ライフサイエンスコーパス: information storage

1 cal processes, including polymer folding and information storage.

2 ergy-efficient device components for digital information storage.

3 as superior state variables for nonvolatile information storage.

4 ory brain areas that have been recruited for information storage.

5 pplications ranging from security marking to information storage.

6 as plasmon lasers, transistors, sensors and information storage.

7 f an appropriate response requires long-term information storage.

8 tional materials in areas such as energy and information storage.

9 e emergent properties of polymers capable of information storage.

10 ems-level memory consolidation and permanent information storage.

11 of neural connectivity and dendrite-specific information storage.

12 ring of coactive synapses is a mechanism for information storage.

13 erfering with synapse-specific mechanisms of information storage.

14 on is regulated by activity and may underlie information storage.

15 AMPA receptors may serve as a mechanism for information storage.

16 NA translation as necessary for long-lasting information storage.

17 are essential for applications in molecular information storage.

18 synaptic potentiation, a model for neuronal information storage.

19 t was not clear what role they could play in information storage.

20 ptic efficacy that could contribute to brain information storage.

21 o elucidate design issues in molecular-based information storage.

22 r Si(100) provide a benchmark for studies of information storage.

23 ns of magnetic nanocrystals for high-density information storage.

24 , while retaining the capacity for long-term information storage.

25 g a potential structural basis for long-term information storage.

26 act spintronic nanodevices, nanosensors, and information storage.

27 for electrically addressable molecular-based information storage.

28 ese synaptic elements was essential for such information storage.

29 inkers for the purpose of multibit molecular information storage.

30 rientation, landmark recognition, and visual information storage.

31 barrier have emerged as prime candidates for information storage.

32 be central to invertebrate model systems of information storage.

33 ent of appropriate neural circuits and brain information storage.

34 suggests that LTD is involved in associative information storage.

35 ly believed to be the physical substrate for information storage.

36 for the development of neuronal circuits and information storage.

37 c efficacy, both in neuronal development and information storage.

38 e SCSC transformation in display devices and information storage.

39 energy, materials, and space needs of modern information storage.

40 functions, such as molecular recognition and information storage.

41 ed applications in energy-efficient magnetic information storage.

42 the potential use of H(C) OF-101 for optical information storage.

43 istances for applications in next-generation information storage.

44 terogeneity for replication, recognition and information storage.

45 advanced applications in chiral sensing and information storage.

46 plications in nanotechnology, healthcare and information storage.

47 ground states for spin-based operations and information storage.

48 ition and biocatalysis, as well as molecular information storage.

49 h organic molecules support multidimensional information storage.

50 re changes is of technological importance in information storage.

51 nd transport, colloidal molecule design, and information storage.

52 determine whether there are commonalities in information storage across species.

53 information in neural signals via the active information storage (AIS) measure.

54 ealing, as nucleic acids are capable of both information storage and acting as templates that catalys

55 tablish abiotic peptides for next-generation information storage and apply them for the encoding of d

56 ts that RNA was once responsible for genetic information storage and catalysis.

57 sition, which can be harnessed for DNA-based information storage and cell lineage tracing technologie

58 nucleic acids were once responsible for both information storage and chemical catalysis, before the a

59 scaling, are thought to cooperate to promote information storage and circuit refinement.

60 egrees of freedom of electrons for potential information storage and computing technologies.

61 lied field-has potential implications toward information storage and computing, and may also inform t

62 transfer entropy, formal measures related to information storage and flow.

63 Concepts for information storage and logical processing based on magn

64 ctionality will be applicable to schemes for information storage and logical processing, making a sig

65 By contrast, robust information storage and magnetic random-access memories

66 ty that might have an important role in both information storage and metaplasticity.

67 atterns and bio-microarrays for high-density information storage and miniaturized biochips and biosen

68 stems provide a compact platform for quantum information storage and processing by coupling acoustic

69 ic LC defects, their practical potential for information storage and processing has yet to be explore

70 ponents for fuel production, cargo delivery, information storage and processing in living systems.

