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1 rm to explore and exploit Weyl point physics on chip.
2 lumn processing of chromatographic fractions on chip.
3 ressure and high-speed liquid chromatography on chip.
4 olarized beams has not yet been demonstrated on chip.
5 annich reaction performed in continuous flow on chip.
6 al for effective low-power nanomanufacturing on-chip.
7 nce nanostructured ZnO UV-detectors directly on-chip.
8 tions in microfluidic bioreactors and organs-on-chips.
9 monitor cellular barrier tightness in organs-on-chips.
10 ture, pH, and morphology of liver- and heart-on-chips.
11 ich quantum information is stored in trapped on-chip acoustic wavepackets, and manipulated in ways th
12                              Throughout this on-chip ADME process, the proposed device can be used as
13 tical elements for flexible light emitter or on-chip all-optical devices.
14 uding full-duplex wireless communication and on-chip all-optical information processing.
15  for application in imaging, bio-sensing and on-chip all-optical signal processing operations.
16 ifferentiators play an important role in the on-chip all-optical signal processing.
17  significant interest in magnetic-field-free on-chip alternatives, such as those recently implemented
18               The analog signal is digitized on chip and then transmitted to a receiving unit.
19                      Cell culturing directly on-chip and free radical release by phorbol-12-myristate
20 se an integratable all-optical quantizer for on-chip and low power consumption all-optical analog-to-
21                                          Lab-on-chips and biosensors open new perspectives and offer
22  models of cancer, such as organoids, organs-on-chips and patient-derived xenografts (PDXs).
23  at five different vancomycin concentrations on-chip, and the sample injection, transport, and mixing
24 es on glass chips, so that all reagents are "on-chip," and these chips show durable storage stability
25 a novel plastic microfluidic biochip with an on-chip anesthetic biosensor that was characterized for
26 osed disposable microfluidic biochip with an on-chip anesthetic biosensor using MIPs exhibited excell
27 s enable clinical enumeration of metastasis, on-chip anti-cancer drug responses and biological molecu
28 ve emerged that hold great potential for lab-on-chip applications, biointegration, low-cost sensing a
29                                 This "organs-on-chips" approach aims to capture key structural and ph
30                                        Cells on chip are powerful experimental tools for high-through
31                 Human tissue in vitro models on-chip are highly desirable to dissect the complexity o
32                                          Lab-on-Chip are miniaturized systems able to perform biomole
33                            We performed ChIP-on-chip assay using anti-SOX9 antibody, covering the Ctg
34 tified in the Ctgf proximal promoter by ChIP-on-chip assay.
35 fmol of trypsin can be detected by using the on-chip assay.
36 ility and behavior were preserved during the on-chip assembly process.
37 entire nerve regeneration studies, including on-chip axotomy, post-surgery housing for recovery, and
38  C1 system, providing its first single-cell, on-chip barcoding method, and we detected gene expressio
39 aluated the performance of the molecular lab-on-chip-based VerePLEX Biosystem for detection of multid
40 ortant considerations for the development of on-chip batteries is the need to photopattern the solid
41 ing distributed feedback laser array with an on-chip beam combiner.
42                                The developed on-chip biosensors are based on the conduction of molecu
43 radient is utilized to achieve the DEP-based on-chip cell separation.
44 ntacting the sample, and pave the way for an on-chip circuit element of practical the zero-field micr
45 n spin resonance (ESR) measurements with the on-chip circuitry already needed for qubit manipulation
46                                          The on-chip circuitry measures the current flowing through e
47 ted that the SSDL concept may lead to future on-chip circulators over multi-octaves of frequency.
48 able active and passive photonic devices for on-chip coherent light sources, optical signal processin
49 -oxide-semiconductor compatible platform for on-chip comb generation using silicon microresonators, a
50  of information using plasmonic antennas for on-chip communication technology.
51 ic nanoscale devices for both free-space and on-chip communication.
52                      Here, we demonstrate an on-chip compatible method to fabricate high energy densi
53 nsumption, open up a path to fast, parallel, on-chip computation based on networks of oscillators.
