ライフサイエンスコーパス: fluid balance

1 ivates animals to drink in order to maintain fluid balance.

2 or the appropriate correction of a patient's fluid balance.

3 Y acts locally on the epithelium to modulate fluid balance.

4 rget of AVP and contribute to the control of fluid balance.

5 ed with a fall in insulin secretion and body fluid balance.

6 ressor use and a greater cumulative positive fluid balance.

7 this unique ENaC regulatory pathway in lung fluid balance.

8 -ATPase and contributes to renal handling of fluid balance.

9 ich appeared more related to sarcopenia than fluid balance.

10 ly ventilated, current smoking, and positive fluid balance.

11 play prominent roles in maintaining cellular fluid balance.

12 ntestine contributes importantly to systemic fluid balance.

13 logies associated with dysregulation of lung fluid balance.

14 rebrain regions implicated in the control of fluid balance.

15 lar epithelium is essential to maintain lung fluid balance.

16 ifferences in body weight, urine output, and fluid balance.

17 e, suggesting a role for AQP4 in Muller cell fluid balance.

18 and 1.39 (95% CI, 1.15-1.69) for cumulative fluid balance.

19 critical role in the maintenance of alveolar fluid balance.

20 hrs, was without effect on hemodynamics and fluid balance.

21 is required to develop a precise measure of fluid balance.

22 ne, renal hemodynamics, and renal sodium and fluid balance.

23 pear equally effective in achieving negative fluid balance.

24 osemide, titrated to achieve negative hourly fluid balance.

25 no correlation between HBP concentration and fluid balance.

26 e studies should consider correcting AKI for fluid balance.

27 d homeostasis and contribute to disorders of fluid balance.

28 I, 1.11-1.28) per liter increase in positive fluid balance.

29 eostasis as they help to maintain sodium and fluid balance.

30 lose monitoring of patient haemodynamics and fluid balance.

31 scular homeostasis and maintenance of tissue-fluid balance.

32 body MRI, isotope dilution, and nitrogen and fluid balances.

33 .83 (95% CI, 4.03-19.33), and for cumulative fluid balance 2.15 (95% CI, 1.51-3.07), at any time poin

34 aying resuscitation increased cumulative net fluid balances (2.1+/-0.5 mL/kg/hr, 2.8+/-0.7 mL/kg/hr,

35 atified according to quartiles of cumulative fluid balance 24 hours and 3 days after ICU admission.

36 y injury before but not after adjustment for fluid balance (31% vs. 11%, p = .005).

37 riteria both before and after adjustment for fluid balance (31% vs. 12%, p < .001) and those who had

38 injury both before and after adjustment for fluid balance (31% vs. 38%, p = .18).

39 Normothermia (38 +/- 0.5 degrees C), fluid balance (5 mL.kg(-1).hr(-1) normal saline), and an

40 HYS patients had a significantly reduced net fluid balance (65 vs 91 mL/kg, P = 0.02).

41 We computed intraoperative fluid balance, accounting for patient morphometry, cryst

42 terstitial fluid does not directly determine fluid balance across microvascular endothelium.

43 the effect of mesenchymal stem cells on lung fluid balance, acute inflammation, and bacterial clearan

44 were independent of base deficit, cumulative fluid balance, acute kidney injury, and other critical i

45 irway pressure), subjects with an overweight fluid-balance-adjusted body mass index had significantly

46 io 0.74 [95% confidence interval 0.59-0.94]) fluid-balance-adjusted body mass indices.

47 at aquaporins are important in neonatal lung fluid balance, adult lung fluid clearance and formation

48 ration index (BHI) is a composite measure of fluid balance after consuming a test beverage relative t

49 ty risk, increased fluid intake and positive fluid balance after ICU admission are associated with wo

50 ized hemodynamic support (including positive fluid balance), along with cardioprotective effects, mod

51 During intensive care unit stay, mean daily fluid balance among survivors was -234 mL/day compared w

52 roves oxygenation, with greater net negative fluid balance and better maintenance of hemodynamic stab

53 Conservative) resulted in a lower cumulative fluid balance and better outcomes than a liberal fluid p

54 a cardiac hormone involved in regulation of fluid balance and blood pressure homeostasis of mammalia

55 Arginine vasopressin (AVP) regulates fluid balance and blood pressure via AVP receptor (AVPR)

56 The patient's overall fluid balance and change in weight were recorded daily.

57 es the vasodilatory state, thereby improving fluid balance and glomerular filtration.

