ライフサイエンスコーパス: smartphone

1 rolled (491 usual care, 500 paper-based, 469 smartphone).

2 sumer devices (such as wearable monitors and smartphones).

3 The colorimetric product was imaged with a Smartphone.

4 tegration of the nanozyme-based ELISA with a smartphone.

5 reen and blue) analytical app installed on a smartphone.

6 -elevation myocardial infarction), and own a smartphone.

7 compact holder and the built-in camera of a smartphone.

8 tients who did not have access to charging a smartphone.

9 imetry (DIC) based technique integrated with smartphone.

10 to allow easy design modification to fit any smartphone.

11 st effective turbidimeter that is based on a smartphone.

12 ammonia, and relative humidity readable by a smartphone.

13 ion platforms that can send information to a smartphone.

14 a device that communicates wirelessly with a smartphone.

15 y, were ported and benchmarked on an Android smartphone.

16 ser Permanente Northwest, and had a personal smartphone.

17 apturing digital images of the sensors via a smartphone.

18 e easily read and analysed by our programmed smartphone.

19 s and mHealth data from wearable devices and smartphones.

20 nd modeling of behavioral data obtained from smartphones.

21 ults could be read by portable LF readers or smartphones.

22 of ambient light sensor contained within the smartphones.

23 nsing systems which are more compatible with smartphones.

24 ected via sensor and log data harvested from smartphones.

25 oral patterns passively collected from their smartphones.

26 devices without internet connection such as smartphones.

27 ict Scale (DCS) preoperatively and collected smartphone accelerometer data continuously from enrollme

28 A smartphone and an optical power meter were employed to r

29 Utilizing only the camera feed from the smartphone and built-in image processing, the nrLFA is i

30 Together, the smartphone and test strip in combination were shown to o

31 int-of-care sensor that snugly fits around a smartphone and which does not face issues usually common

32 Smartphones and data plans were provided free of charge

33 As such, behavioral rhythm sensing with smartphones and machine learning can help better underst

34 ng technology (e.g., scanners, Raspberry Pi, smartphones and other sub-$50 digital cameras) has lower

35 n consisted of a prescribing application for smartphones and regular point-prevalence surveys with pr

36 h) uses mobile communication devices such as smartphones and tablet computers to support and improve

37 The use of Apps running on smartphones and tablets profoundly affects medicine.

38 f physical activity, fitness, and sleep from smartphones and to gain insights into activity patterns

39 sehold shoppers across New Zealand who owned smartphones and were aged >/=18 y.

40 Smartphones' and tablets' chipset/memory/operating syste

41 ems (eg, Medication Event Monitoring System, smartphone), and different types of novel mobile health

42 itored using a photomultiplier tube (PMT) or smartphone, and the images are analyzed using ImageJ sof

43 s cover solutions based on wearable devices, smartphones, and other ambulatory sensors.

44 orescent spots were online counted using the smartphone App based on inter-frame difference algorithm

45 rescence imaging module and a self-developed smartphone app for non-invasive and in situ multi-sensin

46 Finally, a smartphone app interface has been developed for rapid on

47 We have developed a smartphone app that collects smartwatch and activity tra

48 Importantly, passive monitoring of smartphone app usage is low burden and non-intrusive.

49 Passively sensed smartphone app use and actigraphy data were collected fr

50 A smartphone app was also designed to quantify the concent

51 The MyHeart Counts smartphone app was made available in March 2015, and pro

52 either VOT (daily remote observation using a smartphone app) or DOT (observations done three to five

53 0 travelers as they cross time zones using a smartphone app, Entrain.

54 s: first, individual happiness data from the smartphone app, Mappiness, and second, crowdsourced rati

55 T-guided self-help (CBT-GSH) assisted with a smartphone app, Noom Monitor, for binge eating with or w

56 ging at baseline and 1 month after receiving smartphone app-based MT (n = 33) vs. an active control (

57 then read and quantified with a custom-made smartphone app.

58 every dose ingested 7 days per week using a smartphone app.

59 based strategies proposed, a contact-tracing smartphone app.

60 isticated biomachines that will make today's smartphones appear rudimentary.

61 orted by the participants themselves) used a smartphone (Apple iPhone) app to consent to monitoring.

