ライフサイエンスコーパス: heart surgery

1 nital heart defects continue to require open-heart surgery.

2 hypertension, and atrial scars from previous heart surgery.

3 eterization performed early after congenital heart surgery.

4 ications and outcomes in patients after open-heart surgery.

5 e complications and one-year mortality after heart surgery.

6 less than one year of age who underwent open-heart surgery.

7 ly, this may result in completely endoscopic heart surgery.

8 botic technology for totally endoscopic open heart surgery.

9 erative factors for children undergoing open heart surgery.

10 edated in the intensive care unit after open heart surgery.

11 ivery in the first 24 hours after congenital heart surgery.

12 on (FTR) is often left untreated during left heart surgery.

13 rain in a cohort of neonates undergoing open-heart surgery.

14 e detected preoperatively in patients having heart surgery.

15 st common operations performed in congenital heart surgery.

16 dy may be improving outcome after congenital heart surgery.

17 procedure in infants who had undergone open heart surgery.

18 ients aged 60 years or older undergoing open-heart surgery.

19 factors into ischemic myocardium during open-heart surgery.

20 supplementation in children undergoing open-heart surgery.

21 days) versus placebo immediately after open heart surgery.

22 range of operative procedures in congenital heart surgery.

23 provision (inhaled NO) before and after open heart surgery.

24 was defined as a history of heart attack or heart surgery.

25 lation and decrease hospital stay after open heart surgery.

26 range of operative procedures in congenital heart surgery.

27 placement, and cannulation of the aorta for heart surgery.

28 artery bypass graft surgery and/or valvular heart surgery.

29 tive period for patients undergoing valvular heart surgery.

30 (CS) was measured in 32 patients during open heart surgery.

31 accident victims, and 2 patients undergoing heart surgery.

32 ongly promote thrombus formation during open heart surgery.

33 ients in the postoperative period after open heart surgery.

34 n the early postoperative period after right heart surgery.

35 cardioplegia on blood component usage after heart surgery.

36 butamine, a drug commonly administered after heart surgery.

37 y outcomes in children undergoing congenital heart surgery.

38 thetic valve degeneration involves redo open-heart surgery.

39 ler unit water tanks to patients during open-heart surgery.

40 th to 9 years duration) were studied at open heart surgery.

41 41) and non-DM (n = 37) patients undergoing heart surgery.

42 rom patients undergoing clinically indicated heart surgery.

43 population but not among patients undergoing heart surgery.

44 ostoperative management following congenital heart surgery.

45 in children with shock following congenital heart surgery.

46 mellitus, renal failure, and history of open heart surgery.

47 lantation of a prosthetic valve without open heart surgery.

48 malities among infants undergoing reparative heart surgery.

49 in the unstretched valves despite sham open heart surgery.

50 , and morbid events after complex congenital heart surgery.

51 surgeons without specialization in pediatric heart surgery.

52 to influence early outcomes after congenital heart surgery.

53 rare but devastating complication following heart surgery.

54 ngenital heart disease before they underwent heart surgery.

55 life that patients usually experience after heart surgery.

56 of the past year's literature on congenital heart surgery.

57 .0%), pericardial complications (1.4%), open heart surgery (0.2%), and postoperative respiratory fail

58 stent and LSP AF in patients undergoing open heart surgery (1) to test the hypothesis that persistent

59 omplexity: the Risk Adjustment in Congenital Heart Surgery-1 and the Aristotle Complexity Score.

60 for pancreatic resection, 138 for pediatric heart surgery, 195 for repair of abdominal aortic aneury

61 inimum caseload: craniotomy (33%), pediatric heart surgery (25%), repair of abdominal aortic aneurysm

62 Of 575 infants who underwent congenital heart surgery, 34 (6%) sustained a documented cardiac ar

63 (n=482) had a higher frequency of prior open heart surgery (44.0%) than patients from Ohio (n=6046) (

64 to >15 years' duration) were studied at open heart surgery, 8 before and 1 during cardiopulmonary byp

65 erse outcome with CABG, including prior open-heart surgery, age >70 years, left ventricular ejection

66 ied using the Risk Adjustment for Congenital Heart Surgery algorithm.

67 id and accurate in predicting ARF after open-heart surgery; along with increasing its clinical utilit

68 ch is employed, which requires multiple open-heart surgeries and significant attendant morbidity and

69 on the atria of patients at the time of open heart surgery and brought out through the anterior chest

70 een STAT3 and miR-21 that is activated after heart surgery and can contribute to atrial fibrillation.

71 sfunction commonly associated with pediatric heart surgery and cardiopulmonary bypass.

72 ionwide population-based study on congenital heart surgery and catheter-based interventions, unbiased

73 /- 43 mg/day) started 24 to 48 h before open heart surgery and continued for four days postoperativel

74 hrombotic and bleeding complications of open heart surgery and is produced by cleavage of prothrombin

75 detomidine is commonly used after congenital heart surgery and may be associated with a decreased inc

76 rial fibrillation occurs commonly after open-heart surgery and may delay hospital discharge.

