ライフサイエンスコーパス: microfluidics

1 was studied to assess their suitability for microfluidics.

2 a uniform synthetic compartment generated by microfluidics.

3 reaction droplets using programmable digital microfluidics.

4 rtant, which are addressed by acoustic-based microfluidics.

5 be accessible to those without expertise in microfluidics.

6 g and fine control of fluid flow in flexible microfluidics.

7 applications, especially when combined with microfluidics.

8 r an unprecedented expansion in the field of microfluidics.

9 low control and mixing strategies in droplet microfluidics.

10 f nano-assemblies growth and shrinkage using microfluidics.

11 it hierarchical branching scaling applied to microfluidics.

12 der flow, and this was tested in vitro using microfluidics.

13 functional coatings, sensors, actuators and microfluidics.

14 e high sensitivity VEGF detection in arrayed microfluidics.

15 chanical energy into electrical energy using microfluidics.

16 e endothelial permeability in vitro based on microfluidics.

17 "isolated microreactor" benefits of droplet microfluidics.

18 approaches, well-based methods, and digital microfluidics.

19 ing with poly(dimethylsiloxane) (PDMS)-based microfluidics.

20 ential to fundamentally advance the field of microfluidics.

21 tions are highly desired in cell biology and microfluidics.

22 assays and analytical devices based on paper microfluidics.

23 cant when the microcapsules were produced by microfluidics.

24 -in-time flow, can drive efficient mixing in microfluidics.

25 e-scale analysis, conventionally provided by microfluidics.

26 ss in other fields such as soft robotics and microfluidics.

27 tical tool for high-throughput droplet-based microfluidics.

28 step is challenging to implement in droplet microfluidics.

29 carefully designed chemical gradients using microfluidics.

30 gy, single-phase laminar flow and multiphase microfluidics.

31 oretic separation systems in capillaries and microfluidics.

32 ells with DNA-labeled antibodies and droplet microfluidics.

33 ed with versatile, simple, ease to-fabricate microfluidics.

34 believe that the challenge of AMR will give microfluidics a much-needed opportunity to leap from res

35 this review we focus on 'controlled droplet microfluidics' - a portfolio of techniques that provide

36 Microfluidics, a technology characterized by the enginee

37 Here we present printed droplet microfluidics, a technology to dispense picoliter drople

38 Advances in microfluidics allow for chemical sampling with increasin

39 al liquid propulsion provided by centrifugal microfluidics allows for closed fluidic systems that are

40 nces in miniaturization, nanotechnology, and microfluidics, along with developments in cloud-connecte

41 report the development of a method coupling microfluidics and a miniature mass spectrometer, applied

42 g 301 single cells from 11 populations using microfluidics and analyzing single-cell transcriptomes a

43 Combining the advantages of microfluidics and aptamers, this integrated microsystem

44 ethod is reported that integrates drop-based microfluidics and computational analysis to enable the p

45 ties, contrast techniques, microscopy tools, microfluidics and computer controlled systems shifts the

46 rvations were confirmed on single GUVs using microfluidics and confocal microscopy.

47 We have applied microfluidics and digital holographic microscopy to capt

48 viding new opportunities for next-generation microfluidics and directed cell function.

49 Integration of microfluidics and electrical sensing modality in a 3D tu

50 Monolithic integration of microfluidics and electronics on paper is demonstrated.

51 to perform redox-magnetohydrodynamics (MHD) microfluidics and eliminate the need to add redox specie

52 Combining microfluidics and fabrication suitable for mass producti

53 microvolumes, with ramifications for surface microfluidics and fluid-assisted templating applications

54 icrocapsules were formed using two different microfluidics and homogenization.

55 th the antibody fragment and integrated with microfluidics and housed in a tester set-up that facilit

56 proach can also find applications in digital microfluidics and in systems biology where the kinetics

57 cle, we describe a historical perspective on microfluidics and its current challenges, a perspective

58 nanoelectromechanical system, nanomedicine, microfluidics and lab-on-a-chip architectures.

