ライフサイエンスコーパス: technology

1 ny other applications for lateral flow strip technology.

2 l challenge the long-term efficacy of Vip3Aa technology.

3 g the gap between scientists and 3D printing technology.

4 herent in conventional membrane distillation technology.

5 classification models using machine learning technology.

6 e delay their potential adoption as a viable technology.

7 PIs by advancing the use of yeast two-hybrid technology.

8 olving light-emitting devices and solar cell technology.

9 nefit or risk associated with the use of the technology.

10 to look for a more suitable food processing technology.

11 eful gene panel based on whole transcriptome technology.

12 y and 2 inferior PVs ablated using the other technology.

13 ts have been made in the field of biosensing technology.

14 one points coincides with a change in lithic technology.

15 mpatibility complex class I (pMHCI) tetramer technology.

16 ower transformative, energy-efficient memory technology.

17 s on potential risks of this potentially new technology.

18 ed for RT-qPCR test or other early detection technologies.

19 system built on digital data and innovative technologies.

20 materials into sustainable energy and water technologies.

21 dances, challenging the limits of analytical technologies.

22 a way for the commercialization of fuel cell technologies.

23 onential growth in the development of -omics technologies.

24 l detection, high sensitivity, and low-cost) technologies.

25 l for several types of existing and proposed technologies.

26 difficult to observe with common measurement technologies.

27 n neuronal cells using ChIP-seq and ATAC-seq technologies.

28 genetic tools and next-generation sequencing technologies.

29 ight facilitate patient engagement with many technologies.

30 compatible with current rare cell enrichment technologies.

31 , including advanced remediation and sensing technologies.

32 aft materials for renewable and clean energy technologies.

33 in the future translation of genome editing technologies.

34 performance and durability for these energy technologies.

35 from short-read and long-read DNA sequencing technologies.

36 an economic stimulus to capture and storage technologies.

37 nal and systems biology using research-grade technologies.

38 ls will lack the cognitive ability to employ technologies.

39 constituents for the realisation of quantum technologies.

40 tial to make M-N-C catalysts viable in PEMFC technologies.

41 h hinders the continued development of these technologies.

42 rtunities at three scales of resolution: (1) technologies, (2) users and scenarios, and (3) society a

43 Using this technology, 24,752 synapses were fully reconstructed in

44 With the advent of single-cell-based technologies, a new 'worldview' is emerging: the classif

45 New breeding technologies accelerate germplasm improvement and reduce

46 Emerging methods and technologies aimed at tighter regulatory control through

47 New technologies allow high-throughput measurement of the re

48 ed methods for whole-genome-sequencing (WGS) technology allow for the detection of single-nucleotide

49 Thus, no current technology allows fast, sensitive, and in situ detection

50 able between these different electrochemical technologies, although there are also unique complicatio

51 ve been identified using advances in imaging technology, analysis of current research into how these

52 We validate ChromA on multiple technologies and biological systems, including mouse and

53 As technologies and expertise improve, and costs diminish,

54 tution and supports the development of novel technologies and formulations for instant products with

55 n this Perspective, we discuss some of these technologies and how they have (and will) contributed to

56 However, generating the required technologies and infrastructure will drive an increase i

57 Through sanitation technologies and management strategies, resources includ

58 ng will benefit the brain-computer interface technologies and neuroscience studies involving chronic

59 erspective on the future use of live imaging technologies and overcoming their current limitations is

60 ales that capture the grid-scale benefits of technologies and policies that enhance renewable systems

61 w on the market, highlighting the underlying technologies and projecting forward to the future that c

62 eak-even costs are observed across different technologies and scenarios.

63 8 dogs with 2 superior PVs ablated using one technology and 2 inferior PVs ablated using the other te

64 ansfer is an important process in nature and technology and is responsible for the emergence of exoti

65 amics, with potential applications to powder technology and natural flows.

