ライフサイエンスコーパス: wireless

1 A Wireless Amplified NMR Detector (WAND) with cylindrical

2 bserve kidney microstructures in vivo with a wireless amplified nuclear MR detector.

3 technology, five different millimeter-scale wireless amplified nuclear MR detectors configured as do

4 The ease of implantation of these wireless and modular arrays, combined with their high re

5 modes in optogenetics, including completely wireless and programmed complex behavioral control over

6 Wireless and satellite transmission of ultrasound images

7 Here, we demonstrate neural dust, a wireless and scalable ultrasonic backscatter system for

8 d within capacitors for applications such as wireless and self-powered sensors or low-power electroni

9 ree of overlap between the extrasynaptic (or wireless) and synaptic (or wired) connectomes, we find h

10 d with a bluetooth chip to provide accurate, wireless, and real-time monitoring of pulse signals of c

11 of direct ink writing and RF electronics for wireless applications.

12 ing problems for chronic use, while emerging wireless approaches lack the size scalability necessary

13 ons, but the current size, bulk, weight, and wireless area of coverage is often disadvantageous.

14 The wireless aspect of BPEs also makes it possible to electr

15 But wireless bandwidth is costly, prompting a close examinat

16 We propose to use wireless biotelemetry monitoring to define and validate

17 ar-level frequency modulated (FM) receivers, wireless Bluetooth FM systems, and wireless programming

18 rs pH monitoring was then performed with the wireless BRAVO system.

19 r visualize the ear canal or as complex as a wireless capsule endoscope to monitor the gastrointestin

20 hat air enteroclysis compares favorably with wireless capsule endoscopy and double-balloon endoscopy

21 We used wireless capsule enteroscopy to quantitate and assess th

22 Wireless capsule pH-metry (WC) is better tolerated than

23 deployment of malware that spreads over the wireless channel of major urban areas in the US.

24 powering of implantable medical devices and wireless charging of stationary electric vehicles.

25 , spectrometer, filters, microcontroller and wireless circuits have been assembled in a housing of di

26 Solar cells and wireless coils provide options for power supply.

27 singly depend on computing functions such as wireless communication and Internet connectivity for sof

28 o optical frequencies, including full-duplex wireless communication and on-chip all-optical informati

29 connection of wires or components needed for wireless communication are complex and limited by the si

30 statistical methods, device integration and wireless communication are giving rise to new methods fo

31 gle molecular detection and (iv) nanoantenna wireless communication by using microwave inverse scatte

32 As sensors, wireless communication devices, personal health monitori

33 hene integrated circuit to perform practical wireless communication functions, receiving and restorin

34 on the measurement) was caused by infrequent wireless communication interruptions and instrument main

35 In the case of conventional wireless communication links using non-OAM beams, multip

36 y and spectral efficiency of millimetre-wave wireless communication links with a single aperture pair

37 We demonstrate the ability of the sensor and wireless communication module to monitor saliva glucose

38 The wireless communication system exploits a spatially distr

39 Towards this end, we report a nanoscale wireless communication system that operates at visible w

40 requency switches are critical components in wireless communication systems and consumer electronics.

41 nas have potential implications for portable wireless communication systems.The miniaturization of an

42 tegration of skin-like flexible sensors with wireless communication technology creates a unique oppor

43 ic radio could serve as a useful addition to wireless communication technology where the propagation

44 sion using Bluetooth Low Energy 4 (LTE4) for wireless communication with cell phone.

45 rried out with an external RFID reader using wireless communication, there is no need for perforation

46 elated ultrasonic radio that can be used for wireless communication.

47 patient data, and 31 (1.7%) were capable of wireless communication.

48 in principle should minimize attenuation for wireless communication.

49 nals over large distances for more efficient wireless communication.

50 on in a smartphone-like hands-free format by wireless communication.

51 onal and visualization capabilities, and (3) wireless communication/infrastructure.

52 Wireless communications are a fundamental part of modern

53 to be integrated into wearable devices with wireless communications for personalized health monitori

54 the development of components to facilitate wireless communications in the terahertz but the charact

55 The growing demands for wireless communications in tunnel environments are drive

56 The development of components for terahertz wireless communications networks has become an active an

57 Recently developed ideas in the field of wireless communications suggest that the presence of sca

58 In order for the promise of terahertz (THz) wireless communications to become a reality, many new de

59 romagnetic waves in various fields including wireless communications, as our simulation reveals that

60 onents that are fast enough for the required wireless communications, in particular the speed-demandi

61 es in applying the inverse Doppler effect in wireless communications, radar and satellite navigation.