54                                Exploiting an on-chip concentration protocol in the SPM and the single
55 larisation-based quantum dot applications in on-chip conditions.
56 ell level through microfluidic cell pairing, on-chip culture, and multiparameter assays, and allows r
57 hment of both known and de novo motifs based on ChIP data.
58                           Such an engineered on-chip Demon measures and performes feedback on the sys
59                                         With on-chip desalting, the limit of quantitation for histidi
60 rature distribution and photosensors for the on-chip detection and a ground plane ensuring that the h
61 tion with PCR-amplified genomic DNA confirms on-chip detection and identification of Escherichia coli
62 tection efficiency beyond 10%, and estimated on-chip detection efficiency of 14-52% for four detector
63 ll-volume analysis and is a primary tool for on-chip detection in microfluidic devices, yet additiona
64  suitable for on-chip thermal treatments and on-chip detection of biomolecules.
65                                         This on-chip detection simplifies GP imaging as sophisticated
66 lerate an immuno-reaction time, in which the on-chip detection time was 5min, and demonstrating an ab
67                     Here, we present a liver-on-chip device capable of maintaining human tissue for o
68 rk was dedicated to the development of a lab-on-chip device for water toxicity analysis and more part
69 e potential drops in a flow channel in a lab-on-chip device that accommodates chemical reactions on e
70                       This paper presents an on-chip device that can perform gigahertz-rate amplitude
71 termine TEER that is applicable to any organ-on-chip device with two channels separated by a membrane
72 -brain barrier inside our microfluidic organ-on-chip device.
73 of cavity based line-narrowing in MoS2-based on-chip devices as it is required for instance for frequ
74 al and ultimately widespread implementation, on-chip devices compatible with electronic integrated ci
75 iological analysis, lubrications, laboratory-on-chip devices, and near-field imaging techniques.
76 s instruments as well as electrophoretic lab-on-chip devices, while maintaining a performance in term
77 ter harvesting, biochemical analysis and lab-on-chip devices.
78 usive transport of molecules and ions across on-chip DIBs can be studied and quantified using fluores
79                               We demonstrate on-chip, differential DNA and RNA extraction from a sing
80 ssor with off-chip memory (with hypothetical on-chip digital resistive random access memory).
81    The RDM accepts four samples that undergo on-chip dilution to five different concentrations that c
82 llators in a spatially distributed system of on-chip DNA compartments as artificial cells, and measur
83                                              On-chip drop size control measures were applied to stabi
84                   Electrochemical monitoring-on-chip (E-MoC)-based approach for rapid assessment of h
85 en recently successfully used to demonstrate on-chip effects of quantum optics with single atoms in t
86 . aeruginosa (6294), S. aureus(LAC), through on-chip electrical sensing of bacterial lysate.
87                            Here we report an on-chip electrical transport spectroscopy approach for d
88 itting lasers (VCSELs) can be employed as an on-chip, electrically pumped source or detector of plasm
89 trix modified with capturing biomolecule for on-chip electrochemical biosensing.
90 l (2D) membrane based off-surface matrix for on-chip electrochemical immunoassay.
91  we design a nanodevice platform and combine on-chip electrochemical impedance spectroscopy measureme
92 ins with a high electron-phonon coupling and on-chip electronic filters, combined with low-noise elec
93 ation process, we demonstrate cooling of the on-chip electrons from 9 mK to below 5 mK for over 1000
94                                We present an on-chip electrophoretic assay for rapid protein detectio
95                                              On-chip energy storage and management will have transfor
96                                In this work, on-chip energy storage is demonstrated using architectur
97 able a wide range of applications for future on-chip energy storage.
98 d on amorphous silicon validates its use for on-chip energy-storage applications.
99                                       In our on-chip enrichment system, cancer cells were driven by h
100  test, both of which confirm a high level of on-chip entanglement.
101 potentially lead to significant reduction in on-chip estate for waveguide elements and salient enhanc
102         These engineered 3D proximal tubules on chip exhibit significantly enhanced epithelial morpho
103                                          The on-chip fabricated bridging nanosyringe ultraviolet dete
104          Integrated pumps and valves perform on-chip fluid and cell manipulations that provide dynami
105 a over conventional electrodes of equivalent on-chip footprint areas.