59 d the transformative role of nanotechnology, microfluidics and laboratory-on-chip technology in advan

60 Using microfluidics and live-cell imaging, we treat multiple E

61 Using microfluidics and live-cell microscopy, coupled with new

62 t allows conformal coating of islets through microfluidics and minimizes capsule size and graft volum

63 , multiplexing of these measurements through microfluidics and nanofluidics confers many analytical a

64 ed immunosorbent assays utilizing integrated microfluidics and nanosensing elements.

65 n of microorganisms through a combination of microfluidics and on- and off-chip assays.

66 Paper microfluidics and printed electronics have developed ind

67 However, recent technological advances in microfluidics and reporter genes have improved this scen

68 a of research with applications ranging from microfluidics and sensing to sorting of biomolecules.

69 ngal system, Neurospora crassa, with droplet microfluidics and the use of a fluorescent recorder hook

70 applications, including materials assembly, microfluidics, and biomedical devices.

71 tion of mitochondria-tracking microrheology, microfluidics, and Brownian dynamics simulations to expl

72 stories of electrochemistry, biosensors, and microfluidics, and describe how they are combining to fo

73 f being integrated into lab-on-a-chip (LOC), microfluidics, and micro total analysis systems.

74 Examples are presented using semiconductors, microfluidics, and nanomaterials as the artistic media;

75 stretchable and reactive hydrogel-elastomer microfluidics, and stretchable hydrogel circuit boards p

76 We next used a microfluidics approach to profile the receptorome of sin

77 A microfluidics approach to synthesize core-shell nanocarr

78 ts into the microsecond regime by adopting a microfluidics approach.

79 coustofluidic (i.e., fusion of acoustics and microfluidics) approach for generating programmable chem

80 While ample research results in the field of microfluidics are available, their transformation into p

81 that expand the possibilities of centrifugal microfluidics are being introduced at a high pace.

82 Measurement electronics and microfluidics are easily constructed for acoustic wave b

83 As the needs for low-cost rapidly-produced microfluidics are growing with the trend of Lab-on-a-Chi

84 It was demonstrated that MCL obtained by microfluidics are more physicochemically stable than tho

85 Electrochemistry, biosensors and microfluidics are popular research topics that have attr

86 ng (SAXS) and high throughput, droplet based microfluidics as a powerful tool to investigate macromol

87 We have developed hydrogel-based virtual microfluidics as a simple and robust alternative to comp

88 systematically test these hypotheses using a microfluidics assay to mechanically wound an epithelial

89 n stem cells, high-throughput culturing, and microfluidics assays allowing for the introduction of no

90 We developed a platform for microfluidics-assisted cell screening (MACS) that overco

91 Here we used microfluidics-assisted fast tubulin washout experiments

92 , a yeast monocarboxylate transporter, using microfluidics-assisted live-cell imaging.

93 Using a microfluidics-assisted multi-colour TIRF microscopy assa

94 h-throughput biosensing device that utilizes microfluidics based plasmonic microarrays incorporated w

95 Here, we describe a microfluidics-based approach enabling direct imaging of

96 have also highlighted different deliverable microfluidics-based approaches and recent prototypes for

97 -vital imaging of metastatic tumors in mice, microfluidics-based artificial tumor capillary models, a

98 as Boyden chamber assay, barrier assays, and microfluidics-based assays), in this short report we wil

99 Here, we describe the application of a microfluidics-based CE-MS system for analysis of release

100 Here, we present a microfluidics-based cell-cell interaction assay that ena

101 Here we present a microfluidics-based ChIP-seq protocol using as few as 10

102 e: DNA computation, quantum computation, and microfluidics-based computation.

103 We recently developed a simple but unique microfluidics-based culture approach that requires minim

104 response to an in vitro wound within a novel microfluidics-based device.

