ライフサイエンスコーパス: smart

1 ons to social groups (e.g., white-dumb/Asian-smart).

2 Main Results: Of 15,802 patients enrolled in SMART, 1,641 patients were admitted to the medical ICU w

3 A second example applies SMART 2.0 to the characterization of structurally novel

4 l Molecule Accurate Recognition Technology" (SMART 2.0) for mixture analysis and subsequent accelerat

5 uided by cancer cell cytotoxicity, NMR-based SMART 2.0, and MS(2)-based molecular networking.

6 We propose Smart-3SEQ as a highly cost-effective method to enable l

7 In particular, Smart-3SEQ's compatibility with FFPE tissue unlocks an e

8 Here, we present a new method, Smart-3SEQ, that accurately quantifies transcript abunda

9 We present SMART, a tool based on recent algorithmic advances imple

10 ation-dependent, conformationally adaptive, "smart" accelerated antidotes against OP toxicity.

11 infections were incubated for 1 h with the "smart" activatable P2&3TT probe, the total assay time be

12 d facile method that was used to fabricate a smart actuator with precise patterning on a graphene oxi

13 example, in advanced computational systems, smart actuators, and programmable materials.

14 Fibronectin is a 'smart adhesive' that remodels to the lateral edges of th

15 Smart adhesives that undergo reversible detachment in re

16 mic therapy, we have engineered a robust and smart "all-in-one" nanoparticle-based drug delivery syst

17 SMARTS also supports extraction, analysis and visualizat

18 rease circulation time, we synthesized a new SMART analogue, SMART-OH, and its polymer-drug conjugate

19 wax-printed paper-microchip and a self-made smart analysis equipment for the concentration detection

20 comprising a PET/paper chip (PP-chip) and a smart analytical device is developed for detection of su

21 the application of CaCO(3) crystals for the smart and controlled delivery of antimicrobial agents an

22 , as well as inspire and improve designs for smart and effective devices in the future.

23 Pooled data from the SMART and START trials were used to compare deferred/int

24 count and viral suppression were similar in SMART and START.

25 shion imposes the emergent requirement for a smart and stretchable hazard avoidance sensing platform

26 Engineered biomaterials with smart and tunable properties offer an intriguing tool to

27 f 170,097 drug users are provided as part of SMARTS and can be used by researchers as a reference.

28 In this paper, we present a novel, smart, and automatic filtering technique for locally min

29 paradigm shift toward deploying integrated, smart, and eco-friendly strategies is required to advanc

30 nalyses into strategies to develop novel and smart anticancer metal compounds.

31 se to stimuli, which enables a wide range of smart applications, in soft robotics, adhesive systems o

32 Mode of transmission based hotspots is a smart approach to HIV mitigation yet remains poorly eval

33 and parasite thermal performance curves is a smart approach to improve predictions of temperature eff

34 ferent functionalities should be combined in smart architectures on nano- and microscales.

35 To meet this need, we developed SMAC (SMart Automatic Classification method): a tool to extrac

36 trarily shape propagation-invariant beams by smart beam design based on caustics.

37 and play' platform will be expanded towards smart biomaterial engineering for therapeutic delivery,

38 e (Sc-CO(2)) technology for manufacturing a "smart" biomaterial scaffold, which retains the native pr

39 enable the development and investigation of smart biomaterials and extend protein hydrogel capabilit

40 erent biomolecules/functional units, imaging smart biomaterials capable of sensing, interacting, deli

41 "Smart" biomaterials that are responsive to physiological

42 sensor as an example of portable, rapid, and smart biosensing devices widely used for qualitative and

43 searchers in their future work of developing smart biosensors, which can further improve detection se

44 Heart rate sensing smart bras are manufactured for females who participate

45 Smart building management systems equipped with portable

46 academic achievement and being perceived as smart by other students.

47 nal ethology, and so on, one person, however smart, cannot master everything.

48 A "smart canopy" ideotype has been proposed with leaves bei

49 le distribution in sorghum according to the "smart canopy" ideotype.