106 exceed 1 cm in thickness and can be perfused on chip for long time periods (>6 wk).
107 escribe the generation of pressure gradients on-chip for driving liquid phase separations in submicro
108 d microfluidic injection system was included on-chip for performing precise dynamic biochemical stimu
109  Further, conditions were selected to enable on-chip fractionation of multiple analytes.
110                                       We use on-chip frequency demultiplexers and reconfigurable opti
111                          Here we demonstrate on-chip generation of entangled qudit states, where the
112                                          The on-chip glycan modification and probing (on-chip GMAP) m
113 The on-chip glycan modification and probing (on-chip GMAP) method provides a platform for analyzing p
114 ation of magneto-optic nonreciprocal systems on chip have made imperative the exploration of magnet f
115  but also may enable the compact, integrated on-chip high-speed mid-infrared photodetectors, modulato
116 of SP-PCR and SAF microlens array allows for on-chip highly sensitive and multiplexed pathogen detect
117 6 fM (338 molecules) for target RNA after 1h on-chip hybridization.
118 uilibrium solubility determination, based on on-chip hydrodynamic particle trapping and optical parti
119                                              On-chip imaging of intact three-dimensional tissues with
120  a large field-of-view of >16 mm(2) using an on-chip imaging platform, where the sample is placed at
121 hat provides such capabilities in a scalable on-chip implementation, allowing direct integration of G
122 atible with all necessary manipulation steps on-chip, including the matrix delivery for MALDI-TOF ana
123 hip heat denaturation followed by sequential on-chip incubation of the nucleic acids and MNPs, produc
124 tive cellular interaction with E. coli cells-on-chip indicating that the cells suffered from severe c
125 zation of high-performance, small-footprint, on-chip inductors remains a challenge in radio-frequency
126  in micro- and nanostructures is crucial for on-chip information processing.
127 l wavelength, thereby relaxing the design of on-chip integrated filters for separating pump, signal a
128 hold the key to future high-bandwidth, dense on-chip integrated logic circuits overcoming the diffrac
129 tations have prevented the realization of an on-chip integrated mid-infrared microresonator comb sour
130 ce can enable tunable, compact THz emitters, on-chip integrated spectrometers, inspire a broader use
131 otential for exploring Weyl point physics in on-chip integrated systems.
132                             The demonstrated on-chip integration is up and down-scalable, compatible
133                                              On-chip integration of optical detection units into the
134 nco et al. stride toward this goal by hybrid on-chip integration of Si3N4 waveguides and GaAs nanopho
135 eart of many emerging technologies that seek on-chip integration of solid-state photonic systems.
136 ough thin-film batteries are well-suited for on-chip integration, their energy and power per unit are
137 ctrodes not compatible with manufacturing or on-chip integration.
138                                          The on-chip iridium oxide (IrOx) pseudo-reference electrode
139 lti-electrode polysilicon nanogap (PSNG) lab-on-chip is designed in this study, facilitates multiplex
140                        This work presents an on-chip isothermal nucleic acid amplification test (iNAA
141             Here we report a low-phase-noise on-chip Kerr frequency comb with mode spacing compatible
142                                   While many on-chip key components have been realized, to date polar
143  materials and sensing platforms such as lab-on-chip, lab-on-CD, lab-on-paper etc.
144 ties can be utilized in applications such as on-chip light modulation, photonic logic gates, optical
145                                      Compact on-chip light sources lie at the heart of practical nano
146 in energy transfer as the basis for flexible on-chip light sources, amplifiers, nonreciprocal devices
147 with microfluidic- and nanofluidic-based lab-on-chip (LOC) devices for point-of-care (POC) diagnostic
148 ength scales, the development of complex lab-on-chip (LOC) systems is in the focus of many current re
149  developed submersible analyzer based on lab-on-chip (LOC) technology.
