ライフサイエンスコーパス: miniaturize

1 which are bulky, expensive, and difficult to miniaturize.

2 and the system design can easily be further miniaturized.

3 In this article, a novel, miniaturized 3D wearable PAT (3D-wPAT) technique is desc

4 A miniaturized 3D-printed device has been designed, manufa

5 idic plates (cPlate), which are comprised of miniaturized 96-well plates and their corresponding chan

6 ch may form the basis for the development of miniaturized all-solid-state ion-selective electrodes fo

7 Miniaturized alternatives to Western blot based on micro

8 ss tracking requires reliable, non-invasive, miniaturized, ambulatory, and inexpensive systems for co

9 Here we present a miniaturized analog of a blinking human eye to reverse e

10 decades, there has been immense progress in miniaturizing analytical methods based on electrophoresi

11 Here, we miniaturize and automate the previously described Cell S

12 The blister packages seem difficult to miniaturize and none of the existing liquid handling tec

13 us emulsion creamer (ICEcreamer) was used to miniaturize and optimize measurements of various enzymat

14 and transport systems have been integrated, miniaturized and combined with flexible materials for im

15 re obtained under optimal conditions for the miniaturized and conventional approaches, respectively.

16 protocol with less sample volume and easily miniaturized and cost-effective instrumentation.

17 zymatic biosensors represent cost-effective, miniaturized and easy to use devices; particularly biose

18 les has a great potential for fabrication of miniaturized and extremely powerful sensors to investiga

19 urposes, a three-electrode configuration was miniaturized and fitted onto a biochip.

20 y enhancing analytical performance, but also miniaturized and full-functional sensing components that

21 nce imaging devices are recognized for their miniaturized and implantable nature that can benefit the

22 s may be used with devisible consequences in miniaturized and implementable submersible probes, and (

23 Developing miniaturized and inexpensive detectors remains an import

24 Here, a miniaturized and integratable electronic antibiotic sens

25 the present study was to combine the use of miniaturized and integrated impedimetric transducers and

26 l solutions are available for the automated, miniaturized and integrated induction of defined wound a

27 nsitive and accurate transducers that can be miniaturized and multiplexed, and that are easy to opera

28 Although this technique is readily miniaturized and numerous instruments have been develope

29 the FGF14:Nav1.6 complex, we have developed, miniaturized and optimized an in-cell assay in 384-well

30 ion of various biosensing components with/in miniaturized and portable devices are essential but stil

31 ent techniques can be implemented that allow miniaturized and portable instrumentation.

32 Therefore, a simple, miniaturized and selective biosensor was developed, bein

33 ensor can be easily incorporated into future miniaturized and semiautomatic devices for EV determinat

34 pacing in a leadless fashion by implementing miniaturized and wirelessly powered pacemakers.

35 development of universal, highly sensitive, miniaturized, and integrated nanoelectronic devices that

36 e preparation, a trained operator, cannot be miniaturized, and lack the ability to perform automated

37 approach offers a new platform for a rapid, miniaturized, and sensitive diagnostic sensor in a singl

38 However, miniaturized antenna designs often have lower performanc

39 in pola2 mutants, leading to regeneration of miniaturized appendages.

40 hermore, the muHDBD-PID can be driven with a miniaturized ( approximately 5 cm x approximately 2.5 cm

41 sharing many attributes of other art forms, miniaturized art enables the direct engagement of sensor

42 rapid nucleic acid preparation methods with miniaturized assay and sensor technologies would pave th

43 This test screen demonstrated that the miniaturized assay is extremely suited for high-throughp

44 They miniaturize assays to reduce sample and reagent consumpt

45 etic particles inside microfluidic chips for miniaturized assays is often challenging due to ineffici

46 rbon, and then deposited on the surface of a miniaturized Au electrode (7mm(2)) to prepare a miniatur

47 Here we report the development of a miniaturized, automated AlphaScreen ultra-high-throughpu

48 surface of microbeads to create millions of miniaturized barcoding reactions in a single tube.