58 e present study was undertaken to assess the fluid balance and hemodynamic effects during the first 8

59 ificant inverse relationship existed between fluid balance and hemoglobin decline.

60 isease on the association between cumulative fluid balance and hospital mortality in critically ill s

61 ribute significantly in maintaining alveolar fluid balance and in resolving airspace edema.

62 ritical for regulation of blood pressure and fluid balance and influences cardiovascular remodeling.

63 Our exposure was intraoperative fluid balance and our primary outcome was the grade of a

64 f the association between post-ICU admission fluid balance and pediatric septic shock outcomes.

65 body mass index combined with daily positive fluid balance and positive end-expiratory pressure great

66 luate the association between intraoperative fluid balance and postoperative acute kidney injury (AKI

67 luate the association between intraoperative fluid balance and postoperative acute kidney injury (AKI

68 served no association between intraoperative fluid balance and postoperative AKI.

69 The ability to maintain fluid balance and prevent increased intracardiac filling

70 analyzed effects on BP, kidney function, and fluid balance and related this to renal clearance of diu

71 We found no association between fluid balance and renal recovery.

72 Observed associations between fluid balance and septic shock outcomes are likely confo

73 l knock-out mice revealed roles for OPCML in fluid balance and temperature regulation consistent with

74 ces in serum creatinine caused by changes in fluid balance and the impact of these differences on dia

75 : 1) identify an inverse association between fluid balance and ventilator-free days; and 2) determine

76 ed heart failure and commonly monitored with fluid balance and weight loss.

77 iofacial development, (3) ionoregulation and fluid balance, and (4) cholesterol synthesis and homeost

78 After adjusting for steroid administration, fluid balance, and baseline vasopressor score, T4 admini

79 Hemodynamic variables, volume shifts, fluid balance, and cardiac function were monitored durin

80 The lymphatic system maintains tissue fluid balance, and dysfunction of lymphatic vessels and

81 s duration of CT drainage, net perioperative fluid balance, and LOS after the Fontan operation.

82 mphatic system regulates interstitial tissue fluid balance, and lymphatic malfunction causes edema.

83 osures, routes of nutrition, blood products, fluid balance, and modes of ventilatory support.

84 Anesthesia, fluid balance, and normothermia were maintained.

85 Our exposure was intraoperative fluid balance, and our primary outcome was the grade of

86 of blood glucose concentration, temperature, fluid balance, and oxygenation.

87 score, day 0 vasopressor-inotrope score and fluid balance, and PaO2/FIO2 6 hours after pediatric acu

88 , blood urea nitrogen (BUN), creatinine, net fluid balance, and positive end-expiratory pressure.

89 regulate diverse functions such as motility, fluid balance, and sensory perception.

90 ive end-expiratory pressure, mean cumulative fluid balance, and the minimal ratio of arterial oxygen

91 euroendocrine control of energy homeostasis, fluid balance, and the stress response.

92 oendocrine regulation of energy homeostasis, fluid balance, and the stress response.

93 ssures (p < .05) without apparent effects on fluid balance, and was associated with a significantly (

94 CO, cardiac or renal impairment and positive fluid balance appear first hits, whereas suboptimal flui

95 that fluid overload and positive cumulative fluid balance are associated with increased mortality in

96 Acute kidney injury (AKI) and disordered fluid balance are common in premature neonates; a positi

97 Mandatory modes of ventilation and positive fluid balance are risk factors for ventilator-associated

98 it is unclear whether positive and negative fluid balances are associated with poor outcome compared

99 sed by intubation time, CICU length of stay, fluid balance, arterio-venous O2 difference (DeltaA-VO2)

100 nitoring was associated with a more positive fluid balance at 24 hrs.