62 application possibilities in high data rate wireless communications, security, night-vision, biomedi

63 e of spread-spectrum encoding, borrowed from wireless communications, wherein object pixels are conve

64 e directional transmitters and receivers for wireless communications.

65 ering in the transfer of information through wireless communications.

66 Similarly, data centres in wireless computing system are facing increasing efficien

67 .7% for a wired configuration and 2.5% for a wireless configuration when illuminated with 1 sun (100

68 ernet access for users in tunnels as well as wireless connections for wireless sensors, security, and

69 POCT test menus will continue to grow, wireless connectivity with automatic data capture will b

70 an open source software, which established a wireless connectivity with the LFM-POCT device to perfor

71 rganic light-emitting diodes (mu-ILEDs) with wireless control and power delivery strategies offer imp

72 mplant (2 mm, 70 mg) capable of closed-chest wireless control of the heart that is orders of magnitud

73 ensors, actuators, power supply systems, and wireless control strategies.

74 We designed and implemented wireless control systems that linked online neural decod

75 pumping systems, microscale inorganic LEDs, wireless-control electronics, and power supplies.

76 A wireless-controlled miniature rectilinear ion trap mass

77 th technical challenges related to elongated wireless coverage in two opposite near-end-fire directio

78 We also created a wireless data acquisition system able to record fetal bl

79 Soul Mate is a novel implantable wireless data transmission system that analyzes 9 intram

80 The HBFC generated sufficient power for wireless data transmission to a local computer.

81 ltammetric detection of OP vapor threats and wireless data transmission to a mobile device.

82 extraocular unit containing electronics for wireless data, power recovery, and generation of stimulu

83 Wireless deep brain stimulation of well-defined neuronal

84 neural probe systems that provide targeted, wireless delivery of fluids and light into the brains of

85 t PPTg locations on gait and posture using a wireless device that lets rats move freely while receivi

86 It is widely believed that wireless devices can cause life-threatening interference

87 ng on the body is a possible choice to power wireless devices implanted in the surface of the vehicle

88 Mobile and wireless devices yield information about where and when

89 tremendous applications in sensor networks, wireless devices, and wearable/implantable electronics,

90 mand economics, and partly by the utility of wireless devices.

91 patient management, is progressing toward a wireless digital future.

92 ory and communication technologies have made Wireless Distributed Environmental Sensory Networks (WDE

93 The BCI device integrates wearable, wireless, dry electroencephalogram and electrooculogram

94 The wireless ECoG system has low energy consumption and high

95 d Janus particles, could be employed for the wireless electroaccumulation of heavy metal ions in the

96 In the present manuscript, a novel wireless electrochemiluminescence (ECL) DNA array is int

97 Significantly, bipolar, or wireless, electrochemiluminescence can be generated with

98 In this paper, we present a portable wireless electrocorticography (ECoG) system.

99 umor cells by dielectrophoresis at arrays of wireless electrodes (bipolar electrodes, BPEs).

100 dor-evoked local field potentials (LFPs) via wireless electrodes were also examined in response to th

101 Wireless electroencephalogram transmitters were implante

102 se proximity interactions (CPIs) measured by wireless electronic devices are increasingly used in epi

103 ve test values (PTVs) measured by cabled and wireless electronic percussive testing (EPT) devices and

104 Printed electronics are considered for wireless electronic tags and sensors within the future I

105 m the digestive system for powering a future wireless endoscopy capsule.

106 veloped a centrifugal microfluidic automatic wireless endpoint detection system integrated with loop

107 A safe, compact and robust means of wireless energy transfer across the skin barrier is a ke

108 ithin this work allow for the fabrication of wireless enzyme sensing systems, which can also be used

109 The wireless EPT device gives PTVs higher than the cabled EP

110 The intraobserver reliability of the wireless EPT device was evaluated as excellent for the m

111 intra- and interobserver reliability of the wireless EPT device was evaluated.

112 PTVs measured by the wireless EPT device were significantly higher than the c

113 intra- and interobserver reliability of the wireless EPT device.

114 oelectric energy harvester, and self-powered wireless flow speed sensor.

115 Here we present a miniaturised wireless fluorescence endoscope capsule with low power c

116 ehavioural states in both fiber-tethered and wireless, freely moving animals when expressed in brain

117 te the usefulness of particle arrays for the wireless generation of electrochemiluminescence at relat

118 e goal range (70-180 mg/dL) collected with a wireless glucometer.

