ライフサイエンスコーパス: portable

1 ofluidic biosensing system that is genuinely portable.

2 tissue model that is expandable, modular and portable.

3 te (R(2)) can be measured by an inexpensive, portable 0.5 Tesla bench top magnetic resonance relaxome

4 cientific and engineering aspects of a field-portable (3)He/(4)He ratio detector, we found elevated r

5 It also has bearing upon designs for field portable (3)He/(4)He ratio detectors aimed at earthquake

6 Our design is portable across cell lines and enables predictable tunin

7 oncept, we have demonstrated the use of this portable analysis system to monitor porcine kidneys for

8 sense diagnostically relevant proteins with portable analysis technology, to create molecular gates

9 re detection, but has rarely been applied in portable analytical devices in a lab-on-a-chip format.

10 A rapid and portable analytical methodology has been developed for a

11 ingly, the approach has great potential as a portable analytical system for field analysis of complex

12 Nanopore sequencing offers a portable and affordable alternative to sequencing-by-syn

13 t recently reported mcr gene, mcr-9, using a portable and affordable lab-on-a-chip (LoC) platform, of

14 Fast, portable and automated nucleic acid detection should fac

15 The device is portable and can be adapted for different wavelength irr

16 Here we introduce NanoSPC, a scalable, portable and cloud compatible pipeline for analyzing Nan

17 A simple, portable and cost-effective device was also utilized.

18 RiboFlow is highly portable and customizable across a large number of compu

19 This assembly provides a portable and disposable electrochemical platform, assemb

20 refore, an urgent need for rapid, sensitive, portable and easy-to-operate detection methods for numer

21 techniques, including diagnostics, by making portable and electricity-free heating available at any l

22 ques, potential automation thereby making it portable and eliminating the need of trained personnel,

23 librated with our compact technique promises portable and inexpensive onsite rapid and accurate quali

24 ave been invested towards the development of portable and integrated analytical devices combining mic

25 ation Pipeline and iDentification (VAPiD), a portable and lightweight command-line tool for annotatio

26 blot paves the path to the development of a portable and multiplex paper based platform for point-of

27 ra of a lung cancer diagnosis with low cost, portable and non-invasive clinical sampling, nanotechnol

28 Especially in neonates, the development of portable and nonharmful monitoring devices is urgently n

29 g of other analytes as they are inexpensive, portable and quantitative.

30 rst time, a field deployable, user-friendly, portable and rapid electrochemical pesticide sensing sys

31 Finally, we demonstrate a portable and real-time POC device to detect SARS-CoV-2 f

32 vity and specificity, but they are not field-portable and require electricity to operate in field set

33 ensors pave the path to the development of a portable and reusable biosensor platform for POC testing

34 unmet need to develop rapid, cost-effective, portable and user-friendly point-of-care (POC) disease d

35 The development of portable and user-friendly sensing platforms is a hot to

36 onmental aggressors on human surfaces, using portable and wearable devices for monitoring exposome.

37 ficant demand due to the explosive growth of portable and wearable electronic devices in the fifth-ge

38 ving trend toward the ever-growing market of portable and wearable electronics has accelerated develo

39 PCR-based testing if they can be made rapid, portable, and accurate.

40 circuit will be beneficial for open-source, portable, and budget-friendly instrumentation requiring

41 paradigm shift in shielding of lightweight, portable, and compact next-generation electronic devices

42 re is an urgent need for precise, sensitive, portable, and cost-effective technologies to track patie

43 n in a noncontact, nondestructive, low-cost, portable, and easy-to-use way.

44 report presents an inexpensive, disposable, portable, and field-deployable paper-based device as a g

45 ing towards the development of new low-cost, portable, and label-free optical biosensors that join th

46 It is simple, portable, and low-cost and consumes a very low amount of

47 d is economic, environmentally friendly, and portable, and might useful for small producers and famil

48 fer much to the selective, sensitive, cheap, portable, and real-time analysis of anion presence where

49 y to continue, with an aim to deliver cheap, portable, and reliable devices to meet the demands of he

50 The assay system is easy to use, portable, and stable for at least 30 days at ambient tem

51 Emerging low-cost, portable, and user-friendly imaging systems make the cas

52 spectrometers have significant potential for portable applications such as consumer electronics, heal

53 st owing to their potential for wearable and portable applications.

