ライフサイエンスコーパス: diastolic filling

1 in RV systolic function and RV and LV early-diastolic filling.

2 tion, delayed untwisting, and impaired early diastolic filling.

3 consequence of left heart anatomy and aid LV diastolic filling.

4 , critically linking systolic contraction to diastolic filling.

5 systolic ejection time, which may compromise diastolic filling.

6 uscle stiffness; an important determinant of diastolic filling.

7 f myocardial oxygen consumption and impaired diastolic filling.

8 r valve disease, due to impaired ventricular diastolic filling.

9 ad in patients with CTEPH causes abnormal LV diastolic filling.

10 ents stored energy that may facilitate early diastolic filling.

11 ay be an increase in stretch due to enhanced diastolic filling.

12 implantable ventricular assist device on LV diastolic filling.

13 oppler echocardiography in the assessment of diastolic filling.

14 after transplantation with respect to RV/LV diastolic filling.

15 < 0.0001), increased atrial contribution to diastolic filling (0.47 +/- 0.09 vs. 0.30 +/- 0.08 m/s,

16 LV systolic function (S' z score) and late-diastolic filling (A' z score) improved to normal in 11

17 rast, captopril almost completely normalized diastolic filling abnormalities (E velocity 82 +/- 5 cm/

18 Diastolic filling abnormalities after pericardiectomy co

19 e of subclinical contractile dysfunction and diastolic filling abnormalities are both predictive of s

20 l systolic function, elevated BNP levels and diastolic filling abnormalities might help to reinforce

21 nction but markedly improves the restrictive diastolic filling abnormalities that are seen in untreat

22 ed in left ventricular systolic function and diastolic filling after exercise in the control groups.

23 duced ischemia impairs systolic function and diastolic filling after exercise.

24 pairs left ventricular systolic function and diastolic filling after exercise.

25 w, which should improve the understanding of diastolic filling and function of the heart.

26 arked by the hemodynamic pattern of impaired diastolic filling and restrictive cardiomyopathy.

27 on-invasive MRI of early, chronic changes in diastolic filling and systolic ejection in both the left

28 ties during early (E wave) and late (A wave) diastolic filling, and myocardial performance index.

29 ties during early (E-wave) and late (A-wave) diastolic filling, and the myocardial performance index.

30 s with MI showed progressively restricted LV diastolic filling as assessed by transmitral Doppler rec

31 sional transmural strains during systole and diastolic filling, at 1 and 12 weeks postoperatively.

32 arametrized diastolic filling-based E-wave analysis (k, c or DTs and

33 likely to impact functional transitions and diastolic filling behavior during development of the hea

34 Noninvasive assessment of diastolic filling by Doppler echocardiography provides i

35 dilated cardiomyopathy significantly impact diastolic filling by lowering myocardial stiffness.

36 se of abnormal left ventricular (LV) Doppler diastolic filling characteristics in chronic thromboembo

37 pressure overload and left ventricular (LV) diastolic filling characteristics in patients with chron

38 Diastolic filling characteristics remain abnormal in a s

39 s, preserved ejection fraction, and impaired diastolic filling, characterized by reduced deceleration

40 Early diastolic filling decreased after four days of pacing fr

41 r hypertension, E/A, a diagnostic measure of diastolic filling, decreases, and isovolumic relaxation

42 3 mm Hg; P=0.0007), suggesting inadequate LV diastolic filling, despite high pulmonary capillary wedg

43 ults provide a standard reference concerning diastolic filling dynamics by trimester.

44 d to identify abnormal left ventricular (LV) diastolic filling dynamics, inherent limitations suggest

45 c function (S' z score -2.7+/-0.8), RV early-diastolic filling (E' z score -2.3+/-1.1), and LV early-

46 illing (E' z score -2.3+/-1.1), and LV early-diastolic filling (E' z score -2.3+/-1.1).

47 mproved to normal in 11 to 30 days, LV early-diastolic filling (E' z score) in 4 to 6 months, and RV

48 The peak rate of left ventricular (LV) early diastolic filling (E) and velocity of the mitral annulus

49 ales, but abnormal fractional shortening and diastolic filling (E/A ratio) patterns were more common

50 Isovolumic relaxation time (IVRT), early diastolic filling (E/A), myocardial performance index (M

51 an energy-saving/efficient mode: it improves diastolic filling (enhanced lusitropy - lowering HRT), m

52 It is associated with impaired diastolic filling, even in seemingly asymptomatic obese

53 function was quantified via the parametrized diastolic filling formalism that yields relaxation/visco

54 r) by analyzing E-waves via the parametrized diastolic filling formalism.