119 nce may occur between cardiac pacemakers and wireless hand-held (cellular) telephones, posing a poten

120 d-EEG system and from a commercial, low-cost wireless headset (light-EEG) in patients with cirrhosis

121 ng can be obtained from a cheap, commercial, wireless headset; this may lead to more widespread use o

122 e student network, and an empirical Montreal wireless hotspot usage network.

123 providing a basis for the next generation of wireless implantable devices.

124 lised electronic system to management with a wireless implantable haemodynamic monitoring (W-IHM) sys

125 ss III heart failure who were managed with a wireless implantable haemodynamic monitoring system.

126 Using wireless in vivo recording, we measured BG output from t

127 kinds of uses: from broadcast television to wireless Internet access.

128 s is a report of the first implantation of a wireless intraocular pressure transducer (WIT) in a huma

129 a ring-shaped intraocular device that allows wireless IOP measurements through radiofrequency.

130 ed symptoms were completed using a dedicated wireless laptop.

131 logical paradigm for performing tethered and wireless large-scale recordings based on movable volumet

132 We propose that wireless large-scale recordings could have a profound im

133 ion by performing biventricular pacing via a wireless left ventricular (LV) endocardial pacing electr

134 ght the importance of the reliability of the wireless links between spacecraft (nodes) to enable any

135 A robust, zero power, absolute accuracy wireless liquid-volume monitoring is realized in the pre

136 of-concept integrated device, which features wireless locomotion and on-site triggered therapeutics w

137 We describe a handheld, wireless low-temperature plasma (LTP) ambient ionization

138 Wireless magnetothermal stimulation in the ventral tegme

139 We have developed a method that allows wireless measurement of renal tissue oxygen tension in u

140 ly is integrated with a glucose sensor and a wireless measurement system.

141 The wireless Medtronic Bravo pH system has been validated as

142 In this contribution, a wireless method for the electrolytic sampling of heavy m

143 Capsule endoscopy, a novel wireless method of investigation of the small bowel, has

144 nments is an effective approach for powering wireless mobile electronics to meet a wide range of appl

145 ed to nonionizing electromagnetic fields and wireless mobile telephones.

146 electron-transfer reactions is applied in a wireless mode using bipolar electrochemistry with the ac

147 operation for physiological monitoring in a wireless mode.

148 Wireless monitoring of combined subjective and objective

149 f magnetoelastic transduction allows for the wireless monitoring of enzymatic activity through the as

150 ology has broader applications in continuous wireless monitoring of multiple physiological parameters

151 A combined subjective and objective wireless monitoring program of patient-centered outcomes

152 A wireless motility capsule is a new method for ambulatory

153 These results indicate that a wireless motility capsule is a promising technique to as

154 A wireless motility capsule successfully detected accelera

155 this study was to evaluate the ability of a wireless motility capsule to detect drug effects on gast

156 Advances in gastric emptying testing include wireless motility capsules and nonradioactive breath tes

157 Wearable, wireless motion sensor data, analyzed by activity patter

158 The new wireless mouthguard biosensor system is able to monitor

159 Existing wireless mu-ILED embodiments allow, however, illuminatio

160 pattern analysis, to provide a very low cost wireless muL-resolution liquid-volume monitoring without

161 o overcome these constraints, we developed a wireless multi-channel system for recording neural signa

162 Using a wireless multichannel neural recording technique, we obs

163 present a simple but powerful setup based on wireless, near-field power transfer and miniaturized, th

164 A fully automated wireless network that facilitates simultaneous 12-lead E

165 A fully automated wireless network that transmits ECGs simultaneously to t

166 he effects of implementing a fully automated wireless network to reduce door-to-intervention times (D

167 Devices such as PDAs and computers with wireless networking can be used to access this informati

168 Wired and wireless networking capabilities are implemented.

169 a novel real-world application of D-Wave in wireless networking-more specifically, the scheduling of

170 Security in wireless networks has traditionally been considered to b

171 Nevertheless, wireless networks in tunnel environments are associated

172 mmon technology like cellular telephones and wireless networks is a simple, cost-effective way to imp

173 , provide a critical basis of ever-pervasive wireless networks.

174 called physical layer to provide security in wireless networks.