77 ased interventions, with elimination of open heart surgery and new electronic devices enabling, for e

78 edures with prolonged ischemia, such as open heart surgery and organ transplant.

79 nges in key metabolites following congenital heart surgery and to examine the potential of metabolic

80 t transfusion practices following congenital heart surgery are showing promise in reducing donor expo

81 infants with cardiac arrest after congenital heart surgery are unknown.

82 (0 to 18 years of age) undergoing congenital heart surgery at 38 US centers from 2003 to 2008.

83 ca sternotomy site infections following open heart surgery at hospital A.

84 A total of 33,217 patients underwent open-heart surgery at the Cleveland Clinic Foundation (1993 t

85 patients (63 +/- 9.1 years) undergoing open-heart surgery at the San Diego Veterans Administration H

86 ficantly reduces the prevalence of post-open heart surgery atrial fibrillation.

87 evaluation of quality of care in congenital heart surgery based on the complexity of the surgical pr

88 onstruction typically involves multiple open-heart surgeries because all existing graft materials hav

89 performed within six weeks after congenital heart surgery between August 1995 and January 2001 were

90 frequency of atrial fibrillation after open-heart surgery but the effectiveness of oral amiodarone i

91 g the incidence of atrial fibrillation after heart surgery, but did not significantly alter length of

92 jor morbidity and mortality after congenital heart surgery, but its mechanism remains unclear.

93 mics in children with shock after congenital heart surgery, but the adverse effects of the therapy in

94 ease have been given a new chance at life by heart surgery, but the potential for neurological injury

95 At the time of ICU admission after open heart surgery, clinical criteria are evident that highli

96 ed with acute renal failure (ARF) after open-heart surgery continues to be distressingly high.

97 alternative to one of the foundational open-heart surgeries currently performed to treat single-vent

98 the Society of Thoracic Surgeons Congenital Heart Surgery Database (STS-CHSD) will begin voluntary p

99 the Society of Thoracic Surgeons Congenital Heart Surgery Database between January 1, 2010, and Dece

100 the Society of Thoracic Surgeons-Congenital Heart Surgery Database to examine associations between s

101 the Society of Thoracic Surgeons Congenital Heart Surgery Database who underwent cardiac surgery bet

102 Although surgical LAA exclusion during heart surgery does not seem to add incremental harm, the

103 ents presenting with an ACS who undergo open-heart surgery during the same hospitalization is associa

104 ical management of heart failure, early open heart surgery (endocardectomy and valve repair/replaceme

105 eart transplantation after failed congenital heart surgery, especially after failed single-ventricle

106 clusion does not add significant harm during heart surgery for another indication, but evidence on st

107 logic outcomes following neonatal and infant heart surgery for complex congenital heart lesions.

108 Twenty-eight patients who underwent open-heart surgery for congenital heart defects.

109 in the early postoperative period after open heart surgery for congenital heart disease (CHD).

110 enoxaparin (n=151) before proceeding to open heart surgery for urgent therapy during the same hospita

111 hort time period, mortality after congenital heart surgery has been reduced substantially in Guatemal

112 Open heart surgery has long been considered the gold standard

113 fants who have transient seizures after open heart surgery has not been studied.

114 Many infants who undergo heart surgery have a congenital cyanotic defect in which

115 Advances in congenital heart surgery have resulted in the increased survival of

116 US News & World Report list of top heart and heart surgery hospitals performed on acute myocardial in

117 the US News & World Report top 50 heart and heart surgery hospitals.

118 ith symptomatic aortic stenosis without open-heart surgery; however, the benefits are mitigated by th

119 that it may reduce the total number of open heart surgeries in these patients.

120 underwent coronary artery bypass or valvular heart surgery in 43 Department of Veterans Affairs medic

121 as) frequently complicate recovery from open heart surgery in children and can be difficult to manage

122 se of CA to support vital organs during open heart surgery in infancy is associated, at the age of 4

123 enic peptides or plasmid vectors during open heart surgery in patients.

124 Open heart surgery in the fetus has yet to be done successful

125 in 13 of 15 patients (87%) after congenital heart surgery, in the posterior subannular region of the

126 rt Team was to refer the patient for an open-heart surgery, in which two thrombi were removed.

127 sks associated with pediatric reconstructive heart surgery include injury of the sinoatrial node (SAN

128 cember 2006 through April 2008) in the major heart surgery intensive care unit (MHS-ICU) of our insti

129 In survivors of congenital heart surgery, intra-atrial reentrant tachycardia (IART)

130 Congenital heart surgery is a constantly evolving specialty informe

131 on of the median sternotomy wound after open heart surgery is a devastating complication associated w

132 Congenital heart surgery is a young and constantly evolving field.

133 Congenital heart surgery is an evolving field.

134 d-crystalloid cardioplegia in pediatric open heart surgery is dependent on age and degree of cyanosis

135 Fluid overload after congenital heart surgery is frequent and a major cause of morbidity

136 mental outcomes in children who undergo open heart surgery is hampered by the absence of a suitable c

137 The field of congenital heart surgery is poised to incorporate new innovations s

138 cidence of tachyarrhythmias after congenital heart surgery, it may be associated with increased odds

139 of the approach in pediatric reconstructive heart surgery may reduce risks of injuring nodal tissues

140 al tachyarrhythmias in our young canine open heart surgery model.

