form an adhesive contact with a glass microcantilever, which gave a measure of the tethering f

143 d be improved by coating the gold surface of microcantilever with a self-assembled monolayer of a lon

144 Here, a bimaterial microcantilever with an embedded microfluidic channel wi

145 SMRs) are highly sensitive, batch-fabricated microcantilevers with embedded microchannels that can di

146 NNVs with functionalized AMPs onto a sensing microcantilever yielded induced surface stresses, indica