49 Miniaturized, battery-powered piezoelectric pumps are ut

50 Moreover, by utilizing a miniaturized beam projector, it can back-project 2D cros

51 Here we introduce a miniaturized bio-optoelectronic implant that avoids thes

52 ow-cost, rapid, sensitive, reproducible, and miniaturized bioanalytical devices, which exploit the hi

53 SECM is important in the development of miniaturized bioanalytical systems with enzymes, since i

54 are poised to replace robotic automation by miniaturizing biochemical reactions to the droplet scale

55 The advent of miniaturized biologging devices has provided ecologists

56 c devices have the potential to automate and miniaturize biological experiments, but open-source shar

57 The miniaturized bioreactors, with maximized surface area-to

58 enables the establishment of a low-cost and miniaturized biosensing platform.

59 The miniaturized biosensor, which is composed of five chambe

60 of PN hybrids for the construction of these miniaturized biosensors are focused.

61 in 0.5-M NaIO(4) for 48 hours, devices were miniaturized by 78% in surface area, and this treatment

62 that paper patterned via wax printing can be miniaturized by treating it with periodate to produce hi

63 An automated and miniaturized chemiluminescence method for screening of f

64 tern and polarization programmability into a miniaturized chip-scale THz sensor.

65 resulting technology, FloChIP, automates and miniaturizes ChIP in a beadless fashion while facilitati

66 may enable in the future the development of miniaturized cold-atom instruments.

67 This methodological approach illuminates how miniaturized components interact and function in complex

68 optical signal processing functionalities in miniaturized components.

69 upling with a detection technique of choice, miniaturized configuration and simple implementation for

70 To validate this device, we implemented a miniaturized coupled assay for NAD(+)-dependent amino ac

71 Developing easy-to-use and miniaturized detectors is essential for in-field monitor

72 The MDC-TENG realizes both the miniaturized device and high output performance.

73 orporation of portable hand-held readers and miniaturized devices are then surveyed.

74 n silicon is critical for reliable design of miniaturized devices operating at high temperatures.

75 Organ-on-chip (OOC) devices are miniaturized devices replacing animal models in drug dis

76 The miniaturized devices were shown to be compatible with re

77 otonic platforms for realizing and designing miniaturized devices, their chromatic aberrations have h

78 acid biomarkers of pathogens and diseases in miniaturized diagnostic devices.

79 e, we developed an optofluidic platform that miniaturizes digital assays into a mobile format by para

80 s, with an emphasis on multimodal operation, miniaturized dimensions, biocompatible designs, advanced

81 ylated polythiophene films on the surface of miniaturized, disposable, gold screen-printed electrodes

82 We developed a miniaturized Distributed Oxygen Sensor ("mDOS") specific

83 opy imaging as a quantitative technique in a miniaturized droplet format, which is shown to be as rel

84 Following this goal, a low cost miniaturized, easy-to-use and highly automated microanal

85 s remarkable potential for highly sensitive, miniaturized, easy-to-use, and versatile gas sensing.

86 An ultra-miniaturized electrochemical biosensor for continuous gl

87 We propose that adopting miniaturized electrochemical EBOV immunosensing can dete

88 or the development of low-cost, portable and miniaturized electrochemical systems for point-of-care a

89 ivity and rapid response, MIPs combined with miniaturized electrochemical transducers offer the possi

90 as "the internet of biology" in the same way miniaturized electronic sensors have enabled "the intern

91 h types of technologies, by combining highly miniaturized electronics and energy harvesters with inje

92 EL biosensor is amenable to integration with miniaturized electronics, which could afford a portable,

93 undary electrophoresis (GEMBE), a robust and miniaturized electrophoretic separation technique, was e

94 The 3DI instrument is composed of a miniaturized electrostatic analyzer (ESA) and a deflecto

95 Micro-supercapacitors are promising miniaturized energy storage devices that have attracted

96 iaturized Au electrode (7mm(2)) to prepare a miniaturized enzyme anode.

97 A miniaturized FAIMS device capable of rapid compensation

98 temperature in nanostructures is needed for miniaturizing ferroelectric devices.

