ライフサイエンスコーパス: information processing

1 ant for developing new approaches to quantum information processing.

2 lated to encryption, optical patterning, and information processing.

3 ight into the precise nature of hierarchical information processing.

4 ultiple disorders with impairments in social information processing.

5 e of choice for quantum-state generation and information processing.

6 applications in opto-spintronics and quantum information processing.

7 ritical for supporting synaptic function and information processing.

8 quantum protocols such as communication and information processing.

9 ellular metabolism, structural dynamics, and information processing.

10 nals that the nervous system can exploit for information processing.

11 tal elements for microwave communication and information processing.

12 dying large-scale spatiotemporal dynamics of information processing.

13 a patterning and plasticity prior to sensory information processing.

14 dual neurons that are the hallmark of neural information processing.

15 anging from optical communication to quantum information processing.

16 ts for quantum many-body physics and quantum information processing.

17 hment in circuits that participate in social information processing.

18 nd are often considered too slow for quantum information processing.

19 CNS to perform complex but circuit-specific information processing.

20 bits form an essential ingredient of quantum information processing.

21 larization of carriers enables a new DOF for information processing.

22 putational model for memory from the view of information processing.

23 of impulse is central to cerebellar cortical information processing.

24 with postoperative global and local parallel information processing.

25 ribute to synapse-specific and circuit-level information processing.

26 doping in ultrascaled transistors to quantum information processing.

27 ntial to enable practical and robust quantum information processing.

28 erging 2D materials in classical and quantum information processing.

29 required for large-scale trapped-ion quantum information processing.

30 mportant step towards fault-tolerant quantum information processing.

31 gest a functional role for ISR in cerebellar information processing.

32 may support sparse coding during hippocampal information processing.

33 spintronics, quantum metrology, and quantum information processing.

34 via norepinephrine) amplifies selectivity in information processing.

35 each activity pattern plays a unique role in information processing.

36 isolation--fundamental challenges in optical information processing.

37 response to irreducible noise during neural information processing.

38 mputing systems that perform order-dependent information processing.

39 uce the resources needed for optical quantum information processing.

40 profound effects on early stages of sensory information processing.

41 reless communication and on-chip all-optical information processing.

42 o- and nanostructures is crucial for on-chip information processing.

43 plications in magnetic resonance and quantum information processing.

44 merge as a consequence of optimising sensory information processing.

45 m sensing, quantum communication and quantum information processing.

46 ent that could have broad utility for neural information processing.

47 tential for quantum optical measurements and information processing.

48 twork with functional consequences for odour information processing.

49 tive deficits that reflect impaired cortical information processing.

50 re attractive platforms for scalable quantum information processing.

51 entation, social cognition, and hierarchical information processing.

52 as will be required for large-scale quantum information processing.

53 able SIM, an excellent candidate for quantum information processing.

54 acting memory function and simulating memory information processing.

55 s and serves as a substrate for motivational information processing.

56 may reflect their unique functional roles in information processing.

57 ly cortical responses that support selective information processing.

58 ectome is fundamental for exploring neuronal information processing.

59 that regulates alpha oscillations and visual information processing.

60 flat, non-hierarchical organization in odor information processing.

61 sensing, materials engineering, and quantum information processing.

62 ards the paradigm of self-correcting quantum information processing.

63 ic currents, suggesting an active role in IN information processing.

64 ontrolled are a promising system for quantum information processing.

65 em may offer great flexibilities for quantum information processing.

66 species in structuring this center of visual information processing.

67 activity allows formation of two streams of information processing.

68 e towards spintronics and spin-based quantum information processing.

69 of motor, sensory, emotional, and cognitive information processing.

70 kov Decision Process bounded by noisy neural information processing.

71 or the solid-state implementation of quantum information processing.

72 isms impacting dissociable aspects of visual information processing.

73 agnitude of neuronal output and, ultimately, information processing.