62 Dispatching citizen responders through a smartphone application (app) holds the potential to incr

63 cores were captured by daily ratings using a smartphone application and were analyzed with linear mix

64 We used machine learning to develop a smartphone application for automated image analysis to f

65 ic acid amplification detection; and (iii) a smartphone application for data acquisition, visualizati

66 or non-optical real-time DNA sensing, with a smartphone application for data acquisition, visualizati

67 , wireless operation using a custom designed smartphone application makes it convenient to use in com

68 tative point-of-care (PoC) system based on a smartphone application that is capable of accurately tra

69 combinations were used in a custom-developed smartphone application that performed automated backgrou

70 Finally, we demonstrate a simple and useful smartphone application whereby the user is notified when

71 With this method, a smartphone application would be capable of documenting a

72 In this study, we used an Android-based smartphone application, in conjunction with commercially

73 -includes the first cardiology Apple CareKit smartphone application, which is paired with an Apple Wa

74 main sealed - and interpreted by a companion smartphone application.

75 occurrence of ILI/ARI symptoms daily using a smartphone application.

76 e cocaine concentrations were analyzed via a smartphone application.

77 on models and is available as an interactive smartphone application.

78 inical atrial fibrillation detection through smartphone applications or implantable cardiac devices,

79 Development of tailor-made software (e.g., smartphone applications) for advanced image analysis req

80 loyment of novel technical solutions such as smartphone applications, telemedicine, and mobile stroke

81 now empowered by the unlimited creativity of smartphone applications.

82 ients with hand arthritis to effectively use smartphone apps and might facilitate patient engagement

83 t technical and ethical issues regarding new smartphone apps that facilitate contact tracing and expo

84 from mobile handsets to automobiles and from smartphone apps to scientific fields, early growth patte

85 This present research methodology uses smartphone apps, Google Earth environmental datasets, Gl

86 Smartphones are nearly ubiquitous and offer a ready capa

87 Participants in the smartphone arm experienced a modestly greater reduction

88 cantly greater linkage in the usual care and smartphone arms of the trial.

89 ars in cachaca employing digital image and a smartphone as detector.

90 The assay is accompanied by a smartphone-assisted portable imaging device that can aut

91 bioluminescent-based analyte quantitation by smartphone (BAQS), provides an opportunity for onsite an

92 o-beat variability in ECG morphology using a smartphone based platform.

93 The new smartphone based test has the potential of being as a ra

94 it dynamics were concurrently recorded using smartphone-based accelerometry.

95 very promising and should be considered for smartphone-based analysis.

96 ed their potential symptoms of COVID-19 on a smartphone-based app.

97 They also completed a validated smartphone-based assessment in their own homes, during w

98 Remote, smartphone-based assessments of dual task walking may be

99 t low-cost 3D cell biosensor, we developed a smartphone-based bioluminescent 3D cell biosensor platfo

100 The smartphone-based biosensor relies on immobilized HEK293

101 our approach suitable for the realization of smartphone-based biosensors able to non-invasively detec

102 ledge, this is the first clinical study of a smartphone-based chloride sensor, paving the way for poi

103 ed isothermal amplification (LAMP) assay and smartphone-based color analysis, enabling simple, rapid

104 When combined with smartphone-based colorimetric detection, these C-BPE E-A

105 and are not suitable for simple, affordable smartphone-based detection at the point of care.

106 We report a smartphone-based device and associated imaging-processin

107 introduction of additional instrumentation, smartphone-based digital phenotyping presents us with se

108 We developed a 12-lead smartphone-based electrocardiogram (ECG) acquisition and

109 Our objective was to assess the ability of a smartphone-based electroencephalography (EEG) applicatio

110 age machine learning to demonstrate accurate smartphone-based eye tracking without any additional har

111 all, Pdots have great potential for enabling smartphone-based fluorescence assays with high sensitivi

112 wearable patch, which further paired with a smartphone-based fluorescence imaging module and a self-

113 A custom-made smartphone-based fluorescence microscope and automated i

114 y injected into the microfluidic chip on the smartphone-based fluorescent microscopic system, and the

115 The smartphone-based FP assay platform can also be implement

116 Smartphone-based fundus imaging (SBFI) allows for low-co

117 Smartphone-based fundus imaging based on indirect ophtha

118 Smartphone-based fundus imaging can meet DR screening re

119 Smartphone-based fundus imaging might aid in alleviating

120 In addition, we demonstrate the utility of smartphone-based gaze for detecting reading comprehensio

121 Therefore, we evaluated the use of smartphone-based geofencing to track hospitalizations.

122 60% of MSM in the US use the internet and/or smartphone-based geospatial networking apps to find sex

123 in the United States use the internet and/or smartphone-based geospatial networking apps to find sex

124 In this article, we utilized a smartphone-based image acquisition method for capturing

125 Here, we present a smartphone-based imaging platform (SIP) in tandem with m

126 y TAC through saliva via simple naked-eye or smartphone-based inspection.