66 Review highlights future directions for mNGS technology and other hypothesis-free testing methodologi

67 ntraoperative guidance, and advanced imaging technology and software have contributed to improvements

68 ome shortcomings in CIs by improving implant technology and surgical techniques, but with limited suc

69 l microbial populations-progress in sampling technology and techniques to enumerate bacterial populat

70 nnovative and proficient acoustic cavitation technology and well characterized using various techniqu

71 erived from digital phenotyping and wearable technologies, and how new discovery may be advanced thro

72 ctronic health record or wearable monitoring technologies, and the optimization of treatment strategi

73 research might benefit from improved imaging technology, and attention to other brain characteristics

74 General Hospital, Massachusetts Institute of Technology, and Harvard University; Cambridge, MA, USA)

75 number of contemporary genetic and molecular technologies applicable to nonconventional organisms hav

76 This technology, applied in the past decade to solve structur

77 -loop and on-demand stimulation, and sensing technologies are expected to enhance the efficacy and to

78 New storage technologies are needed to keep up with the global deman

79 Two key requirements to realize quantum technologies are qubit initialization and read-out.

80 of scaffold-based extracellular matrix (ECM) technologies as alternatives to autogenous soft tissue g

81 ss, and sensitivity, we envision the current technology as a powerful tool for early warning and dete

82 tor" that uses exclusively conventional CMOS technology as well as offering key improvements over pre

83 person care model to real-time, dynamic, and technology-assisted assessments and interventions.

84 plays in its regulation of neuroimplantable technologies based on the above parameters.

85 Pacific Biosciences (PacBio) HiFi sequencing technology bridges this divide by delivering long reads

86 otentially allow a multiplexed "QCR-on-chip" technology, bringing a paradigm shift in speed, accessib

87 ightning Network is a so-called second-layer technology built on top of the Bitcoin blockchain to pro

88 BPSs are a labor and cost-efficient technology but are still mainly operated as black box sy

89 o allows for future sequencing and synthesis technologies, by changing the parameters of the encoder/

90 ntimicrobial applications, a new sustainable technology, called electrodialysis with ultrafiltration

91 based on Optical coherence tomography (OCT) technology, called OCT angiography (OCTA), capable of vi

92 High-throughput phenotyping (HTP) technologies can produce data on thousands of phenotypes

93 While conventional silicon-based technology can be used in this context, the resulting ne

94 Current sRNA-Seq technology can determine the sRNAs present in any symbio

95 MR technology can enhance surgical planning, improve visual

96 Overall, our technology can greatly facilitate rapid, sensitive, and

97 sequence and expression vector, this simple technology can likely be used with many model organisms.

98 In that regard, wearable biosensing technologies, capable of tracking drug pharmacokinetics

99 science, Hong Kong University of Science and Technology, Clear Water Bay, Kowloon, Hong Kong, China".

100 ned, spanning from high-throughput, printing-technology-compatible synthesis of nanocrystalline parti

101 e European-funded Cooperation in Science and Technology (COST) Actions that can help facilitate inter

102 This work evaluates the emission pricing and technology costs required to convert an existing NGCC po

103 sumption problem, new building materials and technologies could provide a safe strategy for geoengine

104 Many such technologies could use in vivo paternal haploid inductio

105 Digital health technology could enable patient-reported outcomes to inf

106 estication processes, together with emerging technologies, could be exploited to improve modern crop

107 a-cell lines, and advances in genome-editing technologies coupled with improved protocols differentia

108 detect the influence of different processing technologies, data fusion and PARADISe presented advanta

109 were uploaded to the Intelligence in Medical Technologies database directly from the carotid ultrasou

110 Independent analyses across technologies demonstrated that nuclear factor kappa B (N

111 Recent technology development has paved the way to the construc

112 he large data availability and unprecedented technology developments.

113 A variety of wearable technology devices report heart rate.

114 The rapid adoption of LEPA technologies did not slow pumping, but it reduced energy

115 th PPRD, which were generated by CRISPR-Cas9 technology displayed low level of expression of mutant C

116 Among all imaging modalities, retromode technology DR and DL may be a potential supplementary mo

117 In technology, droplets on solid surfaces are of widespread

118 trate what can be learned with this emerging technology during preclinical and especially clinical st

119 tion, sensing, simulation, and communication technologies, e.g., as robust sources of indistinguishab

120 Currently available label-free technologies, e.g., thermal shift assays, circular dichr

121 Specifically, technology ease of use must improve and support multipar

122 arcoding via a multi-modal cellular indexing technology, ECCITE-seq, our approach allows a combined a

123 The current state-of-the-art technology employed to assess anti-human leukocyte antig

124 Our microfluidic technology enabled highly reproducible production of mul

125 Later, the spread of genetic engineering technology enabled investigators to develop models of fa

126 er recovery, and productivity across the two technologies-energy consumption is appropriately compare

127 contribute to gender imbalances in science, technology, engineering and mathematics (STEM) fields, a

128 fy problematic areas throughout the Science, Technology, Engineering and Mathematics (STEM) pipeline

129 Current technologies focus on pathogen identification that lack

130 advantages for improving current gene-drive technologies for field population modification.

