ライフサイエンスコーパス: on-chip

1 c bioreactors, drug delivery systems and Lab-On-Chip).

2 lumn processing of chromatographic fractions on chip.

3 annich reaction performed in continuous flow on chip.

4 stem that offers precise temperature control on-chip.

5 d via centrifugation and in plasma separated on-chip.

6 realization of efficient nonlinear processes on-chip.

7 ated by electronic cigarettes (e-cigarettes) on-chip.

8 perfused through the multi-organ human-body-on-chips.

9 rotocol for microfabrication of human organs-on-chips.

10 On-chip acceleration provides the possibility for a comp

11 The electrical signal generated by on-chip ACNTCs results from the temperature difference b

12 ich quantum information is stored in trapped on-chip acoustic wavepackets, and manipulated in ways th

13 On-chip actuation and readout of mechanical motion is ke

14 for application in imaging, bio-sensing and on-chip all-optical signal processing operations.

15 y have led to the generation of human organs-on-chips (also known as organ chips) that are now being

16 significant interest in magnetic-field-free on-chip alternatives, such as those recently implemented

17 nisms, we developed an amnion membrane organ-on-chip (AM-OOC) and tested the interactive and transiti

18 show significant advances towards efficient on-chip amplification, opening a route to large-scale in

19 Amnion membrane organ-on-chip: an innovative approach to study cellular intera

20 The platform consists of an on-chip analysis system integrated with an aerosol sampl

21 vides a promising spectroscopic platform for on-chip analytical applications.

22 We conducted the smFISH protocol on chip and demonstrated that image quality is preserved

23 l-based detection, biosensors, robotics, lab-on-chip, and paper-based analytical devices.

24 at five different vancomycin concentrations on-chip, and the sample injection, transport, and mixing

25 ted on the performance parameters of a novel on-chip antenna based on metasurface technology at terah

26 The proposed metasurface on-chip antenna is constructed on an electrically thin h

27 The metasurface on-chip antenna is shown to exhibit an average measured

28 how that the proposed GaAs-based metasurface on-chip antenna is viable for applications in terahertz

29 which is significant development over other on-chip antenna techniques reported to date.

30 This paper presents a novel on-chip antenna using standard CMOS-technology based on

31 s enable clinical enumeration of metastasis, on-chip anti-cancer drug responses and biological molecu

32 idic device described in this study, permits on-chip anti-cancer treatment and viability analysis, an

33 a microfluidic-based AP-MS workflow, called on-chip AP-MS, to identify PPIs using minute amounts of

34 d MIMO antenna array shows the potential for on-chip applications at 60 GHz.

35 s (Gaussian, focused and collimated) for lab-on-chip applications of Infrared, Raman and fluorescence

36 PLEIADES device goes beyond the current lab-on-chip approaches that still require bulky external ins

37 Lab-on-Chip are miniaturized systems able to perform biomole

38 ro models such as microfluidic chips ('tumor-on-chip') are showing tremendous promise at predicting a

39 ide a perspective on how personalized 'tumor-on-chip', as well as high-throughput microfluidic platfo

40 After loading, the on-chip assay steps were automated.

41 us perfusion and cell viability was analysed on-chip at different time points using fluorescence micr

42 entire nerve regeneration studies, including on-chip axotomy, post-surgery housing for recovery, and

43 substrate (MF-SERS) was developed to perform on-chip bacterial enrichment, metabolite collection, and

44 hromatography for the separation of alcohols on chip-based systems aiming the determination of alcoho

45 ortant considerations for the development of on-chip batteries is the need to photopattern the solid

46 established in microfluidic devices, injured on-chip by exposure to lipotoxic agent (palmitate), and

47 ansferred monosaccharides can be visualized "on chip" by a 1,3-dipolar cycloaddition reaction with an

48 e, we demonstrate that our array can conduct on-chip Ca(2+) imaging in C2C12 cells that were chemical

49 resent a low-cost, label-free, and real-time on-chip cell counting and quantifying method for sorted/

50 As scFTD-seq decouples on-chip cell isolation and library preparation, we envis

51 On-chip cell lysate electrical impedance spectroscopy ha

52 Strong correlation between results from on-chip cell lysis, conventional off-line lysis and ELIS

53 In this work, we demonstrate enhanced, on-chip CEP detection via optical-field-driven photocurr

54 esults open avenues for compact time-domain, on-chip CEP detection, and inform the development of int

55 ngle shot, which is presently achieved using on-chip charge sensors, capacitively coupled to the quan

56 wnstream library preparation process through on-chip chromatin tagmentation.