127 adults were randomly assigned to a 14-lesson smartphone-based intervention: (i) training in both moni

128 al neuroimaging, computational modeling, and smartphone-based large-scale data collection to test, in

129 d samples to assess the applicability of the smartphone-based method, which is successfully compared

130 study reports for the first time an optical, smartphone-based microfluidic fluorescence sandwich immu

131 geted digital therapeutic treatments such as smartphone-based MT, yielding improved clinical outcomes

132 Here, we implement smartphone-based particle diffusometry (PD) detection of

133 95.2% specificity, and 94.3% accuracy of the smartphone-based PD platform for detection of V. cholera

134 hese results demonstrate the utility of this smartphone-based PD platform for rapid and sensitive det

135 ar effects of diabetes, we hypothesized that smartphone-based photoplethysmography could provide a wi

136 ork (DNN) to detect prevalent diabetes using smartphone-based photoplethysmography from an initial co

137 These findings demonstrate that smartphone-based photoplethysmography provides a readily

138 The developed smartphone-based platform exhibits enhanced sensitivity,

139 ilitate the development of simple, sensitive smartphone-based point-of-care pathogen diagnostics in r

140 oparticles have transformative potential for smartphone-based point-of-need diagnostics because an op

141 In this paper, we investigate the smartphone-based portable retinal imaging systems availa

142 cations ranging from low-cost screening with smartphone-based probes to algorithm-guided detection of

143 To address this challenge, a portable smartphone-based quantitative molecular detection platfo

144 l phone tower triangulation and to trigger a smartphone-based questionnaire when located in a hospita

145 nufactured three-dimensional cartridge and a smartphone-based reader.

146 wo-way lateral flow immunoassay (LFI) with a smartphone-based readout for simultaneous detection of a

147 le detection system was developed based on a smartphone-based readout, which scans the LFI and provid

148 The smartphone-based retina imaging systems can be used as a

149 However, the field of view of the smartphone-based retina imaging systems plays an importa

150 rmance decreases as the field of view of the smartphone-based retinal systems get smaller where iNvie

151 This article demonstrates a new smartphone-based reusable glucose meter.

152 for SCD, thus increasing the practicality of smartphone-based screening technique for SCD in low-reso

153 This paper demonstrates the use of a smartphone-based sensor for fluorescence polarization (F

154 The smartphone-based sensor platform also showed remarkable

155 research work evaluates the feasibility of a smartphone-based spectrometer (740-1070 nm) for salted m

156 A commercially available smartphone-based spectrometer and a benchtop NIR spectro

157 in a wide range of temperatures by using the smartphone-based spectrometer, which has an acceptable a

158 This study seeks to evaluate the impact of smartphone-based strategies in improving reliability, re

159 A smartphone-based study of cardiovascular health is feasi

160 n from aqueous samples using a spectrometric smartphone-based system for the first time.

161 absorption spectrum using the spectrometric smartphone-based system.

162 The overall classification accuracy of smartphone-based systems are sorted as 61%, 62%, 69%, an

163 Using the developed smartphone-based technique, we obtained similar percenta

164 ng demonstrates the potential utility of the smartphone-based test for reducing the overall cost of s

165 ction limit of ~0.3 NTU, this cost-effective smartphone-based turbidimeter can be a useful analytical

166 The accurate performance of our smartphone-based turbidimeter was also confirmed with va

167 6.9 x 10(-15) m, respectively, and read by a smartphone-based user interface.

168 We implemented smartphone-based VIA that included standard VIA training

169 Finally, a smartphone-based video method was developed for dynamica

170 We sought to assess a smartphone-based, gold nanoparticle-based colorimetric l

171 lectroencephalography (EEG) application, the Smartphone Brain Scanner-2 (SBS2), to detect epileptifor

172 visual detection of F(-) was achieved with a smartphone by identifying the RGB value.

173 to early 1970s, to automation, computers and smartphones-by downscaling the physical size of devices

174 The smartphone camera acquired the images of fluorescence de

175 Results are acquired using a standard smartphone camera and analyzed with a simple gray scale

176 of the blue-green complex was captured using smartphone camera and DIC was employed using Red, Green,

177 A smartphone camera application and an user interface are

178 sease-specific DNA sequences that utilizes a smartphone camera as the sensor in conjunction with a ha

179 he lateral flow immunoassay paper sensor and smartphone camera demonstrates its potential in DR scree

180 o urine 8-OHdG and that are discernible on a smartphone camera photograph.

181 ye (on/off) and quantitatively with use of a smartphone camera.

182 different regions of the sensor chip in the smartphone camera.

183 produced with a simple flatbed scanner or a smartphone camera.