131 High-throughput technologies for genomics, transcriptomics, proteomics,

132 w has the potential to act as a new enabling technology for asymmetric synthesis to replace some aspe

133 be instrumental for translation of organoid technology for clinical applications as well as for dise

134 Ribosome profiling (Ribo-seq) is a powerful technology for globally monitoring RNA translation; rang

135 agnetic sorting of untagged CTCs, provides a technology for noninvasive isolation of cancer cells in

136 ill be detrimental to the deployment of this technology for population modification strategies.

137 This paper introduces novel ultrasonic technology for precision, real-time, non-destructive mon

138 ATAC-seq has become a leading technology for probing the chromatin landscape of single

139 (IRE) is a promising new nonthermal ablation technology for pulmonary vein (PV) isolation in patients

140 role as a minimally-invasive, ultra-low-cost technology for reducing and contouring adipose tissue, a

141 Here we detail technology for the generation of 'libraries' of clonogen

142 akes holographic VSP and MR highly promising technology for use in complex craniofacial surgery.

143 bjective has been transformed by advances in technology, foundational genomic resources and analytica

144 ction in price of next-generation sequencing technologies, gene expression profiling using RNA-seq ha

145 Together, these technologies greatly expand our ability to study and und

146 ent progresses of next-generation sequencing technology greatly facilitate the extensive molecular ch

147 microarray and massively parallel sequencing technologies has revealed that genomic disorders and mon

148 3D printing technology has become a mature manufacturing technique,

149 f electrical interconnects, silicon photonic technology has been extensively studied, with various ph

150 , in the context of wastewater sensing, MESe technology has been unable to bridge the gap between the

151 Recent advances in protein profiling technology has facilitated simultaneous measurement of t

152 rapid development of scientific CMOS (sCMOS) technology has greatly advanced optical microscopy for b

153 nt of RNA-guided DNA endonuclease CRISPR-Cas technology has led to radical advances in biology.

154 Improved DNA technology has made it practical to estimate single-nucl

155 th non-health-care consumers, digital health technology has not substantially changed the delivery of

156 Recently, CRISPR-Cas technology has opened a new era of nucleic acid-based mo

157 Technology has revolutionized our ability to track anima

158 cturing, known commonly as 3D printing, this technology has revolutionized the biofabrication landsca

159 Terahertz (THz) technology has witnessed a significant growth in a wide

160 together with the Massachusetts Institute of Technology, has convened to collect data on these events

161 , despite being a more mature electro-driven technology, has yet to be extensively compared to CDI in

162 Imaging technologies have been developed to address these proble

163 Moreover, current technologies have been limited to natural nucleic acids

164 Existing neural interface technologies have been shown to provide high-resolution

165 Genome-scale technologies have enabled mapping of the complex molecul

166 These technologies have enabled previously inaccessible chemic

167 Next-generation sequencing technologies have generated, and continue to produce, an

168 s in soft material synthesis and fabrication technologies have led to the development of integrated s

169 Rapidly developing technologies have recently fueled an exciting era of dis

170 Recent advancements in genetic and proteomic technologies have revealed that more of the genome encod

171 CRISPR/Cas9 technologies have revolutionized our understanding of ge

172 Conventional technologies have several drawbacks (i.e., cross-infecti

173 Single cell transcriptomics technologies have vast potential in advancing our unders

174 Recent advances in technology have made the creation of high quality chromo

175 elative infancy, these developing iPSC-based technologies hold considerable promise to push forward e

176 enarios (which account for policy reform and technology improvements), edible food from the sea could

177 Examples of the use of these technologies in recent neuroscience studies illustrate t

178 In addition, current available imaging technologies in this regard are numerous, and they targe

179 With increased use of robotic technology in colorectal surgery, there is a burden to d

180 pave the way for the deployment of CENH3 HI technology in diverse crops.

181 MPR-IB gene was knocked out using CRISPR-Cas technology in granulosa cells and cultured in vitro with

182 143 biomarkers was measured by using Luminex technology in serum samples from 146 patients with sever

183 Advances in cutting-edge technologies including nanotechnology, microfluidics, el

184 new research needs will be requested by the technology industrial sector.

