ライフサイエンスコーパス: hypovolemia

1 d by hypernatremia or elevated AngII but not hypovolemia.

2 ic reflex vasoconstriction was stimulated by hypovolemia.

3 a, fever, leukocytosis, hypoalbuminemia, and hypovolemia.

4 ic shock caused by myocardial depression and hypovolemia.

5 -mediated amplification of histamine-induced hypovolemia.

6 suggesting greater ability to defend against hypovolemia.

7 ith acute tubular necrosis in the absence of hypovolemia.

8 than 2 mmol/L (>18 mg/dL) in the absence of hypovolemia.

9 ythrocytes in the microcirculation, not from hypovolemia.

10 loading in the critically ill with presumed hypovolemia.

11 onditions of severe hemodilution followed by hypovolemia.

12 w-sodium and high-aldosterone states such as hypovolemia.

13 on, CSF leak, low pressure headache, and CSF hypovolemia.

14 e useful to reduce organ injury after severe hypovolemia.

15 tes in an adult porcine model of hemorrhagic hypovolemia.

16 this pediatric porcine model of hemorrhagic hypovolemia.

17 of dependent extremities with redistributive hypovolemia.

18 ng orthostatic stress after HDTBR than after hypovolemia.

19 5) after HDTBR and by 18+/-8% (P<0.05) after hypovolemia.

20 is not seen with equivalent degrees of acute hypovolemia.

21 to saline infusion to correct the underlying hypovolemia.

22 cardiac disease (9%), drug effects (9%), and hypovolemia (7%).

23 function developing unexplained ARF without hypovolemia after administration of vancomycin without c

24 ction: P < 0.01) were higher during moderate hypovolemia after ketamine vs. placebo administration (P

25 e and heart rate were higher during moderate hypovolemia after ketamine vs. placebo administration.

26 uring orthostatic stress after bed rest than hypovolemia alone, potentially contributing to orthostat

27 le was decreased after HDTBR; however, after hypovolemia alone, the curve was identical, with no chan

28 to head-down tilt bed rest (HDTBR) or acute hypovolemia alone.

29 However, hypovolemia also elicited changes in capillary volume, s

30 A dynamic orthostatic hypovolemia and alpha1-adrenoreceptor hypersensitivity h

31 tolerance after bed rest is characterized by hypovolemia and an excessive reduction in stroke volume

32 d can lead to hypochloremia and subsequently hypovolemia and decreased glomerular filtration rate.

33 ry state of cirrhosis that leads to relative hypovolemia and decreased renal blood flow, patients wit

34 ra were recorded every 10 mins during serial hypovolemia and during a 30-min recovery period.

35 ginine vasopressin (AVP) are elevated during hypovolemia and during cardiac stress.

36 achycardia syndrome (POTS) to counteract the hypovolemia and elevated plasma norepinephrine that cont

37 aria and metabolic acidosis have evidence of hypovolemia and evidence of cardiac dysfunction.

38 er warning signs of severe dengue, including hypovolemia and fluid accumulation, were associated with

39 d characterized by neonatal life-threatening hypovolemia and hyperkalemia.

40 o-baboon kidney transplantation, episodes of hypovolemia and hypotension from an unexplained mechanis

41 Central hypovolemia and impending cardiovascular collapse were i

42 iated with an increased tolerance to central hypovolemia and increased levels of circulating norepine

43 ion was associated with progressive signs of hypovolemia and increased plasma levels of interleukin-6

44 s associated with IOT are principally due to hypovolemia and loss of adequate lower-extremity vascula

45 dy was, therefore, to explore the effects of hypovolemia and pain on tissue oxygen saturation (measur

46 easurement sites) and perfusion index during hypovolemia and pain than during normovolemia and pain.

47 Fatal cases had features of relative hypovolemia and reduced cardiac index reserve.

48 Development of severe IgE-mediated hypovolemia and shock required VE-restricted ABL1 expres

49 Enhanced postural thoracic hypovolemia and splanchnic hypervolemia are associated w

50 al fainting is related to excessive thoracic hypovolemia and splanchnic hypervolemia during orthostas

51 criteria to accurately capture patients with hypovolemia and tissue hypoperfusion who are most likely

52 itral valve (MV) occurring in the setting of hypovolemia and/or inotrope usage.

53 ., pulmonary embolism, cardiac tamponade, or hypovolemia, and signal the return of ventricular contra

54 ropsy and histology ruled out hemorrhage and hypovolemia as causes of death.

55 Many diseases, such as sepsis, hypovolemia, atrial fibrillation, congestive heart failu

56 fluid status to avoid volume overload and/or hypovolemia, avoiding hypo- and/or hypertension, treatin

57 ne do not suppress CRH gene activation after hypovolemia, but instead determine the prestress lower l

58 tion suppresses CRH gene transcription after hypovolemia, but not the preproenkephalin and c-fos mRNA

59 tate levels at admission without evidence of hypovolemia, cardiogenic failure, or vasodilatory shock.

60 Hypovolemia caused an increase in flow heterogeneity in

61 In experimental animals after 4 hours of hypovolemia, corticosterone dropped to 308.9 ng/mL (P =

62 nsion, low CSF pressure, low CSF volume, CSF hypovolemia, CSF hypovolaemia, spontaneous spinal CSF le

63 L/kg/min led to the following changes during hypovolemia: decreases in mean arterial blood pressure (

64 appropriately activating the CRH gene during hypovolemia, does not mediate the suppressed gene respon

65 dizziness is required to clinically diagnose hypovolemia due to blood loss, although these findings a

66 sufficient fluid intake and is distinct from hypovolemia due to excess fluid losses.

