ライフサイエンスコーパス: microfluidics

1 uch as flow lithography or multiple-emulsion microfluidics.

2 transcription/translation and droplet-based microfluidics.

3 d nuclei in droplets of defined volume using microfluidics.

4 esigned specifically for highly parallelized microfluidics.

5 ead into a reservoir, an open-sky version of microfluidics.

6 and filament network techniques, coupled to microfluidics.

7 to hiPSCs with high efficiency in 15 d using microfluidics.

8 dical applications such as blood analysis in microfluidics.

9 of protein diffusion measured via the H-cell microfluidics.

10 omechanical tweezer structure with microwave microfluidics.

11 able antenna, shape-shifting structures, and microfluidics.

12 ts and outlets in traditional closed-channel microfluidics.

13 he composites was controlled through droplet microfluidics.

14 he delivery of modified messenger RNAs using microfluidics.

15 assays and analytical devices based on paper microfluidics.

16 oretic separation systems in capillaries and microfluidics.

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

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

19 e endothelial permeability in vitro based on microfluidics.

20 cant when the microcapsules were produced by microfluidics.

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

22 e-scale analysis, conventionally provided by microfluidics.

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

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

25 nologies of artificial intelligence (AI) and microfluidics.

26 step is challenging to implement in droplet microfluidics.

27 carefully designed chemical gradients using microfluidics.

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

29 ells with DNA-labeled antibodies and droplet microfluidics.

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

31 was studied to assess their suitability for microfluidics.

32 ly split into aliquots by the built-in paper microfluidics.

33 a uniform synthetic compartment generated by microfluidics.

34 low rates of dispersed and aqueous phases in microfluidics.

35 ace to benefit future engineering designs in microfluidics.

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

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

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

39 es to the market, including biotechnologies, microfluidics, advanced materials, biomaterials, smart s

40 Advances in microfluidics allow for chemical sampling with increasin

41 Microfluidics allows for traditional laboratory-based bi

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

43 In emerging fields such as microfluidics and active matter, the formation of long-r

44 Advances in molecular biology, microfluidics and bioinformatics have empowered the stud

45 The recent boom in microfluidics and combinatorial indexing strategies, com

46 high-throughput sequencing, mass cytometry, microfluidics and computational biology have led to a su

47 encapsulated in nanoliter volumes by droplet microfluidics and deposited on spatially defined spots o

48 We have applied microfluidics and digital holographic microscopy to capt

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

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

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

52 y gap" between fluidic operations in digital microfluidics and embedded sensors: "plug-n-play DMF" (P

53 Using microfluidics and fluorescence microscopy, we observed t

54 o applications ranging from drug delivery to microfluidics and from ablation to fabrication.

55 icrocapsules were formed using two different microfluidics and homogenization.

56 advances in the field of synthetic biology, microfluidics and lithography, many exciting development

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

58 This demonstrates that coupling microfluidics and mass spectrometry (SIC-MS) now enables

59 adopted by researchers with no experience in microfluidics and may find applications in a range of fi

60 red tumor models, which have benefitted from microfluidics and mechanical engineering, creating a par

61 With advances in the field of biotechnology, microfluidics and nanotechnologies, many exciting develo

62 d microscope that retains compatibility with microfluidics and open-source software for image acquisi

63 Using microfluidics and pharmacological and genetic studies, w

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

65 Using microfluidics and time-lapse microscopy, we quantitative

66 es are now used in nanomedicine, biosensors, microfluidics, and -omics to enable early diagnosis of H

67 y shows how integration of microfabrication, microfluidics, and 3D cell culture systems could be used

68 Using cold-stages, microfluidics, and fluorescence microscopy, the activity

69 ision liquid aliquoting, flow control within microfluidics, and generation of physiologically relevan

70 Facilitated by the use of robotics, microfluidics, and improved approaches to super-resoluti

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

72 molecule fluorescence in-situ hybridization, microfluidics, and optogenetics, have opened the door to

73 As the techniques in cell culture, microfluidics, and personalized medicine concomitantly i

74 plications including self-cleaning surfaces, microfluidics, and phase change energy conversion.

75 s, including raindrops, irrigation currents, microfluidics, and tiny particles.

