ライフサイエンスコーパス: postural control

1 lar input synergistically to maintain robust postural control.

2 assessments of single and dual-task standing postural control.

3 omatosensory and vestibular contributions to postural control.

4 been shown to decrease dizziness and improve postural control.

5 ial orientation, self-motion perception, and postural control.

6 uggests that the motor cortex is involved in postural control.

7 sider adjuvant surgical treatment for better postural control.

8 arly those that are likely to participate in postural control.

9 bular and autonomic information pertinent to postural control.

10 ral sway characterizes healthy and adaptable postural control.

11 gical and neuromotor functions, particularly postural control.

12 suggesting a preferential motor strategy for postural control.

13 e activity compatible with a contribution to postural control.

14 tor incongruence and contextual relevance to postural control.

15 he body-centric reference frame required for postural control.

16 onomic, and visual inputs are integrated for postural control.

17 and standing, suggesting a relationship with postural control.

18 e muscle mass, cardiovascular stability, and postural control.

19 Only in patients with impaired postural control (3 SD above controls' mean), whole brai

20 act of ICV cerliponase alfa ERT on gait, and postural control across a two-year span in two siblings

21 on is vital for successful recovery of human postural control after injury.

22 ergic system might play a role in supporting postural control after nigro-striatal dopaminergic losse

23 cal disorders, such as stroke, often involve postural control and gait impairment in multiple planes.

24 lacement positively correlated with those of postural control and gluteus medius muscle activities, r

25 hub of sensorimotor integration critical for postural control and locomotion, but the nature and deve

26 less research attention than its effects on postural control and locomotion.

27 n of body motion required to ensure accurate postural control and perceptual stability in our daily l

28 results emphasize the role of sagittal plane postural control and plantar-flexor activation in stabil

29 ons to mitigate the adverse effects of BR on postural control and prevent prolonged recovery times or

30 sed analysis revealed an association between postural control and right hemispheric cholinergic netwo

31 neurons in the vestibular nuclei involved in postural control and self-motion perception.

32 ssing in the vestibular pathways involved in postural control and the computation of self-motion perc

33 herence and causality analyses of the cardio-postural control and used to assess changes in the muscl

34 ctivity, followed by incoordination, loss of postural control, and eventually, sedation.

35 ference and assessment of their relevance to postural control, and may instead operate in parallel.

36 s of interactions with tandem Romberg stance postural control, and that interactions within the spati

37 art of a network involved in proprioception, postural control, and the generation of coordinated move

38 y of motor activities, including locomotion, postural control, and voluntary movements.

39 Our results suggest that, in the context of postural control, appropriate mechanical stimulation is

40 ctions with regions mediating visuomotor and postural control, as previously observed in other mammal

41 is essential to continuously maintain stable postural control, autonomic regulation, and self-motion

42 (STS) test was conducted to evaluate cardio-postural control before and after (R) HDBR while an asse

43 ly plays a role for our sense of balance and postural control but also might modulate higher-order bo

44 Postural control can similarly suffer when conscious att

45 Postural control changes were studied in 27 patients wit

46 To simulate real-life dual-task postural control conditions, the second set of experimen

47 osthesis users' and able-bodied individuals' postural control conforms well to that predicted by a un

48 ic efferent terminals has been implicated in postural control deficits in Parkinson's disease.

49 ovide the first evidence that disruptions to postural control during CMP may be a consequence of insu

50 were calculated as an indicator of reactive postural control during horizontal perturbations.

51 This translates into a lack of postural control during jumping in Brachycephalus and re

52 In quadrupeds, the most critical aspect of postural control during locomotion is lateral stability.

53 and trunk neural mechanisms contributing to postural control during locomotion.

54 Directional deficits in reactive postural control during medial and lateral perturbations

55 to identify directional deficits in reactive postural control during unanticipated horizontal perturb

56 mastoid vibration (MV) could affect dynamic postural control during walking.

57 Postural control, especially when standing and performin

58 the nervous system, ensuring stable gaze and postural control for locomotion on land.

59 and adaptive responses reflect excursions of postural control from quiescent Gaussian stability under

60 addition to its acknowledged importance for postural control, gaze stabilization, and spatial naviga

61 ed using transcranial Doppler ultrasound and postural control (i.e., elliptical area, range, and path

62 High anti-cholinergic burden predicted postural control impairment in a manner dependent on rig

63 veal deficits and visuospatial attention and postural control impairment in PD remain challenging res

64 al of sensory-based interventions to support postural control in autism.

