ライフサイエンスコーパス: attentional control

1 fault mode network, which has been linked to attentional control.

2 erhemispheric competition account of spatial attentional control.

3 sistent with a role for ventrolateral PFC in attentional control.

4 ociated with a much broader dysregulation of attentional control.

5 e task designed to fractionate components of attentional control.

6 anging targets that did not require top-down attentional control.

7 th cortical thinning in regions important in attentional control.

8 e cortical thinning in regions important for attentional control.

9 nother (one or two auditory streams) without attentional control.

10 eas, originating in structures important for attentional control.

11 n regions automatically, largely immune from attentional control.

12 ructures are part of a network for voluntary attentional control.

13 sory input is a central element of exogenous attentional control.

14 re not different between feature and spatial attentional control.

15 nd key for informing developmental models of attentional control.

16 ay, in particular action video game play, on attentional control.

17 al network to enhance functional domains for attentional control.

18 d), also exhibits the defining properties of attentional control.

19 entity and uncertainty to implement top-down attentional control.

20 rtant implications for models of goal-driven attentional control.

21 (FPCN) as a mechanism of internally-oriented attentional control.

22 of parietal and frontal cortex as sources of attentional control.

23 primates showing how thalamus contributes to attentional control.

24 nts, as well as the frontoparietal theory of attentional control.

25 s nor one hitherto thought to be involved in attentional control.

26 n terms of other cognitive processes such as attentional control.

27 d" (MD) system, is involved in cognitive and attentional control.

28 standing of the neural mechanisms underlying attentional control.

29 consistently reported along with deficits in attentional control.

30 ining bottom-up sensory inputs with top-down attentional control.

31 d neural mechanisms underlying this flexible attentional control.

32 sence, unreliable predictors of reward usurp attentional control.

33 al networks mediating top-down and bottom-up attentional control.

34 CC), a brain region thought to contribute to attentional control.

35 to reward cues also exhibit relatively poor attentional control.

36 motional deficit or is secondary to atypical attentional control.

37 ecruitment of regions implicated in top-down attentional control.

38 the development of treatments of deficits in attentional control.

39 ur findings provide insights into how infant attentional control abilities and infant-caregiver visua

40 gic projections and plays a critical role in attentional control (AC).

41 distraction depends on the current level of attentional control activity in frontal cortex, but the

42 deo game play may be leveraged for enhancing attentional control, allowing greater cognitive flexibil

43 ly wide transfer may be mediated by enhanced attentional control, allowing increased signal-to-noise

44 However, whether measures of infant attentional control and caregiver behavior during infant

45 ngs reveal a critical shift around 10 y/o in attentional control and crossing decisions in a road cro

46 Psychosocial stress selectively impaired attentional control and disrupted functional connectivit

47 ietofrontal network previously implicated in attentional control and enhancement is also a locus of c

48 A scores, replicated the correlation between attentional control and FA in left hemisphere anterior c

49 ols reveal a significant correlation between attentional control and FA within a ROI in the left hemi

50 gs have important implications for models of attentional control and invite sensitivity to object siz

51 of microstate D/4 may reflect maturation of attentional control and its underlying neural substrates

52 dinal relationships identified between early attentional control and learning in academic settings [9

53 Because of this tight entanglement of attentional control and motor inhibition, identifying un

54 nvestigated the interaction between top-down attentional control and multisensory processing in human

55 hese negative biases result from deficits in attentional control and punishment prediction, respectiv

56 hich was the condition that required greater attentional control and social engagement from infants.

57 ance is discussed, focusing on the nature of attentional control and the effects of practice.

58 refrontal dopamine has specific functions in attentional control and working memory, mediated mainly

59 ate prefrontal cortex that subserve top-down attentional control and working memory.

60 r understanding the neurobiological basis of attentional control, and highlights the risk of medicati

61 working memory, verbal and motor inhibition, attentional control, and IQ--were assessed at ages 8 and

62 eficits in working memory, processing speed, attentional control, and metacognitive skills.

