ライフサイエンスコーパス: addictive behavior

1 ual reward-seeking behavior is a hallmark of addictive behavior.

2 essive effects), contributing to maladaptive addictive behavior.

3 the mechanisms by which mindfulness reduces addictive behavior.

4 to identify cellular mechanisms relevant for addictive behavior.

5 understanding of their efficacy in reducing addictive behavior.

6 pendent remodeling that may underlie certain addictive behavior.

7 ges are entirely dissociable from changes in addictive behavior.

8 derstanding the neurobiological mechanism of addictive behavior.

9 ng is critical for movement, motivation, and addictive behavior.

10 plays a critical role in the development of addictive behavior.

11 d depression-like behavior and bHRs prone to addictive behavior.

12 ts for sleep disorders, eating disorders, or addictive behavior.

13 Excessive sun tanning can result in addictive behavior.

14 hereby causing development and expression of addictive behavior.

15 mon vertebrate model system for the study of addictive behavior.

16 gmental area (VTA) are pivotally involved in addictive behavior.

17 he formation of drug-associated memories and addictive behavior.

18 has an important role in the development of addictive behavior.

19 ug-induced changes in dendritic spines drive addictive behavior.

20 er than stopping cigarette smoking, a highly addictive behavior.

21 y relevant for the control of stress-related addictive behavior.

22 tress that may help to initiate and maintain addictive behavior.

23 ine-induced aberrant synaptic plasticity and addictive behavior.

24 promotes the development and persistence of addictive behavior.

25 that likely contribute to the maintenance of addictive behavior.

26 he FAAH-endocannabinoid system in regulating addictive behavior.

27 elucidating the biological underpinnings of addictive behavior.

28 ages is a risk factor for the development of addictive behavior.

29 ion might "reset" DMN dysfunction to inhibit addictive behavior.

30 lated reward circuits, ultimately leading to addictive behaviors.

31 ing and gaming disorders as disorders due to addictive behaviors.

32 rning from negative PEs, such as obesity and addictive behaviors.

33 ng and impulsivity in the broader context of addictive behaviors.

34 en their role in the neurobiology of AUD and addictive behaviors.

35 ted with increased risks of engaging in more addictive behaviors.

36 ding these five (potential) disorders due to addictive behaviors.

37 hosocial stress on neural cue reactivity and addictive behaviors.

38 ay drive further ethanol intake, reinforcing addictive behaviors.

39 atal dysfunction, is a key characteristic of addictive behaviors.

40 ribute to the acquisition and maintenance of addictive behaviors.

41 ion in target regions in an effort to dampen addictive behaviors.

42 entifying new therapeutic targets for opiate addictive behaviors.

43 a role in the association between stress and addictive behaviors.

44 ased stress reactivity and irritability) and addictive behaviors.

45 rapeutics to better understand and influence addictive behaviors.

46 xpression in neural circuits responsible for addictive behaviors.

47 fy specific circuit components that underlie addictive behaviors.

48 (LH), are involved in reward processing and addictive behaviors.

49 amygdala, they modulate our pain, fear, and addictive behaviors.

50 onal response that is linked to long-lasting addictive behaviors.

51 in determining who does and does not develop addictive behaviors.

52 Acb) dopamine mediates several motivated and addictive behaviors.

53 A (PKA) pathways are strongly implicated in addictive behaviors.

54 us accumbens modulates both motivational and addictive behaviors.

55 could be related to those that contribute to addictive behaviors.

56 ent of cannabis, shows promise in modulating addictive behaviors.

57 the early onset, escalation, and relapse of addictive behaviors.

58 ptations in the mPFC have been implicated in addictive behaviors.

59 t overeating of palatable food is similar to addictive behavior and characterized by dysregulation of

60 mus (LH), a target region known to influence addictive behavior and mood.

61 -analysis, representing 643 individuals with addictive behaviors and 609 healthy control individuals.

62 a period of heightened vulnerability both to addictive behaviors and drug-induced brain damage.

63 Stress increases addictive behaviors and is a common cause of relapse.

64 l seeking in male mice, which is relevant to addictive behaviors and other compulsive disorders.

65 o a negative affective state contributing to addictive behaviors and risk of relapse.