76 s in areas as diverse as biomedical devices, microfluidics, antifouling, and underwater robots.

77 liquids on solid surfaces is fundamental for microfluidics applications.

78 frequency under conventional conditions, our microfluidics approach enables the robust and cost-effec

79 es were generated with a novel droplet-based microfluidics approach.

80 Electrokinetic separation techniques in microfluidics are a powerful analytical chemistry tool,

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

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 3D printed and paper-based microfluidics are promising formats for applications tha

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

87 The microsystem monolithically integrates microfluidics as well as a potentiometric detection syst

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

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

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

91 Using microfluidics-assisted TIRF, we show that Cyclase-associ

92 able 3D mathematical modelling of human lung microfluidics at micrometre resolution.

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

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

95 dized cross-laboratory study comparing three microfluidics-based approaches for measuring cell mechan

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

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

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

99 ) and unsulfated hyaluronic acid matrices in microfluidics-based choice assays, which is likely influ

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

101 This droplet microfluidics-based method enables high-throughput chemi

102 y (10(5) nuclear fragments per cell) droplet-microfluidics-based method for single-cell profiling of

103 Microfluidics-based methods have enabled single-cell mec

104 By using a set of optical-microscopy- and microfluidics-based methods, we show that liposomes stro

105 Here, we present a low-cost microfluidics-based platform enabling automated screenin

106 bes the development of an integrated droplet microfluidics-based platform for high-throughput generat

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

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

109 In microbial ecology, microfluidics-based techniques, such as the Ribosomal In

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

111 in the 90's has revolutionized the field of microfluidics by almost eliminating the need for a clean

112 o shift the landscape of single-cell droplet microfluidics by expanding the repertoire of current nuc

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

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

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

116 ly demonstration of how 3D printed and paper microfluidics can be hybridized into versatile lab-on-ch

117 Microfluidics can be used to measure cell deformability

118 These results demonstrate that microfluidics can be used to prepare protein-loaded lipo

119 Microfluidics can be used to reproduce the TME in vitro

120 Microfluidics can help address this issue by allowing a

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

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

123 osed to high shear stress in a viscometer or microfluidics channel to mimic mechanical trauma and the

124 arily immobilizing suspension cells within a microfluidics chip.

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

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

127 Using microfluidics combined with fluorescence microscopy, we

128 This has led to interest across the microfluidics community in using rapid prototyping to en

129 rofluidic devices, e.g., Hele-Shaw cells and microfluidics comprising complex patterns resembling up-

130 ted surface enhanced Raman scattering (SERS)-microfluidics device for the detection of immune checkpo

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

132 Here, we generated a microfluidics device with arrays of long monolayer yeast

133 crofluidics method, using a so-called H-cell microfluidics device, for the determination of protein d

134 ed by nanoprecipitation in a glass capillary microfluidics device.

135 scope, leaving some applications of droplet microfluidics difficult to perform or out of reach entir

136 Droplet microfluidics disrupted analytical biology with the intr

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

138 Digital microfluidics (DMF) is a platform that enables highly re

139 Digital microfluidics (DMF) represents an alternative to the con

140 eveloped a new methodology, based on digital microfluidics (DMF), for rapid determination of individu

141 Yersinia pseudotuberculosis (Yptb) growth in microfluidics-driven microdroplets that regenerates micr

142 r a wide range of biomedical applications in microfluidics, drug delivery, biomedical devices, cardio

143 -edge technologies including nanotechnology, microfluidics, electronic engineering, and material scie

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

145 Droplet microfluidics enables high-throughput manipulation of fL

146 The microfluidics engineering is central to achieve a contro

147 With the feasibility of 3D printed microfluidics established, we look ahead at trends in 3D

148 plet Tn-Seq (dTn-Seq) solves this problem by microfluidics facilitated encapsulation of individual tr

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

150 ing efforts to leverage microfabrication and microfluidics for assay development.

151 s amplitude-modulated electrodeformation and microfluidics for characterizing mechanical fatigue in s

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

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

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

155 ), widely applied water-in-oil droplet-based microfluidics for single cell analysis met problems.

