ライフサイエンスコーパス: free water

1 er the same cocaine concentration or cocaine-free water.

2 water to the agar surface, where there is no free water.

3 e treatments included: 1) distilled, pyrogen-free water; 2) 8.5% (w/v) SBHAN; 3) 4.3% (w/v) SBHAN; 4)

4 g every 6 h for 7 days (n=16) or equiosmolar free water/5% mannitol (placebo; n=15).

5 e ability is lost altogether, an increase in free water, a possible source of cataract formation, may

6 and may be a heretofore unrecognized site of free water absorption.

7 free-water clearance, indicating endogenous free water accrual by urine concentration.

8 The United States Microbead-Free Waters Act was signed into law in December 2015.

9 as presumed sources of pathogen- and arsenic-free water, although little is known of the processes th

10 Free-water analyses were performed on diffusion imaging

11 keep the gate of C1C2 closed and to disable free water and ion passage through the putative pore, in

12 e that acts on the kidney to conserve solute-free water and produces a potent vasoconstrictive effect

13 ) the relationship between 4-year changes in free water and striatal binding ratio in a subgroup of P

14 ntial of this food are the low percentage of free water and the high energy and nutritional density.

15 disease, showed a broad network of elevated free-water and altered free-water corrected fractional a

16 Free-water and free-water-corrected fractional anisotrop

17 lated to aquaresis (excretion of electrolyte-free water) and hepatic adverse events unrelated to ADPK

18 rying the ligand set, positions of bound and free waters, and additional protein constraints on the g

19 eta(10-40) conformational ensemble in ligand-free water as reference, we show that FDDNP induces mino

20 they were tested in cocaine- (or U-50,488H-) free water, but not when they were tested in cocaine- (o

21 tion has occurred throughout the world's ice-free waters, but is particularly prevalent in the Indo-P

22 The rate of renal free water clearance (CH2O) was similar between hormone

23 VPA-985 significantly increased solute-free water clearance and urine output and significantly

24 AQP-2 excretion correlated best with solute-free water clearance during T0-T2 and T2-T4 collection,

25 fluid balance (r = 0.51, P < 0.01), and the free water clearance rate (r = -0.90, P < 0.002).

26 that, after the water load, serum sodium and free water clearance were diminished in both groups with

27 ulted in a reduction of the serum sodium and free water clearance without a concomitant increase in t

28 natremia has shown that these agents augment free water clearance, decrease urine osmolality, and cor

29 reased urine osmolyte excretion, but reduced free-water clearance, indicating endogenous free water a

30 al sodium excretion but not higher nocturnal free-water clearance.

31 lasma volume, and 3) limit kidney injury and free-water clearance.

32 ree water T1 (R(2) = 0.72) and cortical bone free water concentration (R(2) = 0.62) showed strong pos

33 Conclusion The cortical bone free water concentration and free water T1 derived with

34 Results The mean free water concentration, bound water concentration, fre

35 d network of elevated free-water and altered free-water corrected fractional anisotropy that included

36 Free-water and free-water-corrected fractional anisotropy maps were com

37 Compared with controls, free-water-corrected fractional anisotropy values were i

38 A model of intra-axonal, extra-axonal, and free water diffusion was fitted to obtain estimates of a

39 ically occult HIVAN) followed by doxycycline-free water during the next 3 weeks.

40 hat the reverse micelles contained a pool of free water, even at a ratio of water to surfactant (Wo)

41 ive to sodium (P=0.01), despite better renal free water excretion (urine osmolality 343+/-101 mOsm/kg

42 Because free water excretion is achieved by continuous sodium re

43 onic hyponatremia, therapy to increase renal free water excretion is often necessary.

44 d flow while vasopressin antagonists promote free water excretion without compromising renal function

45 eability in the collecting ducts and, hence, free water excretion, remain under investigation for dil

46 companied by significant increases in solute-free water excretion.

47 and reversed the lithium-induced increase in free-water excretion, without decreasing blood or kidney

48 followed by depuration in metal- and isotope-free water for up to 21 days.

49 tential error in WD(1) for the estimation of free water (FW) and total body water (TBW) losses and sy

50 y distribution of intracranial extracellular free water (FW).

51 ters, the fractional volume of extracellular free-water (FW) and cellular tissue FA (FA-t), were esti

52 This comparison was then followed by Free Water Imaging analysis, where two parameters, the f

53 Free Water Imaging is a novel diffusion magnetic resonan

54 A previous Free Water Imaging study in schizophrenia identified sig

55 Here, we applied Free Water Imaging to a larger cohort of 63 first-episod

56 Free-water imaging is a new methodology that is sensitiv

57 We applied free-water imaging on diffusion MRI data acquired from s

58 Free-Water Imaging was used to quantify distribution of

59 The analyses examined: (i) 1-year changes in free water in 103 de novo patients with Parkinson's dise

60 d 49 controls; (ii) 2- and 4-year changes in free water in a subset of 46 patients with Parkinson's d

61 yers of macromolecules and its conversion to free water in condensed systems are known as syneresis.

