ライフサイエンスコーパス: microfabrication

1 eatly broaden access to direct-write protein microfabrication.

2 a source for nonlinear, direct-write protein microfabrication.

3 hip CE-EC are commonly used, end-channel and microfabrication.

4 s microfluidic elements without the need for microfabrication.

5 the basis for a broadly applicable method of microfabrication.

6 systems over conventional lithography-based microfabrication.

7 nels, spurious modes, and imperfections from microfabrication.

8 ng with scalability is enabled by makerspace microfabrication.

9 cations in fields ranging from bioimaging to microfabrication.

10 stereolithography and three-dimensional (3D) microfabrication.

11 eterogeneous materials instead of monolithic microfabrication.

12 atterning techniques commonly used in planar microfabrication.

13 better control of the thin layer geometry by microfabrication.

14 arge quantum circuits and is compatible with microfabrication.

15 such as microfluidics, thermal control, and microfabrication.

16 res various manufacturing techniques such as microfabrication, 3D printing, laser micromachining, ele

17 ing on recent advances in bioengineering and microfabrication aimed at solving these issues, and taki

18 Advances in nano-/microfabrication allow the fabrication of biomimetic sub

19 Microfabrication allows the incorporation of multiple el

20 on force and cell-cell adhesion assays using microfabrication and a semiautomated computation scheme

21 -dimensional (3D) microstructures created by microfabrication and additive manufacturing have demonst

22 technological achievements of semiconductor microfabrication and biotechnology.

23 Continued advances in microfabrication and cell culture will allow further stu

24 With advanced microfabrication and data processing, SBCR will become m

25 t architecture, and the rational for design, microfabrication and detection performance is presented.

26 All microfabrication and device assembly steps are expected

27 ell, Hara and Merten (2015) apply the use of microfabrication and in vitro analysis in cell-free extr

28 Using this system in combination with microfabrication and in vivo experiments, we found that

29 impediment to the development of a field of 'microfabrication and measurement' in neuroscience is the

30 l behavior, and emerging efforts to leverage microfabrication and microfluidics for assay development

31 e compact platform, eliminating the need for microfabrication and minimizing the use of specialized f

32 Advances in microfabrication and nanofabrication are opening new opp

33 s are being addressed via the combination of microfabrication and nanofabrication, materials science

34 With the advent of integrated electronics, microfabrication and novel chemistry, NMR (Nuclear Magne

35 rs simple fabrication and compatibility with microfabrication and PCB processing, while maintaining c

36 or simple fabrication and compatibility with microfabrication and printed circuit board processing, w

37 bricated in silicon and glass using standard microfabrication and selective etching techniques.

38 nt collectors, fully compatible with current microfabrication and silicon-based device technology.

39 olled release of an oxidizing species, e.g., microfabrication and singlet oxygen-mediated cell death.

40 ssembly methods are provided, along with the microfabrication and soft lithography protocols necessar

41 uced at an extremely low cost using standard microfabrication and soft lithography techniques (2-3 d)

42 iving matter in general, for living material microfabrication and swarm robotics applications, and fo

43 e constructed in monolithic form by means of microfabrication and, increasingly, by additive techniqu

44 f applications, including sample inspection, microfabrication, and bio-imaging.

45 This paper presents the design, microfabrication, and demonstration of a novel microflui

46 ation plays crucial roles in biodiagnostics, microfabrication, and inkjet printing.

47 w mixing (8% +/- 1%), showed suitability for microfabrication, and microfluidic applications requirin

48 cation scheme based on laser micromachining, microfabrication, and transfer printing to enable scalab

49 zes, is crucial in various microfluidics and microfabrication applications.

50 also makes OET an attractive technology for microfabrication applications.

51 olding-integrated direct laser writing-based microfabrication approach in this study and showcase its

52 The specific advantages of the microfabrication approach include the capability not onl

53 As a result, our microfabrication approach provides glass ESI emitters th

54 how it is instead possible to use a top-down microfabrication approach to effectively encode distingu

55 We report a microfabrication approach to generate well-defined, addr

56 A microfabrication approach was employed to decouple the e

57 Thus, here a pause-print-pause (PPP) microfabrication approach was implemented.

58 A microfabrication approach was used to produce novel anal

59 The protocol describes master microfabrication ( approximately 1 d), polydimethylsilox

60 nanoparticles or quantum dots and the use of microfabrication are proving advantageous for the creati

61 ss is compatible with standard semiconductor microfabrication, as multiple micrometer-sized patterns

62 cyclic olefin copolymer using high-fidelity microfabrication, as templates for colorimetric DNA dete

63 ard the development of practical methods for microfabrication based on self-assembly.

