ライフサイエンスコーパス: wireless

1 Wireless acquisition of EOG further demonstrates accurat

2 precedented multifunctional properties, like wireless activation of enzyme function using electromagn

3 Wireless alternatives eliminate constraints associated w

4 A Wireless Amplified NMR Detector (WAND) with cylindrical

5 of measuring biopotentials, in real time, in wireless and fully-passive manner.

6 lts, possible through recent advancements in wireless and portable EEG technology, suggest that possi

7 stimulation (Mo-DBRS) platform that enables wireless and programmable intracranial electroencephalog

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

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

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

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

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

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

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

15 ones to record spontaneous vocalizations and wireless autonomic monitors to record heart rate, heart

16 neering science include designs that support wireless, battery-free operation; real-time, in-sensor d

17 able photometric modules in a class of fully wireless, battery-free photometer that is fully implanta

18 Here we present a wireless, battery-free platform of electronic systems an

19 We developed a wireless biologging network (WBN), which enables simulta

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

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

22 ineered systems of mobile units with limited wireless capabilities.

23 neural interface schemes, and battery-free, wireless capabilities.

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

25 lesions or gastrointestinal bleeding during wireless capsule endoscopy.

26 Novel telemetric AUM (TAUM) methods that use wireless, catheter-free, battery-powered devices to moni

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

28 utilized for two types of fully self-powered wireless chipless sensors with no microelectronic compon

29 Incorporated with a wireless circuit, the sensor platform achieves continuou

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

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

32 ght weight are highly desirable for flexible wireless communication and other miniaturized microwave

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

34 of microelectronic circuits and, ultimately, wireless communication capabilities, have provided the t

35 nted to demonstrate self-powered sensing and wireless communication capability.

36 Highly integrated, flexible, and ultrathin wireless communication components are in significant dem

37 critical step forward in realizing flexible wireless communication devices.

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

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

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

41 excellent dielectric properties required in wireless communication system.

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

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

44 processor control of actuation and Bluetooth wireless communication through an Android application.

45 evels in neutral fluids mimicking sweat, and wireless communication with a personal computer via an i

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

47 to such radiative nature of the traditional wireless communication, EM signals propagate in all dire

48 pared to >5 m detection range for on-body EM wireless communication, highlighting the underlying adva

49 logies and coupled with machine learning and wireless communication, represent the future trend in th

50 In ultra-wideband or impulse radio terahertz wireless communication, the atmosphere reshapes terahert

51 stom-made heat block controlled by Bluetooth wireless communication.

52 in principle should minimize attenuation for wireless communication.

53 nals over large distances for more efficient wireless communication.

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

55 y electronics in the era of fifth-generation wireless communication.

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

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

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

59 of merit (Range x Bit Rate) for 'THz Torch' wireless communications links.

60 tion of future ubiquitous secure 'THz Torch' wireless communications links; as well as other applicat

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

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

63 g, through novel security applications, fast wireless communications, and new abilities to study and

64 me, are in urgent demand for applications in wireless communications, multifunctional entertainments,

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

66 rcial attention since it could revolutionize wireless communications.

67 redicted spectrum crunch for radio-frequency wireless communications.

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

69 tiotemporal mapping and pathogen tracking by wireless connection and web-based surveillance.

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

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

72 inically and commercially viable digital and wireless consumer and health products.

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

74 ase the clinical relevance of EA by allowing wireless control over device operation (capability to re

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

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

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 networks and finally the IT revolution with wireless data collection and transmission via Bluetooth

80 aptive classifiers, were used to process the wireless data of the subjects at four different postures

81 Wired and wireless data shows <3% discrepancy in deep learning tes

82 As wireless data traffic continues to increase, there is a

83 arvester for powering the sensors and secure wireless data transfer electronics, and machine learning

84 A secure wireless data transfer hardware powered by a piezoelectr

85 (3)(-)) in wastewater that were coupled to a wireless data transmission gateway for real-time remote

86 oencephalogram (EEG) recording combined with wireless data transmission offers an alternative tool to

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

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

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

90 In devices with optimized, wireless designs, these polymers enable stable, long-liv

91 Here, we describe a wireless device designed to be conformally placed on the

92 y integrated pacifier operates as a portable wireless device toward noninvasive chemical monitoring i

93 Mobile and wireless devices yield information about where and when

94 aradigm generates the anti-correlation with "wireless" dipole coupling that consumes no footprint on

95 g testing accuracy for ECG and EMG up to the wireless distance of 240 mm.

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

97 of mice for over four weeks via programmable wireless drug delivery and photostimulation.

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

99 The wireless EA microprobe consists of a millimeter-sized pi

100 PE with objects passing through the pores or wireless ECL-emitting micropores.

101 The wireless ECoG system has low energy consumption and high

102 States Food and Drug Administration-cleared wireless electroceutical dressing (WED) was tested in an

103 In this paper, a novel fully-integrated wireless electrochemical sensing platform is presented.

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

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

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

107 e measured muscle activation intensity using wireless electromyogram recordings.

