ライフサイエンスコーパス: smartphone

1 27 from neither the reference camera nor the smartphone).

2 fluorescence emission that was captured by a smartphone.

3 her completed by using image processing in a smartphone.

4 pectrophotometer or the built-in camera of a smartphone.

5 of 202 adults 18 years or older who owned a smartphone.

6 e 3D-printed simple accessories to adapt the smartphone.

7 a is more sensitive at detecting DR than the smartphone.

8 the gyro sensor and the digital camera of a smartphone.

9 orage of results using cloud computing via a smartphone.

10 ammonia, and relative humidity readable by a smartphone.

11 ion platforms that can send information to a smartphone.

12 ctral sensing with nanometer resolution on a smartphone.

13 d enrollment, conducted entirely remotely by smartphone.

14 energy harvesting and data transmission to a smartphone.

15 less technology to transmit the results to a smartphone.

16 LAMP box" supplemented with a consumer class smartphone.

17 to the operating system and applications of smartphones.

18 however, have been difficult to implement in smartphones.

19 ting stations, dedicated e-mail servers, and smartphones.

20 nsing systems which are more compatible with smartphones.

21 health facilities, and other features using smartphones.

22 uctions on how best to take photographs with smartphones.

23 so 371 from the reference camera but not the smartphone, 170 from the smartphone but not the referenc

24 Ninety-five percent had access to a personal smartphone, 62% used the Internet more than occasionally

25 al (3D) printing technology, we fabricated a smartphone accessory and a minicartridge for hosting bio

26 The NutriPhone technology comprises of a smartphone accessory, an app, and a competitive-type lat

27 ironPhone diagnostic platform comprises of a smartphone accessory, an app, and a disposable lateral f

28 95% CI limits for test-retest variability of smartphone acuity data were +/-0.033 logMAR.

29 Nonclinical photographers using the low-cost smartphone adapter were able to acquire optic nerve imag

30 artridge, which houses the LFIA strip, and a smartphone adaptor with a plano-convex lens and a cartri

31 We present the application of a smartphone anatomy based technology in the field of liqu

32 t, we propose a compact device composed of a smartphone and a custom-designed cradle, containing only

33 Taking advantages of smartphone and DNAzyme, the assay provides great potenti

34 onsists in a cover accessory attached to the smartphone and incorporating a light diffuser over the f

35 Smartphone and nonmydriatic fundus photography are each

36 specificity in the detection of DR for both smartphone and nonmydriatic photography were determined

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

38 based blood typing device is rapidly read by smartphones and easy for the user to operate.

39 The feasibility of using smartphones and other mobile devices as the detection pl

40 iffraction patterns which can be acquired by smartphones and processed by a remote server.

41 In conclusion, novel technologies, such as smartphones and sensors, provide insights in personal ex

42 Novel technologies, such as smartphones and small personal continuous air pollution

43 he potential benefits of interventions using smartphones and social media is still developing.

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

45 Mobile computing devices (e.g., smartphones and tablets) that have low-friction surfaces

46 d application to display the measurements on smartphones and tablets.

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

48 Advances in smartphones and wearable biosensors enable real-time psy

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

50 traditional desktop scanner, augmenting that smartphones (and other mobile devices) promise to be a p

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

52 for convenient score calculation, we built a smartphone app available for free download.

53 retation using a color scale and an optional smartphone app for automated analysis.

54 A 'STROOP' smartphone app has been developed to allow clinicians to

55 The Stroop smartphone app is a short, valid, and reliable tool for

56 to self-monitor calories, but introducing a smartphone app is unlikely to produce substantial weight

57 aimed to investigate the effectiveness of a smartphone app on weight reduction in obese or overweigh

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

59 and r = 0.856 for visual interpretation and smartphone app, respectively), and both POC test methods

60 The aim of this study was to use a Stroop smartphone application (app) (EncephalApp_Stroop) to scr

61 A smartphone application (app), developed for Android plat

62 We selected and trained CHWs to use the smartphone application and compensated them based on per

63 the study period, most subjects who used the smartphone application experienced weight loss in a sign

64 The findings suggest that a multifeatured smartphone application may have significant benefit to p

65 antly, a combination of this platform with a smartphone application provides quantitative data on the

66 We designed a smartphone application to enable CHWs to screen for SSIs

67 Students completed the survey using a smartphone application.

68 oss an average of 27 d using a multiplatform smartphone application.

69 Bluetooth capability for interfacing with a Smartphone application.

70 e cocaine concentrations were analyzed via a smartphone application.