101 stituted blood also had a smaller cumulative fluid balance at 48 hours (-6.9 ml per kilogram of body

102 Every 1-L increase in cumulative fluid balance at 72 hours of ICU admission was independe

103 Higher cumulative fluid balance at 72 hours of ICU admission was independe

104 t of patients with sepsis, higher cumulative fluid balance at day 3 but not in the first 24 hours aft

105 ents in the albumin group had a net negative fluid balance at the end of cardiopulmonary bypass compa

106 t identified a possible mediation effect for fluid balance (average causal mediation effect, 0.95; 95

107 0 mEq/L were older and had higher cumulative fluid balance, base deficit, and Sequential Organ Failur

108 Fluid balances became negative after the third ICU day i

109 NA expression of NKCC2 does not affect BP or fluid balance because of compensatory factors that resto

110 y restore normal electrolyte, acid-base, and fluid balance before renal recovery.

111 There was wide variation in fluid balance between hospitals (P < 0.001, all procedur

112 red for maintaining vascular homeostasis and fluid balance between the circulation and surrounding ti

113 difference in liver enzymes, hypotension, or fluid balance between treatment arms.

114 Fluid balance but not hemoglobin related to secondary in

115 ph pump system impacts not only interstitial fluid balance but other aspects of overall homeostasis.

116 criteria after adjustment of creatinine for fluid balance (but not before) had a mortality rate that

117 The lymphatic vasculature preserves tissue fluid balance by absorbing fluid and macromolecules and

118 e (defined as serum creatinine multiplied by fluid balance [calculated as percentage change from birt

119 ion between exposure to positive or negative fluid balance, compared with even fluid balance, on 1-ye

120 Using Gray's model, negative fluid balance, compared with even fluid balance, was ass

121 l patients, exposure to positive or negative fluid balance, compared with even fluid balance, was ass

122 Following propensity matching, positive fluid balance, compared with even or negative fluid bala

123 th acute kidney injury, exposure to positive fluid balance, compared with negative fluid balance, has

124 nce dilutes serum creatinine, and a negative fluid balance concentrates serum creatinine, both of whi

125 were associated with a relative reduction of fluid balance.Conclusions: Hyperlactatemia is powerfully

126 ion to control patients reduced net negative fluid balance; control patients more frequently develope

127 After fluid balance correction, 13 neonates with AKI were recl

128 During the OOD, weight change and net fluid balance correlated poorly with each other (r=0.36)

129 We characterized cumulative fluid balance cut-offs associated with hospital mortalit

130 ce (p =0.005) such that different cumulative fluid balance cut-offs with the best prognostic accuracy

131 Animals with higher fluid balance developed more ascites, which was associat

132 Fluid balance differed significantly between patients wi

133 are common in premature neonates; a positive fluid balance dilutes serum creatinine, and a negative f

134 r pathophysiological changes associated with fluid balance disorders including renal hypertension.

135 e of ingestive behaviours in regulating body fluid balance during 24 h HU.

136 reinforcement of the importance of adequate fluid balance during exercise are critical for both SCT

137 orize plays an important role in maintaining fluid balance during pregnancy, with possible implicatio

138 A negative mean daily fluid balance during study treatment was independently a

139 during the first 24 hours, percent positive fluid balance during the first 24 hours, and cumulative

140 The mean (+/-SE) cumulative fluid balance during the first seven days was -136+/-491

141 a more negative median (interquartile range) fluid balance during weaning (-2,320 [-4,735, 738] vs. -

142 history, development of atrial fibrillation, fluid balance, echocardiographic findings, medication ad

143 poor outcome compared to patients with even fluid balance (euvolemia).

144 nal age neonates are at risk of disorders of fluid balance (FB), defined as change in fluid weight ov

145 wn of HNS NKCC2 elicited profound effects on fluid balance following ingestion of a high-salt solutio

146 alveolar epithelial fluid transport and lung fluid balance from acute lung injury (ALI) in an ex vivo

147 Fluid overload was assessed as fluid balance from admission to continuous renal replace

148 Beyond intestinal fluid balance, GCC mediates diarrhea induced by bacteria

149 xtubation readiness, and daily discussion of fluid balance goals.

150 ngiogenesis is critically involved in tissue fluid balance, graft rejection, and tumor metastasis.

151 en shown to lower sepsis mortality, positive fluid balance has been associated with adverse outcomes.