99 rbohydrazide (DPC) and finally detected by a miniaturized fiber optic CCD spectrophotometer at 520 nm

100 ed optoacoustic neural stimulation through a miniaturized Fiber-Optoacoustic Converter (FOC).

101 We report a miniaturized filter aided sample preparation method (mic

102 An easily performed fully automated and miniaturized flow injection chemiluminescence (CL) metho

103 to 50 kHz, providing an effective means for miniaturized flow sensing.

104 rmats for applications that require portable miniaturized fluid handling such as point-of-care testin

105 ems are now being designed with precision as miniaturized fluid manipulation devices that can execute

106 Miniaturized fluorescence microscopes (miniscopes) have

107 For this, we used in vivo miniaturized fluorescence microscopy to reliably track r

108 ringing the powerful analytical toolkit in a miniaturized footprint to extreme operating conditions.

109 n of SPR and QCM and has the potential to be miniaturized for application in point-of-care (POC) diag

110 s via antigen-antibody recognition, has been miniaturized for microfluidic platforms to reduce reagen

111 The proposed MCPE is essentially a miniaturized form of traditional cloud point extraction

112 These electrodes can also be fabricated in miniaturized form, and thus used to produce miniaturized

113 The miniaturized format allows for small sample and reagent

114 Miniaturized forms of agrin (mAgrin) have been shown to

115 Miniaturized frequency comb sources across hard-to-acces

116 l resonators have the potential to provide a miniaturized frequency reference for metrology and sensi

117 rkers, an important step toward developing a miniaturized, fully integrated analysis system.

118 mbly techniques on a micro- and nanoscale to miniaturize functional devices for biomedical uses.

119 d multi-parametric flow cytometry panels and miniaturized functional assays validated for use with cr

120 Here, we make an important step towards miniaturizing functional components on this platform, re

121 a dynamic inlet system coupled with a fast, miniaturized gas chromatograph (GC).

122 Here, we report the synthesis of miniaturized gold nanorods absorbing in the NIR-II that

123 The integration of efficient, miniaturized group IV lasers into CMOS architecture hold

124 alysis of the hair bulb region of normal and miniaturized hair follicles from vertex and occipital re

125 d androgen receptor in the dermal papilla of miniaturized hair.

126 vancements have resulted in the emergence of miniaturized handheld ultrasound equipment that is compa

127 iatic nerve implant, powered and driven by a miniaturized head-mounted control unit.

128 Miniaturized heart rate telemetry shows that they use a

129 The miniaturized HEMT chip is packaged in a polymer substrat

130 ctrospray ionization (DESI), hyphenated with miniaturized high-field asymmetric waveform ion mobility

131 asis for the design of nanoarchitectures for miniaturized high-performance magneto-optical devices.

132 der-Waals pressures up to 1 GPa, producing a miniaturized high-pressure container for the crystalliza

133 mg scale using glass microvials providing a miniaturized high-throughput experimentation capability

134 We demonstrate the application of miniaturized high-throughput experimentation methods to

135 dic modules for the implementation of highly miniaturized immunoassays.

136 le, long-lasting neural recording; wireless, miniaturized implants; signal transmission, amplificatio

137 For the evaluation of the miniaturized in stillo reactions, the degradation reacti

138 lectronic detection holds promise for future miniaturized in-situ applications and can be integrated

139 ve micro-PMFC improved significantly through miniaturizing innovative device architectures and connec

140 tandard semiconductor technology to create a miniaturized integrated bioelectronics system that consi

141 ents remain vital for the next generation of miniaturized integrated circuits.

142 will enable the realization of programmable miniaturized integrated optoelectronic devices and on-de

143 multilayer modulator chip offering a robust miniaturized interface for multidimensional liquid chrom

144 tic chemistry conditions discovered in these miniaturized investigations enabled the development of s

145 A wearable and miniaturized iontophoresis interface is an excellent sol

146 Based on the detection principle, a miniaturized kit [20.0 mm (L) x 20.0 mm (W) x 2.15 mm (H

147 nting to build an ultra-low-cost, rapid, and miniaturized lab-on-a-chip (LOC) platform.