105 al-time sequencing, next-generation mapping, microfluidics-based linked reads, and bacterial artifici

106 Here we present a modular, microfluidics-based model (HuMiX, human-microbial crosst

107 We developed a microfluidics-based model to quantify cell-level process

108 targeted RNA sequencing method that couples microfluidics-based multiplex PCR and deep sequencing (m

109 Here we develop a microfluidics-based platform that enables single-molecul

110 Here, we have used a microfluidics-based platform to investigate the activati

111 e highlighted in this review: self-assembly, microfluidics-based preparation, and flash nanoprecipita

112 er trans-synaptic cell-adhesion molecules by microfluidics-based RT-PCR.

113 Microfluidics-based soft-lithography devices have recent

114 Most microfluidics-based sorting methodologies utilize size d

115 Here we describe a microfluidics-based strategy to spin liquid native silk,

116 D-AQuA is a microfluidics-based technology that performs miniaturize

117 This paper describes a microfluidics-based workflow for genetically targeted is

118 We present a microfluidics-based, linked-read sequencing technology t

119 s in tissue engineering, cell encapsulation, microfluidics, bioengineering and drug delivery.

120 embled by ternary liquid phase separation by microfluidics, but the control over their design is limi

121 r high-throughput fabrication of paper-based microfluidics by patterning hydrophobic barriers using a

122 ng closed-loop separation of spiral inertial microfluidics (C-sep).

123 ted healthcare, the fully inkjet-printing of microfluidics can be a solution to it with numerous pote

124 How droplet microfluidics can be used to fabricate solid-shelled mic

125 The exquisite control afforded by microfluidics can be used to tune the compositions and g

126 'Controlled droplet microfluidics' can be regarded as a group of methods cap

127 ion-polymerase chain reaction performed in a microfluidics card containing 378 unique miRNAs.

128 being studied, and designing more versatile microfluidics, cellular interrogation holds promise as a

129 ytes was validated in a dorsal root ganglion microfluidics chamber platform.

130 arily immobilizing suspension cells within a microfluidics chip.

131 ling components and the creation of the MACS microfluidics chip.

132 esign, fabrication and testing of 3D printed microfluidics chips coupled with silicon photomultiplier

133 Using microfluidics combined with fluorescence microscopy, we

134 d to have a delayed onset of cytotoxicity in microfluidics compared with static culture conditions ba

135 throughput, resolution, and availability of microfluidics, computational power, and genetically enco

136 nexin V/propidium iodide assay, performed in microfluidics, confirmed the outcome of the real-time im

137 Microfluidics coupled to quantitative time-lapse fluores

138 Thus, the TRIS microfluidics device provides unique insights into the m

139 nitial steps or require a highly specialized microfluidics device that is not readily available.

140 ed by nanoprecipitation in a glass capillary microfluidics device.

141 lications such as welding, drug delivery and microfluidics devices in controlling small droplets and

142 In droplet microfluidics, different unit operations are combined an

143 d platform combines the strengths of digital microfluidics, digital bioassays, and optical tweezers,

144 ic systems can be positioned between digital microfluidics (DMF) addressing each droplet individually

145 Digital microfluidics (DMF) is a powerful technique for simple a

146 od to facilitate in-line coupling of digital microfluidics (DMF) with HPLC-MS, using a custom, 3D-pri

147 a droplet manipulation mechanism in digital microfluidics (DMF), where droplets can be actuated over

148 n the integration of biosensors into digital microfluidics (DMF).

149 rt the first integration of ECL with digital microfluidics (DMF).

150 ein A, and Protein G, manipulated by digital microfluidics (DMF).

151 cale IP using magnetic particles and digital microfluidics (DMF-IP).

152 Here we combine microfluidics, DNA barcoding and sequencing to collect c

153 address these challenges, here we integrate microfluidics, electronics, and inkjet printing to build

154 Microfluidics enabled reliable and high-efficiency measu

155 ulture system that is easily implemented via microfluidics-enabled fabrication.

