ライフサイエンスコーパス: technological

1 Much research has debated the technological abilities of Neanderthals relative to thos

2 ons, the authors suggest many uniquely human technological abilities.

3 e label of packed foods of any ingredient or technological adjuvant causing allergies is required by

4 ges in management based on the most relevant technological advance in the past decade, the standardis

5 A recent technological advance that shows promise for application

6 polarity electric signals has hampered this technological advance.

7 However, additional technological advancement requires providing this materi

8 ontinues to influence the next generation of technological advancement, using the properties of molec

9 ety of chemical issues coped with and in the technological advancements and implementations.

10 Recent technological advancements have enabled the profiling of

11 Time-to-time technological advancements have heavily revolutionized t

12 ytotoxicity independent of p53 status, major technological advancements in gene sequencing capability

13 Recent technological advancements in sequencing and metabolomic

14 nd Sarah Teichmann review the last decade of technological advancements in single-cell transcriptomic

15 One of the key technological advancements is the use of a functionalize

16 Technological advancements made in the last decade offer

17 Recent technological advancements that allow molecular investig

18 In this review, we survey key technological advancements that support quantitative ass

19 ding all of its aspects requires substantial technological advancements.

20 itative technique, particularly with current technological advancements.

21 if far-reaching lifestyle changes complement technological advancements.

22 tive and allows us to predict the next major technological advances and hurdles in the field.

23 In this Perspective, we outline technological advances and model systems to characterize

24 to accelerate progress in the field through technological advances and the development of drug deliv

25 lution of opioid research and emphasizes how technological advances are facilitating research toward

26 These recent technological advances are improving the scale and resol

27 These technological advances drive and are driven by accompany

28 The experimental and technological advances during this time have been rapid,

29 lly observed decades ago, only recently have technological advances enabled the field to begin elucid

30 Finally, future directions and enabling technological advances for the field are discussed.

31 Technological advances have accelerated the identificati

32 Technological advances have allowed researchers to profi

33 sioned for decades, however only with recent technological advances have devices been suitable for tr

34 Recent technological advances have enabled highly detailed anal

35 Technological advances have enabled the analysis of whol

36 Technological advances have enabled the identification o

37 Technological advances have enabled the profiling of mul

38 Recent technological advances have enabled valuable insights, e

39 Rapid scientific and technological advances have enabled widespread genotypin

40 While recent technological advances have facilitated analysis of the

41 Recent technological advances have introduced diverse engineere

42 While technological advances have made it possible to profile

43 Technological advances have opened a new era of precisio

44 Technological advances have provided insight into GPCR b

45 Technological advances have provided new insights into t

46 A number of technological advances have recently opened the door to

47 While technological advances in automating data collection and

48 Technological advances in characterizing molecular heter

49 Technological advances in computing have led to the intr

50 review is to present the key scientific and technological advances in electrochemical glucose biosen

51 may have a profound impact on transformative technological advances in fields including spin-Hall pho

52 This resurgence is primarily driven by technological advances in genetic engineering and metabo

53 Technological advances in high-resolution mass spectrome

54 ave been gained by the application of recent technological advances in imaging in both real-time and

55 In the current study, we leveraged recent technological advances in molecular biology and herein r

56 This Perspective summarizes recent technological advances in QSAR modeling but it also high

57 re and sequestration (CCS) will require both technological advances in the capture technology, cost r

58 Technological advances in this domain are providing incr

59 lococcus aureus has been greatly enhanced by technological advances in transposon (Tn) mutagenesis.

60 Due in part to technological advances including social media, experimen

61 Technological advances made over the past decade have en

62 hallenges in the field, and how cutting-edge technological advances might help to overcome these.