148 Miniaturized lab-on-a-chip systems offer properties - e.

149 Specifically, we designed a miniaturized label-free aptasensor for B. cereus spores

150 There is a clear demand for rugged miniaturized lasers with stabilities comparable to those

151 The detector was applied within a miniaturized LC system.

152 The miniaturized LCE actuators offer large-area work capacit

153 electrodes: they are bulky and difficult to miniaturize, leak electrolyte to the medium, lose the ab

154 ation of various (bio)chemical analytes in a miniaturized, low-coat, rapid, and user-friendly manner.

155 onic devices and has been widely utilized as miniaturized magentic sensors.

156 d protein detection scheme in a low-cost and miniaturized magnetic levitation setup consisting of two

157 In this study, a miniaturized mass spectrometer in combination with three

158 e experiments show that the combination of a miniaturized mass spectrometer, ambient ionization, and

159 uraging and suggests that RTILs and low-cost miniaturized MATFEs can be combined in amperometric sens

160 A flexible and miniaturized metal semiconductor metal (MSM) biomolecula

161 Cost effective and miniaturized methods aiming for high throughput monitori

162 linearities that are particularly strong for miniaturized micro- and nano-mechanical systems.

163 This paper reports on a miniaturized microbial fuel cell with a microfluidic flo

164 In summary, the concept of miniaturized microcage designs with such straight-forwar

165 Miniaturized microfluidic biosensors have recently been

166 n an Au film electrode in an electrochemical miniaturized microfluidic cell.

167 Miniaturized microfluidic fluorescence sensors are an ap

168 The bioprinter employs a highly miniaturized microfluidic sorter to deterministically se

169 viable pathway for building a dense array of miniaturized (micron-scale) electrochemical sensors with

170 This treatment miniaturized microPADs by up to 80% in surface area, dep

171 We developed miniaturized microphones to record spontaneous vocalizat

172 Therefore, we developed a miniaturized microscope with: a fluorescence (FL) channe

173 ice using two-photon microscopy or an nVista miniaturized microscope.

174 at cellular scale in freely moving animals, miniaturized microscopes and lensless imagers are develo

175 or flexible wireless communication and other miniaturized microwave systems.

176 inting strategy is used to fabricate a novel miniaturized modular microcage scaffold system, which ca

177 a protruded tip, which can be fabricated and miniaturized more readily to facilitate nanoscale SECM i

178 The development of this novel, flexible and miniaturized MSM biomolecular photodetector with excelle

179 Herein, we present a miniaturized multi-sensor platform capable of real-time

180 miniaturized form, and thus used to produce miniaturized multielectrode probes.

181 dicationic ion-pairing compounds through the miniaturized multifunctional device, the single-probe, f

182 The device is a miniaturized neural interface capable of closed-loop rec

183 This requires miniaturized neural interfaces that integrate into brain

184 The miniaturized neural stimulator may facilitate closed-loo

185 r nanoscale component because it can lead to miniaturized non-volatile memory storage devices.

186 The miniaturized noninvasive VOC sensor can be applied to br

187 c acid (mRNA) using magneto-DNA probes and a miniaturized nuclear magnetic resonance device.

188 The needle tip, equipped with a miniaturized OCT depth-sensing probe, was inserted for a

189 e of the spectrally filtered array towards a miniaturized on-chip fluorescence imaging device, which

190 escence imaging approaches based on two- and miniaturized one-photon microscopy.

191 Microresonator solitons are critical to miniaturize optical frequency combs to chip scale and ha

192 on of a microfluidics platform in a homemade miniaturized optical analyzer provides a promising way f

193 would be to devise strategies through which miniaturized optical devices can be monolithically fabri

194 After coupling to a miniaturized optical reader for fluorescence detection,

195 ltimate limit provides more possibilities to miniaturize optoelectronic devices and to test fundament

196 We developed a miniaturized optoelectronic biosensor using a vertical c

197 d by solid-state lasers, a number of new and miniaturized organic lasers have emerged that hold great

198 noparticles sensors were read out by adapted miniaturized oxygen meters.

