ライフサイエンスコーパス: smart

1 n was conducted and data were analyzed using SMART.

2 thms and controls that make these structures smart.

3 of our platform applies our custom-developed SMART 3D (Spatial filtering-based background removal and

4 aging of brain metastasis animal models with SMART 3D, we demonstrate the capability of our integrati

5 alable Metagenomics Alignment Research Tool (SMART), a novel searching heuristic for shotgun metageno

6 In conclusion, P-SMART, a novel polymer-microtubule destabilizer conjugat

7 The utility of SPNs for designing smart activatable probes for real-time in vivo imaging i

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

9 The SMART AF trial participants' mean age was 58.7 (10.8) ye

10 easibility of a reproduction analysis of the SMART-AF trial was demonstrated through an academic data

11 A reproduction analysis of the SMART-AF trial was performed using the data sets, data d

12 SMART-AF was a multicenter, single-arm trial evaluating

13 Symptomatic Paroxysmal Atrial Fibrillation (SMART-AF) trial using shared clinical trial data.

14 loss of specific alleles relevant to climate-smart agriculture.

15 ontinuous glucose monitoring, insulin pumps, smart algorithms), alongside advances in stem cell biolo

16 members of their gender are "really, really smart." Also at age 6, girls begin to avoid activities s

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

18 In our head to head comparison, SMART and CLARK had similar accuracy gains over Kraken a

19 e Vmh2-GFP fusion protein has proven to be a smart and effective tool for the study of Vmh2 self-asse

20 e, using a 3D laser printing technique, into smart and highly biocompatible scaffolds capable of supp

21 bino mice to determine in vivo efficacy of P-SMART and SMART-OH at the dose of 20mg/kg.

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

23 ludes that to make interventions successful, smart, and sustainable, they need to be implemented as m

24 In this work, we report the smart application of AgNPs based sensors for determinati

25 of a lab-based detector by a cellphone with smart applications will further enable cost-effective an

26 the first time TSD determination is given a smart approach and it proves to have a great utility up

27 Broad application of the HIV-SMART approach was demonstrated using a panel of diverse

28 The SMART approach, while drastically reducing system comple

29 nic contaminants from wastewater is deemed a smart approach.

30 ntly discovered ubiquitin ligases Fbxo31 and SMART are induced by mechanical silencing, an induction

31 ntly identified ubiquitin ligases Fbxo31 and SMART are induced by mechanical silencing, an induction

32 rospectively in 426 patients enrolled in the SMART-AV study (SmartDelay Determined AV Optimization: A

33 e feasibility of an automated, non-invasive 'smart bandage' for early detection of pressure ulcers.

34 ng and show great value in the fulfilment of smart biomaterials in emerging areas.

35 Smart biomimetics, a unique class of devices combining t

36 trates that SimCells are able to perform as 'smart bioparticles' controlled by designed gene circuits

37 elivery systems can be designed by utilizing smart biopolymeric compounds with the required pH-sensit

38 The smart biosensor has exhibited a turn-on signal when all

39 d in the chef (OR, 3.08; 95% CI, 2.23-4.25), smart cafe (OR, 1.45; 95% CI, 1.13-1.87), and chef plus

40 (OR, 1.45; 95% CI, 1.13-1.87), and chef plus smart cafe (OR, 3.10; 95% CI, 2.26-4.25) schools compare

41 s after 3 months were then randomized to the smart cafe intervention or to the control group.

42 ong-term or extended exposure to the chef or smart cafe intervention, fruit selection increased in th

43 To assess the effect of choice architecture (smart cafe), all schools after 3 months were then random

44 anoimmune interactions and developing immune-smart cancer nanomedicine that can take advantage of the

45 tudy, we use network-wide data obtained from smart cards in the London transport system to predict fu

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

47 This "smart cell patch", described on page 3115, effectively r

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

49 This review focuses on the smart chemistry that has been utilized in developing pol

50 l nations are focusing on the development of smart cities, linking innovations in the data sciences w

51 Two kinds of humidity-induced, bendable smart clothing have been designed to reversibly adapt th

52 Stable smart coatings on glass demonstrate robust switching ove

53 etwork largely simplifies the fabrication of smart coatings with a prominent triggered topographic re

54 gn space for anisotropic building blocks for smart colloidal materials.

55 The smart composite design strategy should hold a place in d

56 heir void phase make the design of novel and smart composite materials possible.