71 Information storage and processing is carried out at the

72 ctions with intrinsic properties that affect information storage and processing of learned vocalizati

73 Genetic information storage and processing rely on just two poly

74 stration may lead to the realization of both information storage and processing using ferromagnetic m

75 ing energy-efficient and compact devices for information storage and processing(8,9).

76 es of halide perovskites and derivatives for information storage and processing.

77 talytic hairpin assembly, using RNA for both information storage and processing.

78 , and may lead to new approaches for quantum information storage and processing.

79 an be applied as a new degree of freedom for information storage and processing.

80 tates of matter, which enable robust quantum information storage and processing.

81 10 s, which is sufficiently long for quantum information storage and processing.

82 ne for emerging valleytronic applications in information storage and processing.

83 stors provide a power-efficient solution for information storage and processing.

84 c acids display remarkable properties beyond information storage and propagation.

85 s may enable new strategies for high-density information storage and quantum-state control.

86 of general interest for applications such as information storage and radical-initiated polymerization

87 a local protein complex could produce stable information storage and readout.

88 y, precision and efficiency in areas such as information storage and replication, transportation and

89 A sequencing has increased 10,000-fold while information storage and retrieval only 16-fold.

90 g photocopying, recording, or storage in any information storage and retrieval system, without writte

91 ical, including photocopy, recording, or any information storage and retrieval system, without writte

92 ical, including photocopy, recording, or any information storage and retrieval system, without writte

93 model for the development of comprehensive, information storage and retrieval systems for other comp

94 he development of comprehensive, multi-media information storage and retrieval systems for other comp

95 also provide a model for the development of information storage and retrieval systems for other comp

96 ized objects on demand by exploiting digital information storage and retrieval via the Internet.

97 an act as a dynamic readout mechanism during information storage and retrieval.

98 ogen bonding can contribute to every step of information storage and retrieval.

99 erties in solution, making them suitable for information storage and reversible photo-patterning appl

100 e illustrate their promising applications of information storage and security in spatial and temporal

101 color/lifetime has potential applications in information storage and security.

102 des a promising route towards ultralow power information storage and sensor technologies.

103 ge, can be used for the development of novel information storage and signal processing devices with l

104 r molecular recognition, enzymatic function, information storage and structure and is thought to be a

105 ty of engram cells may be crucial for memory information storage and that strengthened synapses in th

106 an important mechanism for the regulation of information storage and the control of actions, as well

107 tional importance of synaptic plasticity for information storage and the development of neuronal conn

108 ong-range magnetic order are synonymous with information storage and the electronics industry, with t

109 tocol may better model behaviorally relevant information storage and the in vivo mechanisms underlyin

110 decisive role in the shaping of hippocampal information storage and the nature of learned experience

111 lications in the fields of pressure sensing, information storage and trademark security.

112 ations in terahertz-frequency plasmonics, in information storage and transport and in the manipulatio

113 ting their potential applications in optical information storage and ultrafast laser-field manipulati

114 future applications in quantum computing and information storage and use as multiferroic materials wi

115 /conversion/storage, environment protection, information storage, and biomedicine.

116 ing, opening new avenues for molecular level information storage, and boosting the emerging field of

117 ection, optical display, optoelectronics for information storage, and cell stimulation.

118 sed materials for on-demand signal transfer, information storage, and cryptography.

119 well-known measures of information transfer, information storage, and dynamical complexity as aggrega

120 hyperfine states are used for robust quantum information storage, and excitation into Rydberg states

121 olecular devices, artificial photosynthesis, information storage, and fuel cells.

122 endent recognition of nucleic acids, genetic information storage, and high fidelity of DNA polymerase

123 nact synaptic plasticity, allowing long-term information storage, and is therefore tightly controlled

124 d applications, including optical computing, information storage, and microanalysis.

125 tical state that optimizes input processing, information storage, and transfer, but the relevance of

126 interest for new magnetoelectric devices and information storage applications.

127 e a viable medium for use in molecular-based information storage applications.

128 s construct a viable candidate for molecular information storage applications.