156 eld by delineating the fundamental theory of microfluidics, fabrication techniques and a detailed acc

157 Here we report on a microfluidics-facilitated approach that allows for contr

158 electrodes and ultrahigh throughput droplet microfluidics focused on the generation of hundreds of t

159 optofluidics technology-fusion of optics and microfluidics for advanced functionalities.

160 face-enhanced Raman spectroscopy (SERS) with microfluidics for detecting papaverine at low concentrat

161 Synthetic biologists have used microfluidics for DNA assembly, cell-free expression, an

162 d electrical sensors compatible with droplet microfluidics for laboratory on a chip applications.

163 ate-of-the-art methodologies with respect to microfluidics for mammalian single-cell 'omics' and disc

164 rket or are currently evaluating centrifugal microfluidics for product development.

165 However, use of drop-based microfluidics for screening high-affinity peptide binder

166 on the present challenges of acoustic-based microfluidics for the handling of cells and molecules, a

167 Here we used high-throughput microfluidics for the screening of yeast libraries, gene

168 Droplet microfluidics has already evolved into a complex field.

169 Centrifugal microfluidics has attracted much interest from academia

170 Microfluidics has been extensively used for this purpose

171 Recently, droplet microfluidics has been used to prevent zone diffusion in

172 hanced speed, accuracy, and cost-efficiency, microfluidics has demonstrated potential in several key

173 Multiphase microfluidics has enabled us to construct hierarchical t

174 Centrifugal microfluidics has evolved into a mature technology.

175 Microfluidics has great potential, but the complexity of

176 The miniaturization of biosensors using microfluidics has potential in enabling the development

177 The advent of microfluidics has seen the development of platforms for

178 Microfluidics has significantly contributed to the expan

179 Although microfluidics has the potential to reduce turnaround tim

180 Microfluidics has the potential to transform experimenta

181 tudy, a novel electrode array and integrated microfluidics have been designed and characterised in or

182 Recent advances in microfluidics have produced faster and smaller-volume ap

183 Drop-based microfluidics have recently become a novel tool by provi

184 With the assistance of microfluidics, hCG sample was delivered via single-injec

185 ('AlphaLISA') in conjunction with integrated microfluidics, herein we developed a microfluidic immuno

186 rging biotechnologies, nanotechnologies, and microfluidics, hold the potential for rapid, accurate, a

187 The field of microfluidics holds great promise for the development of

188 ge numbers of concurrent separations is open microfluidics (i.e., no microchannels).

189 In the past decade, advances in microfluidics, imaging, and high-throughput single-cell

190 ce of tunable porous hydrogel with efficient microfluidics improved the sensitivity of the assay.

191 y in live E. coli cells, we use custom-built microfluidics in combination with single-molecule fluore

192 on of nanomaterials, printed technology, and microfluidics in electroanalysis has resulted in a perio

193 rating for the first time the feasibility of microfluidics in this field.

194 oward this end, we implemented droplet-based microfluidics, in which monodispersed droplets containin

195 performs immune-detection using paper-based microfluidics, instrumented with flexible electronics an

196 Microfluidics is a multidisciplinary field of science ba

197 to act as a unique reaction vessel, droplet microfluidics is a powerful tool for high-throughput dis

198 Droplet microfluidics is a relatively new and rapidly evolving f

199 Droplet microfluidics is among the most promising candidates for

200 these directions, which demonstrate that 2D microfluidics is uniquely set to study complex out-of-eq

201 e integration of micro-optical elements with microfluidics leads to the highly promising photonic lab

202 n contrast to deterministically patterned LM microfluidics, LMPA- and LM-embedded elastomer (LMEE) co

203 This article analyzes the microfluidics market, identifies issues, and highlights

204 Microfluidics may revolutionize our ability to write syn

205 The microfluidics method enabled tracking of the effect of t

206 Herein we report a microfluidics method that enriches cancer stem cells (CS

207 of miniaturized analytical formats, such as microfluidics, microarrays, paper-based analytical devic

208 luidic analysis techniques has been limited, microfluidics offers a ready platform for interrogation

209 These results demonstrate that microfluidics offers a useful and facile experimental ap

210 erformance liquid chromatography and droplet microfluidics on a single high-pressure resistant microf

211 stems, including nanowires, electronics, and microfluidics, on a single substrate.