152 mportant in modulating drinking behavior and fluid balance has led to numerous studies aimed at ident

153 sitive fluid balance, compared with negative fluid balance, has been associated with mortality and im

154 t is identified after adjusting for positive fluid balance have higher mortality rates, and patients

155 ey injury before but not after adjusting for fluid balance have lower mortality rates.

156 ultrafiltration and mortality is mediated by fluid balance, hemodynamic instability, or low potassium

157 luded change in weight, serum total protein, fluid balance, hemodynamics, respiratory system complian

158 rms, low Glasgow coma score, edema, positive fluid balance, high cardiac index, low PaO2/FIO2 ratio,

159 Highest fluid balance hospitals had significantly longer adjuste

160 High fluid balance hospitals have 12% to 14% longer risk-adju

161 This mortality risk associated with positive fluid balance, however, was attenuated by use of renal r

162 ks regulating cardiovascular homeostasis and fluid balance; however, the mechanisms of AngII signalin

163 ne in mice, protected against perturbed lung fluid balance in a bleomycin model of lung injury, highl

164 further adjusted for daily transfusions and fluid balance in a subset of our patients.

165 ransmembrane conductance regulator regulates fluid balance in alveolar epithelial cells and appears t

166 Cs or the conditioned medium restores normal fluid balance in an ex vivo perfused human lung injured

167 portant to understanding edema formation and fluid balance in both normal physiology and disease.

168 of ion channels is critical for maintaining fluid balance in epithelial tissues.

169 tribute to abnormalities in hemodynamics and fluid balance in heart failure through its actions on V(

170 stablishing the endothelial barrier and lung fluid balance in lung inflammatory diseases such as acut

171 ncrease in salt intake of 6 g/d would change fluid balance in men living under ultra-long-term contro

172 hemodynamics and achieving a lower daily net fluid balance in patients with cirrhosis and sepsis-indu

173 arrier, critical for maintaining the correct fluid balance in the brain, entails net secretion of HCO

174 ulmonary bypass compared with a net positive fluid balance in the crystalloid group.

175 Fluid intake, percent positive fluid balance in the first 24 hours, and cumulative perc

176 Fluid balance in the first 3 postnatal days and time to

177 ngoing food and water consumption will alter fluid balance in the future and then to adjust behaviour

178 gs, mechanical ventilation and mean positive fluid balance in the ICU > 1500 ml/24 hours, both during

179 GMP signaling is critical to electrolyte and fluid balance in the neonatal intestine.

180 th with higher quartiles of 3-day cumulative fluid balance in the whole population and after stratifi

181 d fluid accumulation resulted in similar net fluid balances in both groups within 12 hrs after the bu

182 ty analysis including daily transfusions and fluid balance (in a subset of 518 patients) did not qual

183 Estrogens affect body fluid balance, including sodium ingestion.

184 th pretreatment values, urine output and net fluid balance increased by 130% and 156%, respectively,

185 The cumulative fluid balance increased from 1,217 mL (-90 to 2,783 mL)

186 A higher fluid balance increased the time to extubation, to ICU d

187 A higher fluid balance increased the time to ICU discharge, and i

188 d in the two groups assigned to receive high fluid balance, irrespective of the mechanical power rece

189 Fluid balance is an integral component of hemodialysis t

190 nger-term fluid retention and maintenance of fluid balance is of real clinical and practical benefit

191 e urine, conserve electrolytes, and maintain fluid balance, is a frequent clinical problem, particula

192 pressure levels of 50, 60, and 70 mm Hg, and fluid balance levels in quartiles were examined for thei

193 t 1) older subjects would remain in positive fluid balance longer than young subjects after ingestion

194 t mediated by a causal pathway that included fluid balance, low blood pressure, vasopressor use, hypo

195 Fluid balance lower than -594 mL was associated with an

196 sion, age, mean arterial pressure <70 mm Hg, fluid balance lower than -594 mL, and intracranial press

197 or cerebral perfusion pressure <60 mm Hg and fluid balance lower than -594 mL-was associated with an

198 creases in pulmonary capillary pressure, net fluid balance, lung and prefemoral lymph flow and protei