50 pathways, thus paving the way for generating smart CAR T cells able to integrate biological inputs an

51 The resulting 3D F-TENG can be used in smart carpets as a self-powered escape and rescue system

52 se well-known drug reservoirs can be used as smart carriers for multiple cargos, including both naked

53 mple solubilization of hydrophobic drugs to 'smart' carriers that deploy drug in response to a diseas

54 device (digital technology comprising an EAI smart case connected to a mobile APP) with functions tha

55 Its smart catalytic activity under mild conditions was valid

56 we introduce a large-scale, integrated, and smart cell-culture platform (LISCCP) that facilitates di

57 the utility of this transition by designing smart, cell-penetrating polymers that undergo acid-activ

58 lts have direct utility for town councilors, smart-city designers, and other urban decision makers.

59 n technologies, such as electronic circuits, smart clothing, and building environment control systems

60 tative molecular detection platform, termed "smart connected pathogen tracer" (SCPT), has been develo

61 of climate change impacts, devising climate-smart conservation actions, and helping enhance adaption

62 This approach utilizes smart copolymers comprised of poly(ethylene glycol) (PEG

63 folding-coupled reactivity switch (termed a smart covalent bond) could allow the adhesin to undergo

64 d and received individually delivered CPT or SMART-CPT for 12 weeks.

65 y compared the efficacy of standard CPT with SMART-CPT for treatment of veterans with comorbid PTSD a

66 SMART-CPT resulted in additional improvements in the neu

67 Both CPT and SMART-CPT resulted in clinically significant reductions

68 SMART-CPT, a mental health intervention for PTSD, combin

69 The smart delivery of pesticides is essential to reduce the

70 with nano-sized droplets can be utilized as smart delivery vehicles for designing oral therapies in

71 Smart design involves active engagement with the end use

72 permeability trade-off will pave the way for smart design of MD membranes in diverse water purificati

73 The smart design of PET-EVA films enabled us to selectively

74 Key topics include smart design, voice enablement and the integration of el

75 an electrochemical immunoassay for rapid and smart detection of SARS-CoV-2 coronavirus in saliva.

76 They are widely integrated in smart devices and wearables as flexible, high pixel dens

77 bles the development of novel biocompatible 'smart' devices and biosensors with precisely controlled

78 of DNA computing and to develop programmable smart diagnostic nanodevices.

79 rough cellular uptake assay which showed the smart differentiation by KCC-1-NH(2)-FA nanomaterials.

80 Programmable self-assembly of smart, digital, and structurally complex materials from

81 Fighting smart diseases requires smart vaccines.

82 applications, such as logic circuitries and smart displays.

83 Nano-fabricated smart drug delivery systems and implantable drug loaded

84 Their use as "smart drugs" by healthy subjects poses health concerns a

85 ge for humanity, an ethical obligation and a smart economic objective to achieve a sustainable future

86 upport for the idea that humans have evolved smart effort detection systems that are made more accura

87 Among various smart-electro-active nanostructures sensing materials, l

88 as including electrochemical energy storage, smart electronics and healthcare.

89 However, SMART enables detection of non-coding genes, which is no

90 Such mechanosensitive "smart" features may represent novel mechanisms for mecha

91 Such remote-controlled, smart films may open up new application possibilities in

92 e-nerve-cell RNA sequencing, for example, to smart FISH, large-scale calcium imaging from cortex and

93 offer great promises for the development of smart force-responsive materials.

94 y and function in the development of climate smart germplasm for the future.

95 y motions, and analysis of body fluids, (ii) smart gloves and prosthetics to realise the sensation of

96 -methyl-2-carboxyl-propylene carbonate-graft-SMART-graft-dodecanol) (abbreviated as P-SMART), with 14

97 applications of external electric fields as smart, green, and selective catalysts, which can control

98 pear in a wide range of applications such as smart grids, robotics, and intelligent manufacturing.

99 on decoding in emerging applications such as smart hearing aids.

100 This "smart" heparin patch can be transcutaneously inserted in

101 fire rescue and wearable sensors as well as smart home decoration.