184 digital-readout method that requires only a smartphone camera.

185 quantitative readouts were obtained using a smartphone camera.

186 he CRISPR Cas12a system was recorded using a smartphone camera.

187 Specifically, a simple smartphone-camera-based device measures the colour signa

188 ithm to maximize the sensitivity of standard smartphone cameras, that can detect the presence of sing

189 of the eye were taken in 4 subjects using 3 smartphone cameras{Bq, Iphone, Nexus}, 2 lighting levels

190 Despite the significant advantages that smartphones' cameras can provide in teleophthalmology an

191 indoor and outdoor walking, and importantly, smartphones can be used as gait assessment tools in envi

192 Smartphone-captured images of droplet LAMP reactions, an

193 s the excitement of fast-paced technologies, smartphones, cloud computing and machine learning, with

194 interface programming on both PC and Android smartphone, communications over both USB and Bluetooth,

195 mples, and the Color Picker APP installed in smartphone continued to read out the Red, Green and Blue

196 In this work, a smartphone controlled interactive theranostic device has

197 These results enable smartphone-controlled, battery operated transdermal deli

198 Here, we describe smartphone-controlled, minimally invasive, soft optoflui

199 Results obtained via the smartphone correlated well with the yield response of th

200 The spread of GPS-enabled smartphones could increase these benefits by enabling cu

201 inputs from counselor and patient through a smartphone counseling application.

202 es detection of nucleic acid targets using a smartphone coupled to an appropriate optical setup, open

203 mates of steps taken per day correlated with smartphone data (surrogates: n = 13, rho = 0.56, p < 0.0

204 luding a mini dark box was created to enable smartphone detection.

205 ng paper biosensor that can be combined with smartphone detection.

206 s from a drop of blood, is compatible with a smartphone detector, and displays analytical figures of

207 Smartphone digital image colorimetry (SDIC), combined wi

208 Our smartphone employs a novel algorithm utilizing chromatic

209 sing one of these probes and analysis with a smartphone enabled nonspecialists to detect sulfide reli

210 counting, and immunoprofiling of cells on a smartphone, enabled by the highly advantageous optical p

211 rite in urine, accurately quantified using a smartphone-enabled platform.

212 Smartphones enjoy high adoption rates around the globe.

213 ts center for cancer cell capture and direct smartphone fluorescence imaging.

214 ollected magnetically and detected using the smartphone fluorescence reader.

215 context of a "bare bones" device that uses a smartphone for all-in-one excitation and imaging of fluo

216 one convective PCR (cPCR) device linked to a smartphone for rapid detection of nucleic acids using na

217 Photoplethysmography (PPG) measured by smartphone has the potential for a large scale, non-inva

218 The broad adoption and use of smartphones has led to fundamentally new opportunities f

219 d from readily accessible videos (e.g., from smartphones) has the potential to scale this diagnostic

220 collection and transmission via Bluetooth or smartphones have set the foundation to connect remote se

221 ine and found that its accessibility through smartphones helpful to guide clinical decisions.

222 ile fundus examination using an adapter on a smartphone; however, key aspects such as image quality,

223 Our training dataset consisted of 1500 smartphone images of nine mosquito species trapped in Fl

224 Then a smartphone imaging-based sensing platform was constructe

225 c fluorescence sensing strategy coupled with smartphone imaging-based sensing platform was proposed f

226 t Pdots will support multicolor imaging on a smartphone in an optimized assay, although QDs are likel

227 ological developments have enabled to use of smartphones in designing small-sized, low-power, and aff

228 em is powered and complemented by a standard smartphone including a programmed application for measur

229 A 3D printed cradle held the smartphone integrated with optical components.

230 demonstrate the quantification of glucose by smartphone-integrated fiber optics that overcomes existi

231 tool that will passively monitor the subject-smartphone interaction for signs of PD and which could b

232 t are passively captured during natural user-smartphone interaction.

233 Here we present a reconfigurable smartphone-interfaced electrochemical Lab-on-a-Chip (LoC

234 Furthermore, a smartphone-interfaced portable fluorimeter module is dev

235 The app transforms the smartphone into a portable reflectometer, relating the r

236 A smartphone is a facile, handy-analytical device that mak

237 Quantification of colorimetric assays with smartphones is being increasingly reported.

238 lectronic components found in every consumer smartphone, is extremely fast because no complex labelli

239 randomized trial comparing effectiveness of smartphone-linked versus standard home BP monitoring.

240 The universal use of smartphones makes the developed platform suitable for ch

241 detection of bacterial infection, utilizing smartphone measurement of contact angle from oil-immerse

242 na to evaluate the accuracy and precision of smartphone-mediated soil analysis.