57 ntacting the sample, and pave the way for an on-chip circuit element of practical the zero-field micr

58 ted that the SSDL concept may lead to future on-chip circulators over multi-octaves of frequency.

59 is a rapidly emerging field in which complex on-chip components are required to manipulate light wave

60 nsumption, open up a path to fast, parallel, on-chip computation based on networks of oscillators.

61 Exploiting an on-chip concentration protocol in the SPM and the single

62 larisation-based quantum dot applications in on-chip conditions.

63 derable potential as magnonic waveguides for on-chip control of the spatial extent and propagation of

64 hment of both known and de novo motifs based on ChIP data.

65 phone imaging, and (iii) the integration of on-chip delay lines and sample processing to allow serum

66 With on-chip desalting, the limit of quantitation for histidi

67 ples of various qubit types, without further on-chip design changes.

68 rature distribution and photosensors for the on-chip detection and a ground plane ensuring that the h

69 suitable for on-chip thermal treatments and on-chip detection of biomolecules.

70 Furthermore, we demonstrate on-chip detection of C580Y, the most prevalent single-nu

71 Our study provides a route to develop on-chip detection of optical OAM modes, which can enable

72 This on-chip detection simplifies GP imaging as sophisticated

73 lerate an immuno-reaction time, in which the on-chip detection time was 5min, and demonstrating an ab

74 es place when the focal point aligns with an on-chip detector.

75 Rapid thermal cycling (RTC) in an on-chip device can perform DNA amplification in vitro th

76 lectronics for solid-state refrigeration and on-chip device cooling.

77 diagnosing the BK virus, was amplified on an on-chip device in less than 60 min.

78 egrated enzymatic glucose quantification Lab-on-Chip device is presented and evaluated considering th

79 e potential drops in a flow channel in a lab-on-chip device that accommodates chemical reactions on e

80 This paper presents an on-chip device that can perform gigahertz-rate amplitude

81 based blood-plasma separation to develop lab-on-chip device that facilitates rapid diagnosis (within

82 or Epilepsy Modelling In Vitro (MEMO), a lab-on-chip device, in which three hPSC-derived networks are

83 ndation for BC mutational profiling on a Lab-on-Chip device, to help the early detection of patient r

84 of cavity based line-narrowing in MoS2-based on-chip devices as it is required for instance for frequ

85 They are widely used in lab-on-chip devices for the manipulation, trapping, separati

86 g possibilities of implementation of the lab-on-chip devices has been discussed.

87 ves sampling cell-conditioned media in organ-on-chip devices.

88 luidics can be hybridized into versatile lab-on-chip devices.

89 ssor with off-chip memory (with hypothetical on-chip digital resistive random access memory).

90 x 3 mm(2) chip with an array of 16 sensors, on-chip digitization, and serial data output that can be

91 The spectrometer integrates an on-chip dispersive echelle grating with a single-element

92 ncorporated microextraction approaches using on-chip disposable sorbents, and (iv) automatic dynamic

93 An on-chip double emulsion method was implemented to genera

94 en recently successfully used to demonstrate on-chip effects of quantum optics with single atoms in t

95 pplications of CRISPR-Cas9 technology to the on-chip electrical detection of nucleic acids.

96 . aeruginosa (6294), S. aureus(LAC), through on-chip electrical sensing of bacterial lysate.

97 trix modified with capturing biomolecule for on-chip electrochemical biosensing.

98 l (2D) membrane based off-surface matrix for on-chip electrochemical immunoassay.