62 ols, and further demonstrates an increase of free water in Parkinson's disease over the course of 4 y

63 , and describe the pattern of progression of free water in patients with a 4-year follow-up tested in

64 Here, the goal was to validate free water in the posterior substantia nigra as a progre

65 tudy demonstrates an increase over 1 year in free water in the posterior substantia nigra in a large

66 ollectively, these findings demonstrate that free water in the posterior substantia nigra is a valid,

67 sites and the 1-year and 2-year increase in free water in the posterior substantia nigra predicts su

68 Prior work demonstrated that free water in the posterior substantia nigra was elevate

69 ive ice cover in 2010 and 2011 to nearly ice-free waters in 2012.

70 in Parkinson's disease, we observed elevated free-water in all regions except the dentate nucleus, su

71 Free-water in the posterior substantia nigra is elevated

72 progressive supranuclear palsy have elevated free-water in the substantia nigra.

73 that all forms of parkinsonism had elevated free-water in the substantia nigra.

74 Further, free-water increased longitudinally over 1 year in the p

75 predicted 4-year changes in free water; (iv) free water increases over 1 and 2 years were related to

76 a full-factorial design, we demonstrate that free water-induced intravascular hemolysis produces dose

77 ter losses and impaired thirst or restricted free water intake or both.

78 e, but water treatment is important where As-free water is not available.

79 eline free water predicted 4-year changes in free water; (iv) free water increases over 1 and 2 years

80 arkinson's disease but not in controls; (ii) free water kept increasing over 4 years in Parkinson's d

81 Results demonstrated that: (i) free water level in the posterior substantia nigra incre

82 We previously found elevated free-water levels in the substantia nigra for patients w

83 Here, we test the hypotheses that free-water levels in the substantia nigra of Parkinson's

84 ing 1 year of progression, and that baseline free-water levels in the substantia nigra predict the ch

85 e narrow resonance of the hydrogen ((1)H) in free water, limit both the attainable spatial resolution

86 ded for children with urinary or extra-renal free water losses or hypernatremia.

87 promotes aquaresis--excretion of electrolyte-free water--might be of benefit in hyponatremia.

88 easing water content, reflecting the lack of free water molecules around kuromanin that can accommoda

89 easing water content, reflecting the lack of free water molecules around kuromanin, which may accommo

90 Here we demonstrate self-mending in metal-free water of synthetic polyacrylate and polymethacrylat

91 or hydrogen-bonding sites with the remaining free waters on the surface of the hydration shell.

92 ved less than 1 L of intravenous electrolyte-free water per day during the development of hypernatrem

93 nths; (iii) whether 1- and 2-year changes in free water predict 4-year changes in the Hoehn and Yahr

94 Parkinson's disease; (iii) sex and baseline free water predicted 4-year changes in free water; (iv)

95 The ease of making such surfactant-free, water-processed, carbon thin films could lead to t

96 These findings demonstrate that free-water provides a potential non-invasive progression

97 hythmical mineralocorticoid release promoted free water reabsorption via the renal concentration mech

98 Mineralocorticoid-coupled increases in free water reabsorption were counterbalanced by rhythmic

99 antibody (MAb), decreased urine cAMP levels, free water reabsorption, and urine osmolality and increa

100 of intravascular volume expansion, increased free water reabsorption, urinary prostaglandin E2 excret

101 eased urine osmolality, and increased solute-free water reabsorption.

102 Free water reserve [FWR; urine volume (mL/24 h) minus ob

103 doxorubicin-loaded nanoparticles compared to free water-soluble doxorubicin.

104 hen the horizontal hydraulic gradient at the free water surface is equal to zero and the vertical is

105 molecules (T(2b)), trapped water (T(21)) and free water (T(22)).

106 Cortical bone free water T1 (R(2) = 0.72) and cortical bone free water

107 e cortical bone free water concentration and free water T1 derived with UTE imaging are good predicto

108 er concentration, bound water concentration, free water T1, and bound water T1 in the recruited popul

109 A free water table equation is adopted to clarify under wh

110 the activity of the water (i.e., converting free water to bound water).

111 ted in increased magnetization exchange from free (water) to macromolecular-bound protons, within a d

112 Thus, the free water-to-bound water ratio decreases with increasin

113 followed by depuration for 2 weeks in metal-free water using live-animal gamma-spectrometry.

114 up after 1 year (P = 0.006), whereas control free-water values did not change.

115 Free-water values increased for the Parkinson's disease

116 Baseline free-water values predicted the 1 year change in bradyki

117 Using a bi-tensor model, free-water values were found to be increased in the post

118 A group effect indicated free-water values were increased in the posterior substa

119 atureless transmission spectrum-from a cloud-free water-vapour atmosphere to a Venus-like one.

120 over 4 years; and (v) the 4-year increase in free water was associated with the 4-year decrease in st

121 No supplemental electrolyte-free water was prescribed during the first 24 hours of h

122 Compared with controls, free-water was increased in the anterior and posterior s

123 on rates of MS2 coliphage in photosensitizer-free water were measured (kobs) under different light co

124 e, denuded collagen matrices associated with free water (which serves as a collagen cleavage reagent

125 g the estimation of the fractional volume of free water within a voxel, which is expected to increase

126 zoosporic reproduction of chytrids requires free water, yet we found that chytrids constituted over