63 underlying differences in social motivation, attentional control, and sensory processing.

64 e function, episodic memory, working memory, attentional control, and social cognition.

65 MMFT emphasizes interoceptive awareness, attentional control, and tolerance of present-moment exp

66 ve tasks assessing working memory, executive/attentional control, and/or verbal memory (ps = 0.03 to

67 or both imaging modalities and age groups in attentional, control, and sensorimotor networks.

68 ndicating that the neural systems supporting attentional control are transient in nature, tending to

69 sal area PITd, has been suggested as a third attentional control area.

70 sually guided responses to more executive or attentional control areas.

71 This, in turn, permitted assessment of attentional control as manifest in motor biases, process

72 a common CHT coding substitution and reduced attentional control as well as attenuated frontal cortex

73 mine the effects of distractor expectancy on attentional control as well as target and distractor pro

74 lly with lower Executive Attention (top-down attentional control) at age 2, and the combination of FH

75 tivity, negative emotional balance, impaired attentional control, avolition, and social mistrust.

76 e-back task varied greatly in the demand for attentional control because of differences in trial-to-t

77 sk context interacted with the efficiency of attentional control being present for those trials elici

78 Despite normal attentional control between levels, LPD patients showed

79 ried behavioral consequences for preparatory attentional control beyond lapses of attentional engagem

80 cial layers of V1, and then feeds forward to attentional control brain regions to guide attention and

81 cally, HTPs showed greater BOLD responses in attentional control brain regions, including bilateral i

82 n which the ACC serves not to exert top-down attentional control but instead to detect and signal the

83 plicated in implementing context-appropriate attentional control, but the learning mechanisms underly

84 uggest that exogenous attention helps refine attentional control by rapidly mobilizing neural units s

85 ults from a single global deficit or whether attentional control can be fractionated, with some aspec

86 tent as younger adults, and that declines in attentional control can limit word recognition.

87 the place code is under the kind of dynamic attentional control characterized in primates as selecti

88 eous actions, as well as three components of attentional control (conflict resolution, set switching,

89 Given its role in attentional control, decision-making, and emotional regu

90 response features, stimulus categories, and attentional control demands.

91 SCZ and SIB from healthy controls (HC) using attentional control-dependent FC patterns, and to test t

92 pothesis that freezing is related to altered attentional control during gait, and suggest that differ

93 As infants grow, they develop greater attentional control during interactions with others, shi

94 ents exhibited no significant dysfunction of attentional control during task performance.

95 rated tripartite framework for understanding attentional control, emphasizing the interaction and com

96 ontext of language use critically determines attentional control engagement during language processin

97 ributes to peculiar kinesthetic experiences, attentional control facilitates multisensory integration

98 task to dissociate brain activity related to attentional control from that related to selective proce

99 positive changes in key neural signatures of attentional control (frontal theta inter-trial coherence

100 elated oscillatory brain activity underlying attentional control function.

101 These findings reveal that the attentional control functions of posterior parietal and

102 In the light of the proposed attentional control functions of ventrolateral PFC and t

103 aled Scores were used to assess executive or attentional control functions.

104 cessing speed (g = 0.41; 95% CI, 0.19-0.62), attentional control (g = 0.53; 95% CI, 0.33-0.73), and m

105 Studies investigating attentional control generally manipulate and cue specifi

106 Theories of spatial attentional control have been largely based upon studies

107 d to freezing and may play a role in altered attentional control; however, this relationship has not

108 arkinson's disease (PD) is likely related to attentional control (ie, ability to divide and switch at

109 Memory and attentional control impairments are the two most common

110 ildren show similar to adult performance and attentional control in a visually guided task; in a natu

111 the implementation of proactive and reactive attentional control in dorsal anterior cingulate and dor

112 g at least two physically activated modes of attentional control in humans: altered gain control and

113 wever, the neural pathophysiology of altered attentional control in individuals with PD who freeze is

114 ble, it is still unclear how this relates to attentional control in naturalistic auditory scenes.