99 we design a nanodevice platform and combine on-chip electrochemical impedance spectroscopy measureme

100 In this work, an on-chip electrochemical method to measure endothelial pe

101 dy opens a new avenue for developing compact on-chip electrochemical micropower units integrated with

102 Most studies have involved on-chip electrochemical microsupercapacitors that have b

103 ation process, we demonstrate cooling of the on-chip electrons from 9 mK to below 5 mK for over 1000

104 uticals from urine, which was followed by an on-chip electrophoretic separation of the concentrated t

105 In addition, on-chip elusion and lysis of the protein and RNA content

106 ogies in the current Internet-of-Things era, on-chip energy harvesting is highly attractive, and to b

107 On-chip energy storage and management will have transfor

108 In this work, on-chip energy storage is demonstrated using architectur

109 d on amorphous silicon validates its use for on-chip energy-storage applications.

110 d electronic systems requires integration of on-chip energy-storage units to interface with various t

111 On chip, exciton-polaritons emerged as a promising syste

112 resolve unexpected challenges and biases in on-chip experiments involving particles and gas-permeabl

113 Under on-chip exposure to the psychoactive cannabinoid, Delta-

114 trally filtered array towards a miniaturized on-chip fluorescence imaging device, which may open up n

115 On-chip fluorescence imaging devices are recognized for

116 red passive Si photodiode array designed for on-chip fluorescence imaging of intracellular Ca(2+) dyn

117 a over conventional electrodes of equivalent on-chip footprint areas.

118 wever, performing efficient reagent exchange on chip for large numbers of embryos remains a bottlenec

119 actuation will open the door to entirely new on-chip functionalities.

120 o lasers simultaneously, hence leading to an on-chip fusion of the different parts of the Raman spect

121 ates on a mass-manufactured chip, using four on-chip-generated photons.

122 Here we demonstrate on-chip generation of entangled qudit states, where the

123 ward fabrication technique for patterning an on-chip graphene-based device with hole arrays, in which

124 Additionally, on-chip guided plasmonic probe beams sample the terahert

125 Research on 'tumor-on-chips' has grown enormously worldwide and is being wi

126 ation of magneto-optic nonreciprocal systems on chip have made imperative the exploration of magnet f

127 However, until now advances in Lab-on-Chip have not been translated to the anticipated degr

128 On-chip HDX of Hb at time points ranging from 0.14-1.1 s

129 but also may enable the compact, integrated on-chip high-speed mid-infrared photodetectors, modulato

130 liable integrated spectroscopy using a novel on-chip hollow core waveguide platform.

131 plex-valued images acquired using a lensfree on-chip holographic microscope, the resolution of which

132 mobilization of ssDNA or dsDNA molecules and on-chip hybridization of complementary target cDNA) is d

133 ingle-stranded DNA (ssDNA), in-solution- and on-chip-hybridized double-stranded DNA (dsDNA) has been

134 Our proposed device is able to capture and on-chip image ROR1+ cancer cells within a complex sample

135 a large field-of-view of >16 mm(2) using an on-chip imaging platform, where the sample is placed at

136 nanoantenna assay sensor is developed as an on-chip immunoassay platform for ultrasensitive detectio

137 s were isolated by DEP chip and subjected to on-chip immunofluorescence (IF) staining to determine th

138 on and synapse models, our design simplifies on-chip implementation and real-time tunability by reduc

139 hat provides such capabilities in a scalable on-chip implementation, allowing direct integration of G

140 f 6 x 6 x 1 mm(3) that makes it suitable for on-chip implementation.

141 The array lyses cells on-chip in lysis buffer augmented with a 2s pulse of a s

142 zation of high-performance, small-footprint, on-chip inductors remains a challenge in radio-frequency

143 We establish a murine lung-on-chip infection model and use time-lapse imaging to re

144 l wavelength, thereby relaxing the design of on-chip integrated filters for separating pump, signal a

145 hold the key to future high-bandwidth, dense on-chip integrated logic circuits overcoming the diffrac

146 a platform for technological developments in on-chip integrated optoelectronics.

147 information-processing technology calls for on-chip integrated sources of structured light.