54 This cost-efficient and "portable" approach could permit a broader clinical appli

55 It is fully portable, as only a Python installation is required to r

56 We have also developed a wireless portable automated calibration platform so that biosenso

57 We have developed a portable, automated, battery-powered, and remotely opera

58 was performed in 88% of patients and mostly portable/bedside studies, with 87% of patients receiving

59 s demonstrate the potential of the developed portable biosensor platform and its suitable application

60 Mobile health technologies (wearable, portable, body-fixed sensors, or domestic-integrated dev

61 ortant step toward commercial development of portable ceramic devices with high volumetric power (>10

62 rmal lung (79%) and interstitial process for portable chest radiograph (29%).

63 solidation for both pulmonary ultrasound and portable chest radiograph (96% and 73%, respectively).

64 so differed between pulmonary ultrasound and portable chest radiograph (right: 99% vs 87%; p = 0.009

65 verall agreement of pulmonary ultrasound and portable chest radiograph findings with correlating lobe

66 ffered most between pulmonary ultrasound and portable chest radiograph for interstitial findings (86%

67 agreement for both pulmonary ultrasound and portable chest radiograph respectively (right lung: 92.5

68 a 9-point pulmonary ultrasound protocol and portable chest radiograph with chest CT for localization

69 xty-seven patients had pulmonary ultrasound, portable chest radiograph, and chest CT performed within

70 monary ultrasound significantly outperformed portable chest radiograph.

71 Of the 100 portable chest radiographs evaluated by three reviewers,

72 Highly portable, cloud-enabled neuroimaging technologies will f

73 below a wavelength (30 m at 1 MHz) has made portable communication systems in the very low frequency

74 Odyssey was built to be flexible, portable, compatible, scalable, and easy to setup.

75 study provides new opportunities to develop portable, cost-competitive, and ultrasensitive sensing s

76 SmartME has great potential to be used as a portable, cost-effective, and globally connected tool to

77 We sought to understand how portable current ONT analysis methods are.

78 ronics (SKINTRONICS) that offers continuous, portable daily stress and management practice monitoring

79 Finally, some commercialized portable detection device, current challenges and future

80 Impressively, a high-throughput and portable detection method was established by the integra

81 padlock probe-based assay for the simple and portable detection of pathogens coupled with a glucose o

82 Our study demonstrates the rapid and portable detection of the two most relevant genetic mark

83 The portable detection strategy achieved a limit of detectio

84 ence transduction, we used a contact imaging portable device based on cooled CCD, and measured the li

85 to considerably facilitate the built-up of a portable device for determination of analytes at the poi

86 ulatory beat-to-beat BP was recorded using a portable device for multiple 24-hour time periods before

87 RS-CoV-2 RNA can be detected in 17 min via a portable device integrating reverse transcription, fast

88 We developed a portable device to assess RT and SSRT.

89 lt interpretation and data transmission in a portable device, detecting gluten proteins at or below t

90 wer, and the feasibility to miniaturize to a portable device.

91 osensing components with/in miniaturized and portable devices are essential but still challenging.

92 Hence, electrochemical nanobiosensors as portable devices for rapid detection of cancer biomarker

93 -invasive saliva diagnosis using wearable or portable devices may pave a new avenue for monitoring co

94 o inexpensive, screen-printed electrodes for portable devices represents a potential major advance in

95 aboratory but the development of affordable, portable devices that measure multiple cardiac biomarker

96 s field training program that uses low-cost, portable devices to conduct genomics-based training dire

97 33/34 portable devices were able to correctly classify 5 out o

98 Wearable and portable devices with desirable flexibility, operational

99 arly, inexpensive, and accurate diagnosis by portable devices, especially aptasensors can increase th

100 s wearables, embedded systems, and low-power portable devices, has led to increasingly complex mechan

101 such as biosensing, optical monitoring, and portable devices.