156 This metasurface integrated with microfluidics further enhances the light-matter interact

157 st decade, extensive research on paper-based microfluidics has accumulated a large number of scientif

158 Droplet microfluidics has already evolved into a complex field.

159 Studying the basic phenomenon in microfluidics has also generated new knowledge, which co

160 Microfluidics has been extensively used for this purpose

161 athematical modelling of pulmonary lymphatic microfluidics has been limited by the lack of accurate a

162 Inertial microfluidics has been proven to be a powerful tool for

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

164 Microfluidics has great potential, but the complexity of

165 Although the application of droplet microfluidics has grown exponentially in chemistry and b

166 Microfluidics has has enabled the generation of a range

167 Microfluidics has the potential to transform experimenta

168 Microfluidics have many potential applications including

169 Recent advances in microfluidics have opened opportunities for droplet-base

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

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

172 Here we describe a method that combines microfluidics, hydrogels, and Xenopus laevis egg extract

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

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

175 However, the current obstacle of inertial microfluidics in biological applications is the broad si

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

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

178 s of SCD mice in vivo and SCD human blood in microfluidics in vitro.

179 s of SCD mice in vivo and SCD human blood in microfluidics in vitro.Conclusions: These results are th

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

181 le also removing some troublesome aspects of microfluidics including the use of surfactants and the c

182 Inertial microfluidics is a promising approach for particle separ

183 Droplet microfluidics is a relatively new and rapidly evolving f

184 Droplet microfluidics is a well-established tool for high-throug

185 Droplet microfluidics is among the most promising candidates for

186 Droplet microfluidics is an enabling platform for high-throughpu

187 try tool, although an inherent limitation of microfluidics is their low sample throughput.

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

189 e using electric signals(1)-known as digital microfluidics-is used in optical(2,3), biomedical(4,5),

190 onent that has so far been overlooked in the microfluidics literature-the fuse-is a passive safety de

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

192 on optical imaging and the implementation of microfluidics make it promising for future adaptation in

193 small, biotinylated liposomes with protein, microfluidics manufacturing was used.

194 ics, electronics, digital signal processing, microfluidics, mechatronics, and flow cytometry can comp

195 The microfluidics method enabled tracking of the effect of t

196 In this study, we developed a microfluidics method, using a so-called H-cell microflui

197 as micro/nanotechnology-based device such as microfluidics, microdroplets, and microchamber.

198 Microfluidics offer high throughput and reduced sample c

199 Automated microfluidics offers advantages in high-throughput and p

200 stic technologies, including nanotechnology, microfluidics, -omics science, next-generation sequencin

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

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

203 upled to thin layer Au-based electrochemical microfluidics operating at -0.20 V under controlled flui

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

205 -probing-labelled microbial cells, combining microfluidics, optical tweezing and Raman microspectrosc

206 aporating sessile droplets, laminar flows in microfluidics or electrochemistry.

207 se of a commercially available droplet-based microfluidics platform for high-throughput scRNA-seq to

208 ve of this study was to develop an automated microfluidics platform for multiplexed detection of anal

209 Finally, we used a microfluidics platform to assess the timing of parkin re

210 Here we describe a high-throughput droplet microfluidics platform to profile chromatin landscapes o

211 ated a 3D-bioprinted perfused drug screening microfluidics platform.

212 Bespoke EWOD-based digital microfluidics platforms are very well suited to take ful

213 rage and aliquoting of reagents on different microfluidics platforms.

214 sing of the separated cells is enabled using microfluidics platforms.

215 Using microfluidics, protein could easily be incorporated in t

216 mmunication between single cells isolated by microfluidics provided evidence for only one Stochastic

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

218 Printed droplet microfluidics provides a programmable and robust technol

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

220 .g. microbes around a rising oil droplet) in microfluidics remains challenging.