199 digital communication electronics for thin, miniaturized pacing platforms weighing 110 mg with capab

200 Thus, we demonstrated a remote-controlled miniaturized pacing system with low power consumption, t

201 Herein, we developed a simple, miniaturized paper/PMMA (poly(methyl methacrylate)) hybr

202 In the miniaturized parasitoid wasp Trichogramma evanescens Wes

203 non-toxic, thermally stable and feasible for miniaturized PCR chips.

204 rotocols were tested in the development of a miniaturized peptide map procedure.

205 The chemiluminescence in the miniaturized photocurrent sensing system was successfull

206 potential coupling with previously reported miniaturized photodetectors.

207 owth rates and size distribution using a USB miniaturized photometer.

208 The recent emphasis on the miniaturized photonic platform is thus motivated by the

209 Miniaturized photonic sources based on semiconducting tw

210 promoter, and increase dynamic range with a miniaturized photosensor kinase.

211 on the development of simple, low-cost, and miniaturized photothermal diagnostic platforms for quant

212 Our results validate the application of miniaturized physiologically relevant and orthogonal WIP

213 cept, in which all relevant steps for online miniaturized planar chromatography are performed by a si

214 Here we utilize miniaturized plasma exchange to deliver labeled albumin

215 In this context, we have developed a miniaturized plasmonic biosensor platform based on a hyp

216 NL structures open new avenues for designing miniaturized plasmonic nanodevices with various applicat

217 The gel array chip could be a useful miniaturized platform for high-throughput detection of d

218 ment was configured to run on low power in a miniaturized platform to improve the device portability

219 bstrate as a first step towards developing a miniaturized platform.

220 on of various types of bioassays on a single miniaturized platform.

221 lization of highly complex and sophisticated miniaturized platforms for several important healthcare

222 multicolor mu-ILEDs with fully implantable, miniaturized platforms.

223 gh sensitivity, selectivity, robustness, and miniaturized point-of-care cancer diagnostics.

224 didate to replace energy storage devices for miniaturized portable electronic applications.

225 testing is the development of a chip-based, miniaturized, portable, and self-containing system that

226 Miniaturizing potentiostats, keeping their cost low and

227 as then integrated with a lab-built low-cost miniaturized printed circuit board (PCB) to provide an e

228 Miniaturized quarter-wave plate devices empower spin to

229 in a capillary HPLC system and could offer a miniaturized, rapidly stabilized, highly sensitive, and

230 The in stillo miniaturized reactions provided immediate real-time snap

231 done by coupling a three-dimensional printed miniaturized reactor with an integrated electrospray ion

232 y creating libraries of thousands of unique, miniaturized reactors, droplet microfluidics provides a

233 improve the viability of producing low-cost miniaturized reference electrodes with interest in many

234 We fabricated miniaturized SAF microlens array as part of a microfluid

235 cted second-order derivative procedure and a miniaturized sample preparation based on low-density sol

236 This multiplexed, miniaturized sample preparation microdevice establishes

237 Herein, we developed a miniaturized screening assay to identify inhibitors of P

238 However, the development of miniaturized screening procedures/platforms to expedite

239 This robust, low-power, non-invasive, and miniaturized sensor aids in the development of point-of-

240 xperimental data confirm the capability of a miniaturized sensor to identify concentrated blood, whic

241 are agent and provide an opportunity to make miniaturized sensor, indicating considerable promise for

242 red, sensitive, flexible, biocompatibale and miniaturized sensors can find extensive applications in

243 ects of integrating CRISPR/Cas technology in miniaturized sensors for analysis on-site.

244 evelopments of integrating CRISPR sensing in miniaturized sensors for point-of-care applications.

245 The fabricated miniaturized sensors have demonstrated higher shelf life

246 pproach achieves reproducible fabrication of miniaturized sensors with extraordinarily higher sensiti

247 s facilitated the development of paper based miniaturized sensors, which has recently gained ASSURED

248 ing expensive instruments or highly-specific miniaturized sensors.