74 Astrocytes are active partners in neural information processing [1, 2].

75 detrimental for most of the tasks in quantum information processing, a substantial degree of decohere

76 large Hilbert space as a resource in quantum information processing.A logical qubit is a two-dimensio

77 tant implications to both spin-based quantum information processing and coherent phonon dynamics in s

78 elevance for applications, including quantum information processing and communication, and passively

79 us media is the key driving force for modern information processing and communication.

80 onic systems, with potential applications in information processing and communication.

81 urrently untenable, with applications across information processing and computational physics.

82 by the urgent need for realizing large-scale information processing and computing.

83 lime mould's distributed sensing, concurrent information processing and decision making, and parallel

84 action (PPI) network is crucial for cellular information processing and decision-making.

85 ammalian hippocampus is critical for spatial information processing and episodic memory.

86 l states, plays an important role in quantum information processing and exploration of the physics of

87 oject locally and are crucial for regulating information processing and flow throughout the cortex.

88 mechanical resonators are useful for quantum information processing and fundamental tests of physics.

89 which may be applied in trapped-ion quantum information processing and generally in any systems requ

90 sively for potential applications in quantum information processing and high-density data storage at

91 ain regions, which are understood to mediate information processing and integration.

92 rnal and internal signals forms the basis of information processing and is essential for higher cogni

93 tanglement is a crucial resource for quantum information processing and its detection and quantificat

94 ip-based magnetic-free optical isolators for information processing and laser protection.

95 itic spines/synapses, which are critical for information processing and memory storage.

96 in regions were associated with a decline in information processing and motor speed (mean difference

97 a promising platform for solid-state quantum information processing and nanoscale metrology.

98 luminate cellular logic of prefrontal cortex information processing and natural adaptive behavior and

99 adaptation is a universal feature of neural information processing and offer a unifying explanation

100 ults from impairment of global (integrative) information processing and overload of local (sensory) i

101 plications in quantum communication, quantum information processing and sensing.

102 portable quantum device required for quantum information processing and sensors, where precise positi

103 ide further degrees of freedom requisite for information processing and spintronics.

104 ions of the necessary primitives for quantum information processing and the highest-fidelity quantum

105 genic noise can interfere with environmental information processing and thereby reduce survival and r

106 The thalamus is a structure critical for information processing and transfer to the cortex.

107 e to the duality as quantum gate for quantum information processing and transistor for optical inform

108 presenting a paradigm change in electronics, information processing and unconventional computing.

109 confer functional advantages for integrative information processing and/or they might represent a sto

110 ggested to be involved in feedforward visual information processing, and might play an important role

111 on has important implications for cerebellar information processing, and suggests that complex spike

112 rest for a wide range of sensing and quantum information processing applications.

113 hanics and is of great importance to quantum information processing as it relates to quantum precisio

114 quantum dot is a good candidate for quantum information processing as well as for a quantum memory,

115 bio- and chemical sensing, nanoscale optical information processing, as well as transducers for high-

116 evices for multiplexed quantum and classical information processing at the network nodes.

117 al measures of executive function, speed and information processing, attention and learning and memor

118 Rejecting information-processing-based theory permits the merging

119 ligence, Graded Naming Test, Birt Memory and Information Processing Battery (BMIPB), Visual Object an

120 al cortex, which can also serve to integrate information processing between cortical regions.

121 Executive functions rely on coordinated information processing between the prefrontal cortex (PF

122 have the potential to revolutionize optical information processing, beyond conventional binary-logic

123 We then examined these opposing information processing biases against less expected vers

124 itive functions that mitigate the effects of information processing bottlenecks.

125 onic circuits for optical communications and information processing, but have been difficult to achie

126 small set of core genes involved in genetic information processing, but the high level of gene loss

127 protocols.Photons are essential for quantum information processing, but to date only two-qubit singl

128 anics, and necessary for advances in quantum information processing; but not yet established in solid

129 a reassessment of current perspectives on BG information processing by highlighting the functional ro

130 ined volume of space, facilitating efficient information processing by reducing echo interference and

131 ng the advantages and limitations of sensory information processing by relays of chemically coupled c

132 EC) has been identified as a hub for spatial information processing by the discovery of grid, border,

133 n types that can each play distinct roles in information processing by virtue of differences in their

134 ve been made in synthetic biology to program information processing capabilities in cells.