71 Many smartphone applications (apps) for weight loss are avail

72 crepancy exists with regard to the effect of smartphone applications (apps) on weight reduction due t

73 s Diseases Society of America guidelines and smartphone applications as frequent resources for learni

74 feasibility testing of three daily activity smartphone applications based on motivational frames dra

75 positive and negative predictive values of 4 smartphone applications designed to aid nonclinician use

76 The performance of smartphone applications in assessing melanoma risk is hi

77 melanoma risk is highly variable, and 3 of 4 smartphone applications incorrectly classified 30% or mo

78 , which uses dermoscopes in combination with smartphone applications, as well as regarding the possib

79 ght loss using global-scale data provided by smartphone applications.

80 -to-consumer (DTC) telemedicine websites and smartphone apps diagnosing and treating skin disease.

81 Smartphone apps for weight loss may be useful for person

82 Mobile smartphones are rapidly emerging as an effective means o

83 conditions of light, using the flash of the smartphone as a light source, the image captured with th

84 rotation-driven microfluidic devices with a smartphone as a potential alternative for current presum

85 tilize the ambient light sensor (ALS) of the smartphone as light intensity detector and its LED flash

86 n of antibodies directly in solution using a smartphone as the sole piece of equipment.

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

88 Our system includes a 3D-printed smartphone attachment that holds and illuminates the MTP

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

90 This smartphone based device provides a simple, rapid, sensit

91 Here we demonstrate a label-free smartphone based electrochemical WBC counting device on

92 sent a simple, sensitive, rapid and portable smartphone based fluorescence device for E. coli O157:H7

93 s review, our focus is on recent advances on smartphone based sensing and diagnosis applications.

94 We demonstrate a smartphone based spectrometer design that is standalone

95 Smartphone-based analysis is another exciting developmen

96 A smartphone-based analytical application was designed to

97 A smartphone-based application could provide effective con

98 Smartphone-based biochemiluminescence detection could be

99 Thus, the smartphone-based biosensing platform provided a convenie

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

101 The development of smartphone-based biosensors for point-of-care testing (P

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

103 A smartphone-based colorimetric reader (SBCR) was develope

104 A smartphone-based colorimetric reader was also developed,

105 zymatic reaction solution was monitored by a smartphone-based colorimetric reader.

106 This smartphone-based detection opens a new horizon for bioan

107 Additionally, smartphone-based detection shows a linear relationship b

108 microscopic observation to state-of-the-art smartphone-based detection.

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

110 inting low-cost technology we fabricated the smartphone-based device that consists in a cover accesso

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

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

113 The device is portable with smartphone-based end-point detection and provides the as

114 re, we characterized choice preferences in a smartphone-based experiment (n = 25,189) in which partic

115 gy to enhance the detection sensitivity of a smartphone-based fluorescence microscope by using surfac

116 A smartphone-based fluorescence microscope was fabricated

117 ion, end-point detection is achieved using a smartphone-based fluorescence microscope.

118 l permits using a compact and cost-effective smartphone-based fluorescence reader, an important requi

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

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

121 An important need in smartphone-based microscopy and sensing techniques is to

122 13, to March 4, 2014, comparing results from smartphone-based Peek Acuity to Snellen acuity (clinical

123 the laboratory in 74 participants and with a smartphone-based platform in 1833 participants.

124 lectrochemical format and a custom, low-cost smartphone-based potentiostat ($20 USD) yielded comparab

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

126 rfural-a freshness indicator-in beer using a smartphone-based reader.

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

128 This study reports the development of a smartphone-based sensing strategy that employs chemiresp

129 A smartphone-based study of cardiovascular health is feasi

130 In this smartphone-based study of cardiovascular health, partici

131 In this study, we reported a smartphone-based system using impedance monitoring for T

132 ased blood typing device by integrating with smartphone-based technology.

133 Smartphone-based telehealth holds the promise of shiftin

134 -0.10) logMAR, respectively, indicating that smartphone-based test acuities agreed well with those of

135 phone-based test and the ETDRS chart and the smartphone-based test and Snellen acuity data were 0.07

136 The mean differences between the smartphone-based test and the ETDRS chart and the smartp

137 Five different types of smartphones, both Android and iOS devices, were tested,

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

139 camera but not the smartphone, 170 from the smartphone but not the reference camera, and 227 from ne

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

141 ction and quantification is achieved using a smartphone camera and integrated image analysis app.

142 der ambient lighting conditions, utilizing a smartphone camera as a detector.