57 Due to poor water solubility of SMART compounds, co-solvent delivery is required for the

58 rs, substituted methoxybenzoyl-ary-thiazole (SMART) compounds, which inhibited tubulin polymerization

59 icability as an intermittent power source in smart contact lenses.

60 Furthermore, a smart dancing blanket is designed to simultaneously conv

61 Harnessing big data, deep data, and smart data from state-of-the-art imaging might accelerat

62 e toxophores enhances the efficiency of this smart delivery system.

63 tication code storage, cryptography key, and smart delivery tag.

64 avourable compositions and demonstrates that smart descriptors, based solely on alloy properties avai

65 ic impact, there is a powerful incentive for smart design of new materials with enhanced functionalit

66 or building heating or cooling with numerous smart design.

67 c devices and will serve as inspirations for smart designs in flexible electronics.

68 This review covers the smart designs of structural materials inspired by natura

69 Smart detection systems for explosive sensors are design

70 The novel smart detection tool for fluorescently labeled biomolecu

71 The proposed method gives the smart detection, portability, rapidity, sensitivity, sel

72 tism can be computationally assessed by fun, smart device gameplay.

73 tically low levels, thereby functioning as a smart device.

74 evolutionary success of mobile computing and smart devices calls for the development of novel, cost-

75 ay to the development of endless examples of smart devices.

76 sses the latest developments in the field of smart diagnostic systems for cancer biomarkers.

77 SMART Digest enabled complete digestion in 30 minutes co

78 ime peptides was optimised using trypsin and SMART Digest.

79 hey have strong potential for application in smart displays and solar cells.

80 ion which may range from smart filtration to smart dressings.

81 e a firm basis for the development of EVs as smart drug carriers based on straightforward and transfe

82 field of photopharmacology aims to introduce smart drugs that, through the incorporation of molecular

83 Thermoresponsive smart electrolytes based on Pluronic solution are develo

84 soft devices that are critical in robotics, smart engineering surfaces and materials, and biomedical

85 In this study, we demonstrate a smart exendin-4 (Ex4) delivery device based on microneed

86 In addition, the smart fabrics that are readily and non-invasively integr

87 ore importantly, upon wisely configuring the smart fabrics with a scalable sensor network, localized

88 The CNT enabled smart fabrics, fabricated by a cost-effective and scalab

89 The smart film has a reconfigurable laminated structure that

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

91 ent a general approach to remote-controlled, smart films that undergo simultaneous changes of surface

92 energy- and evolution-based approaches with smart filtering to identify additive stabilizing mutatio

93 n practical application which may range from smart filtration to smart dressings.

94 has prompted the development of very diverse smart fluorescent architectures, rationally designed to

95 in the design, synthesis and application of smart fluorescent probes for imaging macrophage cellular

96 anes and has great potential applications in smart gating systems and molecular separation.

97 g the Xpert GBS LB assay and the FDA-cleared Smart GBS assay as a molecular diagnostic comparator.

98 Particularly exciting are "smart" gels that undergo reversible physical changes on

99 new opportunities for emerging self-powered smart glass.

100 Monitoring Antimicrobial Resistance Trends (SMART) global surveillance program collected 103,960 iso

101 We believe this smart glucose-responsive Ex4 delivery holds great promis

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

103 In general, smart graphene interfaces switch bioelectrodes from the

104 atives like gun violence restraining orders, smart gun technology, and gun safety education campaigns

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

106 Like the smart human sweating pores, the flaps can close automati

107 wing demand for creating stimuli-responsive "smart" hydrogels, here we show the synthesis of entirely

108 rfine and single-matched resonance transfer (SMART) HYSCORE, to detect two weakly coupled exchangeabl

109 a universal library preparation method (HIV-SMART [i.e.,switchingmechanismat 5' end ofRNAtranscript]

110 tive efforts to employ DNA nanostructures as smart imaging agents or delivery platforms within living

111 h assemblies opens the way for miniaturised, smart immuno-technologies with 'built-in' programmable i

112 discuss current and future applications of "smart" implantable scaffolds capable of controlling the

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

114 To achieve this goal, smart initiatives must move beyond city-level data to a

115 The above are examples of smart inks, i.e. inks that are active and provide either

116 tration of utilizing RBC membrane to achieve smart insulin delivery with fast responsiveness.