148 ability assay possesses both the benefits of on-chip integration and robustness of the traditional fl

149 Conventional inorganic EO materials make on-chip integration challenging, while organic nonlinear

150 The demonstrated on-chip integration is up and down-scalable, compatible

151 with the mm(2) footprint area necessary for on-chip integration made from high thermoelectric figure

152 nco et al. stride toward this goal by hybrid on-chip integration of Si3N4 waveguides and GaAs nanopho

153 However, the on-chip integration-a task highly relevant for future na

154 on, lacking the spatial control required for on-chip integration.

155 The on-chip iridium oxide (IrOx) pseudo-reference electrode

156 materials and sensing platforms such as lab-on-chip, lab-on-CD, lab-on-paper etc.

157 Here, we developed an on-chip label-free method for determining the CSR.

158 Here, we present an on-chip, label-free technique to detect conformational c

159 , with applications spanning high-efficiency on-chip lasing, frequency comb generation and modulation

160 stor technology and pave a way for practical on-chip light manipulation.

161 in energy transfer as the basis for flexible on-chip light sources, amplifiers, nonreciprocal devices

162 panning the study of reaction kinetics using on-chip liquid-liquid extractions, sample pretreatment t

163 ork is dedicated to the development of a lab-on-chip (LOC) device for water toxicity environmental an

164 ength scales, the development of complex lab-on-chip (LOC) systems is in the focus of many current re

165 (UHF) surface-acoustic-wave (SAW) based lab-on-chip (LoC).

166 On-chip magnetic cooling is a promising approach to meet

167 and resonators, promising a pathway towards on-chip many-body quantum optics and applications in qua

168 microfluidics, to improve the throughput of on-chip material synthesis by allowing parallel and simu

169 ) using a methylated DNA immunoprecipitation on chip (MeDIP-chip).

170 d on the fly, reducing power consumption and on-chip memory, and enabling protocol complexity with a

171 nsfer torque have emerged with potential for on-chip memory, but they suffer from large energy dissip

172 Using a single-cell on-chip metabolic cytometry and fluorescent metabolic pr

173 On-chip metasurfaces have been implemented with two-dime

174 ions to date have been usually restricted to on-chip micro-devices.

175 AC line-filtering on-chip micro-supercapacitors (MSCs) based on coordinati

176 On-chip microarray analysis of serum biomarkers (e.g., c

177 combs and solitons have been generated from on-chip microresonators.

178 ves a compact and cost-effective holographic on-chip microscope and a surface-functionalized glass su

179 rds this aim, we have designed a holographic on-chip microscope operating at an ultraviolet illuminat

180 Barzanjeh et al. demonstrate a magnetic-free on-chip microwave circulator that utilizes the interfere

181 We demonstrate on-chip mimicry of the BBB structure and function by cel

182 For this purpose, different on-chip miRNA bioassays based on sandwich and competitiv

183 iferase chemiluminescent assay that involves on-chip mixing and optical detection.

184 We show that efficient on-chip mixing can be achieved at channel junctions by s

185 al for realization of the next generation of on-chip modulators and switches at THz frequencies.

186 c-based assay for automated manipulation and on-chip monitoring and analysis of stimulus-evoked calci

187 The reported on-chip MSCs showed a low impedance phase angle of -73 d

188 mputation, silicon photonics technology, and on-chip multi-pair sources will be a useful one for futu

189 s by all-electrical means is at the heart of on-chip nano-optical processing.

190 The design space of on-chip nanophotonic components, such as an optical meta

191 ecognition of a DNA target is attractive for on-chip nucleic acid testing due to its high specificity

192 antibodies in an individual can be displayed on chips on which 130,000 peptides chosen from random se

193 On-chip/on-petri dish nanoscale capacitance calibration

194 Organ-on-chip (OOC) devices are miniaturized devices replacing

195 Organs-on-chips (OoCs), also known as microphysiological system

196 Efficient and reliable on-chip optical amplifiers and light sources would enabl

197 tance for frequency-multiplexed operation in on-chip optical communication and sensing.

198 mical sensing, super-resolution imaging, and on-chip optical communication.

199 h is promising for next-generation ultrafast on-chip optical communications.

200 ndered by the lack of sensitive and portable on-chip optical detection technology.