129 states and are very attractive for molecular information storage applications.

130 e constructs viable candidates for molecular-information-storage applications.

131 e are of interest for use in molecular-based information-storage applications.

132 Previous DNA-based information storage approaches have encoded only trivial

133 ccessful applications of this technology for information storage are reviewed.

134 ins unclear whether the parameters governing information storage are similar between species.

135 strating memory cells with up to 6.5 bits of information storage as well as excellent retention and p

136 ng synaptic plasticity, thereby facilitating information storage associated with different learning e

137 Thus, information storage at the cellular level appears to inv

138 Information storage at the molecular level commonly enta

139 f technologies, such as smart drug delivery, information storage, barcoding, and detection.

140 interest on DNA as an attractive target for information storage because of its capacity for high-den

141 e widely used for applications in photonics, information storage, biology and medical therapeutics.

142 ould be advantageous in applications such as information storage, but these properties are usually co

143 ransition included the 'genetic takeover' of information storage by DNA.

144 ng hierarchical neural networks.High-density information storage calls for the development of modern

145 00), which exhibit redox behavior useful for information storage, can meet this challenge.

146 the possibility of up to eight base pairs of information storage capability.

147 temporal response and provide materials with information storage capability.

148 sing and engineering applications due to its information storage capacity and ability to drive gene e

149 hat silent synapses are required to maximize information storage capacity and ensure its reliability,

150 or silent synapses, our results suggest that information storage capacity and reliability are optimiz

151 pses may have roles other than adjusting the information storage capacity and reliability.

152 Our approach is based on maximizing information storage capacity of neural tissue under reso

153 are essential regulators of the function and information storage capacity of neurons.

154 nments are crucially important in energy and information storage, catalysis and sensors.

155 rors within the molecules, making error-free information storage challenging.

156 t concept in the development of high-density information storage, computing and reconfigurable system

157 s their nanoscale dimensions may enable high information storage density and their low threshold for

158 le magnets (SMMs) hold promise for unmatched information storage density as well as for applications

159 rectional switching is possible, yielding an information storage density of 4.9 x 10(13) bit/inch(2).

160 ith ultrashort laser pulses is promising for information storage device applications.

161 we propose and simulate the operation of an information storage device that can operate as an energy

162 ests that the superior IPS may be a flexible information storage device, consistent with the involvem

163 ion and oxidation processes, electrochemical information storage devices can be designed.

164 Our prior designs for molecular-based information storage devices have employed multiple redox

165 omises for high-density and energy-efficient information storage devices owing to their small size an

166 promising for building quantum computing and information storage devices, as they are insensitive to

167 ers are a promising paradigm for sensors and information storage devices, where strain manipulates th

168 tep towards integrated classical and quantum information storage devices.

169 r the design of a variety of molecular-based information storage devices.

170 rtant for the fabrication of molecular-based information-storage devices.

171 ics is instrumental to their applications in information-storage devices.

172 g avenues for optical materials engineering, information storage, display, and encryption, as well as

173 irhinal cortex) plays a time-limited role in information storage, eight rhesus monkeys were trained t

174 the utilisation of silicon nanowires as the information storage element in flash-type memory devices

175 al motif is of limited utility for molecular information storage elements.

176 A molecular approach to information storage employs redox-active molecules tethe

177 red materials with potential applications in information storage/encryption, surface functionalizatio

178 ds and have potential applications including information storage, energy transduction, ultralow-power

179 mpensatory adaptations coexist with synaptic information storage, especially in established networks.

180 Biological information storage events are often rapid transitions b

181 ating that reciprocity can be facilitated by information storage external to the brain.

182 The achieved fidelities show improved information storage for a large, noncommutative set of e

183 regions are activated for different kinds of information: storage for verbal materials activates Broc

184 to be important in working memory and other information storage functions.

185 The quest for higher density information storage has led to the investigation of Sing

186 tion of magnetic tunnel junctions (MTJs) for information storage has so far been limited by the compl

187 Mechanisms underlying information storage have been depicted for global cell-w

188 Most studies of information storage have focused on mechanisms such as l

189 Nanoscale lithography and information storage in biocompatible materials offer pos

190 ism supports highly tuned and differentiated information storage in CA3 synapses.