117 The smart insulin patch effectively regulated the blood gluc

118 e using a painless microneedle-array patch ("smart insulin patch") containing glucose-responsive vesi

119 We sought to create a "smart" insulin, one that can alter insulin clearance and

120 ed (1:1) to receive either the intervention (SMART intervention group) or general information about h

121 iated communication with a health coach (the SMART intervention).

122 The concept of smart is referred to the characteristic of those materia

123 SMART is the first scalable, efficient, and rapid metage

124 The term "smart" is used here to refer to switchable, multifunctio

125 Using probabilistic graphical models, SMARTS iterates between reconstructing different regulat

126 with a hairpin structure to act as both the 'smart key' and the delivery carrier.

127 was evolved previously with three successive smart libraries, each guided by different structural, bi

128 ulticomponent reaction to create a small but smart library of alpha-acyl aminocarboxamides and evalua

129 variants, for continued and reliable use of smart library strategies.

130 h successive mutations, and hampered further smart-library designs.

131 A twice-as-smart ligand is a small molecule that experiences a stru

132 itch upon interaction with its target (i.e., smart ligand) that concomitantly triggers its fluorescen

133 Prototypes of twice-as-smart ligands were recently developed to track and label

134 d to develop a novel application of twice-as-smart ligands, as efficient chemical sensors of bacteria

135 The tailoring of smart material properties is one of the challenges in ma

136 ide expands its technological potential as a smart material.

137 rfaces of the body, comprises an inherently "smart" material that gives hard bones added strength und

138 The shape-change of 3D printed smart materials adds an active dimension to the configur

139 telemedicine, flexible and wearable sensing, smart materials and metamaterials.

140 des a new and robust approach for delivering smart materials and structures for self-powered wireless

141 Smart materials are created in nature at interfaces betw

142 e how the unique and versatile properties of smart materials may be exploited in a wide range of appl

143 polymers provides a strategy for generating smart materials that can respond to environmental stimul

144 Smart materials that mimic the ability of living systems

145 ew and effective way to design molecules for smart materials through mimicking a sophisticated biofun

146 d materials, with applications spanning from smart materials to optoelectronics to quantum computatio

147 alves, for cellular environments composed of smart materials whose size, shape, permeability, stiffne

148 Herein, we report the generation and use of "smart materials", namely molecularly imprinted polymers

149 and performance of a novel type of advanced smart materials, namely, biocomputing agents.

150 in order to access an entirely new class of smart materials.

151 roperties with potential for applications as smart materials.

152 been an essential motivation in the study of smart materials.

153 logical change in protein-based mu3D-printed smart materials.

154 lecules which can lead to stimuli-responsive smart materials.

155 ld has great potential in the development of smart materials.

156 mations present an entirely new approach to 'smart' materials.

157 n College of Physicians (ACP), including ACP Smart Medicine and MKSAP (Medical Knowledge and Self-Ass

158 Editorial consultants from ACP Smart Medicine and MKSAP provide expert review of the co

159 cal to soft robots, programmable matter, and smart medicine.

160 Even though reversible self-actuation of smart membranes is desirable in large-scale, reversible

161 dvance the development of future large-scale smart membranes needed for sustainable indoor climate co

162 Smart membranes, which can selectively control the trans

163 ging from supercapacitors and electrodes to "smart" membranes and thermoelectrics.

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

165 mechanism at the 5' end of the RNA template (SMART) method to obtain full-genome sequences.

166 e mutants, pNPmut1 was then used to create a smart microbial cell responding to pNP production from h

167 applications for channel-free microfluidics, smart microreactors, microengines, and so on.

168 his review highlights the recent advances of smart MNPs categorized according to their activation sti

169 ted the design and fabrication of inventive "smart" MNPs for stimulus-responsive controlled drug rele

170 onality is crucial in the nanofabrication of smart molecular devices.

171 advances in optoacoustic imaging assisted by smart molecular labeling and dynamic contrast enhancemen

172 strategies for designing potentially useful smart multicomponent organic electronics.

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

174 Smart nanocarriers in the form of MNPs that can be trigg

175 Among drug delivery systems (DDSs), smart nanocarriers that respond to specific stimuli in t

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

177 nic-sulfur bond, and we termed the resulting smart nanodrug as FA-HSA-ATO.

178 Specifically, smart nanogels are interesting because of their ability

179 e report the fabrication of multifunctional, smart nanoparticle systems by combining top-down fabrica

180 Next-generation 'smart' nanoparticle systems should be precisely engineer

181 guide the rational design of polymer-coated smart nanopores.