141 rwent early intervention (188 [25%] had open heart surgery, most commonly coronary artery bypass graf

142 and at least one of five risk factors (prior heart surgery, myocardial infarction within seven days,

143 lled trial in which patients undergoing open-heart surgery (n=220, average age 73 years) received ami

144 set, created by the International Congenital Heart Surgery Nomenclature and Database Project, are now

145 Children undergoing congenital heart surgery often receive corticosteroids with the aim

146 hes to carotid revascularization in the open heart surgery (OHS) population.

147 rtery stenosis (ARAS) on outcomes after open-heart surgery (OHS).

148 n a cohort of children undergoing congenital heart surgery on cardiopulmonary bypass.

149 Acutely, following congenital heart surgery or chronically, studies now indicate that

150 Heart surgery or transplantation generally involve globa

151 iology); myocardial preservation during open-heart surgery; organ preservation for transplantation; a

152 maera infections were diagnosed in 2012 in 2 heart surgery patients on extracorporeal circulation.

153 tudy comparing case-patients (n=5) with open heart surgery patients without subsequent sternotomy sit

154 the past two decades, advances in congenital heart surgery, pediatric cardiology, and intensive care

155 the last two decades advances in congenital heart surgery, pediatric cardiology, and pediatric inten

156 In some children undergoing open heart surgery, plasma arginine vasopressin concentration

157 The risk adjustment for congenital heart surgery (RACHS-1) method was used to adjust for ca

158 pe of surgery (Risk Adjustment in Congenital Heart Surgery [RACHS-1] category), center, and center vo

159 gh-dose milrinone after pediatric congenital heart surgery reduces the risk of LCOS.

160 nths and weighting 22+/-4 kg, underwent open heart surgery replicating a nontransannular approach to

161 Thirty-four patients had undergoing heart surgery requiring cardiopulmonary bypass within th

162 und) are an important cause of stroke during heart surgery requiring cardiopulmonary bypass.

163 adjusting for Risk Adjustment for Congenital Heart Surgery risk category, premature birth, major nonc

164 f disease severity (Risk Adjusted Congenital heart surgery score-1, Pediatric Logistic Organ Dysfunct

165 In contrast to open heart surgery, TAVR does not offer the opportunity to me

166 In children undergoing complex congenital heart surgery, the optimal postoperative glucose range m

167 Before coronary angioplasty and heart surgery, these preconditioning mimetics might be u

168 es associated with corrective and palliative heart surgery to antenatal and preoperative factors gove

169 of the heart in a young canine model of open heart surgery to control 2 common postoperative supraven

170 aluable in minimally invasive surgery and in heart surgery to correct congenital defects.

171 other complications compared with MPN (open heart surgery to repair cardiac laceration [6 versus 0],

172 ng of chronic AF in patients undergoing open heart surgery to test the hypothesis that chronic AF is

173 actors for poor outcome, including age, open heart surgery, tricuspid insufficiency (TI), cardiac rhy

174 sequelae continue to occur in neonates after heart surgery using deep hypothermic cardiopulmonary byp

175 re studied immediately before and after open heart surgery using simultaneous LA pressure measurement

176 The presence of CON regulations for open heart surgery was ascertained from the National Director

177 f cardiac arrest in infants after congenital heart surgery was better than that for pediatric intensi

178 vital organ support strategy used in infant heart surgery was total circulatory arrest (CA) or low-f

179 rge cohort of patients undergoing congenital heart surgery, we examined for an association between de

180 l analysis of children undergoing congenital heart surgery, we were unable to demonstrate a significa

181 zed fashion, 118 patients who underwent open heart surgery were assigned to right atrial pacing at 45

182 ee hundred patients undergoing standard open heart surgery were randomized in a double-blind fashion

183 n 34.5+/-44.1 months of age) undergoing open-heart surgery were selected to either alpha-stat (n=51)

184 enting with ACS may be sent directly to open heart surgery while still on anticoagulation, it is impo

185 ed decline in mortality following congenital heart surgery, while important, also has resulted in an

186 ril 2005 including 1,084 patients undergoing heart surgery who were admitted into the fast-track unit

187 s now increasingly used following congenital heart surgery with a low associated incidence of organ f

188 acceptably high risk for mortality from open heart surgery with cardiopulmonary bypass in the setting

189 children younger than 2 years old undergoing heart surgery with cardiopulmonary bypass.

190 ut hypoxic stress (cyanosis) undergoing open heart surgery with cold-crystalloid cardioplegia were in

191 ertificate-of-need (CON) regulation for open heart surgery with higher hospital coronary artery bypas

192 dren (age, 5.4 +/- 2.1 years) and after open-heart surgery without allograft implantation in 11 age-m