102 red tissues and organs, including the use of smart hydrogels that can be modified to enhance organiza

103 propose a postsynthetic methodology for the smart implementation of ferroelectricity in chiral metal

104 spectives in glucose sensitive hydrogels for smart insulin delivery, pH sensitive polymeric hydrogels

105 ration into closed-loop insulin delivery or "smart insulin" systems.

106 Smart/intelligent contrast agent candidates for MRI base

107 The platform contains a smart interfacing circuit to operate an ultra-sensitive

108 ctromechanical systems and microrobotics, to smart intravascular stents, tissue scaffolds, and many o

109 In addition, 3D-SMART is able to quantify the occupancy of single Spinac

110 As a demonstration, 3D-SMART is applied to actively track single Atto 647 N flu

111 Included in SMARTS is a predictive modeling functionality that can,

112 SMARTS is a public, open source, web-based application t

113 SMARTS is designed to analyze data from two popular soci

114 Methods: Secondary analysis of patients from SMART (Isotonic Solutions and Major Adverse Renal Events

115 decades which, although often described as "smart," lack the ability to act autonomously.

116 ly controlling aberrations inherent to these smart lenses holds promise to develop highly versatile n

117 Smart ligand design is essential for implementing contro

118 autonomic behaviors provides a step towards smart liquid dispersions comprising motile microscale ob

119 us weak adhesion, may be exploited to create smart macroscopic structures.

120 ammable microparticle/droplet transport, and smart magnetic micro-tweezers.

121 They have implications for designing climate-smart management practices for these soils.

122 demanding and confined environment of future smart manufacturing tools.

123 s (EMSCs) are reported to serve as a living, smart material that creates a permissive, all-in-one nic

124 Switchable MOFs are a type of smart material that undergo distinct, reversible, chemic

125 Because of the "smart" material ECM, this scaffold may have the potentia

126 ropyl acrylamide) (PNIPAAm) is a well-known 'smart' material responding to external stimuli such as t

127 There has been a recent surge of interest in smart materials and devices with stimuli-responsive prop

128 using the organic linkers as antennae, novel smart materials can be developed, acting as sensors and

129 Although many artificial smart materials exhibit non-directional, nastic behaviou

130 aterials are emerging as the next generation smart materials that have shown promise in advancing a w

131 rtensitic materials are an emerging class of smart materials with enormous tunability in physicochemi

132 They are a unique class of smart materials with great potential in a broad range of

133 l for the development of biologically based "smart materials".

134 emistry, single-molecule force spectroscopy, smart materials, and molecular machines.

135 r platform is used to generate pH-responsive smart materials, and to easily control various sizes, sh

136 at may ultimately lead to the development of smart materials.

137 closer to the application of mechanochromic smart materials.

138 uld enable previously impossible devices and smart materials.

139 acid-based nanostructures and functionalized smart materials.

140 e a physical platform for the realization of smart memories and machine learning and for operation of

141 In this review, we propose the concept of smart microbial engineering (SME) and describe the gener

142 ing implications for emerging fields such as smart microelectronics and soft microrobotics.

143 d complex genetic circuits, recently emerged smart microorganisms have enabled exciting opportunities

144 e lack of design principles, developing such smart microorganisms remains challenging.

145 of MG has much importance, and the design of smart models is desirable.

146 Controlling chain behavior through smart molecular design provides the potential to develop

147 a significant advance in the construction of smart MRI nanoprobes ideally suited for deep-tissue imag

148 This FO-TENG represents a smart multifaceted sensing platform that has a unique ca

149 Smart multifunctional nanoparticles with magnetic and pl

150 h will provide access to a new generation of smart, multifunctional materials, coatings, and surfaces

151 emphasizes the significance of developing a smart nano-delivery system to optimize the delivery effi

152 We assess performance parameters of smart nanobiotechnology-based sensors in plants (for exa

153 in, we discuss the design and interfacing of smart nanobiotechnology-based sensors that report plant

154 hese polymers, we have developed a series of smart nanocarriers with hierarchical structures containi

155 This dynamic approach can be used to build smart nanochannel-based systems, which have strong impli

156 of block copolymers allows the formation of smart nanodimensional structures.