108 Integrating the wireless electronic circuitry into the eyeglasses frame

109 stic substrate and encapsulation coating for wireless electronic components.

110 Wireless electronic devices illustrate the capacity to i

111 Moreover, various complex functional wireless electronics are developed using near-field comm

112 e demonstrate highly stretchable transparent wireless electronics composed of Ag nanofibers coils and

113 degradable drug-loaded patch integrated with wireless electronics for controlled intracranial drug de

114 trochemical sensing, along with miniaturized wireless electronics on a single pacifier platform.

115 gigahertz rectification for fifth-generation wireless electronics, to ultraviolet-visible photodetect

116 cales and levels of neural activity, we used wireless electrophysiology to simultaneously record from

117 Here, we report a system integrating wireless electrophysiology, wireless eye tracking, and r

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

119 exible and integrated rectenna that achieves wireless energy harvesting of electromagnetic radiation

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

121 illating and coupled voltage signals for the wireless energy transfer are developed, showing excellen

122 Here, we introduce a highly miniaturized wireless energy-harvesting and digital communication ele

123 stem integrating wireless electrophysiology, wireless eye tracking, and real-time video analysis to e

124 oxidation, and solderability, which allows a wireless flexible circuit.

125 Through integration with a wireless flexible printed circuit board and seamless bil

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

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

128 The wireless fully-passive acquisition of biopotentials is e

129 These findings support that the real-time wireless fully-passive acquisition of on-body biopotenti

130 The low-profile, wireless, gel-free device shows enhanced breathability a

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

132 upling through a stretchable DFOS-integrated wireless glove that can reconfigure all types of finger

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

134 ies demonstrate an innovative strategy for a wireless 'green' power source and sensing.

135 The use of commercial wireless hardware allows for flexibility in programming

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

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

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

139 enser activations via a wireless signal to a wireless hub divided by a previously validated estimate

140 Designing wireless iBCIs that provide the high-quality recordings

141 inexpensive single-use WPEDs and a reusable, wireless impedance analyzer to provide a wearable soluti

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

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

144 They wore miniature wrist wireless inertial sensors (actigraphs) throughout the ad

145 Wireless integration of multiple LISCCPs across multiple

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

147 g., food preparation, telecommunication, and wireless Internet) and the increasing prevalence of THz

148 The efficacy of wireless intracortical brain-computer interfaces (iBCIs)

149 Here, we describe a wireless, leadless and battery-free implantable neural s

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

151 The low-cost 'THz Torch' wireless link technology is still in its infancy.

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

153 Here, by using in vivo wireless local field potential recordings during working

154 could significantly increase the accuracy of wireless localization in applications.

155 In the Wireless Localization Matching Problem (WLMP) the challe

156 icrocilia array is presented that allows for wireless, localized actuation through the combined use o

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

158 ve respiration information in a wearable and wireless manner.

159 We demonstrate that wireless ME stimulators provide therapeutic deep brain s

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

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

162 large-scale, long-lasting neural recording; wireless, miniaturized implants; signal transmission, am

163 g harmful effects, motivating their use as a wireless, minimally invasive means to control neural act

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

165 c platforms that have unique capabilities in wireless monitoring and control of various biological pr

166 Remote wireless monitoring is a new technology that allows the

167 Wireless monitoring of combined subjective and objective

168 Some applications would benefit from wireless monitoring of proteolytic activity at minimal c

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

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

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

172 Using a wireless multichannel neural recording technique, we obs

173 uring of functional materials that enables a wireless, multilayered, seamlessly interconnected, and f

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

175 Of the many challenges in building a wireless network at terahertz frequencies, link discover

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

177 Motivated by applications in wireless networks and the Internet of Things, we conside

178 Security in wireless networks has traditionally been considered to b

179 Nevertheless, wireless networks in tunnel environments are associated

180 lding physical models of wave propagation in wireless networks, this method can be used more generall

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

182 called physical layer to provide security in wireless networks.

183 Here, we describe an artefact-free wireless neuromodulation device that enables research ap

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

185 Here we present a wireless, non-invasive technology that not only offers m

186 h a flexible printed circuit board, enabling wireless on-body detection of pH, Na(+), and K(+) with f

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

188 n-like electronic devices whose coordinated, wireless operation reproduces the functionality of these

189 Additionally, wireless operation using a custom designed smartphone ap

190 n opportunity given their quick response and wireless operation, despite the difficulty in achieving

191 Emerging wireless options offer important capabilities that avoid

192 The wireless optoelectronic system consists of sub-millimete

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

194 rnal stimuli, here, we report an implantable wireless optogenetic device that bypasses the beta-AR pa

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

196 validated our automated training system with wireless optogenetics and pharmacology experiments, expa

197 The wireless optogenetics stimulation in the subcutaneous ad

198 ultural and phenotyping devices via optical, wireless or electrical signals.

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

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

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

202 ies or uncomfortable transnasal catheters or wireless pH monitoring, which capture abnormal intralumi

203 g esophagogastroduodenoscopy with or without wireless pH monitoring.

