ライフサイエンスコーパス: body water

1 of isotopically anomalous air O(2) in their body water.

2 llular water, extracellular water, and total body water.

3 measures stable heavy water levels in total body water.

4 ip between muscle electrical resistivity and body water.

5 dration, surviving losses up to 70% of their body water.

6 c free amino acids rapidly equilibrated with body water.

7 ience early weight gain from increased total body water.

8 tic congenital heart disease despite reduced body water.

9 termined from the turnover of doubly labeled body water.

10 gence in enrichments of 2 isotopic labels in body water--1 of hydrogen and 1 of oxygen.

11 s were observed for fat mass (11%) and total body water (3%), which were also unabated by allocation.

12 sorptiometry (DXA), hydrodensitometry, total body water, a three-compartment model, a four-compartmen

13 Yang et al. assayed the 2H enrichment of body water after exchange with acetone, by gas chromatog

14 ned the temporal changes in (2)H labeling of body water and amino acids which should build confidence

15 Tooth enamel records the Delta'(17)O of body water and can thus preserve such paleo-pCO(2) or pa

16 cts" that included realistic fluctuations in body water and day-to-day variations in energy intake.

17 Bioimpedance spectroscopy can estimate body water and fat mass.

18 various bioconductor volumes, such as total body water and fat-free mass, are experimentally well es

19 t showed significantly higher BP, BFM, total body water and metabolic age; (2) BMI was positively cor

20 ering substrate metabolism, and accelerating body water and muscle protein loss.

21 l dialysis remove metabolic waste and excess body water and rebalance electrolytes to sustain life.

22 ient of deuterated water (HDO) between blood/body water and the dialysate.

23 Serum metabolites were corrected for total body water and the sum of 24 hr urine plus total body wa

24 between evaporated water (ingested water or body water) and source water, which increases with envir

25 density, bioelectrical impedance, and total body water, and 4-component fat and fat-free masses were

26 t (%BF) that used body density (D(b)), total body water, and bone mineral content was used as the cri

27 were based on measurements of body density, body water, and bone mineral content.

28 n the basis of measurements of body density, body water, and bone mineral content.

29 y labeled water method, measurement of total body water, and measurement of insulin resistance by glu

30 icoid release, endogenous accrual of surplus body water, and precise surplus excretion.

31 at predicting fat-free mass, fat mass, total body water, and RMR.

32 d using the tritium ([(3)H(2)]O) labeling of body water, and the contribution of glucose, via glycoly

33 al-changes in fat-free mass, fat mass, total body water, and total energy expenditure in 63 subjects.

34 n characterized by an accumulation of excess body water as ascites, edema, or both.

35 Underhydration occurs when a decrease in body water availability, due to high losses or low gains

36 differences in measures of changes in total body water balance in the first week of life and chronic

37 Body water balance is determined by fundamental homeosta

38 icles to orchestrate the acute regulation of body water balance.

39 pears to have only a minor effect on overall body water balance.

40 vioral responses to help maintain energy and body water balance.

41 ys a key role in the maintenance of a normal body water balance.

42 Changes in body water, blood volume, and extravascular fluid volume

43 el, which was based on measurements of total body water, bone mineral content, and total body potassi

44 model that determined fat from weight, total body water, bone mineral mass, and body density.

45 4-component model including fat mass, total body water, bone mineral mass, and residual mass (princi

46 ments provide a reasonable estimate of total body water but that the precision of the measurements is

47 ce measure of percentage body fat from total body water by 18O dilution.

48 Bone mineral content measured by DXA, total body water by deuterium dilution, and total body potassi

49 n: measurements of skinfold thickness, total body water by deuterium oxide, and total-body electrical

50 ompared with gold-standard measures of total body water by using stable isotope dilution (deuterium o

51 by dual-energy x-ray absorptiometry); total body water (by deuterium oxide dilution); extracellular

52 ture in mice, in which the 18O enrichment of body water can be monitored down to 0.025%.