64 t stages of tumor development, by using a 3D microfabrication-based approach to engineer ducts compos

65 This paper presents a microfabrication-based approach to integrated, quantitat

66 aring such single-nanopore membranes include microfabrication-based methods, the track-etch method, a

67 Our innovative approach combines microfabrication-based sample preparation with in situ c

68 crucial in applications like microscopy and microfabrication, but their low cross section requires i

69 If incompatibilities between biology and microfabrication can be eliminated, then biofabrication

70 Microfabrication can create architecturally complex scaf

71 High aspect ratio microfabrication can only be achieved with deep reactive

72 Silicon probes based on microfabrication can yield large-scale, high-density rec

73 chip eliminated the requirement for advanced microfabrication capabilities and specialized nanoliter

74 rently face safety, packaging, materials and microfabrication challenges preventing on-chip technolog

75 devices, but size scalability, material and microfabrication challenges, limited surgical accessibil

76 electrochemical, mechanical, biological and microfabrication compatibility requirements.

77 orous gold (np-Au) electrodes, prepared by a microfabrication-compatible self-assembly process and fu

78 analysis of microdroplets, including inkjet microfabrication, disease transmission, and industrial s

79 us biomimetic adhesives obtained by top-down microfabrication (dry adhesives, friction driven), and r

80 ational analysis/design in electrosynthesis, microfabrication, electrochemical energy storage/convers

81 Advances in microfabrication enable the tailoring of surfaces to ach

82 d with new materials and advanced methods in microfabrication/encapsulation to avoid the toxicity of

83 and use by many research laboratories where microfabrication expertise is not available.

84 logic assumptions and/or require specialized microfabrication facilities and expertise.

85 te stream that does not require cutting-edge microfabrication facilities, expensive materials, and hi

86 out the need for expensive lithography-based microfabrication facilities.

87 via strategies untethered from conventional microfabrication facilities.

88 icroelectronics, microfluidics, polymers and microfabrication have enabled the creation of disposable

89 Recent advances in nanomaterials and nano-microfabrication have enabled the development of flexibl

90 crofluidic PAGE without the need for a glass microfabrication infrastructure.

91 Microfabrication, inkjet- and screen-printing can be use

92 lysis systems and assumes previous cleanroom microfabrication knowledge.

93 nalize a variety of common materials used in microfabrication, making it a general purpose building b

94 ions both as a vaccine adjuvant and as a key microfabrication material.

95 The use of microfabrication may also enable incorporation of electr

96 We present a new, robust three dimensional microfabrication method for highly parallel microfluidic

97 Here, we describe a microfabrication method utilizing incline and rotate lit

98 We describe a microfabrication method, termed StampEd Assembly of poly

99 owing to the incompatibility of conventional microfabrication methods (for example, photolithography)

100 re has been a concerted drive to exploit the microfabrication methods developed within the semiconduc

101 echniques, thermoplastic forming (TPF)-based microfabrication methods have been developed which can p

102 Modern, top-down microfabrication methods have succeeded in reducing mask

103 are being addressed by combining traditional microfabrication methods with 'biofabrication': namely,

104 ls on an electrode array created by standard microfabrication methods.

105 of-of-concept study shows how integration of microfabrication, microfluidics, and 3D cell culture sys

106 tive removal of SS at the microscale and the microfabrication of a 5 x 5 array of uMMNs having both b

107 Here, we describe the microfabrication of a biodegradable scaffold patterned f

108 We report the lithographic microfabrication of a movable thin film microelectrode a

109 Here we introduce a matrix platform based on microfabrication of channels of defined wall stiffness a

110 on a prototype of such 'gecko tape' made by microfabrication of dense arrays of flexible plastic pil

111 The microfabrication of electrochemical immunosensors for th

112 sor design, involving extra nanomaterials or microfabrication of electrode structures, are entirely a

113 dure is suitable for users with expertise in microfabrication of electronics and neural recordings.

114 Here, a robust method for microfabrication of helices inspired by Bauhinia seedpod

115 d can be used with, our earlier protocol for microfabrication of human organs-on-chips.

116 Organ-on-a-chip engineering employs microfabrication of living tissues within microscale flu

117 plate in a broadly applicable method for the microfabrication of metallic microstructures.