157 inted electrodes, exploiting carbon black as smart nanomaterial to monitor changes in algae oxygen ev

158 al sensitivity-enhancement methods alongside smart nanomaterials have been used for the creation of n

159 hniques in combination with a broad range of smart nanomaterials have integrated into the design of n

160 ious types of nanocomposites are examples of smart nanomaterials that have drawn intense attention in

161 materials, leading to scalable synthesis of "smart" nanosystems.

162 In addition, smart nanotherapeutic tools have proved their utility in

163 lly administered ASOs.FUNDINGSMA Foundation, SMART, NIH (R01-NS096770, R01-NS062869), Ionis Pharmaceu

164 tron transfer (PET) mechanism, we designed a smart nitric oxide (NO) probe, PYSNO, with high sensitiv

165 Method to Advance and Refine the Treatment (SMART) of CRC through hot and cold homogenization approa

166 n time, we synthesized a new SMART analogue, SMART-OH, and its polymer-drug conjugate, methoxy-poly (

167 s P-SMART), with 14.3+/-2.8% drug payload of SMART-OH.

168 novel opportunities for the fabrication of "smart" or stimuli-responsive devices.

169 ntamination control in food chain, water and smart packaging.

170 ations, ranging from wearable electronics to smart packaging.

171 sting potential applications for sensing and smart payload delivery.

172 propose here and demonstrate the concept of smart PDT, where pH-induced reversible twisting maximize

173 e fiber optic cables were captured using the smart phone and processed using a custom written image p

174 Using a smart phone based operative evaluation application (SIMP

175 ferent concentrations of E. coli O157:H7 and smart phone imaging APP for monitoring color change of t

176 Finally, the color was measured using the smart phone imaging APP to determine the amount of the b

177 using the touchscreen functionality on their smart phone to click on VAS scores (ranging from 0 to 10

178 We developed a 12-lead, blue-tooth/Smart-Phone (Android) based electrocardiogram (ECG) acqu

179 for the baseline and for a cordless phone, a smart-phone and a laptop.

180 , the entire size of which is smaller than a smart-phone and can be handheld, is presented for on-lin

181 4-week MFT- intervention delivered through a smart-phone app (n = 14) or were assigned to a waitlist

182 he signal can be wirelessly transmitted to a smart-phone or cloud sever through the Wi-Fi connection

183 n every-day life such as in touch screens of smart phones and watches, but also used as an optically

184 often eat while electronic devices, such as smart phones, computers, or the television, distract us.

185 stem crossing (ISC) are highly promising for smart photodynamic therapy (PDT), but achieving this goa

186 d light emission promotes the development of smart photonic materials for advanced applications in ch

187 ve vision on how nanotechnology could enable smart plant sensors that communicate with and actuate el

188 anobiotechnology has the potential to enable smart plant sensors that communicate with and actuate el

189 act as tools for research and development of smart plant sensors.

190 nesis offers an avenue to search for climate-smart plants to sustain crop and pasture productivity in

191 Bacterial therapy, which presents a smart platform for delivering and producing therapeutic

192 Though "smart" platforms offer control over protein release in r

193 zwitterionic hydrogels suitable for use in a smart, polymeric engine.

194 nature and phase transition behavior of the smart polymers found suitable for nasal administration,

195 al adhesives, tissue scaffolds, and advanced smart polymers.

196 ata transmission, mobile data processing and smart power utilization.

197 transfer (DAS-CRET) using two non-conjugated smart probes (ADLumin-1 and CRANAD-3) in solutions, brai

198 Bioorthogonally activated smart probes greatly facilitate the selective labeling o

199 Herein, we described a novel type of smart probes with tunable reaction rates, high fluoresce

200 ntative applications to the development of a smart prodrug, delivering a highly cytotoxic chemotherap

201 ght provide a platform for creating emerging smart protonic solids with potential applications in the

202 ganizers (0:31) than in the baseline (1:20), smart pump (1:29), and light-linking (1:22) conditions (

203 (0; 0%) than in the baseline (12; 7.7%) and smart pump conditions (10; 6.4%) (p < 0.01).