115 Hence we have shown for the first time that attentional control in PD is critically determined by ge

116 ne nucleus connectivity contribute to poorer attentional control in people with PD who freeze.

117 erior cingulate cortex (ACC) response during attentional control in the context of task-irrelevant em

118 ture attention was above chance level during attentional control in the cue-to-target interval, it wa

119 However, the neural mechanisms underlying attentional control in the intact human brain remain unc

120 Weak attentional control increases distractibility and causes

121 ) EF assessment, targeting five key aspects: attentional control, inhibition, working memory, flexibi

122 ual scanning task in which all such forms of attentional control interact rapidly, more akin to real

123 A neural network underlying attentional control involves the anterior cingulate in a

124 A key transmitter for attentional control is acetylcholine, but its cellular a

125 processing per se is unchanged, but top-down attentional control is compromised in older adults when

126 underlying visual attention, focusing on how attentional control is encoded and decoded from prefront

127 These findings confirm that attentional control is necessary for an association betw

128 Attentional control is needed to suppress salient distra

129 ange input balance, and the establishment of attentional control is poorly understood.

130 Human attentional control is unrivaled.

131 as identified deficits in tasks that require attentional control like task-switching, and reward-base

132 Findings indicate ACC activity during attentional control may be a transdiagnostic neural pred

133 affective conflicts engage early dissociable attentional control mechanisms and a later common confli

134 Top-down attentional control mechanisms enable selection of the t

135 right frontal cortex proactively implements attentional control mechanisms to help filter out any di

136 ed to impoverished recruitment of prefrontal attentional control mechanisms to inhibit distractor pro

137 ht to act through interoceptive salience and attentional control mechanisms, but until now conflictin

138 challenged with a visual disruptor to reveal attentional control mechanisms, Val89 mice failed to ado

139 rial covariations to gain insight into these attentional control mechanisms.

140 In moderation analyses, data showed that attentional control moderated the relationship between a

141 entional bias); and (b) to determine whether attentional control moderated this relationship.

142 tract decision-making from sensory salience, attentional control, motor planning, and motor output.

143 itive processes related to sensory salience, attentional control, motor planning, and movement.

144 Our results suggest that a bilateral attentional control network comprising the intraparietal

145 erred to collectively as the fronto-parietal attentional control network, are engaged during attentio

146 CC) has been proposed as part of the brain's attentional control network, but the exact nature of its

147 odulations may be driven by a frontoparietal attentional control network.

148 nce analyses point to the involvement of the attentional control networks in PD-VH, while association

149 f functional cross talk between auditory and attentional-control networks during metacognitive assess

150 specially in emotion regulation, reward, and attentional control neural circuitry in BD versus UD dep

151 onal abnormalities in emotion regulation and attentional control neural circuitry in the two depressi

152 According to a recent framework of attentional control, object selection is guided not only

153 Attentional control of executive function declines durin

154 humans with differential roles in motor and attentional control of gait.

155 itry in frontal cortex to implement top-down attentional control of sensory regions.

156 cy interaction mechanistically subserves the attentional control of stimulus selection.SIGNIFICANCE S

157 f task context and transient fluctuations in attentional control on neural processes supporting perfo

158 ict segregation between sources and sites of attentional control on the basis of representational pro

159 an auditory target, suggesting that auditory attentional control operates in part by biasing processi

160 are associated with the timing of a specific attentional control operation that suppresses processing

161 ngle mechanism or separate mechanisms during attentional control or selection is not known.

162 n of the systems and algorithms that support attentional control or that instantiate the effect of at

163 tical for the neurobiological development of attentional control, or vice versa.

164 rmation, perhaps because of better executive/attentional control over behavior, which requires fronta

165 the dorsal premotor cortex was active during attentional control over first-order cues.