118 PSMA with high affinity and selectivity, (2) microfabrication of PEDOT nanowires that entrain these v

119 nd processing may find potential uses in the microfabrication of sensors and other important areas th

120 Methods for microfabrication of solderable and stretchable sensing s

121 However, the microfabrication of such devices relies on expensive equ

122 es and electroosmosis--require sophisticated microfabrication of the chip, bulky instrumentation, or

123 Apart from microfabrication of the molds in a cleanroom (one time o

124 This paper presents parallel microfabrication of three-dimensionally sharp electrospr

125 y for a fraction of the cost of conventional microfabrication or commercial alternatives.

126 devices without increasing the complexity of microfabrication or device operation.

127 optimised a low-cost and highly reproducible microfabrication pipeline.

128 have mechanical stiffness exceeding that of microfabrication polymers, and can be used as masters fo

129 ed on glass substrate using a combination of microfabrication procedures followed by electrodepositio

130 or ESI-MS using simple and widely accessible microfabrication procedures.

131 The microfabrication process allows for inexpensive and repr

132 In addition to improved slide capacity, the microfabrication process offers the possibility of low-c

133 The microfabrication process produces a microneedle with a t

134 Since the microfabrication process readily yields three-dimensiona

135 We outline a microfabrication process that yields single-crystal, sil

136 we developed a gold-gold cold welding-based microfabrication process to integrate ultrathin (10 nm)

137 At this point, the microfabrication process was resumed, and the microfluid

138 sducer was fabricated via a lithography-free microfabrication process, achieving 30.7 W/cm2 (1.92 MPa

139 A microfabrication process, xurography, was used to produc

140 With success in reducing microfabrication process-related optical loss as a limit

141 h a microfluidic channel via a novel silicon microfabrication process.

142 ure is designed for production in a scalable microfabrication process.

143 surface is challenged by the use of standard microfabrication processes that are traditionally design

144 The work described in this paper utilizes microfabrication processes to produce devices that enabl

145 al network, which is possible using ion-trap microfabrication processes, may provide a new quantum si

146 n electrochemical biosensors developed using microfabrication processes, particularly sensors used to

147 area of 200microm) patterned using standard microfabrication processes, with the ability to electric

148 o plasticity, and are easily integrated into microfabrication processes.

149 d by leveraging advanced on-chip designs and microfabrication processes.

150 ng devices, and ongoing research on graphene microfabrication promises compatibility with integrated

151 ernative solution to expensive and laborious microfabrication protocols for droplet microfluidic appl

152 plications is attractive owing to elementary microfabrication requirements.

153 Conventional microfabrication routes result in pyramid-shaped tips, a

154 umerous disciplines such as optoelectronics, microfabrication, sensors, tissue engineering and comput

155 ting is a compelling alternative to existing microfabrication solutions, as robust devices were easy

156 When applied to perform microfabrication-specifically the electrosynthesis of th

157 cently have advances in computer science and microfabrication spurred the rapid development of precis

158 synthesis methods hinder compatibility with microfabrication standards.

159 After one-time microfabrication steps, the system can be assembled in l

160 Our microfabrication strategy allows >50,000 (d = 15 um) TSV

161 eractions, enabled by the versatility of the microfabrication strategy that allows to combine elastic

162 A recently developed microfabrication technique enables fabrication of a new

163 h can be manufactured by almost any existing microfabrication technique.

164 aphy, an intrinsically 3D laser direct write microfabrication technique.

165 on of glass emitters relies only on standard microfabrication techniques (i.e., deposition, photolith

166 Superconducting qubits made with scalable microfabrication techniques are a promising candidate fo

167 Microfabrication techniques are facilitating the creatio

168 s of micrometers that are produced by common microfabrication techniques are poised to provide integr

169 ate sandwich, are constructed using scalable microfabrication techniques derived from the semiconduct

170 We therefore developed microfabrication techniques for silicon, metal, and biod

171 Recent progress in microfabrication techniques has allowed stimulated emiss

172 The implementation of microfabrication techniques in cell biology now enables

173 n a material amenable to advanced growth and microfabrication techniques is an exciting route towards

174 Microfabrication techniques that allow the integration o

175 Finally, special attention is given to the microfabrication techniques that are currently resulting

176 s require the application of a set of planar microfabrication techniques to a nonplanar system with l