249 users) status for point of care diagnosis in miniaturized settings.

250 lytical devices combining microfluidics with miniaturized signal transducers.

251 microfluidics-based technology that performs miniaturized simultaneous propagon-induced amplification

252 such as low detection limit, selectivity and miniaturized size enables potential application of this

253 ompared to silicon-transistor-based systems, miniaturizing size and exhibiting stable ranging and hig

254 Miniaturized spectrometers have significant potential fo

255 Miniaturized spectrometers offering low cost, low reagen

256 ear Magnetic Resonance) methods, embodied in miniaturized spectrometers, have found profound uses in

257 Here, we developed a miniaturized spinning bioreactor (SpinOmega) to generate

258 The miniaturized SPME probe developed for integrated in vivo

259 stem was found to be novel, quick, reliable, miniaturized, stable, reproducible and repeatable and sp

260 ic acid catalyzed by Penicillin G acylase in miniaturized stirred batch reactors or continuous flow m

261 Miniaturized, stretchable antennas represent an essentia

262 This miniaturized system employs an aptameric graphene-based

263 The miniaturized system is based on the use of a gas-diffusi

264 The miniaturized system is composed of a computer-controlled

265 The whole miniaturized system is fully enclosed and can be integra

266 The miniaturized system provides the fast quantification of

267 Lab-on-Chip are miniaturized systems able to perform biomolecular analys

268 al materials combinations, which makes these miniaturized systems very attractive for tissue engineer

269 tron microscopy (cryo-EM) can be provided by miniaturized systems.

270 ding of molecular transport processes within miniaturized systems.

271 Here we miniaturize the concept of affinity pulldown, a gold-sta

272 has been used to fabricate DMS devices that miniaturize the platforms for easier deployment; however

273 r sensing technologies due to the ability to miniaturize the required equipment, a critical advantage

274 The unique composite allowed us to miniaturize the sensor and couple it with a Pt electrode

275 By miniaturizing the chambers and placing only one to sever

276 rease the Sur capture capacity for Sur while miniaturizing the sensor.

277 ors take laboratory analytical protocols and miniaturize them into field-deployable systems for in si

278 Although there have been several attempts to miniaturize these diagnostic platforms, they stand short

279 d on wireless, near-field power transfer and miniaturized, thin, flexible optoelectronic implants, fo

280 y, low running power, and the feasibility to miniaturize to a portable device.

281 In parallel, the cardiac component was miniaturized to facilitate intravascular deployment into

282 nson's disease and that these devices can be miniaturized to millimeter-scale and fully implanted.

283 d largely unchanged, even as transistors are miniaturized to sizes of 10 nanometres.

284 We developed custom miniaturized transducers and demonstrated that these tra

285 uch as photomechanical energy harvesting and miniaturized transport.

286 trated the performance of chip-HPLC/IMS as a miniaturized two-dimensional separation technique.

287 Miniaturized two-terminal field effect point sensors can

288 on-optimized, synthetic transgene encoding a miniaturized utrophin (uUtro), deliverable by adeno-asso

289 ese results pave the way for building future miniaturized valleytronic devices with atomic-scale thic

290 Over time, miniaturized veno-venous extracorporeal membrane oxygena

291 the robustness and reliability of a 384-well miniaturized version of the assay for the screening of S

292 e unique properties of each yields a simple, miniaturized, voltage-controlled oscillator suitable for

293 exposome studies of contaminated soils with miniaturized voltammetric detection, (iii) online phosph

294 s are diverse and their realization to offer miniaturized waveguides, antennas and shielding patterns

295 high-sensitivity sensors are significant for miniaturized wearable physiological signal monitoring sy

296 This miniaturized wearable system enables future evaluation o

297 ing with electrochemical sensing, along with miniaturized wireless electronics on a single pacifier p

298 Here, we introduce a highly miniaturized wireless energy-harvesting and digital comm

299 eous wires connect to an externally mounted, miniaturized wireless potentiostat for data transmission

300 ion of soft and biocompatible materials with miniaturized wireless wearable systems is undoubtedly an