191 showing that shape is a locus of retrievable information storage in cells.

192 te the mechanisms and limitations of dynamic information storage in cells.

193 e possibility of using molecules for ternary information storage in direct analogy to current binary

194 A relatively unexplored avenue of information storage in DNA is the ability to write infor

195 t efforts have illustrated the potential for information storage in DNA using synthesized oligonucleo

196 tion-theoretic approaches to advance digital information storage in DNA.

197 C synapse is considered to be a mechanism of information storage in motor learning.

198 neurons, our results suggest that long-term information storage in neural tissue could reside primar

199 ent of the cellular machinery that underlies information storage in pyramidal neurons of the hippocam

200 LTD thus provides a cellular mechanism for information storage in some forms of learning.

201 o later stages of visual processing, such as information storage in superior IPS, and may explain why

202 ore RAD memory element is capable of passive information storage in the absence of heterologous gene

203 potentiation, unveiling mechanisms hindering information storage in the aged brain and identifying KC

204 ngth, the most established cellular model of information storage in the brain, is expressed by an inc

205 circuits and may form an enduring basis for information storage in the brain.

206 nd function is of fundamental importance for information storage in the brain.

207 ears important computational consequences on information storage in the brain.

208 ngth are the proposed cellular correlate for information storage in the brain.

209 ty and plastic morphology, which may mediate information storage in the brain.

210 apse-specific modifications during long-term information storage in the brain.

211 y synapses and may represent a substrate for information storage in the brain.

212 sion (LTD), are thought to be mechanisms for information storage in the brain.

213 es at the heart of psychological theories of information storage in the brain.

214 of synaptic efficacy that may contribute to information storage in the CA1 region of the hippocampus

215 Although information storage in the central nervous system is tho

216 Serious consideration of LTP as underlying information storage in the intact brain, however, requir

217 c efficacy, are believed to be essential for information storage in the nervous system.

218 h deeper potential wells lead to more robust information storage in the presence of noise.

219 that may serve as the cellular mechanisms of information storage in the vertebrate brain.

220 pulation could be employed to achieve mobile information storage in these metamaterials.

221 in synthesis, anisomycin, into M1 to disrupt information storage in this area.

222 may provide a structural basis for lifelong information storage, in addition to their well-establish

223 enia, however complex interactions among the information storage, information processing and attentio

224 DNA origami information storage is a promising alternative to silico

225 rapolating these data to humans assumes that information storage is comparable across species and is

226 High-speed and multilevel magnetic information storage is further demonstrated.

227 surrounding tissue, the stratum corneum; and information storage is possible in both.

228 aptic weight distribution, but its impact on information storage is unknown.

229 d reactivity, with applications ranging from information storage materials to understanding catalytic

230 studied extensively as a lifelong molecular information storage mechanism put in place during develo

231 alculus that explains phenomenologically the information storage mechanism.

232 eature detectors and potentially as powerful information storage mechanisms.

233 t, given its potential impact as lightweight information storage media.

234 DNA has been the predominant information storage medium for biology and holds great p

235 of bonding that allows it to be the primary information storage medium for life has also allowed it

236 The potential of DNA as an information storage medium is rapidly growing due to adv

237 RNA, DNA can serve as both a catalyst and an information storage medium.

238 utional dynamic systems capable of acting as information storage molecular devices, in which the pres

239 DNA serves as nature's information storage molecule, and has been the primary f

240 of homogeneous DNA from RNA as the principal information-storage molecule, but requires a selective a

241 ls; as optical limiters; in nanoelectronics, information storage, nanopatterning and sensing; as macr

242 ra-compact meta-transformer has potential in information storage, nanophotonics, optical integration

243 osphor has promising applications in optical information storage, night-vision surveillance, and in v

244 or tripodal) for studies of molecular-based information storage on oxide surfaces.