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

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

206 The capabilities include wireless pharmacological and optical intervention for di

207 he residual peripheral field, we developed a wireless photovoltaic retinal implant (PRIMA; Pixium Vis

208 and depression at their clinic, and received wireless physical activity trackers.

209 ied the feasibility of collecting continuous wireless physiological data using Lifetouch (ECG-derived

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

211 stry (BPE) is a powerful method based on the wireless polarization of a conductive object that induce

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

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

214 The wireless potentiostat transmits data via Bluetooth to an

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

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

217 or challenge for miniature bioelectronics is wireless power delivery deep inside the body.

218 , potentiostat, signal processing circuitry, wireless power harvesting circuitry, and wireless teleme

219 Here, we show that an alternative wireless power method based on magnetoelectric (ME) mate

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

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

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

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

224 xt-generation telecommunications, long-range wireless power transfer, and electromagnetic warfare.

225 near gain saturation element provides robust wireless power transfer.

226 wering methods such as energy harvesting and wireless power transfer.

227 A decade ago, non-radiative wireless power transmission re-emerged as a promising al

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

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

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

231 e the innovative Glacsweb subglacial in situ wireless probes, combined with dGPS and custom geophone

232 A wireless pulmonary artery pressure sensor (CardioMEMS) i

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

234 ionality in optical frequency combs, such as wireless radio communication and wireless synchronizatio

235 ously relate changes in chemiresistance to a wireless readout.

236 Participants underwent prolonged wireless reflux monitoring (off PPIs for >=7 days) and a

237 to examine the clinical utility of prolonged wireless reflux monitoring to predict the ability to dis

238 This case series illustrates that a wireless remote vital signs monitoring system on medical

239 configuration and data processing as well as wireless results sharing.

240 ted that real-time, in situ monitoring using wireless S-ISM nitrogen sensors could save 25% of electr

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

242 his paper, a novel needle-injectable mm-size wireless sensing platform is presented to fulfill these

243 s) and chipless transponders stand out among wireless sensing technologies when low cost is a require

244 We experimentally proved this wireless sensor concept by monitoring the presence of a

245 nstrated as a highly-responsive, passive and wireless sensor for glucose monitoring.

246 In industrial applications, low-power wireless sensor networks (WSNs) fulfill requirements sim

247 Recognizing human physical activities using wireless sensor networks has attracted significant resea

248 a digital health platform, which relies on a wireless sensor to track the place and time of inhaler u

249 Finally, wireless sensors and color indicators for intelligent pa

250 Here, we use wireless sensors to measure simultaneously both the loca

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

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

253 nanogenerator (TENG) and fully self-powered wireless sensors.

254 hemical and electrophysiological sensing and wireless signal communication are of high significance t

255 t with a set of candidate locations based on wireless signal measurements taken by the pieces of equi

256 complicated by the noise that is inherent in wireless signal measurements.

257 nitizer and soap dispenser activations via a wireless signal to a wireless hub divided by a previousl

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

259 Here, we introduce soft, wireless, skin-like electronics (SKINTRONICS) that offer

260 his study shows the first demonstration of a wireless, soft, thin-film electronics for a real-time, r

261 ires by demonstrating practical self-powered wireless strain sensing capability.

262 bs, such as wireless radio communication and wireless synchronization to a reference source.

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

264 We introduce an innovative wireless system based on magnetic induction for human ac

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

266 d strategies for achieving fully integrated, wireless systems.

267 m the physical radio transmission aspects of wireless systems.

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

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

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

271 ently, stretchable electronics combined with wireless technology have been crucial for realizing effi

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

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

274 tions between male and female mates, we used wireless telemetric systems for simultaneous measurement

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

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

277 the experiment using a validated implantable wireless telemetry system; high-definition video was rec

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

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

280 ry, wireless power harvesting circuitry, and wireless telemetry unit, all on a single microchip.

281 lectronics, implementation of high-data-rate wireless telemetry, and compatible device packaging-all

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

283 Particularly, the wireless transmission efficiency of a five-turn coil dro

284 able route for in-sensor data processing and wireless transmission in many medical and clinical setti

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

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

287 Wireless transmission of detected arterial pressure sign

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

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

290 r, ultrasound receiver, data acquisition and wireless transmitter, has a small footprint and light we

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

292 oteolytic degradation could be used in these wireless transponders as a transduction mechanism of pro

293 onstrate a magnetic resonance coupling based wireless triboelectric nanogenerator (TENG) and fully se

294 his work presents the integration of a novel wireless two-channel amperometric potentiostat with micr

295 three European countries installed a remote wireless vital signs monitoring system on medical or sur

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

297 The wireless wearable sensor, consisting of ultrasound emitt

298 The system, consisting of two wireless wearable sensors, accurately extracts and class

299 even subjects were recruited to evaluate the wireless wearable sensors.

300 nd biocompatible materials with miniaturized wireless wearable systems is undoubtedly an attractive p