55 ection fraction, cardiac output, heart rate, diastolic filling function, and ventricular mass.

56 tic resonance spectroscopy, left ventricular diastolic filling (heart rate normalized time to peak fi

57 (E' z score) in 4 to 6 months, and RV early-diastolic filling in 6 to 9 months (P<0.001 for all on l

58 lated work was associated with greater early diastolic filling in men only.

59 me (ACE) inhibition on left ventricular (LV) diastolic filling in postinfarction heart failure.

60 bnormalities after the race included altered diastolic filling, increased pulmonary pressures and rig

61 This impairment in diastolic filling is related to both abnormalities of th

62 Peak velocities of early diastolic filling, late diastolic filling, late to early

63 velocities of early diastolic filling, late diastolic filling, late to early filling ratio, decelera

64 cs of the cardiac left ventricle (LV) during diastolic filling may play a critical role in dictating

65 ansmural gradients of oxygen consumption and diastolic filling, may play a role in the cycle of the f

66 ion, we hypothesized that improvements in LV diastolic filling might contribute to the overall benefi

67 le of echocardiography in the "Evaluation of Diastolic Filling of Left Ventricle in Health and Diseas

68 Diastolic filling of the left ventricle (E/A ratio) was

69 ied approach to understanding the process of diastolic filling of the left ventricle and interpreting

70 multiple interrelated factors that determine diastolic filling of the left ventricle, these flow velo

71 s a comprehensive, noninvasive evaluation of diastolic filling of the ventricle, myocardial relaxatio

72 Patients with persistent abnormal diastolic filling on Doppler echocardiography had had sy

73 Diastolic filling pattern at late follow-up was normal i

74 Diastolic filling pattern itself influences chamber pres

75 There was a significant relationship between diastolic filling patterns and symptomatic status (chi2

76 Diastolic filling patterns at rest were assessed by Dopp

77 raphy has been used to examine the different diastolic filling patterns of the left ventricle in heal

78 Diastolic filling patterns were also similar.

79 s with symptoms had higher BNP levels in all diastolic filling patterns.

80 ex >33 ml/m(2), ratio of mitral inflow early diastolic filling peak velocity to early diastolic mitra

81 g ratio, deceleration time of early filling, diastolic filling period and atrial filling fraction wer

82 At similar declines in the diastolic filling period, end-diastolic volume index (ED

83 delity catheters to compare left ventricular diastolic filling pressures (pre-A wave left ventricular

84 blood pressure (-1 vs. +7 mm Hg), and early diastolic filling rate (+1.7 vs. +2.4 end-diastolic volu

85 V ejection fraction (p = 0.006) and LV early diastolic filling rate (p = 0.001), which decreased over

86 The only gender difference was in diastolic filling rate, which was similar in the young m

87 a, LV longitudinal strain rate, and LV early diastolic filling rate.

88 cardiac parameters, including reduced early diastolic filling rates as well as a higher prevalence o

89 al relaxation, pseudonormal, and restrictive diastolic filling, respectively.

90 Heart rate, BP, systolic function, and diastolic filling responses to parasympathetic withdrawa

91 ved for measures of LV systolic function and diastolic filling (RHO from 0.71 to 0.57).

92 ventional echocardiographic and parametrized diastolic filling stiffness (k) and relaxation (c) param

93 The changes in longitudinal diastolic filling strains between 1 and 12 weeks, howeve

94 ns beat by beat in each patient, but overall diastolic filling tended to normalize with an increase o

95 gnose and treat the various abnormalities of diastolic filling that occur in patients with heart dise

96 1), together with a significant reduction in diastolic filling time (377 +/- 138 ms to 300 +/- 118 ms

97 locities, E/A ratio, deceleration time [DT], diastolic filling time [DFT], and isovolumic relaxation

98 n in relation to right ventricular ejection, diastolic filling time as a ratio of cycle length, and s

99 EF are typically exertional, optimization of diastolic filling time by controlling heart rate may del

100 Diastolic filling variables obtained with the SPECT soft

101 ucing the mitral ratio of peak early to late diastolic filling velocity (E/A).

102 dices reflective of atrial pressures and the diastolic filling volume.

103 Diastolic filling was determined by a simulated atrial p

104 eudonormal, and restrictive left ventricular diastolic filling were associated with hazard ratios of