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

144 imaging of QD photoluminescence (PL) with a smartphone camera is a viable, easily accessible readout

145 The smartphone camera is used as light detector, for image a

146 lly observed by the naked eye or imaged by a smartphone camera under a portable UV light source.

147 either a digital camera, consumer webcam, or smartphone camera were sufficient for analysis on the ba

148 e transmitted light of each well through the smartphone camera.

149 PCR assays can be monitored using LEDs and a smartphone camera.

150 m by measuring particle displacement using a smartphone camera.

151 exosome biomarkers, and is read out using a smartphone camera.

152 interface that enables IOP to be read with a smartphone camera.

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

154 Mobile applications on smartphones can communicate a large amount of personaliz

155 hort message service, or text messaging, and smartphones, can improve lifestyle behaviors and managem

156 The glucose meter includes a custom-built smartphone case that houses a permanent bare sensor stri

157 conventional systems taking the advantage of smartphone connectivity and the enhanced performance of

158 ility to perform rapid in-flight assays with smartphone connectivity eliminates delays between sample

159 At this time, the benefits of the smartphone (connectivity, portability, and reduced cost)

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

161 Using the anonymous smartphone data of 1 x 10(5) users in a major city of Ch

162 Smartphone detection was included for true portable dete

163 noassay chemistries, signal enhancement, and smartphone detection.

164 nd cost-effective ion-selective optode and a smartphone detector equipped with a color analysis app.

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

166 Our smartphone employs a novel algorithm utilizing chromatic

167 To address these challenges, we developed a smartphone-enabled optofluidic platform to measure brain

168 The smartphone equipped with a back camera (5 megapixels res

169 ubiquitous consumer electronic devices (e.g. smartphones, flatbed scanner) are considered promising a

170 Smartphone fluorescence microscopy has various applicati

171 We evaluated the smartphone fluorimeter in the context of a fluorescent m

172 ith nonvolatile reagents stored on-board and smartphone for detection.

173 We present an optical sensing platform on a smartphone for high-throughput screening immunoassays.

174 Using a smartphone for stimulus delivery and signal acquisition,

175 The sensitivity and specificity of smartphone fundus photography for the detection of visio

176 The sensitivity and specificity of smartphone fundus photography, compared with 7-field myd

177 We compared smartphone fundus photography, nonmydriatic fundus photo

178 The smartphone G-Fresnel spectrometer and the diffuse reflec

179 Exploiting data from 29,631 users of a smartphone game, we show that, as age increases, working

180 Of the smartphone group, 543 (30%) had a depression history and

181 ndly operating systems and applications, the smartphones have replaced laptops and desktop computers.

182 iability of this optical sensing platform on smartphone, human interleukin 6 (IL-6) protein and six t

183 Smartphone image-based sensing of microfluidic paper ana

184 dy compared the grading of optic nerves from smartphone images with those of a digital retinal camera

185 measurements of replicate samples made with smartphone imaging and a sophisticated fluorescence plat

186 well-turbidity, with results returned to the smartphone in ~1 minute.

187 his work also adds to the growing utility of smartphones in analytical methods by enabling multiplexe

188 These results demonstrate a potential for smartphones in large-scale computational phenotyping, wh

189 The MCFphone is composed by a smartphone integrated with a magnifying lens, a simple l

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

191 tion of various bio-sensing platforms within smartphone-integrated electronic readers provides accura

192 heet on how best to take photographs using a smartphone (intervention group); the other half did not

193 his field-portable fluorescent imager on the smartphone involves a compact laser-diode-based photosou

194 lable to the practitioner through the use of smartphones, iPads, and other personal digital assistant

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

196 s) using community health workers (CHWs) and smartphones is feasible in rural Haiti.

197 Outpatient follow up for SSIs with CHWs and smartphones is feasible in rural Haiti.

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

199 ission of the sensed information to standard smartphones, laptops, and other consumer electronics for

200 evice capable of displaying information in a smartphone-like hands-free format by wireless communicat

201 zed by a software application running on the smartphone microprocessor.