150                                 We introduce on-chip lysis and non-enzymatic DNA cleavage directly fo
151                                              On-chip magnetic cooling is a promising approach to meet
152                       Here we demonstrate an on-chip magnetic-free circulator based on reservoir-engi
153 this article, we describe an acoustic-based, on-chip manipulation method that can rotate single micro
154 vely, we have demonstrated that CRISPR-based on-chip mechanical screening is a potentially powerful s
155 ) using a methylated DNA immunoprecipitation on chip (MeDIP-chip).
156 l allocation scheme of scarce resources like on-chip memory and caches in order to boost performance
157 ic substrates, promising their potential for on-chip memory organization is limited by unreliable bit
158 ) used in the semiconductor industry for the on-chip metallization of interconnects.
159 ions to date have been usually restricted to on-chip micro-devices.
160                            AC line-filtering on-chip micro-supercapacitors (MSCs) based on coordinati
161 ely integrated into microfluidics to provide on-chip microdevices for a variety of applications in bi
162                                    All-glass on-chip microresonators significantly reduce these diffi
163  combs and solitons have been generated from on-chip microresonators.
164 ves a compact and cost-effective holographic on-chip microscope and a surface-functionalized glass su
165 rds this aim, we have designed a holographic on-chip microscope operating at an ultraviolet illuminat
166 m implemented on a wide field-of-view (FOV), on-chip microscopy platform, termed ePetri.
167       This microcolony-counting system using on-chip microscopy represents a new platform that substa
168 Barzanjeh et al. demonstrate a magnetic-free on-chip microwave circulator that utilizes the interfere
169 his spin-photon interface is integrated with on-chip microwave striplines for coherent spin control,
170 ts, the developed microfluidic biochips with on-chip MIP biosensors present the advantages of a compa
171 al for realization of the next generation of on-chip modulators and switches at THz frequencies.
172 c-based assay for automated manipulation and on-chip monitoring and analysis of stimulus-evoked calci
173                                 The reported on-chip MSCs showed a low impedance phase angle of -73 d
174 s by all-electrical means is at the heart of on-chip nano-optical processing.
175 circumvent the phase-matching requirement in on-chip nonlinear wavelength conversion.
176 ved can pave the way to the demonstration of on-chip nonlinear-based applications, including mid-IR s
177                                 Human organs-on-chips offer a potentially powerful new approach to co
178 antibodies in an individual can be displayed on chips on which 130,000 peptides chosen from random se
179 d of a microchip and an adjustable clamp, so on-chip operation only needs pipetting and adjusting of
180 en sources, thus enabling the realization of on-chip optical communication and lab-on-a-chip devices.
181 tance for frequency-multiplexed operation in on-chip optical communication and sensing.
182 and compatible with integrated photonics for on-chip optical communication technologies.
183                                      Present on-chip optical communication technology uses near-infra
184 oscopy, spectroscopy, quantum computing, and on-chip optical communication.
185 mical sensing, super-resolution imaging, and on-chip optical communication.
186 more user-friendly experience; alignments of on-chip optical components are predetermined during fabr
187                                          The on-chip optical delay elements offer an integrated appro
188 ndered by the lack of sensitive and portable on-chip optical detection technology.
189                                          The on-chip optical detection was performed in a single acqu
190 applications including integrated photonics, on-chip optical interconnects and optical sensing.
191 tectors can enable low power, high bandwidth on-chip optical interconnects for silicon integrated ele
192 gain-saturation nonlinearity, we demonstrate on-chip optical nonreciprocity with excellent isolation
193 ualization functionality, the system enables on-chip optimization of electroporation parameters for c
194 eriments (DOE) operation to enable automated on-chip optimization of elution solvent composition for
195  interesting for applications in imaging and on-chip optoelectronic integration.
196 ial fuel cell (MFC) for potentially powering on-chip paper-based devices.
197 single chirality level for nanotube sorting, on-chip passivation, and nanoscale lithography.
198 unts of data every second, store it directly on-chip, perform in situ processing of the captured data
199 d system for rapid label-free separation and on-chip phenotypic characterization of circulating tumor
200 ate, to the best of our knowledge, the first on-chip photon correlation measurements of non-classical
201 tentially compact and efficient platform for on-chip photonic applications.