175 participants chronically implanted with the wireless NeuroPace responsive neurostimulator (RNS) and

176 eered a compact, lightweight, high data rate wireless neurosensor capable of recording the full spect

177 To demonstrate the versatility of our wireless neurosensor, we monitored cortical neuron popul

178 as and battery-free schemes for multichannel wireless operation of independently addressable, multico

179 Here we measure wireless optical power transfer between plasmonic nanoan

180 Emerging wireless options offer important capabilities that avoid

181 ementation protocols will increase access to wireless optofluidic neural probes for advanced in vivo

182 Here, we introduce wireless optofluidic neural probes that combine ultrathi

183 lopment of an easy-to-construct, implantable wireless optogenetic device.

184 lows for chronic (tested for up to 6 months) wireless optogenetic manipulation of neural circuitry in

185 f magnitude smaller than previously reported wireless optogenetic systems, allowing the entire device

186 conduct a proof-of-concept pilot study of a wireless, patient-centered outcomes monitoring program b

187 -effective, energy-efficient and intelligent wireless pervasive healthcare monitoring platforms.

188 sis of GERD based on endoscopy and 48 hours, wireless pH metry.

189 %) and positive predictive values (96%) than wireless pH monitoring (64% and 40%, respectively).

190 nd acid exposure was determined by 48 hours, wireless pH monitoring (BRAVO).

191 ntact fundoplication, as assessed with BRAVO wireless pH monitoring, suggests that antireflux surgery

192 , and findings were compared with those from wireless pH monitoring.

193 cificity and positive predictive values than wireless pH monitoring.

194 gery on Barrett's esophagus (BE) using BRAVO wireless pH monitoring.

195 ors and to compare the performance of MI and wireless pH tests.

196 Wireless pH-metry is a safe and tolerable method when in

197 Wireless pH-monitoring is an accurate method for diagnos

198 The capabilities include wireless pharmacological and optical intervention for di

199 We have previously developed a wireless photovoltaic retinal prosthesis, in which camer

200 Computer-assisted virtual endoscopy and the wireless pill videoendoscope may replace diagnostic endo

201 design that is standalone and supported on a wireless platform.

202 nnect to an externally mounted, miniaturized wireless potentiostat for data transmission.

203 microfluidic device was coupled to lab-built wireless potentiostats and used to monitor real-time sub

204 c radiation is a well-established method for wireless power conversion in the microwave region of the

205 Due to health and safety concerns, most wireless power transfer (WPT) schemes utilize very low f

206 ction of electromagnetic interference (EMI), wireless power transfer (WPT), and magnetic resonance im

207 This enables wireless power transfer from one transmitter to differen

208 Considerable progress in wireless power transfer has been made in the realm of no

209 The development of non-radiative wireless power transfer has paved the way towards real-w

210 remains a fundamental challenge to create a wireless power transfer system in which the transfer eff

211 -time-symmetric circuit should enable robust wireless power transfer to moving devices or vehicles.

212 near gain saturation element provides robust wireless power transfer.

213 value in bioresorbable medical implants with wireless power transmission and communication capabiliti

214 Stretchable wireless power transmission systems provide the means to

215 antennas, beam-shaping devices, nonradiative wireless power-transfer systems, microscopy, and lithogr

216 Although wireless powering has been demonstrated, energy transfer

217 Inductive power transfer enables wireless powering of bioelectronic devices; however, Spe

218 way towards real-world applications such as wireless powering of implantable medical devices and wir

219 ined the feasibility of leveraging mid-field wireless powering to transfer power from outside of the

220 of magnitude smaller than cannulas and allow wireless, programmed spatiotemporal control of fluid del

221 eceivers, wireless Bluetooth FM systems, and wireless programming options are briefly explained and d

222 tric amplification, the detector can harvest wireless pumping power with its end-rings and amplify Ma

223 terfaces with fully implantable, stretchable wireless radio power and control systems.

224 wearable watches, scientific calculators and wireless radio-frequency communication system, which ind

225 ously relate changes in chemiresistance to a wireless readout.

226 Here we report a wireless, real-time pressure monitoring system with pass

227 iber optic tethering and large, head-mounted wireless receivers are desirable.

228 Wireless remote monitoring with automatic clinician aler

229 Device technology has progressed to allow wireless remote monitoring with automatic clinician aler

230 The primary objective was to determine if wireless remote monitoring with automatic clinician aler

231 This paper describes a wireless, remote query glucose biosensor using a ribbonl

232 nts as well as system-level examples such as wireless RF energy harvesting circuits exploit active ma

233 RT-P)/defibrillation capability (CRT-D) with wireless RM.

234 mulated on real-world data for georeferenced wireless routers.