202 A smartphone mobile app providing personalized, real-time

203 Smartphones, mobile geolocators that are ubiquitous, hav

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

205 usual (n = 179) or treatment as usual plus a smartphone (n = 170) with the Addiction-Comprehensive He

206 Our optical sensing platform on the smartphone offers a route toward in situ high-throughput

207 As a next step, we herein designed a smartphone operated chloridometer that optimizes the ana

208 bility, affordability, and connectivity of a smartphone ophthalmoscope make smartphone ophthalmoscopy

209 ectivity of a smartphone ophthalmoscope make smartphone ophthalmoscopy a promising technique for comm

210 Smartphone ophthalmoscopy and biomicroscopy could not be

211 croscopy, the sensitivity and specificity of smartphone ophthalmoscopy for the detection of clinicall

212 Smartphone ophthalmoscopy showed considerable agreement

213 After pupil dilation, the patients underwent smartphone ophthalmoscopy with the D-Eye device, followe

214 We envision that this multichannel smartphone optical biosensor will be useful in high-thro

215 g respiration can be transmitted to a nearby smartphone or tablet computer for post-processing, and s

216 ailable mobile phone (from low-end phones to smartphones) or cellular network (second, third, and fou

217 The unique smartphone paper electrochemical sensor ensures fast cel

218 To overcome these problems, we propose a smartphone paper-based biosensor, in which all the reage

219 To assess whether smartphone photographs of pediatric skin conditions take

220 Advances in smartphone photography (both quality and image transmiss

221 Parent-operated smartphone photography can accurately be used as a metho

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

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

224 ditions, offering one route toward improving smartphone quantification of muPAD assays for in-field w

225 10 ppb DCP effects an irreversible change in smartphone readout.

226 fully integrated lab-on-chip platforms with smartphone readouts, enabling health-care practitioners

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

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

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

230 fouling, drag-reducing, or anti-fogging, for smartphone screens, eye glasses, windshields, or flat pa

231 ods and to receive allocated labels on their smartphone screens.

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

233 e and point to emerging opportunities (e.g., smartphone sensing).

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

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

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

237 The smartphone spectrometer is able to achieve a resolution

238 The performance of the smartphone spectrometer is comparable to existing bench-

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

240 We demonstrate the first use of smartphone spectrophotometry for readout of fluorescence

241 It is projected that 6.3 billion smartphone subscriptions will exist by the year 2021 and

242 Smartphone technology allowed participants to scan barco

243 We developed a smartphone technology to sample people's ongoing thought

244 f paper-based devices to the widely accepted smartphone technology will increase the capability of pa

245 in prolonged daily sitting, and were new to smartphone technology, participated in iterative design

246 rcial immunoassay reagents and off-the-shelf smartphone technology.

247 nhanced the adaptability of the assay to the smartphone technology.

248 is sample of midlife and older adults new to smartphone technology.

249 The study demonstrated that the Peek Acuity smartphone test is capable of accurate and repeatable ac

250 are workers readily accepted the Peek Acuity smartphone test; it required minimal training and took n

251 a 3D-printed case that can be attached to a smartphone, the USB port of which drives the integrated

252 of consent and data collection entirely on a smartphone, the use of machine learning to cluster parti

253 Given the ubiquity of smartphones, this work largely removes any instrumental

254 g the detection hardware and connects with a smartphone through a microUSB port for operational contr

255 itored by a hand-held device and send out to smartphone through Bluetooth.

256 device has a dedicated app interface on the smartphone to communicate, receive, plot and analyze spe

257 integrated with a portable reader system and smartphone to detect THC in saliva using competitive ass

258 we report, for the first time, the use of a smartphone to image and quantify biochemiluminescence co

259 ow immunoassay (LFIA) method integrated in a smartphone to quantitatively detect salivary cortisol.

260 e LFS) as well as the use of devices such as smartphones to mediate the response of LFSs will be anal

261 Electronic consumer products such as smartphones, TV, computers, light-emitting diodes, and p

262 A smartphone-utilized biosensor was developed for detectin

263 ed on G-quadruplex DNAzyme integrated with a smartphone was developed to quantitatively detect formal

264 Then, the smartphone was used to display TNT responses in real tim

265 epartment (ED) and offsite cardiologists via smartphones was developed.

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

267 Panel 18 years or older who owned an Android smartphone were enrolled.

268 cutively admitted adult patients who owned a smartphone, who were ambulatory at baseline, and who rem

269 the quantitative results are collected by a smartphone wirelessly within 1min.

270 GM) and insulin pump connected to a modified smartphone with a model predictive control algorithm.

271 during 2012-2013, the children were given a smartphone with CalFit software to obtain information on

272 Leveraging only a smartphone with its native accelerometers, our system gu

273 we demonstrate the capability of a consumer smartphone with low-cost add-ons to measure concentratio

274 orkers in intervention facilities received a smartphone with the SDA.

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

276 The widespread distribution of smartphones, with their integrated sensors and communica