245 on nanoparticles have a limited capacity for information storage or complexity to prevent counterfeit

246 which the magnetic state is used either for information storage or logic operations.

247 Stable information storage over long periods of time is more ch

248 rapidly emerging as a durable, high-density information storage platform.

249 oposed as elementary binary units (bits) for information storage, potentially enabling fast and effic

250 mediate chemical transformations and energy/information storage processes required to sustain life.

251 Many energy- and information-storage processes rely on phase changes of n

252 for developing tunable devices for magnetic information storage, processing and microwave communicat

253 teric bulk of nonlinking substituents on the information-storage properties of the porphyrin monolaye

254 esting possible applications in high-density information storage, quantum computing and spintronics.

255 The system thus performs information storage, recall, and erase processes.

256 ng provides essential foundation for genetic information storage, replication, transcription and tran

257 Cortical information storage requires combined changes in connect

258 Long-term information storage requires synaptic plasticity and reg

259 it exchange in CaMKII may have relevance for information storage resulting from brief coincident stim

260 capability enables new routes for non-binary information storage, retrieval, and intrinsic encryption

261 an that for PSD-95 and is consistent with an information storage role for CaMKII.

262 molecules that can be employed in molecular information-storage schemes and (2) writing/reading rate

263 atum can transcend their attributed roles in information storage.SIGNIFICANCE STATEMENT The current p

264 ing so, we push the technical limits of this information storage system and optimize strategies to mi

265 tions regarding the functions of the genetic information storage systems and thus of the origin and e

266 The physical architectures of information storage systems often dictate how informatio

267 is a compelling alternative to non-volatile information storage technologies due to its information

268 tructures holds promise for ultra-low energy information storage technologies.

269 s offering great promise for next-generation information storage technologies.

270 In principle, low-power and high-density information storage that combines fast electrical writin

271 ion' represents a previously unknown form of information storage that is distinct from that produced

272 pression (LTD) is a model system of neuronal information storage that is expressed postsynaptically a

273 Using a standardized exchangeable information storage, the J-CKD-DB succeeded to efficient

274 that neural synapses are elemental sites of information storage, there has been no direct evidence t

275 If these changes support long-term information storage, they might be expected to be presen

276 in a process of learning and memory--such as information storage--through the information-specific co

277 lecules have been expanded from pure genetic information storage to catalytic functions like those of

278 s of important stimuli, which may facilitate information storage to guide behavior.

279 nologies ranging from telecommunications and information storage to medical diagnostics and therapeut

280 he intended use of a magnetic material, from information storage to power conversion, depends crucial

281 it is possible to push nonvolatile magnetic information storage to the atomically thin limit.

282 investigation of the microscale world, from information storage to the monitoring of dynamic biochem

283 Workflow Information Storage Toolkit (WIST) is a set of applicati

284 technological implications for high-density information storage, ultrafast spintronics, and effectiv

285 and is both necessary and sufficient for the information storage underlying the type of memory mediat

286 gnalling networks to enzymatic catalysis and information storage, using a notably limited set of chem

287 As part of a program in molecular-based information storage, we have developed routes for the sy

288 ontal cortex synapses, an important relay in information storage, we used a newly developed frontal s

289 ritical (segregated) regime are dominated by information storage, whereas the supercritical (integrat

290 rst two modes encode early and late forms of information storage, whereas the third mode encodes resp

291 r biomimetics, self-assembly, catalysis, and information storage, wherein the primary structure beget

292 attractive alternative for dense and durable information storage, which is sorely needed to deal with

293 We anticipate that mechanical information storage will be broadly useful in studying t

294 utilizing (mixtures of) small molecules for information storage will be discussed.

295 new opportunities for chiral resolution and information storage with CPL.

296 s a unique opportunity for ultrahigh density information storage with high speed.

297 ain (ss-dsDNA), can unlock dynamic DNA-based information storage with powerful capabilities and advan

298 s-dsDNA architecture lays the foundation for information storage with versatile capabilities.

299 l for the cellular process that may underlie information storage within neural systems.

300 Long-term information storage within the brain requires the synthe