204 nts were significantly slower when using the smart pump than all other conditions (p < 0.001).

205 (current practice); line labels/organizers; smart pump; and light-linking system.

206 (OEEF), and other electric-field types, as "smart reagents", which enable in principle control over

207 A tactile, UV- and solar-light multi-sensing smart rechargeable Zn-air battery (SRZAB) with excellent

208 3D-SMART represents a critical step towards the untethering

209 uid-liquid interface, enabling the design of smart responsive structured-liquid systems.

210 06); SE: 3.49%, 0.65 (-0.82, 2.12)] and Oura smart ring [TST: 7.39%, 0.19 (0.04, 0.35); TWT: 36.29%,

211 econdary Manifestations of Arterial Disease (SMART) risk scores (area under the curve: 0.76 vs. 0.54,

212 The design of a smart robot for colonoscopy is challenging because of th

213 The smart rotation workflow outperforms the conventional app

214 In this work, we introduce a smart rotation workflow that utilizes on-the-fly image a

215 an all-point calibration on all sensors, the smart-sampling Kalman filter reduced the mean absolute r

216 Using a smart-sampling Kalman filtering smoothing algorithm impr

217 oronary stents, coronary stenosis, REACH and SMART scores, the Duke coronary artery disease index, an

218 m has applications in soft robotic grippers, smart segmented armors, deployable structures and soft s

219 By a smart selection of membranes [anion exchange membrane (A

220 in, a monolithically integrated self-powered smart sensor system with printed interconnects, printed

221 Nanotechnology-based smart sensors are opening new avenues for early and rapi

222 A sequencing using two independent platforms-SMART-seq (~4,500 neurons) and 10x (~78,000 neurons)-and

223 ndant starting material while the Takara Bio SMART-Seq v4 Ultra Low Input RNA kit (V4) sacrifices str

224 ariety of technologies, such as Drop-seq and SMART-seq, can reveal simultaneously the mRNA transcript

225 th any template-switch based library such as Smart-seq2 or the single-cell 5' gene expression kit fro

226 single cDNA samples, performing SMARTer and Smart-seq2 protocols on two cell lines with RNA spike-in

227 switch in different toggling states but on a smart seven-component mixture that manages the reversibl

228 capability could enable the development of 'smart skin'(1,3-5), which could transform ordinary objec

229 ases and expressed in the community-standard SMARTS (SMIRKS) format, augmented by a rule representati

230 Here, a new model system for the design of smart soft adhesives that dynamically respond to their e

231 ined network of droplets, paving the way for smart soft-matter diagnostics.

232 The SMARTS software analyzes social media posts using natura

233 plication area of the self-powered system to smart sport monitoring and assisting, but also promote t

234 smart sports bras was higher for the Adidas Smart sports bra and Sensoria Fitness sports bra, and lo

235 The Adidas Smart sports bra was valid only during rest (Intraclass

236 The Adidas Smart sports bra, Berlei sports bra, and Sensoria Fitnes

237 Perception of the smart sports bras was higher for the Adidas Smart sports

238 logical barriers on-demand with a simple and smart STICK design.

239 'Smart' supramolecular assembly of catalysts offers preci

240 g research disciplines, from microarrays and smart surfaces to tissue engineering.

241 elp to broaden the applications of lasers as smart surgical tools.

242 n metabolic and physiologic phenotypes using smart switchable luminescent probes.

243 ofluidics, advanced materials, biomaterials, smart systems, photonics, robotics, textiles, Big Data a

244 -efficiency of future electronic devices and smart systems.

245 Additionally, new smart targeted NPs with transformable characteristics re

246 uperior to those of either one alone and how smart task allocation can lead to further efficiencies i

247 itching Mechanism at 5' end of RNA Template (SMART) technology.

248 icrobial, UV-protective and antioxidant) and smart (temperature sensing) properties.

249 threads is ideal for the next generation of smart textile and intelligent clothing.

