ライフサイエンスコーパス: cardiac electrophysiology

1 cAAV) without causing any adverse effects on cardiac electrophysiology.

2 ical action of endogenous miRs in modulating cardiac electrophysiology.

3 r applications in biochemistry, ecology, and cardiac electrophysiology.

4 ping and made a major impact on the field of cardiac electrophysiology.

5 , we sought to determine the role of RFFL in cardiac electrophysiology.

6 used to address current clinical problems in cardiac electrophysiology.

7 CE, a fully automated system for all-optical cardiac electrophysiology.

8 ial duration, recapitulating key features of cardiac electrophysiology.

9 We sought to determine the role of RNF207 in cardiac electrophysiology.

10 remain one of the most intriguing enigmas of cardiac electrophysiology.

11 ple important advances in the field clinical cardiac electrophysiology.

12 oscience, but also in other areas, including cardiac electrophysiology.

13 nding of the regulation of hERG channels and cardiac electrophysiology.

14 sting an as-yet unknown role for Na(V)1.8 in cardiac electrophysiology.

15 vancement in elucidating basic mechanisms in cardiac electrophysiology.

16 is a rapidly growing aspect of computational cardiac electrophysiology.

17 eading to As(2)O(3)-induced abnormalities of cardiac electrophysiology.

18 ia on defibrillation energy requirements and cardiac electrophysiology.

19 of these advances in the realm of pediatric cardiac electrophysiology.

20 channel antagonists have diverse effects on cardiac electrophysiology.

21 heel experiment, a fundamental experiment in cardiac electrophysiology.

22 Wild-type animals had completely normal cardiac electrophysiology.

23 icate that SCN10A plays an important role in cardiac electrophysiology.

24 t perturbations and regulate 24 h rhythms in cardiac electrophysiology.

25 d, Langendorff-perfused rat hearts to assess cardiac electrophysiology after MEHP exposure compared w

26 ocardial ischemia, profound changes occur in cardiac electrophysiology and anatomy, influencing actio

27 hallenges and the perspectives for ML-driven cardiac electrophysiology and arrhythmia research.

28 ion of numerous biological events, including cardiac electrophysiology and arrhythmia, through a cano

29 ovides a comprehensive analysis of models of cardiac electrophysiology and arrhythmias, from the sing

30 n are the other aspects of ML application in cardiac electrophysiology and arrhythmias, such as those

31 ffects of therapy in 3 cardiovascular areas: cardiac electrophysiology and arrhythmias, the vasculatu

32 effects of a human connexin channelopathy on cardiac electrophysiology and arrhythmogenesis, we gener

33 plays an important role in the modulation of cardiac electrophysiology and arrhythmogenesis.

34 were anesthetized and instrumented to assess cardiac electrophysiology and blood pressure.

35 Cardiac electrophysiology and Ca(2+) handling change rap

36 has been driven by two initial applications: cardiac electrophysiology and cancer development.

37 esistance, and increased afterload may alter cardiac electrophysiology and contribute to life-threate

38 l staff working in interventional cardiology/cardiac electrophysiology and correlate them with the le

39 nd the applications of whole-heart models in cardiac electrophysiology and electromechanics research

40 eterogeneity has a profound effect on normal cardiac electrophysiology and genesis of cardiac arrhyth

41 teraction screens provides new insights into cardiac electrophysiology and identifies new candidate g

42 Recent advances in cardiac electrophysiology and imaging have improved our

43 antithrombotic approaches used in different cardiac electrophysiology and interventional procedures

44 iew of organ-level computational modeling of cardiac electrophysiology and its clinical applications

45 en should yield novel tools for the study of cardiac electrophysiology and may lead to novel therapeu

46 Real-time image integration of cardiac electrophysiology and mechanics offers new oppor

47 tand issues such as adrenergic regulation of cardiac electrophysiology and mechanisms of susceptibili

48 we discuss mathematical modelling studies in cardiac electrophysiology and neuroscience that have enh

49 exchange of state-of-the-art information in cardiac electrophysiology and pacing.

50 Daily variations in cardiac electrophysiology and the incidence for differen

51 rmone levels are required to maintain normal cardiac electrophysiology and to prevent cardiac arrhyth

52 EETs regulate cardiac electrophysiology and vascular tone by KATP chan

53 roaches, their contributions to the field of cardiac electrophysiology, and future directions of vari

54 results in impaired ICD structure, abnormal cardiac electrophysiology, and ultimately cardiomyopathy

55 Mathematical models of cardiac electrophysiology are instrumental in determinin

56 -of-day variation; however, daily changes in cardiac electrophysiology, arrhythmia susceptibility, an

57 ese strategies may be applicable not just in cardiac electrophysiology, but in a wide range of discip

58 del reveals a complex temporal regulation of cardiac electrophysiology by temperature, hypokalaemia,

59 hearts have strong time-of-day variation in cardiac electrophysiology, Ca(2+) handling, and adrenerg

60 unctional impact of DeltaPsim instability on cardiac electrophysiology, Ca(2+) handling, and even cel

61 Hypothermia profoundly affected cardiac electrophysiology, decreasing ventricular fibril

62 tive models and computational simulations of cardiac electrophysiology depend on precise anatomical r

63 ne are scarce, although transient effects on cardiac electrophysiology (electrocardiographic QT inter

64 implanted with telemeters to monitor HR and cardiac electrophysiology [electrocardiography (ECG)] we

65 produce a substrate for AF, we have studied cardiac electrophysiology (EP) and inducibility of atria

66 cialties within cardiology, <10% of clinical cardiac electrophysiology (EP) fellows are women.