182 Here, we describe smart nanosystems classified in two categories: (i) thos

183 Smart nanosystems have the potential to produce personal

184 olbox for characterization of self-assembled smart nanosystems used in biosensing, imaging, controlle

185 is to comprehensively describe all types of smart NHC ligands by focusing attention on the catalytic

186 A smart Off-On molecular scaffold/fluorescent probe 1 has

187 to determine in vivo efficacy of P-SMART and SMART-OH at the dose of 20mg/kg.

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

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

190 principles paves the way to self-optimising 'smart' optical technologies.

191 relevance for designing new photo-responsive smart or adaptive stimuli responsive functional material

192 useful for understanding and characterizing smart or bio-inspired materials.

193 Smart or functional surfaces that exhibit complex multim

194 ovide Gene Ontology terms, KEGG pathways and SMART/Pfam domains for each group.

195 rimetric intensity was also measured using a smart phone and computer software at a linear range of 0

196 n of detected arterial pressure signals to a smart phone demonstrates the possibility of self-powered

197 as developed from a simple cardboard box and smart phone for the detection of PNP and ONP.

198 its small size and light-weight similar to a smart phone, the developed system is ready to be applica

199 pulse signals of cardiovascular system on a smart phone/PC.

200 ource interface to the Galaxy system through smart phones and tablets.

201 to satisfy the principal frequency bands of smart phones such as those for cellular communication, B

202 products such as desktops, servers, laptops, smart phones, and tablets.

203 MEMS accelerometers--found in most smart phones--can be mass-produced remarkably cheaply, b

204 ce based on light emitting diodes (LEDs) and smart phones.

205 in photodynamic therapy (PDT), we designed a smart plasma membrane-activatable polymeric nanodrug by

206 Smart poly(2-oxazoline) (POx)-based multifunctional poly

207 Such humidity sensitive smart polymer materials can be utilized to adjust person

208 wledge could help to select more effective ('smart') polymeric systems based on the biological target

209 tural facts about stimuli responsiveness of "smart" polymers.

210 nt of intermittent renewable energy sources, smart power grids, and electrical vehicles.

211 l but the most extreme case, our model of a "smart" power network coupled to a communication system s

212 own the gain of neurotransmission, akin to a smart pre-synaptic ss-blocker.

213 ding its application beyond data transfer to smart preliminary data decision-making prior to full acq

214 ncomitantly triggers its fluorescence (i.e., smart probe).

215 The chosen ligand is a phosphine-based smart probe, whose strong fluorescence depends on the pr

216 Bioorthogonally activated smart probes greatly facilitate the selective labeling o

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

218 with amazing resilience and multifunctional smart properties.

219 electronics and energy harvesting devices to smart prosthetics and human-machine interfaces.

220 The proposed approach offers a smart protocol for IgG immobilization on SU-8 substrate

221 HIV-SMART provides an unparalleled opportunity to identify d

222 scanning Fabry-Perot micro-cavity resonator (SMART) providing a simple, compact and accurate method t

223 The first prototypes of twice-as-smart quadruplex ligands were designed to exploit the se

224 echniques (modified ellipsoid volume [MELV], smart region of interest [ROI] volume, renal cortex volu

225 Smart regulation of substance permeability through porou

226 A smart release system responsive to near-infrared (NIR) l

227 The latter mechanism includes "smart release" of agents when triggered by pathogenic mi

228 ken at the species classification level, but SMART required approximately half the amount of RAM of C

229 The external performance of the SMART risk score was reasonable, apart from overestimati

230 ronic interfaces, military applications, and smart robots.

231 ere are taxonomic group effects in the data, SMART-scan can significantly increase power by using bac

232 SMART-scan is a model selection technique that uses a pr

233 We investigate the statistical properties of SMART-scan through simulations, in comparison to a regul

234 nalysis of Risk factor Trees (referred to as SMART-scan), for identifying taxonomic groups that are a

235 The SMART score (Second Manifestations of Arterial Disease)

236 er highlights the advancements in developing smart sensing strategies to monitor ZIKV progression, wi

237 nts in the development of microfluidic-based smart sensing systems is the manufacturability of integr

238 requirements for a range of battery-powered smart-sensing applications.

239 ny fields such as human-machine interfacing, smart sensor, and processor systems.