135 of spike initiation zones define the cell's information processing capabilities.

136 vant for characterizing the brain's changing information-processing capabilities.

137 stinct, but rather continuous aspects of our information processing capacities.

138 ehavioural deficits, their impact on brain's information processing capacity is currently unknown.

139 We evaluate information processing capacity of a single actin molecu

140 esis that focal lesions decrease the brain's information processing capacity, of which changes in fun

141 se small brains are expected to have a lower information-processing capacity.

142 of determining the evolution of neurons, the information processing cells that compose brains.

143 ach of which represents a discrete olfactory information-processing channel.

144 sciousness" conflates two different types of information-processing computations in the brain: the se

145 a provide a novel mechanism through which VS information processing could influence decision making,

146 promising platforms for solid-state quantum information processing devices with unusual potential fo

147 ing that the differences found constitute an information processing difference between these modules.

148 Here, we found that goal-directed visual information processing differentially modulates shape-ba

149 during ongoing activity to apply to cortical information processing during behavior.

150 match negativity (MMN) indexes pre-attentive information processing dysfunction at the level of prima

151 Neurophysiologic measures of early auditory information processing (EAP) are used as endophenotypes

152 animals (metabolism, temperature regulation, information processing, embryo development, and inherita

153 ting a rationale for the regulation of these information processing features.

154 Here we describe how information processing for cognitive control in this tas

155 tonics could access new regimes of ultrafast information processing for radio, control, and scientifi

156 use of elastic vibrations (i.e., phonons) in information processing, for example, in advanced computa

157 play a critical role in the organization and information processing from genome to whole organisms.

158 n obligatory and crucially important step of information processing from the genome sequences into ce

159 he treatment of cancer, which often involves information-processing gone awry inside human cells.

160 Early auditory information processing had a direct effect on cognition

161 l assembly as the fundamental unit of neural information processing has dominated neuroscience like n

162 Photonic systems for high-performance information processing have attracted renewed interest.

163 a new quality of functional organization of information-processing hierarchies beyond pure feedforwa

164 Quantum information processing holds great promise for communica

165 campal theta rhythm plays important roles in information processing; however, the mechanisms of its g

166 xperiment enables a new platform for quantum information processing in a biological environment such

167 cal and chemical synapses combine to improve information processing in a specific area of the CNS.

168 puts suggests a different extent of synaptic information processing in adapting and non-adapting barr

169 t propagating activity patterns serve neural information processing in area MT and other cortical are

170 G) output nuclei, is an important station in information processing in BG.

171 ovides an effective framework to investigate information processing in biochemical reactions.

172 euron firing by basket cells is critical for information processing in cortical microcircuits, howeve

173 that permit selection and prioritization of information processing in different cognitive domains to

174 signaling may produce aberrant network-level information processing in disorders such as Parkinson's

175 Information processing in early sensory regions is modul

176 Providing the neurobiological basis of information processing in higher animals, spiking neural

177 Given the importance of selective information processing in nearly all domains of cognitio

178 ectivity to dynamics is key to understanding information processing in neocortex.

179 may critically influence both plasticity and information processing in neocortical microcircuits.

180 r release properties, which underlie complex information processing in neural circuits.

181 o shed light on the dynamics of learning and information processing in non-neural metazoan somatic ce

182 risingly little is known about how it shapes information processing in sensory areas.

183 ore broadly, provide a compelling example of information processing in single neurons.

184 tudied extensively, the design principles of information processing in such groups are mostly unknown

185 Information processing in the brain requires multiple fo

186 ), have become a dominant model for studying information processing in the brain.

187 en astrocytes and neuronal synapses regulate information processing in the brain.

188 the synapses are fundamentally important for information processing in the brain.