212 gle particle detection format and the use of microfluidics, only a small volume of serum (~50 nL) is

213 s on areas where key fundamental features of microfluidics open up new possibilities and present adva

214 technology adds a new capability to droplet microfluidics operation, and can be used for adjusting c

215 Microfluidics or lab-on-a-chip technology offer clear ad

216 sors and readout methods for the centrifugal microfluidics platform and cover optical as well as mech

217 The integration of a microfluidics platform in a homemade miniaturized optica

218 based enzymatic substrates and use them in a microfluidics platform to simultaneously measure multipl

219 y conducting experiments with islets using a microfluidics platform.

220 ng (ATAC-seq) integrated into a programmable microfluidics platform.

221 the DNA and RNA and does not require bespoke microfluidics platforms.

222 flow injection system using array integrated microfluidics provided 25 times lower detection limit (1

223 Droplet microfluidics provides a general platform for enzyme scr

224 ds of unique, miniaturized reactors, droplet microfluidics provides a powerful method for automating

225 Printed droplet microfluidics provides a programmable and robust technol

226 tion of genetically encoded FRET sensors and microfluidics provides an attractive tool to monitor the

227 In this context, centrifugal microfluidics provides major advantages over other micro

228 microbead-enzyme complex was integrated with microfluidics pumped by redox-magneto-hydrodynamics (MHD

229 The most frequent application of droplet microfluidics relies on the generation of large numbers

230 The combined use of microfluidics screening and whole-genome sequencing to m

231 has potential applications for channel-free microfluidics, smart microreactors, microengines, and so

232 Tissue microarray and microfluidics staining methods have emerged as powerful

233 used a novel integrative approach, combining microfluidics-steered measurements of dimer-DNA assembly

234 eoretical approaches for using ideas in soft microfluidics, structured adhesive surfaces, and control

235 The biochip has been integrated to a microfluidics system and all steps of the assay have bee

236 The described microfluidics system can be operated with a single syrin

237 Studies in a three-dimensional microfluidics system identified a pericyte-dependent rol

238 ere we describe the fabrication and use of a microfluidics system that allows precise temporally rest

239 and human microbiome samples in the virtual microfluidics system, and demonstrated whole-genome sequ

240 e technology to facilitate mixing in droplet microfluidics systems, which can potentially open up are

241 In summary, centrifugal microfluidics takes advantage of a comprehensive set of

242 The developed inertial microfluidics technology enables single-step neutrophil

243 Here, we describe the use of microfluidics technology to develop a multiplexed rapid

244 homozygous and heterozygous genotypes using microfluidics technology.

245 utilising methods of synthetic chemistry and microfluidics technology.

246 The integrated microfluidics testing methodology facilitates high throu

247 Informed by recent experiments involving microfluidics that provide in vitro quantitative informa

248 vice can be used for several applications in microfluidics that require sorting of the submicrometer

249 een states, and highlight recent advances in microfluidics that will enable characterization of key d

250 ptical tweezers, fluorescence microscopy and microfluidics that, in combination with bulk biochemical

251 pid three-dimensional fabrication process of microfluidics, that relies entirely on an inkjet-printer

252 Using electronically programmable microfluidics, the measurement is in turn used to contro

253 ful and versatile alternative to traditional microfluidics.The complexity of fabricating and operatin