102 thogen interactions, to develop accurate and portable diagnostic tests, and to advance the prevention

103 Rapid and portable diagnostics hold the promise to tackle the spre

104 This methodology reported here is low-cost, portable, easy-operation, and thus potentially attractiv

105 through recent advancements in wireless and portable EEG technology, suggest that possible life-thre

106 ets are being considered for applications in portable electrical devices and flexible energy storage

107 is route may result in dramatic expansion of portable electrochemical sensors for diverse health-dete

108 nt generation of ULF radiation, we propose a portable electromechanical system called a Magnetic Pend

109 utlook of flexible perovskite solar cells in portable electronic devices; and perspectives of commerc

110 ile being compatible with an inexpensive and portable electronic reader for point-of-care application

111 Optical magnifier and portable-electronic magnifier enabled significantly lowe

112 e treated successfully with optical LVAs and portable-electronic magnifiers.

113 is greatly desired for applications such as portable electronics and transportation.

114 sensor readout could also be interfaced with portable electronics at a standoff distance, potentially

115 Lithium-ion batteries have aided the portable electronics revolution for nearly three decades

116 nergy storage for devices ranging from small portable electronics to sizable electric vehicles.

117 Lithium-ion batteries, which power portable electronics, electric vehicles, and stationary

118 rmous research enthusiasm with potential for portable electronics, electrical vehicles, and grid-scal

119 to the energy-storage market, especially for portable electronics.

120 decker buses in an urban road network, using portable emission measurement systems (PEMS).

121 our predefined round-trip study routes using Portable Emission Measurement Systems.

122 a truly transformative technology, providing portable energy storage for devices ranging from small p

123 We show that a portable exosuit that assists hip extension can reduce t

124 Using our newly developed portable experimental system termed the Coral Bleaching

125 Portable FDTI holds promise as a clinical tool for captu

126 In addition, the portable FERS system can provide quantitative informatio

127 recovery using polymer NPs and the NP-based portable filters, which provide strong adsorptive intera

128 nanomaterials can lead to power sources for portable, flexible, foldable, and distributable electron

129 Furthermore, a smartphone-interfaced portable fluorimeter module is developed to facilitate s

130 cence-based SPME method and a prototype of a portable fluorometer that is capable of quickly quantify

131 ese SPRINT reactions are easily adaptable to portable formats and could therefore be used for the det

132 We developed a generic and portable fragmentation model implemented in the open-sou

133 es were prepared, and spectra collected with portable FT-IR and FT-Raman microspectroscopy and subjec

134 ly identifying these compounds on-site using portable gas chromatography-mass spectrometry (GC-MS), s

135 organisms (GMOs) demands low-cost, rapid and portable GMO-detection methods that are technically and

136 ions of PN hybrids with the incorporation of portable hand-held readers and miniaturized devices are

137 ated thermal ablator that is lightweight and portable has been developed.

138 pic measurements were made with a new, field-portable He isotope detector capable of sub-daily monito

139 ological signals in the era of real time and portable healthcare systems.

140 oglobin concentration was measured using the portable HemoCue Hb 201+ (HemoCue AB, Angelholm, Sweden)

141 ltiplexed sensing device (ToMMx), which is a portable, high-throughput and user-friendly microfluidic

142 etric tests, which are known to be rapid and portable; however, they often display false positives an

143 nd glucose hydrogen breath test (GHBT) using portable hydrogen breath test apparatus (Gastro+(TM) Gas

144 Here, we present a low-cost, portable imaging system for long-term, fast-scale calciu

145 A cost-effective wearable and portable impedance analyzer wirelessly transmits pH data

146 We have also developed a portable impedance readout module that can analyze the d

147 d interdigitated electrode (IDE) array and a portable impedimetric reader as a point-of-care (POC) de

148 This portable, inexpensive, and non-invasive tool holds promi

149 osis prevention and treatment, especially as portable inhalation devices in high-risk, resource-poor