199 Managing fluid balance mandates a clear identification of what go

200 Fluid balance may be a target for specific manipulation

201 Correcting serum creatinine for fluid balance may improve diagnosis and increase diagnos

202 eoptic nucleus (MnPo) is critical for normal fluid balance, mediating osmotically evoked drinking and

203 Daily fluid balance, mental status, and serum and urine electr

204 , and vasopressor use, increasing cumulative fluid balance (mL/kg) on day 3 was associated with fewer

205 s been associated with adverse outcomes, net fluid balance (NFB) on CRRT has not been investigated as

206 d cardiac index returned to baseline values, fluid balance normalized, and glomerular filtration rate

207 male sex, RBC and plasma transfusion, higher fluid balance, obesity, hypoxemia, acidosis, tobacco use

208 ds ratio, 3.4; 95% CI, 1.6-8.0) and positive fluid balances (odds ratio, 1.2 per L positive; 95% CI,

209 We analyzed the association between daily fluid balance on clinical outcomes using multivariable l

210 Increasing fluid balance on day 3 in children with acute lung injur

211 Adjusted for weight, daily fluid balance on days 1-3 and cumulative fluid balance o

212 ily fluid balance on days 1-3 and cumulative fluid balance on days 1-7 were higher in these children

213 We observed no effect of fluid balance on either 48-hour AKI, 7-day AKI or on the

214 We observed no effect of fluid balance on either 48-hour AKI, 7-day AKI, or on th

215 by weight gain > 5%) or positive cumulative fluid balance on mortality in adult critical care patien

216 investigated the possible influence of early fluid balance on outcome in a large international databa

217 oliguria have a higher incidence of negative fluid balance on postoperative day 1, as well as avoidan

218 primary end point was incidence of negative fluid balance on postoperative day 1.

219 rosemide groups in the incidence of negative fluid balance on the first postoperative day.

220 We sought to determine the impact of fluid balance on the incidence of nondialysis requiring

221 ogistic regression to estimate the effect of fluid balance on the odds of 28-day mortality, and on co

222 terior descending artery [p <.001]), and net fluid balance on the operative day (p =.015).

223 r negative fluid balance, compared with even fluid balance, on 1-year mortality and renal recovery.

224 se a series of transient kidneys to regulate fluid balance, osmolarity and metabolic waste during dev

225 Primary outcome was cumulative fluid balance over 7 days.

226 Mean cumulative fluid balance over the same period was -1941 vs. +1755 m

227 nd ventilator-free days; and 2) determine if fluid balance over time is more similar to adults in the

228 Albumin and furosemide therapy improves fluid balance, oxygenation, and hemodynamics in hypoprot

229 ury and chronic kidney disease on cumulative fluid balance (p =0.005) such that different cumulative

230 ean arterial pressure (P=0.03) and lower net fluid balance (P<0.001).

231 water increased with positive perioperative fluid balance (p=0.04).

232 Fluid balance parameters comprised body mass loss (BML),

233 Fluid balance parameters were significantly influenced b

234 smolyte in autoregulation of cell volume and fluid balance, particularly for mammalian brain and kidn

235 ay an indispensable role in maintaining body fluid balance partly through their ability to regulate a

236 Our findings and the similarity of fluid balance patterns in our cohort to adults in the Fl

237 Diuretic efficiency was calculated as net fluid balance per total furosemide equivalents.

238 predict the effects of GLY, SOD, and time on fluid balance (percentage change in body mass from basel

239 We stratified hospitals by average fluid balance quartile, and compared patterns across dis

240 ine clearance (r = 0.79, P < 0.05), negative fluid balance (r = 0.51, P < 0.01), and the free water c

241 drainage (r=0.90, n =16), net perioperative fluid balance (r=0.71, n=14), and length of stay (LOS) (

242 complication rates were not associated with fluid balance rankings.