240 We also compare with Smart-Seq to demonstrate CEL-Seq2's increased sensitivit

241 Some steps follow published methods (Smart-seq2 for cDNA synthesis and Nextera XT barcoded li

242 To demonstrate the utility of SMART, several newly isolated compounds were automatical

243 Smart shape-memory polymers can memorize and recover the

244 Similar to its parent drug, P-SMART showed significant anticancer activity against mel

245 ouchpad technology, personalized signatures, smart skin, and silicon-based photonic integrated circui

246 nsfer, we created a tool called the Big Data Smart Socket (BDSS) that abstracts data transfer methodo

247 tion of sophisticated molecular machines and smart soft materials.

248 Such a kernel leads to smart stretching with nonuniform spectral resolution, ha

249 d cognitive impairment were recruited in the SMART (Study of Mental Activity and Resistance Training)

250 ignificance of electrospun nanofiber mats as smart surfaces to capture diverse classes of compounds f

251 ochemical coupling is exploited to generate "smart surfaces", i.e., polymer-modified electrodes, avoi

252 evelopment of novel self-cleaning adhesives, smart surfaces, microelectromechanical systems, biomedic

253 ctronics, such as augmented reality devices, smart surgical glasses, and smart windows.

254 ns that society faces to transition toward a smart, sustainable, and healthy urban future.

255 ew LOC platform might prove interesting as a smart system for detection and remediation of diverse pe

256 Taken together this 'smart-system' technology could be applied to a wide rang

257 uld be used to design the next generation of smart T cell precision therapeutics.

258 In this study, we employed smart tablet computers with touch-sensitive screens and

259 h sufficient power to operate an interactive smart tag, are reported.

260 ce of comfort, suggesting great potential in smart textiles or wearable electronics.

261 and prosthetics, future applications include smart textiles that change breathability in response to

262 ystems can be found in many areas, including smart textiles, autonomous robotics, biomedical devices,

263 nmental stimuli, are essential components of smart textiles.

264 nal Neural Networks (CNNs) to create a tool, SMART, that can assist in natural products discovery eff

265 of nanoparticles is essential for designing smart theranostic carriers.

266 t of DNA-based imaging probes, prototypes of smart therapeutics and drug delivery systems, and explor

267 d to be for children who are "really, really smart." These findings suggest that gendered notions of

268 ttom-up approaches stymies the harnessing of smart tissues' biological, mechanical and organizational

269 We applied SMARTS to analyze human response to influenza and mouse

270 on within scar to standard 3.5-mm catheters (Smart-Touch Thermocool).

271 In addition, P-SMART treatment led to cell cycle arrest at G2/M phase a

272 P-SMART treatment resulted in significant inhibition of tu

273 es for Management of Antiretroviral Therapy (SMART) trial robustly boosted HIV-1 gp120-specific Fc re

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

275 Here, we present a "smart" vaccine that leverages our current understanding

276 ploited to develop individually addressable "smart" valves that can be used to capture, "farm", and t

277 anslation of the next generation, nanoscale "smart" vesicle systems of enhanced functionality, follow

278 ch provides enough d.c. power for charging a smart watch or phone battery, is also successfully devel

279 rging a commercial capacitor, and powering a smart watch.

280 ction among oil, water and additives ions of smart water for further experimental investigations.

281 that ions present in sea water, also called smart water, have a significant influence on the wettabi

282 e realization of devices able to filter in a smart way an external radiation.

283 were randomized into the Strongest Families Smart Website (SFSW) intervention group (n = 232) or an

284 Statistical Metabolomics Analysis-An R Tool (SMART), which can analyze input files with different for

285 orption properties have been widely used for smart window applications to reduce energy consumption a

286 The smart window can be switched from the initial highly tra

287 harnessed in applications such as batteries, smart windows and fuel cells.

288 tions related to display technology, such as smart windows and mirrors and active optical filters.

289 aden their scope for other applications like smart windows and tags, new material properties such as

290 In this work, we combine the benefits of smart windows with energy conversion by producing a phot

291 promote the commercial utilization of VO2 in smart windows.

292 of interest to realizing the application of smart windows.

293 or application in dynamic optical filters or smart windows.

294 otovoltaic devices, NIR optical switches and smart windows.

295 reality devices, smart surgical glasses, and smart windows.

296 chromic effect that could see application in smart windows.

297 c pattern generation, and voltage-controlled smart windows.

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

299 ing sequences we compared Kraken, CLARK, and SMART within the same computing environment.

300 Novel applications include a smart wound dressing capable of sensing the temperatures