150 p an efficient, inexpensive, and easy-to-use portable instrument (bCUBE((R)) by Hyris Ltd) that can b

151 he DNA-based sensing element combined with a portable instrument for a label-free measurement on site

152 for the first time, a near real-time, field-portable instrument for selective quantification of airb

153 OC system combines a paper sensor chip and a portable instrument, which is built on an Internet of Th

154 apabilities of flow cytometry with low-cost, portable instrumentation, and a simple and rapid assay w

155 (bio)-analytes and easily incorporated into portable instrumentation, holding great promise in a myr

156 n analyzed on-site, in duplicate, using hand-portable instrumentation, reasonably repeatable results

157 phy offers a viable solution for compact and portable instruments in applications that require straig

158 The void of more sensitive, accurate, and portable instruments to verify cleaning onsite has to be

159 othermal amplification (LAMP) and a compact, portable, integrated microfluidic platform using microfl

160 etect and characterize chocolate bloom using portable laser spectroscopy could be used to develop in-

161 The portable leaf-clip Raman sensor offers farmers and plant

162 In vivo measurements using the portable leaf-clip Raman sensor under full-light growth

163 Alongside, the results could be read by portable LF readers or smartphones.

164 We have created a portable, lightweight, user-friendly, internet-enabled,

165 ociated vesicle (RAV), that might serve as a portable, local factory for producing proteins destined

166 The result in this work assures a portable low-cost sensor for onsite monitoring of fish f

167 ased photothermal materials, and an original portable low-pressure controlled solar steaming-collecti

168 t and accurate, simple (sample-and-measure), portable, low cost (<$5k), requires no serial dilutions

169 Paper-based E-AB sensors could enable portable, low-cost, and rapid detection of a broad range

170 niaturized electronics, which could afford a portable, low-cost, easy-to-use device for sensitive, ac

171 proposed all-in-one paper chip can provide a portable, low-cost, user-friendly, sensitive, and specif

172 rt building management systems equipped with portable, low-power, non-invasive CO(2) sensing techniqu

173 ment of dissolved (noble) gases with a field portable mass spectrometer is presented.

174 We overcome these limitations by using a portable mass spectrometer system, which enables a fast

175 A portable measurement and speciation procedure for inorga

176 The effectiveness for on-site and portable measurements was validated by testing solid was

177 omatography GC combined with MS) and compact portable membrane inlet MS (MIMS) have been employed for

178 automated real-time capability of this field-portable method by continuously measuring a transient si

179 The quantification with the portable method is comparable to that obtained with the

180 Nanopore sequencing offers a new, portable method to detect base modifications.

181 ack of rapid, inexpensive, user-friendly and portable methods.

182 To achieve this aim, a portable microanalytical flow system for the simultaneou

183 Here, we present a portable microfluidic ELISA technology for rapid (15 min

184 We present a portable microfluidic platform containing carbon nanotub

185 nomena in freely behaving animals requires a portable microscope with multiple optical contrast mecha

186 mising formats for applications that require portable miniaturized fluid handling such as point-of-ca

187 The customisable and portable modelling tool that we have developed allows ma

188 This portable module was capable of detecting picric acid dow

189 Such simple, cost-affordable, portable molecular detection platform has great potentia

190 nities for the development of affordable and portable molecular diagnostic devices for point-of-care

191 s a proof-of-concept bioassay for simple and portable molecular diagnostics of emerging pathogens usi

192 rforming nucleotide extractions as part of a portable molecular lab setup.

193 We exploited the MinION, a portable nanopore device from Oxford Nanopore Technologi

194 A-based tags readable within seconds using a portable nanopore device.

195 t, fast and deployable on either benchtop or portable nanopore sequencers, making this method directl

196 Here, a graphene-based fully integrated portable nanosensing system, the entire size of which is

197 The compact and portable nature of class 2 single effector nucleases, su

198 ls for detection of oregano adulteration, on portable near infrared devices, and comparison to a labo

199 f globally accessible chemometric models for portable near infrared devices, deployed throughout supp