185 platforms, an overhaul of legacy information-technology infrastructures, modification of laboratory/p

186 Development of specific sensor technologies integrating nanomaterials offers a viable a

187 The technology involves HSPC mobilization and intravenous in

188 One of the most promising technologies is based on the development of surface acou

189 Widespread use of gene therapy technologies is limited in part by the lack of small gen

190 These results indicate that FTIR-based technology is a potential tool to detect the progression

191 The technology is easy to handle, and many chemists have man

192 This technology is extended to microbubble-liposome conjugate

193 ce differences and ensure speech recognition technology is inclusive.

194 engineering and the various omics, organoid technology is making possible studies of human biology t

195 Although this technology is promising, several limitations still exist

196 The technology is scalable, and it allows for beam focusing

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

198 primary obstacle for the development of this technology is the efficient delivery of RNAi effectors i

199 o uptake and compliance involved information technology (IT) logistical reasons, lack of motivation,

200 and industry and, with the advent of quantum technology, it is a crucial challenge to design quantum

201 l antifungal compounds extracted by emerging technologies led to a sustainable alternative to control

202 d accelerometer device (activPAL3 micro; PAL Technologies Ltd., Glasgow, United Kingdom) worn continu

203 Digital health technologies may offer a solution by addressing transpla

204 r interventions (n = 12), health information technologies (n = 11), and health system interventions (

205 In many of these emerging technologies, namely, self-regulated insulin delivery an

206 tunities it offers for, for example, quantum technologies, nanoscale magnetometry, and biosensing.

207 New diagnostic technology, new toric IOLs, updated lens formulas, intra

208 Real-world data obtained by mobile technology offer new insights into AR phenotypes and man

209 Yet the impact of this technology on clinical management and patient outcome re

210 formatics concepts using the Oxford Nanopore Technologies (ONT) sequencing platform.

211 ncing (DRS) using the latest Oxford Nanopore Technology (ONT) with exceptional read length.

212 We find that even across different technology options CLEAR matches the observed (post-dict

213 using reads from either a certain sequencing technology or a small assembly.

214 Eprs globally (Eprs(+/-)) using CRISPR-Cas9 technology or in a Postn-Cre-dependent manner (Eprs(flox

215 owed an outsized impact on costs relative to technology parameters.

216 ng on health care services versus biomedical technologies, phasing out low-value care, using value of

217 This technology platform is broadly applicable to various dis

218 In developing a COVID-19 vaccine, we applied technology previously used for MERS-CoV to produce a pre

219 owever, most of the current 'RNA-sequencing' technologies produce a relatively short read length and

220 New advances in algal and microencapsulation technology provide solutions.

221 30 days postoperatively (PO1MO) using Simoa technology (Quanterix, Lexington, MA).

222 With the advent of genomic technologies, recurrent genomic amplification has been m

223 platforms use fluorescence and luminescence technologies, representing more than 70% of the assays i

224 CRISPR technology seems likely to alleviate this problem.

225 Recent studies combine two novel technologies, single-cell RNA-sequencing and CRISPR-Cas9

226 ng tool "Small Molecule Accurate Recognition Technology" (SMART 2.0) for mixture analysis and subsequ

227 constructed with semiconductor manufacturing technology (SMT)-produced electrodes and a streptavidin

228 echnology thus far, the challenges that this technology still has to overcome before reaching the mar

229 Recent high-dimensional single-cell technologies such as mass cytometry are enabling time se

230 Emerging technologies, such as focused microwave heating of liqui

231 her underlines the need for developing other technologies, such as phage therapy.

232 These data show that by using cutting-edge technology, suction blistering offers several advantages

233 Inactivation curves dependency on heating technology suggests specific effects of microwaves on th

234 e biotechnology quad at Georgia Institute of Technology, synthesized multiplexed primers and probes a

235 can be tackled with the recourse of enabling technologies that are showing great potential in improvi

236 We discuss new technologies that can extend the standard regulatory map

237 Therefore, technologies that can improve the visualization of tumor

238 Genome-scale technologies that resolve transcript subpopulations in t

239 Proteomic technologies that use elemental (heavy metal) reporter i

240 Organ-on-a-Chip, a cutting-edge technology that can emulate the physiological environmen

241 Our software introduces new visualization technology that enables independent layers of interactiv

242 luidic ChIPmentation (mu-CM), a microfluidic technology that enables profiling cell samples that indi

243 trate an orbital angular momentum holography technology that is capable of multiplexing up to 200 ind

244 radiotherapy is a novel and rapidly evolving technology that might enhance the risk-benefit ratio.