66 m plays an important role in cocaine-related addictive behaviors and suggest that manipulating and ta

67 asing the probability of impulsive-including addictive-behavior and promoting recovery.

68 c neurotransmission plays a critical role in addictive behaviors, and recent evidence indicates that

69 ipation and/or outcome; participants showing addictive behaviors; and healthy control group.

70 ce use or gambling; participants at risk for addictive behaviors; and studies using the same patient

71 Many addictive behaviors are a result of learned associations

72 mesolimbic dopamine system, suggesting that addictive behaviors are encoded by changes in the reward

73 -wide association study (GWAS) loci of human addictive behaviors are poorly understood.

74 gnificance of learning factors in persistent addictive behavior as well as the neurobiological basis

75 ociated memories is critical for maintaining addictive behaviors, as presentation of drug-associated

76 Addictive behavior associated with alcoholism is charact

77 ber of brain systems have been implicated in addictive behavior, but none have yet been shown to be n

78 (PFC) contribute to several core aspects of addictive behaviors, but the underlying neuronal process

79 re central to pain control, drug reward, and addictive behaviors, but underlying circuit mechanisms h

80 Thus, like other addictive behaviors (cigarette smoking, alcohol and drug

81 The development and persistence of addictive behaviors comes from a complex interaction of

82 d aggression, impulsivity, and proclivity to addictive behaviors compared with low-novelty reactive r

83 et region amygdala, a key area implicated in addictive behavior, differs depending on the GATA4 genot

84 ased sensitivity to environmental events and addictive behaviors during adolescence, whereas the pauc

85 sorders (such as depression and anxiety) and addictive behaviors (e.g., internet addiction) predomina

86 eural systems interact with sex to influence addictive behavior, emphasizing throughout that the impa

87 Human studies of addictive behaviors have clearly implicated both environ

88 the synaptic plasticity associated with drug addictive behaviors; however, the causal role of the CRE

89 and thereby contribute to the maintenance of addictive behavior in cocaine users.

90 s depressive-like effects and contributes to addictive behavior in male nonhuman primates and rodents

91 dopamine stimulation and might contribute to addictive behaviors in CA.

92 ssful events and could augment activation of addictive behaviors in response to stress.

93 on tobacco use, in particular, as well as on addictive behavior, in general.

94 ne and may contribute to an understanding of addictive behavior including disruptions in sleep and ci

95 Addictive behaviors, including relapse, are thought to d

96 This decrease in addictive behavior is associated with a long-term reduct

97 self-administration drives the appearance of addictive behavior is unclear, but the mechanistic expla

98 anding the neural basis of this control over addictive behavior may aid in the development of treatme

99 ormones in the development and expression of addictive behaviors may provide new insights into treatm

100 opamine D1 receptors has profound effects on addictive behavior, movement control, and working memory

101 defense functions; the partially selfish and addictive behavior of the defense systems; and coupling

102 , revealing another negative influence of an addictive behavior on household resource allocation.

103 asticity and its synaptic concomitants drive addictive behaviors or whether they reflect homeostatic

104 Do negative feelings in general trigger addictive behavior, or do specific emotions play a stron

105 Substantial evidence from rodent models of addictive behavior points to the involvement of the vent

106 nt dendritogenesis are also involved in such addictive behavior remains unknown.

107 regulate VTA GABA neuron activity and drive addictive behaviors remains poorly understood.

108 y be responsible for the augmentation in the addictive behavior reported.

109 ability of neuropsychiatric traits including addictive behavior, schizophrenia, and neuroticism, thus

110 e of the transcriptional networks underlying addictive behaviors suggests intricate cooperation betwe

111 e synaptic changes associated with facets of addictive behavior, supporting partial coincident neurol

112 ibute to impulsivity, which is a hallmark of addictive behaviors that underlie compulsive drug seekin

113 t the applicability of theoretical models of addictive behaviors to the social-networks-use disorder

114 st the role of NMDAR-dependent plasticity in addictive behavior, we genetically inactivated functiona

115 king behavior, novelty-seeking behavior, and addictive behavior, we hypothesized alterations of the f

116 d-based learning and therefore contribute to addictive behavior, whereas the projection to the SNc ma

117 ompulsivity occurs during the development of addictive behavior, which provides insights into the gen

118 tly or indirectly-to processes of reward and addictive behavior, with a focus on psychostimulants and