189 e matter tracts from the cortex facilitating information processing in the cortico-basal ganglia netw

190 like receptors (D2LRs) were likely to affect information processing in the EP.

191 Reliable quantum information processing in the face of errors is a major

192 ndered by our still limited understanding of information processing in the human brain.

193 ur understanding of the mechanisms of visual information processing in the lateral geniculate nucleus

194 Synapses are the fundamental units of information processing in the mammalian brain.

195 o not meaningfully describe the hierarchy of information processing in the microprocessor.

196 Chemosensory information processing in the mouse accessory olfactory

197 he development of multicellular organisms to information processing in the nervous system.

198 y developed tool for dissecting multivariate information processing into distinct parts) to quantify

199 putation in the brain, in particular, in the information processing involving the generation of theta

200 the effects of emotional arousal on neutral information processing is crucial for the predictions of

201 extrastriatal dopamine receptors (DRs) in BG information processing is less clear.

202 network interactions, and presumably optimal information processing, is therefore a systems-level mec

203 decoupling, and asked whether impaired local information processing leads to a loss of information tr

204 remains elusive due to the brain's inherent information-processing limitations.

205 se results imply a novel role for functional information-processing loops in optimizing saccade gener

206 tudied in isolation, interact via functional information-processing loops in the brain to produce com

207 They appear to have a complete genetic information processing machinery, but lack almost all pr

208 tify several novel ways in which hippocampal information processing may be disrupted in dementia, whi

209 Here, we examined how goal-directed visual information processing may differentially impact visual

210 e, -0.31; 95% CI, -0.51 to -0.11; P = .003), information processing (mean difference in z score, -0.4

211 Unrealistic assumptions about agents' information processing mechanisms and poor knowledge of

212 the differences between animals' and plants' information processing mechanisms, such tests should hel

213 ate the extent to which enhancement of basic information processing might improve cognition and psych

214 Serial information processing models, in which motor circuits s

215 s, may contribute to disturbances in spatial information processing observed in this model of dementi

216 A main line of viscerosensory information processing occurs first in the nucleus of th

217 e elucidate one potential mechanism by which information processing occurs in natural networks, and o

218 unt the role of CCK-BC in the generation and information processing of theta oscillations.

219 ity patterns in prefrontal cortex to logical information processing operations required for cognitive

220 The teleporation scheme enables quantum information processing operations with circuit-QED based

221 promise for the molecular charge storage and information processing or the elaboration of the electro

222 e that mediates the first stage of olfactory information processing, participates in generating this

223 With the exception of genes involved in information processing, particularly translation, which

224 ries, is influenced by both individual-level information-processing phenomena and by the conversation

225 t, enhanced two biomarkers of early auditory information processing: prepulse inhibition and mismatch

226 These results provide insight into information-processing principles in frontostriatal circ

227 implement various quantum communication and information processing protocols.

228 and operations for use in few-qubit quantum information processing protocols.Photons are essential f

229 Quantum information processing (QIP) offers the potential to cre

230 is a fundamental requirement for any quantum information processing (QIP) system.

231 cuits have enabled demonstrations of quantum information processing (QIP) that promises to transform

232 Quantum information processing (QIP) would require that the indi

233 s from magnetic resonance imaging to quantum information processing (QIP).

234 ir environment is a critical task in quantum information processing, quantum simulation and sensing.

235 ng of scalable many-body systems for quantum information processing, quantum simulations, and precisi

236 mous structures, motion and work generation, information processing) rather than on specific material

237 oscopy, display, security, data storage, and information processing.Realizing metasurfaces with recon

238 ating from the ocellar photoreceptors to the information processing regions in the bee brain.

