ライフサイエンスコーパス: micromachine

1 ry, design, and construction of this kind of micromachine.

2 roposed as a paradigm for the development of micromachines.

3 or iterative multiphoton microscopy and opto-micromachining.

4 nsity on graphene films by femtosecond laser micromachining.

5 compatible fabrication process based on bulk micromachining.

6 a load sensor fabricated by means of surface micromachining.

7 We have micromachined a silicon-chip device that transports DNA

8 To obtain pH sensitivity, laser micromachining (ablation) is utilized to introduce contr

9 ipulation, colloid research, manipulation of micromachines and studies of the properties of light bea

10 spects, among which are quantum information, micromachining and diagnostic tools.

11 sampling probe microfabricated in Si by bulk micromachining and lithography.

12 c hysteresis plasma switch made from silicon micromachining, and implemented in a two-stage efficient

13 as been realized as an advantageous tool for micromachining, and the feasibility of employing it for

14 Using a laser micromachining approach, the required electrode(s) geome

15 Functional compound micromachines are fabricated by a design methodology usi

16 ction in the diameter of the orifices of the micromachined arrays led to an additional signal gain of

17 We characterize the performance of these micromachined BNGs by ion imaging in a pseudorandom time

18 complished by the mitotic spindle, a bipolar micromachine built primarily from microtubules.

19 rylate thermoset polymer substrate, and were micromachined by standard MEMS processes.

20 Lamella micromachining by focused ion beam milling at cryogenic

21 d at the rim of the channel during CO2 laser micromachining by passing the laser beam through a stain

22 Silicon micromachined calorimeters ("calorimeter on a chip") are

23 s a promising approach to the fabrication of micromachined calorimetric gas sensors for combustible g

24 This paper shows that in situ micromachining can be used to simultaneously position an

25 of the MEMS devices, silicon dioxide surface-micromachined cantilever arrays and zinc oxide surface-m

26 an agarose bead detachment from the tip of a micromachined cantilever resulting from BoNT-B action on

27 nts inside an AC, leading to the assembly of micromachines capable of sensing and responding to chang

28 ntages of a diamond electrode detector for a micromachined capillary electrophoresis (CE) system are

29 A micromachined capillary electrophoresis chip is describe

30 agent compounds, based on the coupling of a micromachined capillary electrophoresis chip with a thic

31 ining microbeads are selectively arranged in micromachined cavities localized on silicon wafers.

32 The microspheres are selectively arranged in micromachined cavities localized on silicon wafers.

33 A micromachined chemical amplifier was successfully used t

34 detector combines a separation column and a micromachined chemoresistive gas sensor fully integrated

35 e been immobilized on beads, introduced into micromachined chips on the electronic tongue sensor arra

36 Silica-sputtered micromachined columns showed promising separations of li

37 For this purpose, an adapted set of micromachined columns was filled with 10 mum calibrated

38 forms a spindle, a precise self-constructed micromachine composed of microtubules and the associated

39 dex changes were preserved after storing the micromachined corneas and lenses for 1 month.

40 This type of micromachine could provide a generic pump or separation

41 duce dynamically autofocused 3D pulsed laser micromachining (d-3DPLM) using a nanosecond pulsed near-

42 l cells have the potential to be designed as micromachines deployed in a host of clinical and industr

43 On the ventral surface, a micromachined device revealed that traction forces were

44 orces generated by fibroblasts using a novel micromachined device that is capable of determining the

45 The poly(methyl methacrylate) micromachined device was fabricated using X-ray lithogra

46 The separation approach is coupled to a micromachined differential mobility detector to enhance

47 ogy that involves detection via a sensitive, micromachined differential mobility spectrometer (microD

48 microextraction (SPME) and analyzed using a micromachined differential mobility spectrometer with a

49 ion, cost-effective fabrication via advanced micromachining, easier assembly, biocompatibility, pain-

50 such as microfabrication, 3D printing, laser micromachining, electrospinning, screen printing, inkjet

51 microanalytical subsystem comprising silicon-micromachined first- and second-dimension separation col

52 detection in CE microchip systems and other micromachined flow analyzers.