65 ew work on molluscan feeding, maintenance of postural control in cats and humans, simulations of loco

66 ng eyes closed as well suggests that reduced postural control in glaucoma is not entirely attributed

67 t with a set of experimental observations of postural control in healthy subjects and three groups of

68 l dual-task interference effects with stance postural control in healthy young adults.

69 her a tailored tai chi program could improve postural control in patients with idiopathic Parkinson's

70 and their thalamic efferents play a role in postural control in patients with Parkinson's disease, p

71 , which is essential for maintaining precise postural control in response to unexpected movements.

72 easure the sensory organizational process of postural control in the presence of altered sensory inpu

73 nstrained pin-controller model in explaining postural control in unilateral prosthesis users.

74 the majority of rays retain a high degree of postural control, indicating significant functional resi

75 Standing postural control is complex, meaning that it is dependen

76 During unperturbed bipedal standing, postural control is governed primarily by subcortical an

77 Knowledge of brain correlates of postural control is limited by the technical difficultie

78 These results indicate that dual task postural control is reliant on CBF, yet the nature of th

79 Another component of postural control is the postural strategy, traditionally

80 ers of motor skills obtained from kinematic, postural control, joint torque, and proprioception varia

81 e (COPr) can quantify the behavior of cardio-postural control loop.

82 keletal and feedback components of the human postural control loop.

83 ood cancer may suffer late effects of poorer postural control manifested as reduced contribution of v

84 e visual brain network may negatively impact postural control measured with dynamic posturography in

85 Unanticipated postural control measures may better identify mechanisms

86 eased EMG activity of the gluteus medius and postural control muscles during leg swing, and increased

87 otion and orientation estimates required for postural control, navigation, and reaching are computed

88 reproductive and defensive behaviors to the postural control of suckling-induced kyphotic nursing an

89 conclude that activity in the nMLF provides postural control of tail orientation and thus steers the

90 were investigated: IJV stenosis, reversal of postural control of the cerebral venous outflow pathways

91 Such results suggest an 'unlinking' of postural control of the forequarters from the hindquarte

92 Poor postural control of the head-neck can be a debilitating

93 These findings highlight that postural control of the paretic limb is a key determinan

94 In summary, this study found that postural control performance was associated with visual

95 em changes that associate with inter-sensory postural control processing features as assessed by dyna

96 ng expiration, coughing, sneezing, vomiting, postural control, production of speech, straining, facil

97 Postural control research has focused on standing balanc

98 im, their hindquarters showed little lateral postural control resulting in rotation about the longitu

99 Efficient postural control results from an effective interplay bet

100 In the control group, IJV stenosis (P=0.12), postural control reversal of the cerebral venous outflow

101 In the study group, IJV stenosis, postural control reversal of the cerebral venous outflow

102 ual, and autonomic inputs are integrated for postural control.SIGNIFICANCE STATEMENT Our sensory syst

103 ffect of whole-body vibratory stimulation on postural control strategies employed to maintain an upri

104 trate that the NU is crucial for maintaining postural control, suggesting it could play an important

105 l functional link between sensory gating and postural control, supporting future investigations into

106 on, while the later response arises from the postural control system attempting to align the body wit

107 ith more accurate internal states, the human postural control system can further adjust the standing

108 ssessing the effect of additive noise on the postural control system has found a positive effect of a

109 his work was to formulate the human standing postural control system in the framework of the free-ene

110 demonstrate a decrease in variability of the postural control system regardless of the structure of t

111 nction depends in part on the ability of the postural control system to integrate visual, propriocept

112 e is a lack of adequate understanding of how postural control varies as a function of available senso

113 e IdX task, the relationship between CBF and postural control was dependent upon age (p = 0.03).

114 d Ankle Instability Tool (CAIT), and dynamic postural control was measured with the Star Excursion Ba

115 processes significantly involved in dynamic postural control, was a reliable and performing discrimi

116 briometer to measure ethanol-induced loss of postural control, we identified cheapdate, a mutant with

117 SOTN) and those, the majority, with abnormal postural control when sensory feedback was limited (SOTA

118 stem, and cerebellum play essential roles in postural control, whereas the role of the forebrain is u

119 llidotomy on motor and sensory components of postural control, which may reflect the underlying patho

120 Human postural control, which relies on information from vesti

121 score reflects sensory and motor aspects of postural control, with normal sensory feedback, while th