239 his affective instability is associated with information processing related to the default mode (DMS)

240 The physical implementation of quantum information processing relies on individual modules-qubi

241 ization of functional spin-based devices for information processing remains elusive due to several fu

242 al low-inhibition task because their limited information-processing resources are overwhelmed by the

243 were caused by interference with orientation information processing (sensory deficit) versus with the

244 hibition, verbal memory, decision speed, and information processing-showed no relative improvement wi

245 a task that demands both object and spatial information processing, single neurons in PRC, LEC, and

246 In distributed quantum and classical information processing, spatially separated parties oper

247 resonance (MR) imaging correlates to explain information processing speed (IPS) and executive functio

248 Cerebellar damage has been implicated in information processing speed (IPS) impairment associated

249 ed for late-stage HIV disease progression on information processing speed (p=0.002), executive functi

250 cognitive deficits in schizophrenia- reduced information processing speed and impaired working memory

251 as also associated with a steeper decline in information processing speed and more than quadrupled th

252 correlated with both associative memory and information processing speed and normalized when these f

253 raumatic amnesia demonstrated impairments in information processing speed and spatial working memory.

254 on study (GWAS) of executive functioning and information processing speed in non-demented older adult

255 line and follow-up in the domains of memory, information processing speed, and executive function; an

256 rbal memory, working memory, decision speed, information processing speed, and psychomotor response s

257 interaction on five neurocognitive domains: information processing speed, executive function, episod

258 nd scores (eg, G factor, executive function, information processing speed, memory, motor speed) and d

259 neuronal activity manifests at early visual information processing stages and progressively increase

260 The neocortex comprises multiple information processing streams mediated by subsets of gl

261 oses challenges for labeled line theories of information processing, suggesting that downstream regio

262 ations for our understanding of multisensory information processing, suggesting that the nature of an

263 meters that critically govern neural circuit information processing-suggesting that similar changes m

264 Photonic quantum information processing system has been widely used in co

265 reflect the learning rules that sculpted the information-processing system within which they reside.

266 ubits, the fundamental units of both quantum information processing systems and quantum sensors, cons

267 Microprocessors are among those artificial information processing systems that are both complex and

268 otprint and resource requirements of quantum information processing systems, but its practical implem

269 become increasingly dependent on electronic information-processing systems at home and work, it's ea

270 urvival depends on highly complex biological information-processing systems.

271 Here we identify information processing tasks, the so-called projections,

272 increasingly important platform for quantum information processing tasks, we developed a new set of

273 amental resource for a wide range of quantum information processing tasks.

274 which seem to occur simultaneously requires information processing that accounts for these different

275 By examining the principles of information processing that are common to speech and mus

276 olecular structures capable of intracellular information processing that couple responses from biomar

277 es a template for attention-mediated laminar information processing that might be applicable across s

278 olean logic has been the backbone of digital information processing, there exist classes of computati

279 Like other forms of information processing, this one is too readily characte

280 mation processing and transistor for optical information processing, this versatile spin-cavity quant

281 s ensure proper neural network formation and information processing throughout the visual field.

282 te retina has an exquisite ability to adjust information processing to ever-changing conditions of am

283 old potential for construction of an in-situ information processing unit to be used in electrochemica

284 ice applications in integrated photonics and information processing using spin-dependent transportati

285 oherence between molecules targeting quantum information processing using the agency of SCRPs.

286 venue for exploring the process for quantum information processing using the superconducting artific

287 and suggests a novel way to modulate neural information processing using transcranial currents.

288 in accordance with the memory phenomena from information processing view.

289 xiety disorder (SAD) is maintained by biased information-processing vis-a-vis threat of social exclus

290 ents in higher-order cognitive functions and information processing, which persist independently of c

291 The brain is capable of massively parallel information processing while consuming only approximatel

292 stimuli are presented in a sequence, neutral information processing will change.

293 t applications in optical communications and information processing with OAM states.

294 al systems, and provides a route for quantum information processing with otherwise linear interaction

295 gical studies have renewed the idea that the information processing within different temporal windows

296 en and within brain regions is essential for information processing within functional networks.

297 cal circuits is critical for ensuring normal information processing within the brain.

298 tational benefits over cell-wide scaling for information processing within the cell.

299 or, coordinated neural network function, and information processing within the hippocampus place cell

300 these dynamics are related to differences in information processing within- and between-specific func