53 ssess the effectiveness of BIA in monitoring body water changes during fluid therapy with ECMO suppor

54 IA utilization may be helpful for monitoring body water changes during the early phase of ECMO suppor

55 Cyanotic patients had reduced body water compared with control subjects, although the

56 rterial oxygen difference (AaDO2), and total body water content (bioimpedance) were measured.

57 Percent increase of body water content at 180 minutes of reperfusion was sig

58 The changes in weight, fat mass, total-body water content, and exercise functional capacity did

59 t often exceeds water intake, resulting in a body water deficit (hypohydration) and electrolyte losse

60 Dehydration (body water deficit) is a physiologic state that can have

61 ompartment model based on body weight, total body water (deuterium dilution), and body volume.

62 , body volume (hydrodensitometry), and total body water (deuterium dilution).

63 Total body water differences comprised between-group differenc

64 Urea is important for the conservation of body water due to its role in the production of concentr

65 The extent to which the variability in body water during pregnancy invalidates use of pregnancy

66 ntinuous infusion of 8% (2)H(2)O to maintain body water enrichment.

67 patial data (irrigated land use, groundwater bodies, water entitlement location, and volume).

68 e change from birth weight] divided by total body water [estimated 80% of birth weight]).

69 ors have examined correlations between total body water, extracellular fluid, and body cell mass and

70 can survive when approximately 50% of their body water freezes.

71 s of body density from hydrostatic weighing, body water from deuterium dilution, bone mineral and %BF

72 ith measured residual lung volume, and total body water from traditional BIS.

73 3% (at least 2.5% must have been from total body water) from baseline or an increase of at least 100

74 Body water homeostasis depends critically on the hormona

75 rome, is known to be associated with altered body water homeostasis, but the molecular mechanisms are

76 of aquaporin-2 (Aqp2) gene is essential for body water homeostasis.

77 ge of interstitial osmolytes into urine, and body water homeostasis.

78 et complex, components in the maintenance of body water homeostasis.

79 nctions with the maintenance of nutrient and body water homeostasis.

80 s to brain networks controlling nutrient and body water homeostasis.

81 ranes and are essential in the regulation of body water homeostasis.

82 er, participants were exposed to daily lower body water immersion for 10 days in cold (CWI, 15 min at

83 composition and content and distribution of body water in critically ill patients.

84 Glycogen content and whole-body water increased at AR21 (14%, P < 0.001; 3.1%, P <

85 realistic muscle innervation, body flexion, body-water interaction, and movement is then used to eva

86 luconeogenesis (deuterium incorporation from body water into glucose), hepatic triglyceride (magnetic

87 sition parameters other than fat mass (total body water, intra- and extra-cellular water, fat-free ma

88 ysis population (participants with estimated body water <=42.5 L), mean session duration was 216 minu

89 ctions of fat-free mass, fat mass, and total body water matched actual measurements within 1 kg.

90 The effects of SGLT2 inhibitors on body water may be one of the contributing mechanisms by

91 ggested that hyperhydration (increased total body water) may reduce physiologic strain during exercis

92 water and the sum of 24 hr urine plus total body water metabolites of PA, TYR, HPPA, HPLA and HGA we

93 The sum of total body water metabolites were significantly higher post-ni

94 egnant women using the deuterium labeling of body water method.

95 ercentage; thereafter 50 ml/wk) with regular body water monitoring in saliva via high-temperature con

96 Despite significant losses of body water, most RXc vector scores for ED and ID groups

97 her the decreases in fat-free mass and total body water observed in all subjects, and the decrease in

98 In summary, the alterations in body water observed with glucocorticoid excess may be a

99 er cells of rodents with 2H2O enrichments in body water of 2.2-2.8% were 9.0-9.5%, and less than 1.0

100 ple frequency bioimpedance estimate of total body water of 47.7 +/- 9.4 L was statistically different

101 s that translate the raw data into liters of body water or kilograms of fat-free mass (FFM) or fat ma

102 by skinfold-thickness measurements and total body water (P = 0.008 and 0.02, respectively) and for fa

103 changed, fat-free mass (P = 0.004) and total body water (P = 0.013) were decreased, and percentage bo

104 ring the incorporation of deuterium from the body water pool into newly formed glucose.