63 Technological advances now enable large-scale datasets,

64 e on context-specific PI3K signaling and how technological advances now make it possible to move from

65 The technological advances of cutting-edge high-resolution m

66 Emerging technological advances present an opportunity to provide

67 These groundbreaking technological advances promise to revolutionize genetic

68 Nevertheless, recent technological advances provide us potential solutions to

69 or large patient cohorts generated by recent technological advances provides an opportunity to dissec

70 Technological advances such as high-resolution mass spec

71 chnical improvements in ultrasound scanners, technological advances such as ultrasound contrast agent

72 we discuss design considerations and recent technological advances to modulate electrical signaling

73 However, despite recent technological advances, achieving efficient oligonucleot

74 ral insulin delivery, summarizes significant technological advances, and outlines future perspectives

75 Our technological advances, combined with further approaches

76 Recent technological advances, including serology, transcriptom

77 Technological advances, including single-cell and other

78 Propelled by a set of recent technological advances, new insights into the molecular

79 However, in recent years, with the rise of technological advances, not only is the existing dogma b

80 hat are now enabled by recent scientific and technological advances.

81 ered materials can accelerate scientific and technological advances.

82 n a prerequisite for critical scientific and technological advances.

83 anticipated following recent scientific and technological advances.

84 ated with the promise of achieving important technological advances; from efficient, high-performance

85 We discuss how our findings may lead to technological and fundamental science applications of dy

86 henomena of bioinspired materials in diverse technological and fundamental scientific fields and prov

87 Technological and logistical challenges, however, have l

88 Technological and managerial solutions-such as active de

89 uclei such as the periaqueductal gray due to technological and methodological limitations.

90 Advanced technological and methodological tools provided novel in

91 re variation, a fascinating property of high technological and scientific relevance.

92 ntable diseases have been spawned by several technological and social factors, including the erosion

93 ly find novel materials, which can have huge technological and social impact.

94 concentrations of phenolic metabolites), and technological and structural properties of these EGs wer

95 Recent technological and treatment advances have provided insig

96 ital role in a broad range of environmental, technological, and physiological processes, making their

97 re to external stimuli, yielding interesting technological applicability.

98 se unique nanostructures and their potential technological applications are discussed.

99 We first outline how these technological applications are permitting researchers to

100 These findings are relevant for (bio)-technological applications involving electric fields pro

101 ystalline nanostructured materials and their technological applications is provided.

102 fast actuation, expanding the repertoire of technological applications of microcombs.

103 apsulating other 2D crystals in a variety of technological applications, from optoelectronic and tunn

104 materials science for various biomedical and technological applications, including opto-bioelectronic

105 ision and accuracy, with many scientific and technological applications, including precision tests of

106 s with impacts ranging from basic science to technological applications.

107 after for fundamental scientific studies and technological applications.

108 es that could find use in a wide spectrum of technological applications.

109 infection, could have important medical and technological applications.

110 s of the materials, which have wide reaching technological applications.

111 donor-acceptor structures are attractive for technological applications.

112 treme oxygen sensitivity limits their use in technological applications.

113 llic compounds) are key components of modern technological applications.

114 ems and present opportunities for innovative technological applications.

115 materials for both fundamental research and technological applications.

116 mbination that is favorable for a variety of technological applications.

117 critical to a wide range of geochemical and technological applications.

118 osites in nature and widely used in arts and technological applications.

119 tion is important both fundamentally and for technological applications.

120 heir therapeutic effects and their potential technological applications.

121 thus have multiple scientific, medical, and technological applications.

122 the importance of this catalytic process for technological applications.

123 ble phase transformations in the oxide-based technological applications.

124 physical properties with great potential for technological applications.

125 ch renders this method highly attractive for technological applications.

126 ion CO(2) capture and storage (CCS) is a key technological approach to reducing greenhouse gas emissi

127 Research and development enabling new technological approaches and more effective management s

128 Here, we argue that technological approaches offer potential solutions, but

129 We also highlight the emerging technological approaches to enhance the locomotion of mi

130 AR-T cell therapy and describe the different technological approaches, mainly based on gene editing,

131 critical in a broad range of biomedical and technological areas.

