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1 l bilirubin, balding, hemoglobin levels, and lung capacity.
2 with impaired muscle function, fitness, and lung capacity.
3 functional residual capacity (FRC) and total lung capacity.
4 flation was defined as residual volume/total lung capacity.
5 common in an ageing population, that reduce lung capacity.
6 d had a higher percentage of predicted total lung capacity.
7 expiratory volume in 1 second, and diffusing lung capacity.
8 n antibody, anti-RNP antibody, and decreased lung capacity.
9 fants from lung volumes initiated near total lung capacity.
10 ty (FVC) (P <.01) but not with FVC and total lung capacity.
11 piration thickness of the diaphragm at total lung capacity (0.386 +/- 0.144 cm vs. 0.439 +/- 0.134 cm
12 rmalities were associated with reduced total lung capacity (-0.444 liters; 95% confidence interval [C
13 es in residual volume as compared with total lung capacity (16 percent vs. 6 percent), but the decrea
14 and it reduced lung volumes (change in total lung capacity -16%; change in residual volume -55%) in a
16 Hb-SS were characterized by decreased total lung capacities (70.2 +/- 14.7% predicted) and DLCO (64.
17 8% predicted (normal range, 80%-120%); total lung capacity, 72% predicted (normal range, 80%-120%); f
18 el displayed hyperinflation (change in total lung capacity +8%; change in residual volume +66%), redu
19 ); and the ratio of residual volume to total lung capacity, a measure of thoracic gas trapping, decre
21 a would interact to cause increases in total lung capacity, airspace enlargement, and pulmonary infla
24 lated immunity were associated with impaired lung capacity and diffusion, suggesting a postinjury pro
25 nd 3 years (28 patients; p=0.004), but total lung capacity and DLCO were not improved significantly a
26 canner, with spirometric monitoring at total lung capacity and during forced exhalation, with 40 mAs,
28 of interstitial lung abnormalities on total lung capacity and emphysema was dependent on COPD status
32 y and full-lung CT-derived measures of total lung capacity and high attenuation area (HAA), and inter
33 terstitial disease and air-trapping in total lung capacity and residual volume images, respectively.
35 , proton signal difference between TLC total lung capacity and RV residual volume correlated positive
36 ormalities are associated with reduced total lung capacity and the extent of emphysema is not known.
37 lung volumes (FVC, vital capacity, and total lung capacity) and lesser flows (FEV1 and forced expirat
38 tween 38.6 (39.8)% and 62.8 (31.1)% of total lung capacity, and 28 (36.3)% and 41.3 (38.7)% of pressu
39 xpiratory volume in 1 second, 116% for total lung capacity, and 60% for diffusing capacity of carbon
40 rea, airway wall area and thickness at total lung capacity, and air trapping at functional residual c
41 d significantly increased lung volume, total lung capacity, and alveolarization compared to wild type
42 4 significantly increased lung volume, total lung capacity, and alveolarization, while VEGF120 did no
43 nificantly decreased FEV(1), increased total lung capacity, and donor organ with lower pO(2) when ven
45 ion lung capacity for carbon monoxide, total lung capacity, and forced vital capacity (rho = -0.76, -
46 ion lung capacity for carbon monoxide, total lung capacity, and forced vital capacity were rho = -0.6
48 tissue damping, inspiratory capacity, total lung capacity, and others, were significantly and simila
49 0.60, P = .0008), and residual volume/total lung capacity (beta = -0.26, P = .02) were significant v
50 oxygen metabolism in an animal model with a lung capacity comparable to the human with minimal utili
51 individual lungs after LVRS, CT-derived mean lung capacity decreased 13% and residual volume 20% (p <
52 rs of smoking, current smoking status, total lung capacity, display field of view, and scanner type.