250 re, we present a single-layered, ultra-soft, smart textile for all-around physiological parameters mo

251 t washability, the single-layered ultra-soft smart textile is simultaneously capable of real-time det

252 Next, we systematically review smart textiles according to their abilities to harvest b

253 Finally, we provide a critical analysis of smart textiles and insights into remaining challenges an

254 nsor holds great promise for applications in smart textiles and wearable electronics.

255 review will not only deepen the ties between smart textiles and wearable NGs, but also push forward f

256 lexible supercapacitor (SC) for self-powered smart textiles and wearable systems is presented.

257 arch activities regarding the utilization of smart textiles for harvesting energy from renewable ener

258 is of great significance for next-generation smart textiles for real-time and out-of-clinic health mo

259 Recently, electronic skin and smart textiles have attracted considerable attention.

260 duction to contextualize the significance of smart textiles in light of the emerging energy crisis, e

261 NGs endow smart textiles with mechanical energy harvesting and mul

262 erve as the basis for future multifunctional smart textiles with passive-cooling functionalities.

263 is review will push forward the frontiers of smart textiles, which will soon revolutionize our lives

264 Underlying risk was greater in SMART than START.

265 ces between treatment groups were greater in SMART than START.

266 hey have potential as multifaceted adaptable smart therapeutics for treating inflammatory disorders.

267 e an innovative approach to produce anchored smart thin films both thermo- and electro-responsive, wi

268 The aim is to train smart thinkers, not technicians, to embrace challenges a

269 (ts)T is thereby a "smart" thymidine analog, exhibiting a 28-fold brighter f

270 the design and fabrication of cost-effective smart tires by demonstrating practical self-powered wire

271 Smart tires enable continuous monitoring of dynamic para

272 The 'smart' toilet, which is self-contained and operates auto

273 uce the use of a piezoelectric system called Smart-touch fine needle (or STFN) mounted directly onto

274 Therefore, these studies suggest that this smart unimolecular NP could be a promising nanoplatform

275 In recent years, smart upconversion nanoparticles with the ability to exp

276 tion holds the potential to enable a host of smart urban mobility strategies, including integration o

277 licability of our developed SWSP sensor as a smart, user-friendly, ultra-low-cost (~0.03 $ per sweat

278 has been focused on the literature update of smart using of biosensing for detection of mycotoxin at

279 Fighting smart diseases requires smart vaccines.

280 ruction materials and component recovery and smart waste management.

281 The developed Smart Wearable Sweat Patch (SWSP) sensor comprises highl

282 In Delphi step 1, a smart web-based survey based on background evidence from

283 olecule active real-time tracking method (3D-SMART) which is capable of locking on to single fluoroph

284 mber of detected coding genes decreased with SMART, while stayed constant with AmpliSeq.

285 rest as advanced materials for energy-saving smart window applications.

286 l oxides, makes it a potential candidate for smart window coating.

287 We have successfully fabricated a potential smart window device after the optimum design of a multil

288 potential of the structure to be used for a smart window device.

289 mendous potential to increase electrochromic smart window efficiency, speed, and durability.

290 ing EM waves in imaging and thermal control, smart windows and electronic papers.

291 he research on VO(2) thin films, not only as smart windows but also for numerous other applications l

292 researched for displays, adjustable mirrors, smart windows, and other cutting-edge applications.

293 ectrochemical systems such as electrochromic smart windows, batteries, solid oxide fuel cells, and se

294 ns, such as controllable light diffusers and smart windows, both for residential and mobile use.

295 nting rates and magnitudes across large-area smart windows.

296 on rates and reversibility across large-area smart windows.

297 hanism at 5' End of RNA Template technology (SMART) with two different library preparation methods (N

298 aft-SMART-graft-dodecanol) (abbreviated as P-SMART), with 14.3+/-2.8% drug payload of SMART-OH.

299 a novel method not only to detect AF from a smart wrist watch PPG signal, but also to determine whet

300 lling circle transcription acts as both the "smart zipper lock" and the delivery carrier to alternate