200 A portable near infrared spectroscopy (NIRS) instrument wa

201 We evaluated two commercially available, portable, near-infrared Raman systems operating at excit

202 tional, yet unresolved, ELSI issues posed by portable neuroimaging: (1) informed consent; (2) privacy

203 quencing results obtained with the low-cost, portable next generation sequencer MinION from Oxford Na

204 This study investigated the use of a portable NIR spectrometer combined with chemometric tool

205 gest that, using subcutaneous fat samples, a portable NIRS could be used in commercial abattoirs as a

206 present the development and validation of a portable NLP approach for automated surveillance of SSIs

207 As a microfluidic device, this portable novel platform can be integrated with a variety

208 The development of portable nucleic acid diagnostic devices has the potenti

209 missing the objective primary endpoint, the portable OCS Lung resulted in 87% donor lung use for tra

210 e provides an innovative first step toward a portable OP quantification method that surmounts convent

211 m, we demonstrate a promising component of a portable optical atomic clock architecture.

212 Optical biosensors are defined as portable optical devices that use biorecognition molecul

213 gy could be useful in the development of new portable or wearable blood pressure monitors.

214 rong demand for high-performance, rapid, and portable (or point-of-care) diagnostic sensors in applic

215 was to evaluate the efficacy of normothermic portable Organ Care System (OCS) Lung perfusion and vent

216 ently sequenced the amplified genomes on the portable Oxford Nanopore MinION platform and analyzed th

217 used large environmental chambers (ECs) and portable oxidative flow reactors (OFRs) is difficult.

218 This study describes changes in portable oximeter-measured peripheral oxygen saturation

219 A novel, low-cost, and portable paper strip biosensor was developed for the det

220 Integrating SNIPRs with portable paper-based cell-free reactions enables conveni

221 esent a simple, user-friendly, low-cost, and portable photonic system for in situ detection of low cy

222 biosensor provides a simple, economical, and portable piece of field kit for on-site monitoring of te

223 dASM, a scalable, ultra-efficient, turn-key, portable pipeline on Google Cloud Platform (GCP) that us

224 Tibanna accepts reproducible and portable pipeline standards including Common Workflow La

225 This article presents a novel design of portable planar microwave sensor for fast, accurate, and

226 This portable platform demonstrates satisfactory analytical p

227 Development of a rapid and portable platform for detecting and monitoring waterborn

228 icroPADs) are emerging as cost-effective and portable platforms for point-of-care assays.

229 ply the photothermal biosensing principle in portable PMMA/paper-based analytical devices, which offe

230 oposed platform suggests high potential as a portable point-of-use biosensor for the detection of oth

231 of the samples in microwave oven, and with a portable potentiostat after the mild eating procedure.

232 active molecules namely Hoechst-33258 and a portable potentiostat.

233 and in the presence of pesticides by using a portable potentiostat.

234 ith a solid gold electrode (SGE) and using a portable potentiostat.

235 is proven to exhibit a great potential as a portable prostate cancer biosensor, also as a universal

236 SION-105 has been combined with a portable prototype sampling device that was designed and

237 Here, we report the design and testing of a portable prototype scanner for brain MRI that uses a com

238 These include being inexpensive, portable, pump-free, and having the ability to store rea

239 to the development of quantum computers and portable quantum sensors(1-4).

240 We envision that a portable Raman instrument could be combined with the cap

241 Here, we demonstrate a portable Raman probe that clips around a leaf for rapid,

242 muL of whole blood with the assistance of a portable Raman reader, achieving a limit of detection of

243 Herein, we report the development of a portable, rapid and user-friendly GMO-detection biosenso

244 smon resonance (SPR) sensor as an example of portable, rapid, and smart biosensing devices widely use

245 vice (large-field-of-view extreme-resolution portable research imager) is a system for nonhuman prima

246 s paper, we investigate the smartphone-based portable retinal imaging systems available on the market

247 iosensors are crucial for the development of portable, reusable, and convenient biosensors, otherwise

248 ermentation technologies that are not easily portable, reusable, or suitable for on-demand production

249 we use the GyBAR, a backpack-like prototype portable robot, to investigate the hypothesis that the b

250 nt-of-care diagnostics since they are cheap, portable, robust, selective, fast and easy to use.