221 However, microfluidics remains far from well-established mainstre

222 applications of LIG in broad fields, such as microfluidics, sensors, and electrocatalysts, are highli

223 ld-effect transistor (EGOFET) with a 6.5 muL microfluidics set up capable to provide an assessment of

224 cent assay in real time (BART), with droplet microfluidics, should enable high-throughput, low copy,

225 r (CMOS) compatible thin film waveguides and microfluidics shows great promise toward highly integrat

226 Tissue microarray and microfluidics staining methods have emerged as powerful

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

228 lity using flow cytometry cell sorting and a microfluidics system for live imaging of oxidation dynam

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

230 CelliGO is a droplet microfluidics system that combines high-throughput scree

231 rt the design and operation of an integrated microfluidics system that uses cellulose ester dialysis

232 Our method was validated on a microfluidics system using three different cancer cell l

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

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

235 We present a high-throughput microfluidics technique facilitating in situ measurement

236 Using microfluidics techniques, we investigate the influence o

237 By live-cell microscopy and microfluidics techniques, we uncovered three previously

238 Advances in microfluidics technology has enabled many discoveries on

239 utilising methods of synthetic chemistry and microfluidics technology.

240 The integrated microfluidics testing methodology facilitates high throu

241 d-Effect Transistor (EGOFET) integrated with microfluidics that allows for the detection of amounts o

242 extraction (SFNE), a method based on droplet microfluidics that allows multiple liquid-liquid extract

243 ased electrokinetics (DC-iEK) is a branch of microfluidics that has demonstrated to be an attractive

244 type nitrate/nitrite sensor based on droplet microfluidics that in contrast to standard (continuous p

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

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

247 multivariate investigation of live-cells in microfluidics that unmasked that cellular noise can affe

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

249 intercellular secretion heterogeneity using microfluidics, the challenges in operation of these syst

250 ort in conventional agitation systems and in microfluidics, the latter underpinning many new life sci

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

252 By using principles of open and suspended microfluidics, the Stacks system is easily assembled or

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

254 automated library preparation by centrifugal microfluidics thus offers attractive automation options

255 In this study, we combine microfluidics, time-lapse microscopy, and computational

256 etic concentration polarization with droplet microfluidics to accomplish in-droplet demixing.

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

258 We used microfluidics to apply force to branches formed from pur

259 related to electrochemistry, biochemistry or microfluidics to assess the commercial state of the art

260 Using microfluidics to control the application of shear, we ge

261 Previously we applied microfluidics to deliver stable concentrations of H(2)S,

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

263 and implement it at the microscale by using microfluidics to expose bacteria to a sequence of decisi

264 The approach used massively parallel microfluidics to generate libraries of natively paired,

265 ice (DMD), an air-free reaction chamber, and microfluidics to independently control monomer compositi

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

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

268 ed time-lapse microscopy in combination with microfluidics to measure growth, division and replicatio

269 chemical compounds, was integrated into the microfluidics to minimize the required human interventio

270 Here, we use microfluidics to produce monodisperse polyurea microcaps

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

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

273 es, and here, we use microdroplet generation microfluidics to supply picoliter aliquots for analysis

274 e compactness, high efficiency, and speed of microfluidics to synthesize short-lived radiolabeled com

275 c methods (i.e., the fusion of acoustics and microfluidics) to bioanalytical chemistry.

276 microfabrication method for highly parallel microfluidics, to improve the throughput of on-chip mate

277 zing apparatus was used, in combination with microfluidics, to isolate large-unilamellar vesicles and

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

279 The high success rate of reprogramming in microfluidics, under completely defined conditions, enab

280 nalysis of droplets have been limited by the microfluidics used so that stable, long-term operation n

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

282 gy for quantitative nucleic acid analysis on microfluidics using a thermometer, which brings fresh in

283 all the basic fluidic operations of digital microfluidics using water on doped silicon wafers in air

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

285 d onboard depressurization events, while the microfluidics was developed considering alterations of p

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

287 maging with high-pressure, rapidly switching microfluidics, we reveal the key role of electrostatic s

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

289 ary systems are a rapidly evolving branch of microfluidics where fluids are manipulated by capillary

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

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

292 Here, by combining paper-based microfluidics with acoustics, we present a rapid and pow

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

294 and integrated analytical devices combining microfluidics with miniaturized signal transducers.

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

296 lvanic cells embedded within skin-interfaced microfluidics with passive valves serve as sweat-activat

297 Here, we combined microfluidics with single-cell live imaging to monitor S

298 Using microfluidics with single-molecule imaging, we simultane

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

300 The combination of 3D cultures and microfluidics would allow for the production of a dynami