177 Using microfabrication techniques to allow epithelial cell she

178 Here, we use microfabrication techniques to create an accordion-like

179 We used photolithographic microfabrication techniques to create very small stainle

180 ized cleanroom facilities and time-consuming microfabrication techniques typical of conventional manu

181 a future where advanced 3D printing or other microfabrication techniques will allow shape of chromato

182 vably by offering new surface modifications, microfabrication techniques, and diverse nanomaterials w

183 printing, shape-memory materials, adhesives, microfabrication techniques, and soft and stretchable bi

184 there is a great need for the integration of microfabrication techniques, automation systems, and hig

185 rectly onto glass substrates via traditional microfabrication techniques, including photolithographic

186 Enabled by scalable microfabrication techniques, the display achieves actuat

187 pite ongoing challenges and limitations with microfabrication techniques, the efforts witnessed in re

188 ng classical halo assay and state-of-the-art microfabrication techniques, this single cell approach a

189 is based on batch processing using standard microfabrication techniques, which provides bifunctional

190 We construct the device using standard microfabrication techniques, which will facilitate its i

191 industrial-scale crystal growth and advanced microfabrication techniques.

192 be easily fabricated using standard silicon microfabrication techniques.

193 ce on expensive, inaccessible, and laborious microfabrication techniques.

194 indow platform fabricated through clean-room microfabrication techniques.

195 is readily integrated on chips via standard microfabrication techniques.

196 using MEMS (microelectromechanical systems) microfabrication techniques: capillary deposition proved

197 eir widespread use is limited by inefficient microfabrication technologies and their low energy densi

198 The microfabrication technologies of the semiconductor indus

199 Microfabrication technologies were employed to produce w

200 array were fabricated using standard silicon microfabrication technologies, and modified with methyle

201 y merging the advances in microfluidics with microfabrication technologies, novel platforms are being

202 methods of fabricating such surfaces rely on microfabrication technologies, which are only applicable

203 ical and thermal restrictions of traditional microfabrication technologies.

204 f inkjet printing as an attractive bottom-up microfabrication technology due to its simplicity and po

205 simplifying atomic cooling and loading using microfabrication technology has proved difficult.

206 Developments in microfabrication technology have enabled the production

207 Microfabrication technology offers the opportunity to co

208 r achieving pulsatile release involves using microfabrication technology to develop active devices th

209 g a xurography-based cost-effective benchtop microfabrication technology using just a desktop cutting

210 Microfabrication technology was used to create regular a

211 CVD polymers bridge microfabrication technology with chemical, biological, a

212 stem cell-derived cardiomyocyte biology and microfabrication technology, diseased HOCs are highly tu

213 Inspired by the use of sacrificial layers in microfabrication technology, here we propose a novel met

214 Solid-state microfabrication technology, similar to that used to mak

215 Despite significant advances in the microfabrication technology, the commercial adoption of

216 yzer based on toroidal trapping geometry and microfabrication technology.

217 ation could be achieved by scaling up modern microfabrication technology.

218 abricated by combining sol-gel chemistry and microfabrication technology.

219 erent electrode geometries are fabricated by microfabrication technology.

220 ter was fabricated by means of silicon-based microfabrication technology.

221 resents a much greater speed increase due to microfabrication than has been obtained in other assay s

222 Here we describe an approach for microfabrication that encodes the two-dimensional spatia

223 s in this area as well as recent advances in microfabrication that have allowed for more precise cont

224 Combined with monolithic microfabrication, this room-temperature system paves the

225 Microfabrication through the use of multilevel stamps pr

226 Relatively unexplored is the use of microfabrication to create sampling probes.

227 ing microtubule (MT) nucleation pathway with microfabrication to develop "cytoskeletal circuits." Thi

228 ge recent advances in tissue engineering and microfabrication to develop novel in vitro models of dis

229 The protocol uses microfabrication to enable user-defined geometries of th

230 easibility is demonstrated for using in situ microfabrication to guide the contact position of cortic

231 chip device thoroughly exploits the power of microfabrication to produce high-density capillary elect

232 Microfabrication tools allow precise control over the ce

233 ng of tissues for in vitro applications: the microfabrication tools that serve to both define the cel

234 from device physics, material synthesis, and microfabrication, we aim to unfold the fundamental limit

235 By integrating microfabrication with cell and molecular biology techniq

236 It avoids costly microfabrication with clean-room use, and the accessibil

237 18 different large MN patch designs by laser microfabrication with different MN length (800-1500 um),

238 FDM was suitable for microfabrication with minimum features of 321 +/- 5 mum,