67 illness induces capillary leak resulting in hypovolemia, edema, tissue dysoxia, organ failure and ev

68 increased infection risk, cold diuresis and hypovolemia, electrolyte disorders, insulin resistance,

69 of which include hyponatremia, hyperkalemia, hypovolemia, elevated plasma renin activity, and sometim

70 Safety outcomes were hypovolemia, fractures, falls, genital infections, diabe

71 le diameter was 32 mm (95% CI, 29-35) in the hypovolemia group, 29 mm (95% CI, 26-32) in the hyperkal

72 resuscitation from cardiac arrest caused by hypovolemia, hyperkalemia, and primary arrhythmia.

73 resuscitation from cardiac arrest caused by hypovolemia, hyperkalemia, or primary arrhythmia (i.e.,

74 assigned to cardiac arrest caused by either hypovolemia, hyperkalemia, or primary arrhythmia.

75 d renal loss of NaCl, K+, and water, causing hypovolemia, hypokalemia, and polyuria.

76 also common, including sodium depletion and hypovolemia, hypophosphatemia and hypomagnesemia.

77 namic instability during progressive central hypovolemia in humans.

78 The treatment of hypovolemia in patients with non-cerebral trauma should

79 ex are proposed as early indirect markers of hypovolemia in trauma patients.

80 saturation and perfusion index as markers of hypovolemia in trauma patients.

81 sly assessed in a pediatric porcine model of hypovolemia induced by hemorrhage.

82 M NaCl, in addition to water, in response to hypovolemia induced by subcutaneous injection of 30% pol

83 Of the 320 cases, 153 were hypovolemia-induced AKI (48%), 93 were HRS-AKI (29%), 39

84 d by 20+/-4% after HDTBR and by 7+/-2% after hypovolemia (interaction P<0.001).

85 Hypovolemia is associated with increased sympathetic ner

86 Intravascular hypovolemia is common at the time of anesthesia inductio

87 rdial contractility or induce hypotension if hypovolemia is corrected, and preliminary evidence sugge

88 Both HDTBR and hypovolemia led to a similar reduction in plasma volume.

89 n and perfusion index are further reduced by hypovolemia (lower body negative pressure, -60 mm Hg).

90 The etiologies of shock unrelated to hypovolemia must also be investigated.

91 ents, its effect on the indirect measures of hypovolemia needs to be clarified.

92 RBC velocity in septic shock, heart failure, hypovolemia, obstructive shock, and hemodilution and thu

93 recognition of complicating physiology (eg, hypovolemia or cardiogenic shock), while invasive hemody

94 ption or maximal K+ secretion in response to hypovolemia or hyperkalemia, respectively.

95 ation from the scaling relation may indicate hypovolemia or hypervolemia and aid diagnosis.

96 ndogenous generation of Ang II during either hypovolemia or hypotension.

97 bolus of 10 ml per kilogram in patients with hypovolemia or no bolus in patients with normovolemia, f

98 - areas previously shown to be activated by hypovolemia or peripheral angiotensin.

99 PEG; a colloid that produces non-hypotensive hypovolemia) or isoproterenol (hypotensive agent).

100 Hg) without increasing risk of hypotension, hypovolemia, or other serious adverse events, irrespecti

101 ossible underlying pathophysiologies include hypovolemia, partial dysautonomia, or a primary hyperadr

102 ce of a dry axilla supports the diagnosis of hypovolemia (positive likelihood ratio, 2.8; 95% CI, 1.4

103 by drinking hypertonic saline) and sustained hypovolemia (produced by subcutaneous injections of poly

104 Irreversible hypovolemia remains a major clinical problem.

105 aC persisted at day 5 in nephrotic mice when hypovolemia resolved and steady-state was reached.

106 identified as massive pulmonary embolism and hypovolemia, respectively.

107 Treatment with L-NAME during hypovolemia resulted in increased log low-frequency hear

108 After 50% hemorrhage followed by 1 hour of hypovolemia resuscitation with 35% of blood volume using

109 d finger perfusion index were reduced during hypovolemia/sham compared with normovolemia/sham.

110 activation in a setting of left ventricular hypovolemia stimulates ventricular afferents that trigge

111 analysis, the right ventricle was larger for hypovolemia than for primary arrhythmia (p < 0.001).

112 ot been studied with the concomitant central hypovolemia that occurs during haemorrhage.

113 Among ICU patients with hypovolemia, the use of colloids vs crystalloids did not

114 efill (2C); for septic shock associated with hypovolemia, the use of crystalloids or albumin to deliv

115 tabolic acidosis is frequently attributed to hypovolemia, tissue hypoperfusion, and lactic acidosis.

116 nduced tissue hypoperfusion and suspicion of hypovolemia to achieve a minimum of 30 mL/kg of crystall

117 toire of putative clinical applications from hypovolemia to Alzheimer's disease.

118 ting to emergency departments with suspected hypovolemia, usually due to vomiting, diarrhea, or decre

119 rats with APX also was observed when marked hypovolemia was induced by s.c. administration of a hype

120 Central hypovolemia was induced with lower body negative pressur

121 Hypovolemia was maintained for 60 mins in test animals,

122 85 mL/kg) every 10 mins until 30% cumulative hypovolemia was reached.

123 Hypovolemia with reduced oxygen delivery and microvascul

124 ase in arterial pressure without evidence of hypovolemia, with a systolic pressure lower than 90 mm H