202  a realization of a microprocessor that uses on-chip photonic devices to directly communicate with ot
203                                              On-chip photonic networks hold great promise for enablin
204 -infrared thin-film waveguide technology and on-chip photonics facilitating next-generation label-fre
205 c, stable and efficient emitter material for on-chip photonics without the need for epitaxy and is at
206 rials promising for fast optoelectronics and on-chip photonics.
207  a proof-of-concept technology comprising an on-chip planar Goubau line, integrated with a microfluid
208 aterials used for the fabrication of the lab-on-chip platform were selected in order to obtain a devi
209 current trend is toward fully integrated lab-on-chip platforms with smartphone readouts, enabling hea
210 nt and tunable transport in microfluidic lab-on-chip platforms.
211 etection scheme for low-cost, disposable lab-on-chip point-of-care (POC) diagnosis system.
212           We also demonstrate all-dielectric on-chip polarization rotators based on phased arrays of
213 and 10(2)-10(4)CFU for typing bacteria by an on-chip polymerase chain reaction.
214                                   The entire on-chip process of sonication and IP took only 1 h.
215 s that will make commercial upscaling of lab-on-chip products financially viable.
216                   As a proof of concept, the on-chip protease assays are used to detect trypsin in bu
217 ing either the intact protein mass or, after on-chip proteolytic digestion, the peptide mass fingerpr
218 To this aim, we adapted iTRAQ labeling to an on-chip protocol.
219 entations of high-speed quantum networks and on-chip quantum information processors using nanophotoni
220 early has an impact on technology (e.g., for on-chip quantum networking).
221 ene platform here constitutes a step towards on-chip quantum simulators of graphene and unique monoli
222  of incorporating plasmonic metamaterials in on-chip quantum state engineering tasks.
223 evelopment of quantum network nodes requires on-chip qubit storage functionality with control of the
224 se to use the photon-assisted shot noise for on-chip radiation detection.
225  on-chip vortexing of the magnetic beads and on-chip reagent storage and actuation were developed.
226 roof-of-concept results pave the way towards on-chip realization of efficient graphene-based active p
227                        In a principle study, on-chip recombinase polymerase amplification (RPA) on de
228          Analysis of intestinal inflammation on-chip revealed that immune cells and lipopolysaccharid
229 tonic systems, including an array of coupled on-chip ring resonators at communication wavelengths.
230 tly the transport of a tracer in a Reservoir-on-Chip (RoC) micromodel filled with two immiscible flui
231  off-chip preparation of reagents and 10 min on-chip run).
232                         Fully-integrated lab-on-chip sample preparation overcomes technical barriers
233                              Here, we report on-chip sample preparation, amplification-free detection
234                         The aptamer-antibody on-chip sandwich immunoassay may be further refined to a
235 ions, thus demonstrating their potential for on-chip scalable quantum light-matter interfaces.
236 d purification of liposomes which offers lab-on-chip scale production.
237 ercome by using optical communications based on chip-scale electronic-photonic systems enabled by sil
238 plemented by more recent advancements toward on-chip semiconductor waveguides, it is anticipated that
239 ion, the inner surface provides an excellent on-chip sensing platform that truly opens up the possibi
240 w touch paper spray method was developed for on-chip, sensitive, and cost-effective analyte detection
241  and novel amplification scheme for entirely on-chip, sensitive, and highly specific miRNA detection
242 anes that are compatible with integration in on-chip sensor arrays is demonstrated.
243 me also offers a new approach for integrated on-chip sensors.
244                            This simultaneous on-chip separation and concentration shows feasibility o
245 ifs can be identified from a network trained on ChIP-seq data and that nucleosome positioning signals
246 transcription factor flexible models trained on ChIP-seq data for vertebrates, which capture dinucleo
247 unctional genomics' public catalogs is based on ChIP-seq data.