132 With this in mind, we discuss here the technological basis and rare disease applicability of th

133 We review the technological basis and the clinical development of tota

134 To overcome these current technological bottle-necks, herein we present, for the f

135 r-residue distance information or the latest technological breakthrough in deep learning that has rec

136 mphasis on innovation and development, major technological breakthroughs have been achieved in this a

137 Here, we review recent major technological breakthroughs made with these two approach

138 nt biosensors that have led to scientific or technological breakthroughs.

139 challenges and speculate about how emerging technological capabilities may enable the discovery and

140 iamagnetism, this work opens the door to new technological capabilities such as stable electrostatic

141 A major technological challenge in materials research is the lar

142 s (CDs) have been widely used to solve these technological challenges.

143 rties and were evaluated for nutritional and technological characteristics.

144 irst quintile of its habitable window, but a technological civilization did not blossom until its las

145 ief tour of several important scientific and technological concepts, from the open-source paradigm to

146 eur, Napoletana and Sirora), under different technological conditions (temperature, roasting, use of

147 unt for ecological, economic, regulatory and technological constraints.

148 ral biotic and abiotic processes and in many technological contexts.

149 relation between the evolution of cumulative technological culture (CTC) and the evolution of reasoni

150 The debate on cumulative technological culture (CTC) is dominated by social-learn

151 skills in the emergence of human cumulative technological culture (CTC), in contrast to previous acc

152 her than imitation as the key for cumulative technological culture (CTC), Osiurak and Reynaud argue t

153 methodological choice to examine cumulative technological culture (CTC).

154 fore, appear to be the product of cumulative technological culture (CTC).

155 te - three processes essential to cumulative technological culture (CTC).

156 nological reasoning is crucial to cumulative technological culture but it fails to discuss the implic

157 This commentary draws connections between technological culture emergence and recent trends in usi

158 al skills; and (3) a model of how cumulative technological culture evolves.

159 that research into the origin of cumulative technological culture has been too focused on social cog

160 Osiurak and Reynaud argue that cumulative technological culture is made possible by a "non-social

161 The argument that cumulative technological culture originates in technical-reasoning

162 with a reading of the history of cumulative technological culture that is based largely on modern ex

163 We agree that the emergence of cumulative technological culture was tied to nonsocial cognitive sk

164 of non-social cognition in human cumulative technological culture, truly neglected in comparison wit

165 ly non-primate species exhibiting cumulative technological culture.

166 ght a major omission of models of cumulative technological culture.

167 sus cognitive niche hypothesis of cumulative technological culture.

168 ighlight areas where continued discovery and technological development can further advance these revo

169 a from multi-omic platforms coupled to rapid technological development could lead to new diagnostic,

170 compliance monitoring, further research and technological development is needed to improve represent

171 These results show further technological development must occur in parallel with em

172 expected to contribute to new materials and technological development.

173 imaging in living subjects, highlighting key technological developments and their emerging applicatio

174 Recent technological developments have enabled to use of smartp

175 Recent technological developments in mitochondrial imaging have

176 Recent technological developments in mobile brain and body imag

177 Technological developments in the emerging field of spat

178 We further discuss new technological developments to study, diagnose, and quant

179 Yet these technological developments urgently require analysis of

180 e an integral part of the next generation of technological developments-allowing us to gain new insig

181 m the computational skills to keep pace with technological developments.

182 In conclusion, besides the technological differences, the storage was able to preve

183 s, inheritance rules, marriage practices and technological diffusion.

184 Together, our analysis highlights technological divergences between two reproducible somat

185 haride composition, its cytotoxicity and the technological effect as a stabilizer in ice cream.

186 d diploid species and provides insights into technological evolution in resolving complex genomes.

187 ntinuous time random walk, which depicts the technological evolution of human kind, in conjunction wi

188 dvent of metal processing was one of the key technological evolutions presaging the development of mo

189 creage in the Corn Belt (as determined using technological extrapolation domains).