243 The lymphatic system is important in tissue fluid balance regulation, immune cell trafficking, edema

244 Achieving and maintaining optimal fluid balance remains a significant challenge; better mo

245 ded 24-hour arterial pH, serum electrolytes, fluid balance, resource utilization, and in-hospital mor

246 egrate hydromineral and hormonal circulating fluid balance signals, information which is transmitted

247 FACTT Lite had a greater cumulative fluid balance than FACTT Conservative but had equivalent

248 After adjustment for fluid balance, the incidence of acute kidney injury was

249 iated circulatory overload included positive fluid balance, the number and type of products transfuse

250 hannels that maintain bronchial and alveolar fluid balance: the cystic fibrosis transmembrane conduct

251 opic/vasotropic actions and to optimize body fluid balance, this candidate pathway might benefit sept

252 Close monitoring of fluid balance to avoid hypervolemia is essential.

253 an coordinate structural reorganization with fluid balance to maintain cellular integrity.

254 The addition of cumulative fluid balance to the admission Sequential Organ Failure

255 Failing to correct serum creatinine for fluid balance underestimates the prevalence and impact o

256 st 24 hours, and cumulative percent positive fluid balance up to 7 days.

257 Daily fluid balance, urine output (UOP), and creatinine for da

258 Within each category, we assessed three fluid balance variables: total fluid intake/kg/d during

259 Cumulative fluid balance was 1,918 +/- 323 mL in FACTT Lite, -136 +

260 Fluid balance was associated with a longer time to first

261 Daily fluid balance was associated with higher admission Hunt

262 Conversely, positive fluid balance was associated with higher mortality throu

263 Fluid balance was associated with longer time to ICU dis

264 Increased cumulative percent positive fluid balance was associated with mortality in the low-r

265 djusted odds ratio, 0.81; 95% CI, 0.43-1.55) fluid balance was associated with renal recovery.

266 In addition, a negative mean daily fluid balance was associated with significantly increase

267 Positive fluid balance was associated with the development of int

268 Among 18,084 patients, fluid balance was categorized as negative (< 0%), even (

269 In the RENAL study, a negative mean daily fluid balance was consistently associated with improved

270 of acute kidney injury before adjustment for fluid balance was greater in those managed with the cons

271 As a result, myocardial fluid balance was improved, and cardiac inflammation, fi

272 s similar in survivors and nonsurvivors, but fluid balance was less positive in survivors because of

273 Cumulative fluid balance was linked to mortality in patients with s

274 llment, 609 without baseline shock (for whom fluid balance was managed by the study protocol).

275 After day 5, fluid balance was more negative in the crystalloid group

276 Cumulative fluid balance was more positive among patients with high

277 ltivariable analysis, the 24-hour cumulative fluid balance was not associated with an increased hazar

278 At 210 min, fluid balance was predicted to be greater with ingestion

279 Fluid balance was similar in the two groups, as was the

280 criteria after but not before adjustment for fluid balance was similar to patients with acute kidney

281 r negative fluid balance, compared with even fluid balance, was associated with higher 1-year mortali

282 luid balance, compared with even or negative fluid balance, was associated with increased mortality (

283 , negative fluid balance, compared with even fluid balance, was associated with lower short-term mort

284 of the lymphatic vasculature in maintaining fluid balance, we tested the hypothesis that ANP or BNP

285 st 24 hours, and cumulative percent positive fluid balance were all associated with increased odds of

286 Fluid overload and cumulative fluid balance were both associated with pooled mortality

287 Total daily amount of fluids and fluid balance were calculated over 15 days.

288 ong HBP concentrations, disease severity and fluid balance were considered secondary endpoints.

289 ration, plasma colloid osmotic pressure, and fluid balance were measured before and after scalding an

290 commonly consumed drinks on urine output and fluid balance when ingested in a euhydrated state, with

291 ore and maintain cardiovascular function and fluid balance while minimizing secondary edema-related d

292 ls the association of daily fluid intake and fluid balance with disease severity, hospital complicati

293 relationship between daily fluid intake and fluid balance with hospital complications and functional

294 nificant association of fluid intake but not fluid balance with hospital complications and poor funct

295 alyses showed similar associations of higher fluid balance with ICU mortality (OR 1.17 [95% CI 1.05 t

296 , and an endolymphatic duct and sac allowing fluid balance with the cerebrospinal system.

297 e to cardiac comorbidity and a more positive fluid balance with use of transpulmonary thermodilution

298 tic vasculature is essential for maintaining fluid balance within organs and tissues.

299 has been drunk than is necessary to restore fluid balance within the body.

300 received renal replacement therapy (positive fluid balance x renal replacement therapy interaction (a