53 Micromachined fluid-filled variable impedance waveguides

54 c media; these utilized techniques including micromachining, focused ion beam milling, two-photon pol

55 ely heated, temperature-programmable silicon micromachined gas chromatograph that employs a standard

56 ew stationary phase deposition technique for micromachined gas chromatography columns was presented.

57 have been produced by bonding 10-cm-diameter micromachined glass wafers to form a glass sandwich stru

58 tial microswitch micro-fabricated by surface micromachining has been evaluated using the drop hammer

59 In addition, micromachining has been used to construct picolitre-scal

60 Planar electrochemical microcells were micromachined in a microcrystalline boron-doped diamond

61 ilters realized from small resonant cavities micromachined in thin films of Yttrium Iron Garnet.

62 ications for synthetic cells as programmable micromachines in biomedicine and biotechnology.

63 systems suggest great potential for complex micromachines in the future, for application in microrob

64 ompetitive assay are carried out in channels micromachined into fused silica substrates.

65 Solvent and reagent filters were micromachined into quartz wafers using deep reactive ion

66 and micrometre-scale features have been bulk micromachined into titanium substrates of various thickn

67 The micromachined IREs are shown to outperform a 25 mm radiu

68 Cryogenic focused ion beam (cryo-FIB) micromachining is used to prepare a thin lamella-shaped

69 nductor under mechanical stress, while laser micromachining manufactures flexible, serpentine pattern

70 up to 28 orders of parametric resonance in a micromachined membrane resonator when electrically undam

71 We describe a micromachining method for making monolithic BNGs using d

72 que hybrid fabrication scheme based on laser micromachining, microfabrication, and transfer printing

73 The silicon micromachined microHP arrays contain heating elements (1

74 This paper describes the fabrication of a micromachined miniaturized array of chambers in a 2-mm-t

75 The new micromachine-MIP-based target isolation strategy can be

76 An implantable micromachined multi-electrode array (MEA) microprobe mod

77 Consequently, we have developed a micromachined nanocalorimetric biological sensor using a

78 Photolithographic micromachining of silicon is a candidate technology for

79 s have permitted the highly anisotropic bulk micromachining of titanium microelectromechanical system

80 , (2) an array of pyramidally shaped nozzles micromachined on a silicon wafer, and (3) a spacer which

81 m(2) and a spacing of 200 microm, which were micromachined on a single 3mm long micro-needle having a

82 aser engravers/cutters, the use of CO2 laser micromachining on poly(methyl methacrylate) (PMMA) has t

83 n miniature soft actuators, and light-fueled micromachines operating in an environment resembling bio

84 m (cryo-FIB) milling has been used to carve (micromachining) out 100-250-nm-thin regions (called lame

85 ing chromatographic experiments on 4 cm long micromachined packed bed columns filled with radially el

86 ting possibilities for applications in laser micromachining, particle micromanipulation, and optical

87 100-fs pulse duration at 80 MHz were used to micromachine phase gratings into each corneal wedge at s

88 opment of chemical sensors utilizing silicon micromachined physical transducers with integrated piezo

89 nd entrapment of single polymeric spheres in micromachined pits while providing to each bead the rapi

90 A micromachined plasma chip is coupled to a conventional g

91 SnO2 NRs and their integration with silicon micromachined platforms, but also allows for in-situ fun

92 ilayer column) in a series of interconnected micromachined pockets.

93 on the basis of specific application in bulk micromachining, primarily because of the predominance of

94 The integration of micromachining process and nanofabrication process endue

95 A micromachining process is described for fabricating a ma

96 Conventional photolithographic micromachining processes are typically used to construct

97 on techniques are primarily based on silicon micromachining processes, resulting in rigid and low asp

98 e capillary tube without any need of special micromachining processes.