190 potential for innovation in the most diverse technological fields, including organic fine chemistry,

191 modalities that spans several scientific and technological fields.

192 lets have become core to many scientific and technological fields.

193 used as a source of mucilages with different technological functions that can be widely explored.

194 n (SSC) in channels/rivers include costs and technological gaps but this paper shows that a solution

195 agnetism with electric fields-a longstanding technological goal in spintronics and multiferroics(1,2)

196 s in affluent countries are still plagued by technological hurdles and limited market potential.

197 Technological impact is expected in the tissue engineeri

198 LnSNCs is unfortunate, given the tremendous technological impact that these nanomaterials could have

199 ic, optoelectronic, and quantum devices, but technological implementation will be hampered by the lac

200 conditioning regimens seems dependent on its technological implementation, aiming to make the whole p

201 ically protected spin textures with profound technological implications for high-density information

202 ith high thermal conductivity (kappa) are of technological importance and fundamental interest.

203 extensive research due to its scientific and technological importance as a common industrial practice

204 con, phosphorus, and sulfur is of particular technological importance because they represent some of

205 nd actinides are elements of ever-increasing technological importance in the modern world.

206 Specific technological improvements for future prototype developm

207 Here, we review key technological improvements that have established AFM as

208 ring the last three decades, a series of key technological improvements turned atomic force microscop

209 ent a website centralizing quail genomic and technological information to facilitate the design of ge

210 amines, sulfur dioxide and proteins used as technological ingredients such as fining material.

211 The next decade is critical for technological innovation and deployment to meet mid-cent

212 ll depend on factors such as policy reforms, technological innovation and the extent of future shifts

213 on with an extremely high inductance-the key technological innovation in our experiment-and measure t

214 The technological innovation of Islamic glassmaking in Spain

215 ove cultural development, including maritime technological innovation, and from ca. 6400-5900 BP, und

216 ving the focus from cultural transmission to technological innovation, falls flat through a lack of t

217 hich could also be extended to the domain of technological innovation-offering insights from a compar

218 to be confirmed experimentally, and further technological innovations are needed to reduce capital a

219 al-time environments and may lead the way to technological innovations for time-critical video analys

220 d rapidly in the past decade, largely due to technological innovations in cryoelectron microscopy.

221 We envision that continuing materials and technological innovations through interdisciplinary coll

222 past decade have led to major scientific and technological innovations towards tight monitoring of di

223 differences in pollution output that reflect technological innovations, market demands, or demise of

224 It is also of great technological interest due to DNA's ability to form vers

225 pigments have various properties that are of technological interest including photo- and radiation pr

226 ning materials are of fundamental as well as technological interest.

227 and implementation of practical training and technological interventions for drowsy driving in nurses

228 rtain but enthusiastic about educational and technological interventions preferring practical trainin

229 riving, countermeasures, and educational and technological interventions.

230 Nowadays, this is becoming an important technological issue, which may result in the reduction o

231 While this likely reflects both technological limitations as well as the fact that well-

232 dictates species response to climate change, technological limitations have obfuscated explicit tests

233 he overall abundance of AR genes in the gut, technological limitations of short-read sequencing have

234 species but have gone undetected because of technological limitations, research biases, and logistic

235 g, in part, due to plasticity, entropic, and technological limitations.

236 ood feeding remains poorly understood due to technological limitations.

237 st be taught proficiencies in scientific and technological literacy, the importance of the scientific

238 ement, and, preferences and expectations for technological mitigations.

239 herapeutic protein products remains an unmet technological need.

240 delivery to other tissues represents a major technological need.

241 that large natural, biological, social, and technological networks are fragile, convincing theories

242 ier in social networks than in biological or technological networks.

243 d gastrointestinal conditions), and improved technological (no moisture loss, lower proteolysis and o

244 modal radiographic imaging of biological and technological objects in a single laser shot.