248                                              On ChIP-seq datasets, our method obtains best AUC result
249                                     Focusing on ChIP-seq experiments, we developed a novel approach t
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 n increasingly important component in System-on-Chip (SoC) designs with increasing transistor scaling
253                         Our assay integrates on-chip solid-phase extraction (SPE) with online nanoflo
254  Our results demonstrate the availability of on-chip solid-state mechanical resonators as light-matte
255  This paper presents wavelength configurable on-chip solid-state ring lasers fabricated by a single-m
256 el with their integrability in semiconductor on-chip solutions and the potential that photon emission
257 f exosomes, and so open up the potential for on-chip sorting and quantification of these important bi
258 the main principles which are underneath the on-chip spectrophotometric detection, approaching the Ph
259 rization state of light, enabling integrated on-chip spectropolarimetric analysis.
260                                    Arrays of on-chip spherical glass shells of hundreds of micrometer
261 pment of an automated, integrated system for on-chip sputum processing and analysis.
262 iter scale by combining whole-cell catalyzed on-chip syntheses, chiral microchip electrophoresis, and
263 is review will also highlight the integrated on-chip systems for isolation and characterization of EV
264 ose alternatives to magneto-optic effects in on-chip systems.
265 from fluid processing to 3D printing and lab-on-chip systems.
266 lem, we developed the Tumor-microenvironment-on-chip (T-MOC), a new microfluidic tumor model simulati
267  recombinase and polymerase proteins through on-chip target amplification and solid-phase elongation
268 ro-supercapacitors are attractive for system on chip technologies and surface mount devices due to th
269 f a substrate is essential for realizing lab-on-chip technologies.
270                                      The lab-on-chip technology described by A. M. Cabibbe et al. pot
271 nanotechnology, microfluidics and laboratory-on-chip technology in advancing the field.
272 hondrial damage, a unique advantage of organ-on-chip technology.
273 ing Stokes flow and the accessibility of lab-on-chip technology.
274 ological systems (MPS), also known as organs-on-chips, that recapitulate the structure and function o
275 dly solid-state refrigeration and integrable on-chip thermal management.
276 elop a multifunctional platform suitable for on-chip thermal treatments and on-chip detection of biom
277 mounting accessory specifically designed for on-chip thin-film GaAs waveguides is presented serving a
278 icated on plastic substrates were integrated on-chip to excite the test line of a quantum dot-based L
279  unit operations are combined and integrated on-chip to miniaturize complex biochemical assays.
280 t integration of the immunosensor with liver-on-chips to carry out continual quantification of biomar
281  the target cell population, enabling direct on-chip tumor cell identification and enumeration.
282 ith low operation voltage and graphene-based on-chip ultrafast optical communications.
283    The trapped mitochondria were depolarized on chip using an ionophore with results showing that the
284 lian mitochondria arrays were rapidly formed on chip using this technique without any surface modific
285 perometric detection of silver nanoparticles on-chip using a microelectrode array.
286 sly reported non-valved device by 74% due to on-chip valve integration providing controlled and accur
287                We have developed a versatile on-chip vortex-assisted electroporation system, engineer
288                           Novel concepts for on-chip vortexing of the magnetic beads and on-chip reag
289                   The amount of protein used on-chip was about 11 ng.
290                                        Cells-on-chip was then allowed to interact with different size
291 gration and miniaturization, the need for an on-chip waveguide type waveplate becomes extremely urgen
292 dimensional (3D) integrated Si photonics for on-chip wavelength-division multiplex (3D WDM) systems f
293  experimentally demonstrate an ultracompact, on-chip waveplate using an asymmetric hybrid plasmonic w
294  on the observation of quantum Zeno blockade on chip, where a lightwave is modulated by another in a
295 must generate and control qubit entanglement on-chip, where quantum information is naturally encoded
296 charge photoionization detector (muHDBD-PID) on chip with dimensions of only approximately 15 mm x ap
297         Leukocytes in blood are first washed on-chip with defined buffer to remove background activit
298 an innovative approach to stabilize surfaces on-chip with multiple layers of immunochemistry.
299 rates at room-temperature and are integrated on-chip with planar nanoantennas, which provide remarkab
300 ly determine the TEER in microfluidic organs-on-chips without the need for integrated electrodes clos

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