ライフサイエンスコーパス: behavioral analyses

1 munostaining, RNA sequencing, lipidomic, and behavioral analyses.

2 e ventral tegmental area and psychotomimetic behavioral analyses.

3 ctical and theoretical limitations of common behavioral analyses.

4 Mi{MIC} mutants and focused on molecular and behavioral analyses.

5 with the parental lines via histological and behavioral analyses.

6 ysiological recordings of the subiculum, and behavioral analyses.

7 A total of 21 participants were included in behavioral analyses; 17 purchased cannabis and were thus

8 Behavioral analyses also confirmed that variations of al

9 et the current diagnostic procedures rely on behavioral analyses and interviews, without objective sc

10 Using a combination of behavioral analyses and single-cell Ca(2+) imaging in wi

11 proaches, building from molecular targets to behavioral analyses and vice versa, respectively.

12 Neuronal time-lapse imaging, behavioral analyses, and electrophysiological recordings

13 etroviral fate mapping of neural stem cells, behavioral analyses, and various network analyses of tra

14 Our behavioral analyses capture both the structure and tempo

15 Electrophysiological and behavioral analyses confirmed that rationally designed,

16 Histological, electrophysiological, and behavioral analyses demonstrate that MEF2C-directed neur

17 Behavioral analyses demonstrated higher basal locomotor

18 Behavioral analyses demonstrated that pan-neural loss of

19 Behavioral analyses found that NeuroD1 and Dlx2-treated

20 Behavioral analyses have long indicated that additional,

21 Recent advances in quantitative behavioral analyses have paved the way for investigating

22 her, our cellular, electrophysiological, and behavioral analyses highlight the importance of axonal t

23 histochemistry, in vivo Ca(2+) imaging, and behavioral analyses in a mouse model of AD, we demonstra

24 rboring this mutation and performed detailed behavioral analyses in acute and chronic pain models.

25 It also reveals the importance of behavioral analyses in studies aimed at understanding th

26 r, histological, and biochemical methods and behavioral analyses in vivo we demonstrate, to our knowl

27 In this study, both recordings in vitro and behavioral analyses in vivo were used to examine cellula

28 Through a battery of behavioral analyses, including primate-unique eye-tracki

29 ptic tracing together with physiological and behavioral analyses indicate that integrated sensory inf

30 ls overall, but computational model fits and behavioral analyses indicate that these deficits could b

31 -imaging, hormone-measurement, and cognitive-behavioral analyses indicate the importance of mentaliza

32 Our behavioral analyses indicated that DJ-1 deficiency led t

33 This approach combined with molecular and behavioral analyses, led us to recognize, in hippocampus

34 when combined with electrophysiological and behavioral analyses, make this an attractive model syste

35 Behavioral analyses of BACHD/GFAP-CreERT2-tam mice demon

36 Electrophysiological, imaging, and behavioral analyses of Caenorhabditis elegans mutants la

37 Behavioral analyses of offspring exposed to BPA revealed

38 Behavioral analyses of optomotor head-turning reflex, vi

39 Here, we provide detailed behavioral analyses of the highly acrobatic Australian a

40 , electrophysiological, and vision-dependent behavioral analyses of the mouse model revealed a unique

41 ly amenable to molecular, physiological, and behavioral analyses of the neural features responsible f

42 Behavioral analyses of the ontogeny of memory have shown

43 Behavioral analyses of the R6/2 mouse reveal age-related

44 hat can now be used to correlate with future behavioral analyses of these compounds and may provide i

45 Behavioral analyses of these mice showed selectively slo

46 Comprehensive behavioral analyses of transgenic and knockout mice have

47 High-throughput behavioral analyses of trpa1a and trpa1b mutant larvae i

48 We used a combination of molecular and behavioral analyses, pharmacology, and in vivo amperomet

49 ed a combination of slice electrophysiology, behavioral analyses, pharmacology, in vivo microdialysis

50 We used improv to orchestrate real-time behavioral analyses, rapid functional typing of neural r

51 Behavioral analyses reveal robust relationships between

52 Behavioral analyses reveal that many of the 43 male-spec

53 Microarray, imaging, and behavioral analyses reveal that tomatidine maintains mit

54 endrite patterning in the cerebellar cortex, behavioral analyses reveal that TRPC5 knockout mice have