245 ity of additively manufactured parts are key technological obstacles for the widespread adoption of a

246 colloidal quantum dots (CQDs) faces several technological obstacles, as conventional lithographic an

247 ing two-dimensional (2D) materials offer new technological opportunities beyond the modern III-V plat

248 sity or spin transition offers unprecedented technological opportunities for their integration into f

249 These findings may afford new scientific and technological opportunities not only for adaptive optics

250 ove antioxidant quality without reducing the technological or sensorial properties.

251 he proof-of-concept system provides a unique technological pathway for CO(2) capture and conversion f

252 Data integration using multiple technological platforms will lead to a better understand

253 From a technological point of view, the response of inductive m

254 anging capabilities of cephalopods and their technological potential as biophotonic and bioelectronic

255 harvesting, which showcase the unprecedented technological potential enabled by hydrogels and hydroge

256 rengths and weaknesses as well as the future technological potential of each imaging modality.

257 n is also presented, demonstrating its great technological potentiality.

258 ssary to improve consumer acceptance through technological processes prior to marketing.

259 Biological and technological processes that involve liquids under negat

260 lates studied in this paper, translated into technological products, could help develop standardised

261 new insights into the spread of information, technological progress and economic development.

262 Here we first review how recent technological progress has opened up this field, providi

263 s of energy per unit of land area, and rapid technological progress in competing technologies, land i

264 impetuous growth in recent years, due to the technological progress in the generation of ultrashort l

265 cover the basic biological processes driving technological progress.

266 rm increases in step with the rapid march of technological progress.

267 its influence on nutritional composition and technological properties (emulsion stability, pH, water

268 The physicochemical, structural and technological properties of mucilages extracted from sev

269 ol strain to investigate the nutritional and technological properties of the isolated strains.

270 e addition exerted significant effect in the technological properties only in the brown rice cake, re

271 tion changes sensorial, nutritional and also technological properties, such as dough or batter hydrat

272 fiber) and with some modifications in their technological properties.

273 The addition of DFC did not affect the technological quality of cookies, with the exception of

274 However, fiber can affect the technological quality of pasta if not properly distribut

275 Unanswered scientific/technological questions are identified, emerging researc

276 ource consumption rates and best estimate of technological rate growth our study shows that we have v

277 target article reviews evidence showing that technological reasoning is crucial to cumulative technol

278 We argue that Osirak's and Reynaud's technological-reasoning hypothesis raises conceptual and

279 functions in all biological domains, but for technological reasons their large-scale investigation ha

280 he opportunities and threats associated with technological, regulatory and social change.

281 Yet, charge disproportionation lacks technological relevance because it occurs only under spe

282 trypanolysis test, but biosafety issues and technological requirements prevent its large-scale use.

283 By the technological reserve hypothesis, social-motivational an

284 nthesis of more complex MNCs have been major technological roadblocks in the pathway for clinical tra

285 aterials, with a keen eye on the foreseeable technological scenarios where they are poised to become

286 fueled by coevolution studies and orthogonal technological screening platforms.

287 erformance of organic matter in cutting edge technological sectors, such as solar energy conversion.

288 Archaeological research documents major technological shifts among people who have lived in the

289 emistry of silicon, highlighting subjects of technological significance such as the production of sil

290 sing attention because of its scientific and technological significance.

291 o achieve many different goals demonstrating technological skills and reasoning contradicting the aut

292 quires the rapid evolution of a multitude of technological, social, political and economic factors.

293 In contrast, we project that purely technological solutions are unlikely to fully address th

294 The presented technological strategies for formulating nature-identica

295 albedo, therefore, has been considered as a technological strategy to mitigate global warming.

296 s been facilitated by recent advances in the technological toolbox and perturbative techniques, as we

297 systems could no longer sustain the desired technological trajectory.

298 However, fundamental discoveries and technological translations of chiral nanoceramics have r

299 ced by softening and have the advantage of a technological valorisation for the processing industry.

300 ing modes of activation, particularly from a technological viewpoint.