99 lamellae generated by cryo-focused ion beam micromachining provides insights into the ultrastructura

100 Refractive index changes in the micromachined regions were calculated immediately and af

101 Refractive index (RI) changes in micromachined regions were measured immediately by recor

102 The overall performance of the micromachined resonators is demonstrated for the example

103 ion of technical advances in microchemistry, micromachining, separation technologies, detection syste

104 rane was sandwiched between two chips having micromachined serpentine channels.

105 lsed laser ablation in both the clinical and micromachining setting is the uncertainty regarding the

106 ry robust boron-doped diamond deposited on a micromachined Si wafer, which provides extended mid-IR t

107 Thin, micromachined Si wafers, designed as internal reflection

108 micromachined-Si focuser for injection, dual micromachined-Si columns for separation, and an integrat

109 igh-volume sampler of conventional design, a micromachined-Si focuser for injection, dual micromachin

110 We present a micromachined silicon attenuated total reflection-infrar

111 array of individually addressable sites on a micromachined silicon chip.

112 e demonstrate the Casimir effect between two micromachined silicon components on the same substrate.

113 leneglycol monohexadecyl ether (C16EO8) onto micromachined silicon hotplate structures.

114 By using a micromachined silicon substrate with moving parts, we de

115 fabricated by imprinting or molding using a micromachined silicon template as the stamping tool.

116 onlinear saturation phenomenon on a compound micromachined structure of U-shape (micro portal frame).

117 Bulk micromachined structures are generally free of residual

118 We demonstrate that the adhesion of micromachined surfaces is in a regime not considered by

119 e size created by most entry-level CO2 laser micromachining systems is too large to become a function

120 Micromachines take the micromotor concept a step further

121 ricated platform was constructed using laser micromachining techniques for the rapid fractionation an

122 The device is manufactured using silicon micromachining techniques, and we have conducted acute r

123 Using micromachining techniques, we fabricate both 2-pole and

124 ems was made possible through utilization of micromachining technologies.

125 The coupling of screen-printing and laser micromachining technology has been used to create a nano

126 The chamber was prepared by 3D micromachining technology utilizing deep reactive ion et

127 The chamber was prepared by 3D micromachining technology utilizing deep reactive ion et

128 SonoTransformer," the acoustically activated micromachine that delivers shape transformability using

129 Microsensors and micromachines that are capable of self-propulsion throug

130 ggered delivery systems are based on complex micromachines that are controlled with electromagnetic w

131 's engineering frontier, building artificial micromachines that emulate the biological machinery of l

132 hemical stimuli can be used to build dynamic micromachines that lie at the interface between biologic

133 re we introduce light-driven micromotors and micromachines that rely on optoelectronic tweezers (OET)

134 thography is an alternative to silicon-based micromachining that uses replica molding of nontradition

135 d-dimension separation columns and a silicon-micromachined thermal modulator (muTM) for comprehensive

136 ct in microelectromechanical systems using a micromachined torsional device.

137 source for mass spectrometry named array of micromachined ultrasonic electrosprays (AMUSE) is presen

138 nics, including piezoelectric and capacitive micromachined ultrasonic transducer (i.e., pMUT and cMUT

139 udy proposes a silicon nanocolumn capacitive micromachined ultrasonic transducer (snCMUT) array for r

140 based on Lithium Niobate (LN) Piezoelectric Micromachined Ultrasonic Transducers (pMUTs).

141 We manufactured and tested a capacitive micromachined ultrasound transducer (CMUT)-based sensor

142 a fully-encapsulated, flexible piezoelectric micromachined ultrasound transducer that incorporates a

143 distance, and hexagonal unit cell pattern is micromachined using a combination of state-of-the-art mi

144 onal (3D) photonic crystals--such as silicon micromachining, wafer fusion bonding, holographic lithog

145 visioned that thousands and millions of such micromachines will swarm and communicate with each other

146 torque for the transformation of the entire micromachine within milliseconds.