251 integration with low-power electronics and a portable saliva swab serves as a roadside DUI hand-held

252 A portable sample pretreatment was optimized to determine

253 a-hypopnea index >=15/h) was assessed with a portable SDB monitor the night before surgery.

254 y, ultra-low-cost (~0.03 $ per sweat patch), portable, selective, rapid, and non-invasive healthcare

255 Wearable and portable self-powered units have stimulated considerable

256 ign of synthetic gene networks, the fast and portable sensing of compounds, on-demand biomanufacturin

257 Portable, sensitive and cost-effective sensors represent

258 This portable sensor provides rapid detection alongside low c

259 Nanopores are key in portable sequencing and research given their ability to

260 ows promise for the development of rapid and portable SERS-based assays which can be utilized in the

261 escribe the development and performance of a portable single-sided magnetic-resonance sensor for grad

262 To address this challenge, a portable smartphone-based quantitative molecular detecti

263 manufacturable solar-steaming materials, and portable solar steaming-collection systems for individua

264 Nanopore sequencing provides a real-time and portable solution to genomic sequencing, enabling better

265 We show that a portable spectrometer's ability to quantify collagen con

266 ere collected by several operators using the portable spectrometer, without any optimization of measu

267 tment to simplify off-chip analysis, and for portable spectroscopic analyses.

268 The portable system is robust and reliable in the challengin

269 Therefore, this portable system offers the practicality to be potentiall

270 is performance increase within a potentially portable system presents a compelling avenue for substan

271 board into a compact, fully integrated, and portable system to conduct real-time monitoring of gases

272 Portable systems for rapid assays of herbicide and insec

273 Portable technologies allow for in situ molecular biodiv

274 There is a growing need for low-cost, portable technologies for the detection of threats to th

275 re needed to protect electronic circuits and portable telecommunication devices and to eliminate cros

276 It is thus a rapid, low cost portable test suitable for point-of-need detection of ch

277 there is a rising need for rapid, low-cost, portable testing of blood coagulation time or prothrombi

278 s reported, which is more cost-effective and portable than optical-transduction-based biosensors.

279 In this work, the low power, portable TinyLev acoustic levitation system is used in c

280 erable, and reuseable): its tools are easily portable to diverse computing environments, run on the c

281 transition function or the optimal policy is portable to new contexts, but achieving "deep transfer"

282 research community with a user-friendly and portable tool that integrates bioinformatics analysis an

283 d therefore exists for more rapid, low-cost, portable tools for multiplexed determination of metals i

284 In the realm of education, portable tools such as DNA sequencers facilitate in situ

285 e ions with the convenience of dipsticks and portable tools, such as cellphones, informed decision ma

286 rence is a key advance in the development of portable trapped-ion quantum sensors and clocks, providi

287 thers makes it a very promising solution for portable TRBGs.

288 Small and portable ULF antennas within a diameter of 1 meter would

289 ctrical impedimetric FET measurements with a portable unit for the ultrasensitive detection of cancer

290 btained in conventional X-ray suites or with portable units, are the first-line imaging test because

291 The entire device is highly portable, user-friendly, battery-operated and can provid

292 Here, we report a facile sensitive, portable, user-friendly, cost-effective and time saving

293 -care diagnostics since they are affordable, portable, user-friendly, rapid and robust.

294 For this, a low-cost, portable, wavelength modulation spectroscopy (WMS) syste

295 as 23 cents (US dollars) to manufacture, is portable (weighs 13 g and requires no electricity), can

296 rotein was designed and applied to cheap and portable Whatman filter paper as the carrier to prepare

297 This fully integrated pacifier operates as a portable wireless device toward noninvasive chemical mon

298 Portable X-ray fluorescence (pXRF) spectrometry provides

299 ract solutions on a continuous scale using a portable X-ray fluorescence analyzer.

300 Driven by the vision of robust and portable, yet sensitive DNA detection systems for point-