67 The field of cardiac electrophysiology (EP) had adopted simple artifi

68 S) guidance is increasingly used in invasive cardiac electrophysiology (EP) procedures for femoral va

69 disciplinary group of experts in cardiology, cardiac electrophysiology, epidemiology, and SDM, as wel

70 iew, we focus on acute mechanical effects on cardiac electrophysiology, explore molecular candidates

71 We then examined the changes in cardiac electrophysiology following injection of adenovi

72 The field of cardiac electrophysiology has been on the cutting edge o

73 Drugs with overt effects on cardiac electrophysiology have failed in the clinic owin

74 ground genotypes, and lifestyles, we studied cardiac electrophysiology, hypertrophy, and histopatholo

75 on the integrative role of K(+) channels in cardiac electrophysiology, i.e. how K(+) currents shape

76 lowering financial thresholds, this powerful cardiac electrophysiology imaging modality may gain wide

77 pathophysiology of the ionic basis of human cardiac electrophysiology in health and disease.

78 that dietary fish intake is associated with cardiac electrophysiology in humans, including heart rat

79 l consumption directly or indirectly affects cardiac electrophysiology in humans.

80 -scale computational modeling in general and cardiac electrophysiology in particular.

81 are Medicine, Endocrinology, Cardiology, and Cardiac Electrophysiology in the hope that it will facil

82 posure, using a clinically relevant dose, on cardiac electrophysiology in the intact heart.

83 (f/f)/alphaMyHC-Cre) mice and analyzed their cardiac electrophysiology in vivo and in vitro.

84 limited by their degree of homology to human cardiac electrophysiology, including ion channel express

85 Tissue-scale simulations of cardiac electrophysiology, incorporating both dynamic ac

86 The complexity of cardiac electrophysiology, involving dynamic changes in

87 Cardiac electrophysiology is one of the most advanced ar

88 Cardiac electrophysiology is regulated by continuous tra

89 ne of the most rapidly growing procedures in cardiac electrophysiology, is associated with magnetic r

90 ll one of the most challenging procedures in cardiac electrophysiology, limited, in part, by unmappab

91 diographic imaging (a method for noninvasive cardiac electrophysiology mapping) and advanced late gad

92 A new mouse cardiac electrophysiology method was used to study mice

93 In the field of cardiac electrophysiology, ML applications have also see

94 We developed an in silico cardiac electrophysiology model of a transmural cross se

95 ion restitution to create reaction-diffusion cardiac electrophysiology models.

96 ar, particularly in large animal models with cardiac electrophysiology more similar to humans than pr

97 rdic model of arrhythmogenesis, an aspect of cardiac electrophysiology not previously recapitulated i

98 ate dimeglumine has no detrimental effect on cardiac electrophysiology or other safety parameters in

99 ption, recruited from general cardiology and cardiac electrophysiology outpatient clinics from Septem

100 and impacted healthcare delivery, including cardiac electrophysiology practice throughout the globe.

101 ltiscale mechanistic computational models of cardiac electrophysiology provide precise control over i

102 Fluorescent reporters of cardiac electrophysiology provide valuable information o

103 Cardiac electrophysiology simulation is a mature area of

104 ormula: see text]-ep provides easy access to cardiac electrophysiology simulations for a wide user co

105 hysiology have been an integral component of cardiac electrophysiology since its inception, and are c

106 A large number of cardiac electrophysiology studies have been enabled and

107 t describes a novel in vivo mouse epicardial cardiac electrophysiology study based on clinical protoc

108 priately selected procedures in the field of cardiac electrophysiology (such as intracardiac ablation

109 O(3) exposure causes several alterations in cardiac electrophysiology that are likely mediated by mo

110 bout fundamental mechanisms underlying human cardiac electrophysiology that has come about because of

111 Despite dramatic differences in cardiac electrophysiology, the cardiac fight-or-flight r

112 ustion and e-cigarette byproduct, may impair cardiac electrophysiology through autonomic imbalance.

113 studies, with reference to recent studies in cardiac electrophysiology to illustrate key points.

114 , leukocyte surface markers, hemostasis, and cardiac electrophysiology were conducted to 24 hours pos

115 In an application to cardiac electrophysiology with 226 GWAS loci, only 46 (2

116 Scaling of cardiac electrophysiology with body mass requires large

117 We have seen advances in basic cardiac electrophysiology with data suggesting that secr

118 e changing clinical practice and research in cardiac electrophysiology, with emphasis on disease dete

119 s models and accurate methods for simulating cardiac electrophysiology within a high-performance fram