166 Prefrontal cortex can exercise goal-driven attentional control over sensory information via cortica

167 Attentional control over sensory processing has been lin

168 y to moment-by-moment changes in preparatory attentional control over spatial selection.

169 indicate that temporal-parietal areas exert attentional control over the neural transformations occu

170 reconciled with neuropsychological models of attentional control, particularly the Supervisory Attent

171 As we navigate through the day, our attentional control processes are constantly challenged

172 e function including working memory (WM) and attentional control processes.

173 e imaging response during working memory and attentional control processing, and impaired working mem

174 assume or to respond to a non-action-related attentional control question.

175 sistent with the inhibition of TPJ by dorsal attentional control regions during top-down serial visua

176 g of the systems-level mechanisms underlying attentional control remains limited.

177 (FP) areas underlies the representation and attentional control, respectively, of sensory informatio

178 Models of action control assume that attentional control settings regulate the processing of

179 eflect online, bottom-up priming of top-down attentional control settings.

180 ch the contextual cue was translated into an attentional control signal that facilitated behavior.

181 th ongoing sensory information to provide an attentional control signal to FEF.

182 xtual information and translating it into an attentional control signal.

183 e novel evidence for the organization of the attentional control signals at the level of distributed

184 Attentional control signals depended on muscarinic, not

185 ptors affect basic neuronal excitability and attentional control signals in different cell types in m

186 linergic receptors are critical to establish attentional control signals in the frontal eye field in

187 ed by PFC lesions, other sources of top-down attentional control signals to visual cortex must exist

188 led that muscarinic and nicotinic effects on attentional control signals were highly selective even f

189 provide the source of at least some forms of attentional control signals.

190 th those of unattended objects, via top-down attentional control signals.

191 riability of features in service of top-down attentional control.SIGNIFICANCE STATEMENT Theories of a

192 These results show that attentional control spans three cortical lobes and overa

193 l representations of stimulus categories and attentional control states.

194 abstract, "internal" event features such as attentional control states.

195 features, stimulus categories, and internal attentional control states.

196 attention involves dynamic interplay between attentional control systems and sensory brain structures

197 between network communities, particularly in attentional control systems, facilitate the integration

198 osed to be an important component of frontal attentional control systems.

199 plicit emotion regulation (EER) and top-down attentional control (TAC).

200 or to trauma-relevant images in an affective attentional control task.

201 g during performance of an affective Stroop (attentional control) task.

202 th reduced performance in working memory and attentional control tasks in healthy humans.

203 o train 11-month-old infants on a battery of attentional control tasks.

204 rtex may underlie the functional deficits in attentional control that are symptomatic of stress-relat

205 amygdala and regions implicated in top-down attentional control (the dorsomedial and lateral frontal

206 al frontoparietal systems are key players in attentional control, their distinct contributions remain

207 The possibility of enhancing attentional control through targeted interventions, be i

208 motions and memory but is also important for attentional control through unknown synaptic mechanisms.

209 potentials indexed feature-general top-down attentional control to one of several coexisting auditor

210 t demonstration of distal transfer following attentional control training in infancy.

211 Reduced effectiveness of top-down attentional control under SD, especially when conditions

212 IB with 39 matched HC underwent the Variable Attentional Control (VAC) task.

213 ortex (rIFC) is specifically associated with attentional control via the inhibition of behaviorally i

214 s, we independently manipulated the need for attentional control (via visual distractors) and motor c

215 Greater impairment of attentional control was associated with reduced volume i

216 The impairment in flexible shifting of attentional control we observed is distinct from lapses

217 anations that posit limits in the sources of attentional control, we show that mechanisms at the site

218 ustained attention, selective attention, and attentional control were assessed with the Test of Every

219 ferent blocks of trials, and fluctuations of attentional control were considered by examining differe

220 ut little is known about the neural basis of attentional control within and between other sensory mod

221 tivation of prefrontal regions important for attentional control, working memory, and cognitive flexi