243 Our findings suggest that smartphone mentorship provided experiential learning to

244 Smartphones, mobile geolocators that are ubiquitous, hav

245 A custom smartphone multi-view App was developed to control the o

246 Using mobility data from a large sample of smartphones, nationally representative consumer preferen

247 lessly transmits pH data in real-time to the smartphone of the user, where a custom-developed App ena

248 uantitative response can be obtained using a smartphone or scanner and free imaging software within a

249 The signal is captured with a smartphone or tablet working in video mode and processed

250 Adult smartphone-owners undergoing surgery for breast, skin-so

251 Using the geotracking data of 15 million smartphones per day, we found that US counties that vote

252 ng of a low cost, robust, and field portable smartphone platform fluoride sensor that can detect and

253 resolution fluorescence imaging (FLI) into a smartphone platform.

254 ell as delivered by telephone, Internet, and smartphone platforms.

255 multiplex fluorescence-based detection on a smartphone provides new opportunities for the developmen

256 A smartphone readout-based system has been developed to de

257 e, we designed a nanoprobe compatible with a smartphone RGB camera for detection of nucleic acids.

258 Using a smartphone RGB camera, the nanoprobe response can be rea

259 n laboratory (rho = -0.54; P < 1 x 10-6) and smartphone (rho = -0.30; P < 1 x 10-39) data.

260 block that can be used in conjunction with a smartphone's ambient light sensor (ALS) to perform spect

261 However, calibration of a smartphone's camera is essential when extracting objecti

262 A simple cradle that houses the smartphone, sample tube, and collection lens supports th

263 and valid tool to assess allergic control on smartphone screens, at the population level.

264 or allergic rhinitis) app (Allergy Diary) on smartphones screens to evaluate allergic rhinitis sympto

265 e to extract objective data from a patient's smartphone, specifically, step and global position syste

266 he first time, we demonstrate a multichannel smartphone spectrometer (MSS) as an optical biosensor th

267 se reflectance spectroscopy system using the smartphone spectrometer and demonstrated the capability

268 The smartphone spectrometer is able to achieve a resolution

269 Current reported smartphone spectrometers are only used to monitor or mea

270 Results from the smartphone spectrophotometer in comparison with commerci

271 unication, using paper-based tools); and 3) "smartphone" (tailored behavioral communication, using sm

272 By combining optical methods and smartphone technology with molecular assays, the sensiti

273 e" (tailored behavioral communication, using smartphone technology).

274 with behavioral communication strategies and smartphone technology, can increase linkage of individua

275 le by the analysis of a picture taken with a smartphone that is analysed by the use of the color-defi

276 Including the smartphone, this cost-effective device weighs only ~350

277 Data were uploaded continuously via smartphone to a cloud analytics platform.

278 is work, we propose a method that employed a smartphone to capture images obtained from a colorimetri

279 ed a desktop scanner, a digital camera and a smartphone to determine iron using three standard colour

280 Our optical approach utilizes a smartphone to extract and track changes in the red (R),

281 that, during lockdown, individuals use their smartphones to access social support, which may help gua

282 diverse and complex technology, ranging from smartphones to aircraft, and yet young children find eve

283 ively estimated from the analysis of natural smartphone touchscreen typing via deep learning networks

284 btrusive screening of subtle FMI via natural smartphone usage, may assist in consolidating early and

285 h between digital social engagement, general smartphone use, and physical activity-selectively under

286 lity data from a large, anonymized sample of smartphone users to assess the relationship between neig

287 y patterns, aggregated from over 300 million smartphone users.

288 gnetic separation, fluorescence labeling and smartphone video processing.

289 nts on the immobilized control antibody, and smartphone video recording of LFIAs during their develop

290 rticles (Pt@Au NPs) as a signal probe, and a smartphone was developed to specifically detect ZIKV wit

291 Furthermore, the smartphone was introduced to combine with the ALISA for

292 A smartphone was used to record, via time-lapse video, the

293 al activity data from the current-generation smartphones was feasible in approximately 50% of patient

294 noparticles imaged at 68X magnification on a smartphone, we can detect as few as 6 V. cholerae cells

295 attachment coupled to the rear camera of the smartphone, which contains two white light-emitting-diod

296 lyzed to calculate the GSH concentrations by smartphone with an auto-analysis software.

297 resection of breast tumours in vivo using a smartphone with modified optics.

298 Here we leverage the wide usage of smartphones with built-in accelerometry to measure physi

299 Demand for smartphones with cameras has driven down the price and s

300 of four common cyanotoxins with an ordinary smartphone within 5 min of reaction.