235 Here, by taking advantage of the wireless, scalable and spatiotemporally selective capabi

236 ust' originally referred to cubic-millimetre wireless semiconducting sensor devices that could invisi

237 ew exciting avenues in the field of wearable wireless sensing devices and body-sensor networks, and t

238 This paper presents a wireless sensing system capable of monitoring the intrac

239 We further introduce printable wireless sensor arrays and show their use in real-time s

240 ower energy harvester chip integrated with a wireless sensor capable of monitoring the EP itself.

241 Using wireless sensor network technology, we obtained high-res

242 treatment plants or for powering autonomous wireless sensor networks.

243 tunnels as well as wireless connections for wireless sensors, security, and control networks.

244 diverse applications, including self-powered wireless sensors, structural and human health monitoring

245 ments in demanding, complex systems, such as wireless, skin-compatible electronic sensors.

246 nes colorimetric temperature indicators with wireless stretchable electronics for thermal measurement

247 cose monitoring (CGM) system consisting of a wireless, subcutaneously implantable glucose sensor and

248 Given the high prevalence of wireless substitution among young adults and the declini

249 y was to examine whether recent increases in wireless substitution have affected estimates of tobacco

250 include appropriate amplifiers, filters and wireless subsystems, thus reducing the complexity and co

251 , a novel ultra-lightweight (<2 g) low power wireless system allowing 72-hours of recording from 16 c

252 Comparisons with a state-of-the-art wireless system demonstrated a significant improvement i

253 m the physical radio transmission aspects of wireless systems.

254 low-noise amplifiers and power amplifiers in wireless systems.

255 These fully integrated wearable wireless tattoo and textile-based nerve-agent vapor bios

256 Wireless technologies used to transmit prehospital elect

257 Advances in wireless technologies, low-power electronics, the intern

258 rt materials and structures for self-powered wireless technologies, sensors and Internet of Things (I

259 However, wireless technologies, while mitigating some of these is

260 ive toward universal health coverage, mobile wireless technologies-mHealth tools-in support of enumer

261 ing, solid-state potentiometry, fluidics and wireless technologies.

262 aging array, miniaturised optical isolation, wireless technology and low power design.

263 sure that their products are not affected by wireless technology even when placed immediately next to

264 onments suitable for testing, while existing wireless technology is still too heavy for extended reco

265 electronic system interfaced with Bluetooth wireless technology to transmit the results to a smartph

266 This review provides an overview of current wireless technology used for patient monitoring and dise

267 search advances in the following fields: (1) wireless technology, (2) digital chip technology, (3) he

268 t cecal ligation and puncture, and an HD-X11 wireless telemetry monitor (Data Sciences International)

269 ol amperometric biosensors integrated with a wireless telemetry system were developed and used for th

270 At 6 weeks of age, mice were implanted with wireless telemetry transmitters that enabled continuous

271 We exposed male mice implanted with wireless telemetry transmitters to a 10 day CSDS regimen

272 Using underwater wireless telemetry, we recorded the TDP of Apteronotus l

273 V and 512 muW at MPP) successfully powered a wireless temperature sensor that requires a voltage of 2

274 ld find applications ranging from high-speed wireless to defence electronics.

275 dy testing of the tattoo sensor coupled to a wireless transceiver during exercise activity demonstrat

276 rmance along with the wearable nature of the wireless transceiver makes the new epidermal potentiomet

277 sensor, coupled with a miniaturized wearable wireless transceiver, for real-time monitoring of sodium

278 amplification and filtering), processing and wireless transmission in wearable biosensors by merging

279 itions, providing sufficient power to enable wireless transmission of a signal to a data logger.

280 Wireless transmission of detected arterial pressure sign

281 rmware, software, and Glassware that enabled wireless transmission of sensor data onto the Google Gla

282 een printing on a flexible substrate for the wireless transmission of the measurement to a remote rea

283 es, the developed platform enables real-time wireless transmission of the sensed information to stand

284 limits on storage capacity or bandwidth for wireless transmission, data compression is important.

285 lator arrays that provide RF references, and wireless transmitters clocked by the oscillators.

286 Wireless video capsule endoscopy allows direct visualiza

287 ght weight and low cost printed graphene for wireless wearable communications applications.

288 nabled low cost and environmentally friendly wireless wearable communications systems in the near fut

289 l functionalities of RF signal processing in wireless wearable communications systems.

290 ium arsenide microwave devices, the consumer wireless workhorse, in a transferrable thin-film form.