55 the proportion of patients with a diffusing lung capacity for carbon monoxide (Dlco) less than 80% o
56 ing: pulmonary function tests with diffusing lung capacity for carbon monoxide (DLCO); post-traumatic
57 ragmentation of the rhythm and the diffusing lung capacity for carbon monoxide (rho = -0.35) were obs
58 whole CT scan, correlated with the diffusion lung capacity for carbon monoxide, total lung capacity,
59 he disease extents correlated with diffusion lung capacity for carbon monoxide, total lung capacity,
60 (PFTs) included forced vital capacity, total lung capacity, forced expiratory volume in 1 second, and
61 ation were associated with a decreased total lung capacity, forced vital capacity, and diffusing capa
62 piratory pressure after deflation from total lung capacity, further demonstrating the effects of volu
63 Twelve-month changes in dyspnea score, total lung capacity, FVC, partial pressure of arterial oxygen,
65 predicted, significant hyperinflation (total lung capacity >100% and residual volume >150%), a restri
66 ed respiratory distress revealed compromised lung capacity in animals of both age groups at peak dise
70 lts from rat experiments indicate that total lung capacity is increased when PEG is first added to th
72 ly to have a restrictive lung deficit (total lung capacity <80% of the predicted value; odds ratio, 2
74 rameters were significantly lower than total lung capacity, occurring at volumes between 38.6 (39.8)%
76 reduction in mean (SD) residual volume/total lung capacity of -12% (12%) and an increase in FEV1 of 2
77 g volume was 4.0 L, with PFT showing a total lung capacity of 6.2 L, residual lung volume of 2.1 L, a
81 ty (P = .0017), FEV(1) (P = .037), and total lung capacity (P = .013) but not their lung carbon monox
82 entage predicted, total lung capacity, total lung capacity percentage predicted, DLCO, or DLCO percen
83 tance, and ratio of residual volume to total lung capacity postalbuterol predicted more than 75% of F
84 1), oxygen utilization (p=0.04), lower total lung capacity % predicted (p=0.05), higher residual volu
85 ecipient oversizing based on predicted total lung capacity (pTLC) is associated with a reduced risk o
88 lung volume or residual lung volume to total lung capacity ratio, is associated with greater LV mass.
89 ced vital capacity and residual volume/total lung capacity ratios) and greater reversibility to beta-
90 s loops performed after deflation from total lung capacity remained close to the envelope deflation c
91 structural changes with an increase in total lung capacity, resulting in chronic hypoxemia, hypercapn
92 sed by the ratio of residual volume to total lung capacity (RV/ TLC) (r = 0.66, p < 0.05) and exhaled
93 predicted ratio of residual volume to total lung capacity (RV/TLC%) (r = -0.65, P <.001), and percen
94 as defined as either a residual volume/total lung capacity (RV/TLC) above the upper limit of normal (
98 the residual volume as a proportion of total lung capacity (RV:TLC) did not change in either group.
99 an men after accounting for height and total lung capacity (segmental lumen diameter, 8.05 mm +/- 0.1
100 orrelated most strongly with decreased total lung capacity (Spearman rank correlation coefficient [r(
101 inspiration, static recoil pressure at total lung capacity, static lung compliance, expiratory flow r
102 Six-month changes in dyspnea score, total lung capacity, thoracic gas volume, FVC, FEV1, diffusing
103 0.05), and decreasing residual volume/total lung capacity (TLC) (P = 0.02) and % predicted residual
105 mary endpoints were CT lung density at total lung capacity (TLC) and functional residual capacity (FR
107 (CXR) measurements to estimate actual total lung capacity (TLC) could account for disease-related lu
108 ilator FEV1, residual volume (RV), and total lung capacity (TLC) were determined at baseline and at 6
110 S/LABA treatment, residual volume (RV)/total lung capacity (TLC)% predicted was reduced compared to b
111 iour, present in the dependent 4 cm at total lung capacity (TLC), affects the dependent 11 cm at func
112 pirometric, Feno, residual volume (RV)/total lung capacity (TLC), AHR, and Scond values significantly
114 ility, and accuracy of measurements of total lung capacity (TLC), FRC, and their ratio, we determined
116 c transpulmonary pressures obtained at total lung capacity (TLC); actual TLC %of predicted and flow;
118 al capacity [ FRC+1 L 1 L above FRC ], total lung capacity [ TLC total lung capacity ]) with breath h
120 qCT images (maximal bronchodilation at total lung capacity [TLC], or inspiration, and functional resi
121 group (-1.51 g/L per year [SE 0.25] at total lung capacity [TLC]; -1.55 g/L per year [0.24] at TLC pl
122 d unit (HU)-based density changes from total lung capacity to functional residual capacity (DeltaHU);
124 uotient of tidal volume (normalized to total lung capacity) to tidal change in Pdi (normalized to Pdi
125 d vital capacity percentage predicted, total lung capacity, total lung capacity percentage predicted,
126 d in each infant, after recruitment to total lung capacity, using stepwise airway pressure decrements
127 as excised and inflated three times to total lung capacity (volume at 30 cm H2O) and expiratory compl
128 tional adjusted percent difference for total lung capacity was -1.33% (95% CI: -4.29, 1.72) and for c
129 ond (FEV1), forced vital capacity, and total lung capacity were categorized based on age, gender, hei
130 the ratio between residual volume and total lung capacity were significantly different between the E
131 static lung expansion that approaches total lung capacity with its negative impact on venous return.
132 above FRC ], total lung capacity [ TLC total lung capacity ]) with breath holds of 10-11 seconds, by