201 The on-chip optical detection was performed in a single acqu

202 Here, we report ultra-high on-chip optical gain in erbium-based hybrid slot wavegui

203 ich can be used for sensitive biosensing and on-chip optical information processing.

204 ootprint for the next generation of Si-based on-chip optical interconnects.

205 ualization functionality, the system enables on-chip optimization of electroporation parameters for c

206 single chirality level for nanotube sorting, on-chip passivation, and nanoscale lithography.

207 unts of data every second, store it directly on-chip, perform in situ processing of the captured data

208 d system for rapid label-free separation and on-chip phenotypic characterization of circulating tumor

209 handling of biological materials followed by on-chip photometric detection, (ii) flow-through bioacce

210 Here, we demonstrate on-chip photon sources that simultaneously meet each of

211 nstruction of nanoscale optical switches for on-chip photonic integrations.

212 On-chip photonic networks hold great promise for enablin

213 c, stable and efficient emitter material for on-chip photonics without the need for epitaxy and is at

214 tion of the clip-magazine-assembled PT-Disk, on-chip photothermal effect of PB NPs triggered both dos

215 Here we demonstrate an on-chip piezo-optomechanical transducer that systematica

216 a proof-of-concept technology comprising an on-chip planar Goubau line, integrated with a microfluid

217 On-chip planar photonic waveguide-based beam engineering

218 his framework to manage the hemodynamics for on-chip platelet thrombosis assay on type 1 fibrillar co

219 aria-causing parasite worldwide, using a Lab-on-Chip platform developed in-house.

220 luidic components into a complete functional on-chip platform owing to its simple geometric structure

221 present a first of its kind flow through lab-on-chip platform using a single AC excitation source for

222 This study describes how tumor-on-chip platforms could be designed to create a heteroge

223 way to utilizing space-time wave packets in on-chip platforms, and enable phase-matching strategies

224 Lab-on-chip platforms, such as microfluidic chips and micro-

225 We also demonstrate all-dielectric on-chip polarization rotators based on phased arrays of

226 nt is only 520 nL; the total duration of the on-chip process is less than 40 min.

227 tion of a microfluidic chip capable of rapid on-chip protein labeling and reaction quenching.

228 ow into an initially empty cavity allows for on-chip protocol development and refinement.

229 The multiplexable organic electronic lab-on-chip provides a statistically solid, reliable, and se

230 Different pumping mechanisms, including on-chip pumps for better portability and syringe pumps f

231 Under optimal conditions, the on-chip quantitative detection of the target DNA was rea

232 We measure on-chip quantum interference with a visibility of 0.96 +

233 early has an impact on technology (e.g., for on-chip quantum networking).

234 This paper represents a step towards on-chip quantum simulation of materials science and inte

235 evelopment of quantum network nodes requires on-chip qubit storage functionality with control of the

236 on-chip vortexing of the magnetic beads and on-chip reagent storage and actuation were developed.

237 echnology Zhao et al. have developed 'organs on chips' representing the different chambers of the hea

238 tly the transport of a tracer in a Reservoir-on-Chip (RoC) micromodel filled with two immiscible flui

239 Fully-integrated lab-on-chip sample preparation overcomes technical barriers

240 ion chip microarrays, molecular computation, on-chip selection of functional nucleic acids, high-thro

241 ion, the inner surface provides an excellent on-chip sensing platform that truly opens up the possibi

242 atures the optofluidic light cage as a novel on-chip sensing platform with unique properties, opening

243 We present a new concept for on-chip separation that leverages bidirectional flow, to

244 unctions and cofactors of a given HMR, based on ChIP-seq data mining.

245 transcription factor TF target genes (based on ChIP-seq data) with the status of upstream signaling

246 unctional genomics' public catalogs is based on ChIP-seq data.

247 Our analysis on ChIP-seq experiment in human embryonic stem cells (hE

248 A number of algorithms draw on ChIP-seq tracks to define TFs and cofactors behind ge

249 Here, using an integrated on-chip shield technology, we measure the capacitance of

250 conducting qubit processors with multiplexed on-chip signal processing and readout.Nonreciprocal opti

251 sound waves on a surface has applications in on-chip signal processing and sensing.