55 Behavioral analyses revealed a significant interaction,

56 Behavioral analyses revealed no differences from wild ty

57 Our behavioral analyses revealed that formoterol, a long-act

58 Behavioral analyses revealed that humans executed a hier

59 Behavioral analyses revealed that mice lacking CRFR1 dis

60 Behavioral analyses revealed that poker players were fas

61 Exploratory behavioral analyses revealed that regions showing increa

62 Behavioral analyses revealed that suppression of GAD1 in

63 Genetic and behavioral analyses revealed that tank acts in the adult

64 Consistent with these observations, behavioral analyses show that bitter-compound-mediated i

65 Behavioral analyses show that multiple elements of behav

66 Furthermore, behavioral analyses show that PRMT8 conditional knock-ou

67 Behavioral analyses show the blinks of mudskippers are f

68 Similarly, behavioral analyses showed impaired auditory and context

69 Motor behavioral analyses showed no changes in reach rate acro

70 Behavioral analyses showed that both age-groups learned

71 Human genetic and mouse behavioral analyses suggest that ENGRAILED-2 (EN2) contr

72 Our genetic, pharmacological, and behavioral analyses suggest that in sir-2.1(0) and older

73 Behavioral analyses suggest that serotonin facilitates l

74 Finally, behavioral analyses suggest that such increased connecti

75 Genetic and behavioral analyses suggest that the NCA channels enable

76 Behavioral analyses suggest that these molecular effects

77 viral vectors and gene editing to automated behavioral analyses, there has been a recent wave of int

78 These connectomic and behavioral analyses therefore reveal further complexity

79 ophysiological recordings were combined with behavioral analyses to assess whether removal of AKAP150

80 Based on this finding, we performed behavioral analyses to determine whether a gain-of-funct

81 graphical, morphological, physiological, and behavioral analyses to determine whether key functional

82 mouse genetics, single-cell dye tracing, and behavioral analyses to determine whether Tbr2 regulates

83 Such information may be correlated with pain behavioral analyses to help shed light on the complex mo

84 approach using high-throughput, quantitative behavioral analyses to identify the neural substrates of

85 We utilized in vivo EEG recordings and behavioral analyses to perform a battery of electrophysi

86 ng brain imaging with social, cognitive, and behavioral analyses to understand how parental brain cir

87 Behavioral analyses using a Bayesian framework showed th

88 Behavioral analyses using video microscopy revealed that

89 By performing biochemical and behavioral analyses we can show that UCH-L1 deficiency c

90 With combined brain-imaging and cognitive-behavioral analyses, we are in the early phases of under

91 ysiological recordings, calcium imaging, and behavioral analyses, we demonstrate that ionotropic rece

92 ular, biochemical, electrophysiological, and behavioral analyses, we demonstrate that NRG1-IV/NSE-tTA

93 Using newly developed quantitative behavioral analyses, we demonstrate that the T(S) repres

94 in vivo electrophysiology, optogenetics, and behavioral analyses, we demonstrated that anterior cingu

95 Through behavioral analyses, we find that multiple components of

96 Using microstructural behavioral analyses, we identified the spatiotemporal dy

97 By transcriptomic, proteomic, and behavioral analyses, we report that heterozygous Grin2a

98 Using genetic and behavioral analyses, we show that apt mediates sensitivi

99 genetics, cell-specific ablation- and mutant behavioral analyses, we show that the male makes this sh

100 analysis, calcium imaging, optogenetics and behavioral analyses, we uncovered a circuit specific for

101 Behavioral analyses were conducted using a newly-develop

102 sed to varying concentrations of PM(2.5) and behavioral analyses were conducted.

103 ohistochemical, biochemical, functional, and behavioral analyses were performed in nerves harvested f

104 In the present work we combined behavioral analyses with calcium imaging of odor induced

105 By coupling behavioral analyses with computational modeling, we show

106 Combining behavioral analyses with in vivo synaptic imaging, we sh