254 Along with microfluidics, these microdevices make single-cell manip

255 stretchable and bio-integrated electronics, microfluidics, tissue engineering, soft robotics and bio

256 n system by massively parallelizing inertial microfluidics to achieve a macroscopic volume processing

257 mer-based fluorescent detection with droplet microfluidics to achieve high throughput screening of ye

258 his study underscores the potential of using microfluidics to aid the diagnosis of Lyme disease at th

259 al-on-a-chip, combining micropropagation and microfluidics to allow direct microscopic study of live

260 Chemometrics has the potential to embolden microfluidics to become that enabling technology for so

261 Application of droplet microfluidics to combinatorial screening applications re

262 flexible high-throughput approach that uses microfluidics to compartmentalize individual cells for g

263 Using microfluidics to confine cellular motion to a 1D channel

264 We have developed a method using droplet microfluidics to couple multiwell plate-based assays to

265 assisted purification of nuclei with droplet microfluidics to develop a highly scalable single-nucleu

266 The new method uses digital microfluidics to extract steroids from CNB tissue sample

267 Here, we used live-cell imaging and microfluidics to investigate the adaptive response of bu

268 dvances in the applied physics of drop-based microfluidics to isolate and sequence rare recombinants

269 mic sequencing (SiC-seq), which uses droplet microfluidics to isolate, fragment, and barcode the geno

270 tudies, has been extensively integrated into microfluidics to provide on-chip microdevices for a vari

271 and continuous technique utilizing inertial microfluidics to separate E. gracilis by a key shape par

272 The interface coupling the microfluidics to the mass spectrometer achieves up to 96

273 The prototype device integrates paper microfluidics (to enable fluid handling) and a multilaye

274 MF-ECL represents a valuable new tool in the microfluidics toolbox for a wide variety of applications

275 pulation techniques available in the droplet microfluidics toolbox to handle particles encapsulated i

276 easily accessible fabrication of paper-based microfluidics using a desktop pen plotter integrated wit

277 he three 3D printing technologies dominating microfluidics was conducted using a Y-junction microflui

278 postcolumn reaction system based on droplet microfluidics was developed for capillary electrophoresi

279 Then, droplet-based microfluidics was used to generate 1000 cDNA libraries,

280 of hydrogels and successful integration with microfluidics, we developed a class of hydrogels that co

281 Contrary to laminar flow in most microfluidics, we find that the flow is three-dimensiona

282 Using droplet microfluidics, we isolate, amplify, fragment and barcode

283 Here, using nematic microfluidics, we study the cross-talk of topological de

284 Using single-cell imaging and microfluidics, we study the yeast general stress respons

285 Reconfigurable microfluidics were developed to ensure that seeding of "

286 ay to assess the quality of botanicals using microfluidics, where enzyme inhibition was employed to i

287 Our approach was applied in microfluidics, where the downsides related to nonspecifi

288 Combining OM-SBs with microfluidics will enable higher throughput screening of

289 re prototype system by integrating capillary microfluidics with a microfabricated photodiode array an

290 Such a merger of microfluidics with biosensing technologies allows for th

291 The combination of large scale integrated microfluidics with highly fluorescent semiconductor NRs

292 an be overcome with the integration of spray microfluidics with MEMS.

293 ves as a proof-of-concept for integration of microfluidics with miniature mass spectrometry.

294 the microfluidic regime, the integration of microfluidics with orthogonal systems and the generation

295 By combining fast-flow microfluidics with single-molecule fluorescence, we are

296 Using microfluidics with single-molecule imaging, we simultane

297 Here we demonstrate the coupling of microfluidics with small angle neutron scattering (SANS)

298 tate the expanded use of electrochemical LOC microfluidics, with its easier integrability, for applic

299 2H simplifies and accelerates the drop-based microfluidics workflow for screening random DNA librarie

300 lementation of chromogenic assays in droplet microfluidics workflows.