252 ases of matter as well as to enable advanced on-chip simulators.

253 ed mode of a SiN waveguide and study how the on-chip single photon extraction can be maximized by int

254 na thermophila as an example, we demonstrate on-chip single-cell calorimetry measurement with metabol

255 The demonstrated on-chip single-photon spectrometer features small device

256 CA)-based nucleic acid amplification with an on-chip size-selective trapping of amplicons on silica b

257 numerous areas of research, including organs-on-chip, small animal experiments, and neonatology.

258 n increasingly important component in System-on-Chip (SoC) designs with increasing transistor scaling

259 This work can support integrated-on-chip solutions for spatiotemporal optical control, di

260 volutionized integrated photonics, providing on-chip solutions to a wide range of new applications.

261 Here, we demonstrate an on-chip spectrometer that can satisfy all of these requi

262 Arrays of on-chip spherical glass shells of hundreds of micrometer

263 ave been developed that cope separately with on-chip storage and fluidic operations e.g., hydrophobic

264 epend on a low-cost device that incorporates on-chip storage and fluidic operations.

265 lows for a highly integrated electrochemical on-chip storage solution.

266 ic structure that enables the realization of on chip sub-wavelength optical sources.

267 There is a need for scalable automated lab-on-chip systems incorporating precise hemodynamic contro

268 nowire laser arrays for ultra-high frequency on-chip systems with very low foot-print and energy requ

269 meable membranes that are required for organ-on-chip systems, therefore providing a physiological pla

270 le decreasing the application barrier of lab-on-chip systems.

271 Microcarriers generated with the on-chip technique showed more sustained VEGF release pro

272 ro-supercapacitors are attractive for system on chip technologies and surface mount devices due to th

273 e liposomes and lipid-based nanoparticles by on-chip technologies that are applicable in a laboratory

274 f a substrate is essential for realizing lab-on-chip technologies.

275 Lab-on-Chip technology comprises one of the most promising t

276 wide range of myocardial diseases using lab-on-chip technology.

277 ing Stokes flow and the accessibility of lab-on-chip technology.

278 Here, we combined organoids and Organs-on-Chips technology to create a human Duodenum Intestine

279 hod can potentially allow a multiplexed "QCR-on-chip" technology, bringing a paradigm shift in speed,

280 of DMF have pushed the barriers of this "lab-on-chip" technology.

281 We used on-chip terahertz spectroscopy to measure the frequency-

282 ological systems (MPS), also known as organs-on-chips, that recapitulate the structure and function o

283 Moreover, transient on-chip THC treatment also decreased spontaneous firing

284 By controlling the flow conditions on chip, the threshold of selection can be modified, ena

285 dly solid-state refrigeration and integrable on-chip thermal management.

286 elop a multifunctional platform suitable for on-chip thermal treatments and on-chip detection of biom

287 lead to convergence problems and slowdown of on-chip training.

288 Here we demonstrate a proof-of-concept on-chip transducer using trivalent ytterbium-171 ions in

289 -system design holds potential for realizing on-chip transformation optics, mathematical operations a

290 the target cell population, enabling direct on-chip tumor cell identification and enumeration.

291 cal devices, which offers not only versatile on-chip visual quantitative signal outputs, but also the

292 We have developed a versatile on-chip vortex-assisted electroporation system, engineer

293 Novel concepts for on-chip vortexing of the magnetic beads and on-chip reag

294 The capability of on-chip wavefront modulation has the potential to revolu

295 wide variety of functions through a mesh of on-chip waveguides, tunable beam couplers and optical ph

296 probe annealing on the target were performed on-chip, we found a limit of detection (LOD) for a synth

297 on the observation of quantum Zeno blockade on chip, where a lightwave is modulated by another in a

298 ical or chemical experiments to be conducted on-chip while reducing manual intervention.

299 padlock probe annealing, could be performed on-chip with an LOD of 20 pM after 45 min of RCA.

300 allowing parallel optical signal processing on-chip within an ultracompact dimension.