245 Here we present a wireless, non-invasive technology that not only offers measurement equivalency

246 lifetime imaging microscopy (FLIM) is a key technology that provides direct insight into cell metabo

247 We also discuss the state-of-the-art technology that's been made taking advantage of electron

248 ently, through the advent of high-throughput technologies, that scientists gained the ability to prof

249 With this technology, the authors isolate and characterize tumor-s

250 espite remarkable progress in DNA sequencing technologies there remains a trade-off between short-rea

251 h the proliferation of high-throughput assay technology, there is an imminent need to study the pre-a

252 cy approaching that of short-read sequencing technologies, these platforms have proven their ability

253 The new multilevel SLIM technology thus enables wider mobility range ultrahigh-r

254 itations, the successes and failures of this technology thus far, the challenges that this technology

255 The potential for next-generation technologies to address the current limitations of syste

256 ramework for the design of new DEL synthesis technologies to enable next-generation drug discovery.

257 ment of controlled-release nanoparticle (NP) technologies to further improve the gene therapy efficac

258 ion of AF drivers holds promise, but current technologies to identify drivers are limited by spatial

259 , public access defibrillation, mobile phone technologies to summon first responders, and an enhanced

260 lication of single-cell and integrated omics technologies to the identification of refractory RA endo

261 emistry has begun its rise as a new enabling technology to add to the ever increasing arsenal of tech

262 Body sensor network is a promising medical technology to address the overwhelming global aging, whi

263 We have now expanded this technology to adeno-associated viral vectors.

264 capsules were effectively applied as a novel technology to adsorb and sequester PFOA contamination in

265 We applied the technology to calcium imaging of entire dendritic spans

266 e DAS technique can be an effective security technology to detect and to identify highly similar acou

267 Specifically, we adapt modern image analysis technology to determine the parcel-specific neurite leng

268 Here, we adapted the 3D-bioprinting technology to develop multiple all-inclusive high throug

269 SPINE is the first technology to enable saturated domain insertion profilin

270 Here, we used this technology to evaluate if M. tuberculosis peptides can a

271 panies proposing to utilize lateral drilling technology to excavate boreholes for SNF disposal in sed

272 precursor complex (GPC) and murine hybridoma technology to generate 25 mouse monoclonal antibodies (M

273 Applying this technology to GPe parvalbumin-expressing neurons in a mo

274 nsive stroke centres) and the development of technology to improve communication across different par

275 lar, has leveraged advances in MI agents and technology to improve the accuracy of tumor detection, i

276 Using a high-throughput technology to interrogate most single transmembrane rece

277 Nurses' enthusiasm for training and technology to prevent drowsy driving suggests high level

278 Here, we investigate the ability of this technology to provide long-term modulation of allergy in

279 talytic CO(2) reduction (ECR) is a promising technology to simultaneously alleviate CO(2) -caused cli

280 We used this technology to study differences between healthy controls

281 We pragmatically applied the technology to the production of human neutralizing antib

282 ve that the deployment of aggressive medical technology to win the "war" against the pandemic may rep

283 material concepts and carbon-derived battery technologies towards commercial implementation.

284 However, many of the technologies utilized to couple these workflows to mass

285 pment of next generation instrumentation and technologies utilizing entangled quantum light.

286 consumers benefit financially from electric technology vehicles (1.7% of drivers).

287 n (GE) profiling of 184 genes using nCounter technology was performed in 110 localized-stage and 556

288 This technology was used to create a group of drugs for the t

289 oss-of-function and gain-of-function genetic technologies, we are able to confirm previously describe

290 Using long-read sequencing technologies, we provide a high-quality genome sequence

291 Using this technology, we identified which chromosome arm harbors t

292 Mobile health technologies (wearable, portable, body-fixed sensors, or

293 to hydrogen and oxygen is a well-established technology, whereas fundamental advances in CO(2) electr

294 The low-cost 'THz Torch' technology, which exploits the thermal infrared spectrum

295 the implementation of policies for renewable technologies, while efficiency improvements are especial

296 Virtual reality is an emerging technology with a limited body of evidence, which is of

297 ars, attempts combining molecular imprinting technology with a variety of visualization and detection

298 induced pluripotent stem cell (hiPSC)-based technology with CRISPR-based genome engineering facilita

299 Combining this technology with mass spectrometry (MS)-based proteomics

300 We validate this technology with the rapid generation of three BCR KI lin