105 and 6 of glucose after deuterium labeling of body water pool.

106 e-of-the-art quantum simulations with a many-body water potential energy surface, which exhibits chem

107 netics is to measure the (2)H enrichments of body water (precursor) and protein-bound amino acid or p

108 During water deprivation, body water preservation is ensured by the selective tran

109 , and brain) and molecular components (total body water, protein, and bone minerals) of FFM.

110 me status measured by extracellular to total body water ratio was not associated with SBP variation (

111 he edema index (extracellular water to total body water ratio) significantly improved in all patients

112 Similarly, combined 24 hr urine:total body water ratios for all analytes were significantly hi

113 water balance, an excess or deficit of total body water relative to body electrolyte content, are com

114 ncentration represents an imbalance of total body water relative to electrolyte content.

115 Moreover, it is unclear whether body water returns to nonpregnant values by 2 wk postpar

116 soft tissue minerals based on measured total body water (TBW) and extracellular water (ECW) and a sim

117 l impedance analysis (BIA), to measure total body water (TBW) and extracellular water (ECW) in 35 pat

118 ric BIA-based predictive equations for total body water (TBW) and fat-free mass (FFM) and to refit th

119 l-body potassium were used to estimate total-body water (TBW) and intracellular water (ICW), respecti

120 y absorptiometry (DXA), measurement of total body water (TBW) by isotope dilution, measurement of tot

121 We measured total body water (TBW) by using D2O dilution, extracellular vo

122 An estimate of total body water (TBW) has important implications in clinical

123 e estimates of fat-free mass (FFM) and total body water (TBW) in healthy populations.

124 Accurate estimation of total body water (TBW) is a critical component of dialysis pre

125 Total body water (TBW) is commonly used to derive estimates of

126 the estimation of free water (FW) and total body water (TBW) losses and systematically evaluated its

127 Total body water (TBW) metabolites were derived using 60% body

128 nce (BI) with anthropometry to measure total body water (TBW) was evaluated in very-low-birth-weight

129 Total body water (TBW) was not significantly different, fat-fr

130 l mass (BCM), fat-free mass (FFM), and total body water (TBW) were derived from direct measurements t

131 s, and a four-compartment model of FM, total body water (TBW), bone minerals (BM), and PM was derived

132 ve, rapid method for the assessment of total body water (TBW), extracellular water (ECW), and intrace

133 Total body water (TBW), intracellular water (ICW), extracellul

134 in fat-free mass (FFM), fat mass, and total body water (TBW), there were no significant differences

135 Total body water (TBW), total body potassium (TBK), body densi

136 , tumors and (2)H(2)O level of ~ 8% in total body water (TBW).

137 isplacement plethysmography (ADP), and total body water (TBW).

138 um (TBK; whole-body (40)K counting) to total body water (TBW; isotope dilution) methods (ECW(TBK-TBW)

139 accurate and less biased predictor of total body water than multiple frequency bioimpedance.

140 s were administered (2)H(2)O to enrich total body water to 5% over the last 4-5 h of each fasting per

141 Hydration, the observed ratio of total body water to fat-free body mass, is stable at approxima

142 rected for some measure of body size such as body water (V) or body surface area (BSA).

143 Total body water was measured by the isotopic dilution of (18)

144 n; intraperitoneal (2)H(2)O (to enrich total body water) was used to quantify sources of glucose (TCA

145 ns, stable long-term (2)H(2)O enrichments in body water were achieved by daily (2)H(2)O intake, witho

146 carbons 2, 5, and 6 of blood glucose and in body water were determined.

147 of local sources in the water inputs to the body water, whereas d(13)Cca values indicate food resour

148 hat there is rapid equilibration of (2)H (in body water) with the carbon-bound hydrogens of amino aci