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1 d2 for several T cell measures and Prkca for bone mineral content.
2 easurements of body density, body water, and bone mineral content.
3 easurements of body density, body water, and bone mineral content.
4 over markers and a positive association with bone mineral content.
5 l times; growth; and whole body and regional bone mineral content.
6  and spine bone area-and spine area-adjusted bone mineral content.
7  lean tissue mass, bone mineral density, and bone mineral content.
8                                   Whole-body bone mineral content, adjusted for height, age, sex, deg
9 ce was associated with a 3% reduction in hip bone mineral content and bone mineral density (P < 0.02)
10 ake during childhood and adolescence and hip bone mineral content and bone mineral density (P < 0.04)
11 as positively associated with offspring TBLH bone mineral content and bone mineral density (SD scores
12 d 0.19 (0.16, 0.23), respectively] and spine bone mineral content and bone mineral density [boys, 0.2
13  mice resulted in further reduction of total bone mineral content and bone mineral density and revers
14                                              Bone mineral content and bone mineral density were measu
15                                              Bone mineral content and bone mineral density were withi
16 follow-up revealed a significant increase in bone mineral content and density (24 months postburn, p
17       Significant increases occurred in both bone mineral content and density in the lumbar spine but
18 rged the radio-opaque area and increased the bone mineral content and density in the radiological ana
19                           Total and regional bone mineral content and density were assessed.
20  assessed every 6 mo included the total-body bone mineral content and density, cortical and trabecula
21 ex were associated with increased whole-body bone mineral content and maintenance of the bone mineral
22         Oxandrolone improved lean body mass, bone mineral content and muscle strength compared with c
23 region as body length, lean tissue mass, and bone mineral content and on chromosome 13 in the same re
24 rolone improves lean body mass accretion and bone mineral content and that the administration of the
25                                   Bone area, bone mineral content, and areal bone mineral density wer
26 luding menstrual history), lumbar spine BMD, bone mineral content, and BMD z score values were lowest
27 itropic hormones, urinary calcium excretion, bone mineral content, and body composition in 19 young g
28 group, and total mass, fat-free soft tissue, bone mineral content, and bone mineral density increased
29 e height, bone volume, bone volume fraction, bone mineral content, and bone mineral density).
30  composition, including fat mass, lean mass, bone mineral content, and bone mineral density, was dete
31 nterindividual variability in the hydration, bone mineral content, and density of FFM; 3) evaluate th
32 one volume and area, cortical and trabecular bone mineral content, and density.
33 ury, successfully improved lean muscle mass, bone mineral content, and growth.
34                      Improvements in height, bone mineral content, and IGF-1 concentrations persisted
35 e, sex, body mass index, knee pain), general bone mineral content, and joint space width at baseline
36 olone significantly improves lean body mass, bone mineral content, and muscle strength.
37 ignificant increase in bone mineral density, bone mineral content, and other parameters of bone growt
38  or absence of vitamin D deficiency rickets, bone mineral content, and serum parathyroid hormone conc
39 s based on measurements of total body water, bone mineral content, and total body potassium.
40 ein intake and bone mineral density (BMD) or bone mineral content at the main clinically relevant sit
41          There were significant decreases in bone mineral content at the spine (3.96%; 95% CI: 4.86%,
42  knee alignment, traditional covariates, and bone mineral content (AUC 0.79).
43 t differences at any timepoint in whole-body bone mineral content between casein-fed (112.5 +/- 2.1,
44 entrations most-strongly predicted childhood bone mineral content (BMC) [beta = 2.8 (95% CI: 1.1, 4.5
45 e relative influence of fat and lean mass on bone mineral content (BMC) among 1600 early postmenopaus
46             Patients lost 3% +/- 1% of their bone mineral content (BMC) and 2 +/- 1% of their bone mi
47                                              Bone mineral content (BMC) and areal bone mineral densit
48 itudinal modelling of BMD and its components bone mineral content (BMC) and bone area (BA), from 9 to
49 onflicting results with regard to changes in bone mineral content (BMC) and bone mineral density (BMD
50          Techniques for cross-calibration of bone mineral content (BMC) and bone mineral density (BMD
51                                              Bone mineral content (BMC) and bone mineral density (BMD
52  at ages 6, 14, 17, and 20 y, and whole-body bone mineral content (BMC) and bone mineral density (BMD
53                           Total-body and hip bone mineral content (BMC) and bone mineral density (BMD
54  total femur, femoral neck, and lumbar spine bone mineral content (BMC) and bone mineral density (BMD
55 ndicators of vitamin K status are related to bone mineral content (BMC) and markers of bone formation
56 ential nutrients that are needed to increase bone mineral content (BMC) and potentially decrease frac
57 cle is associated more closely than fat with bone mineral content (BMC) as well as with bone mineral
58 n D during pregnancy have greater whole-body bone mineral content (BMC) at birth than those of mother
59 h bone mineral density (BMD), bone area, and bone mineral content (BMC) in a cohort of young adults.
60 e of this study was to measure the change in bone mineral content (BMC) in children with IE treated w
61 ting algorithm was used to calculate BMD and bone mineral content (BMC) in the head, neck, and trocha
62 rease in femoral neck and total body BMD and bone mineral content (BMC) in the WM group than in the W
63              We sought to compare whole-body bone mineral content (BMC) of newborns exposed vs not ex
64 d's triangle, radius, and total body and the bone mineral content (BMC) of the spine, radius, and tot
65 f whole-body (WB) and skeletal site-specific bone mineral content (BMC) relative to linear growth in
66 bjects aged 4-20 y, whole-body and vertebral bone mineral content (BMC) was determined by using dual-
67 and spine (S) bone mineral density (BMD) and bone mineral content (BMC) were determined by using dual
68  lumbar spine bone mineral density (BMD) and bone mineral content (BMC) were measured by using dual-e
69 de association study of areal BMD (aBMD) and bone mineral content (BMC) Z-scores measured by dual ene
70 pring total body bone mineral density (BMD), bone mineral content (BMC), and bone area (BA) were meas
71 f total body fat (TBF), fat-free mass (FFM), bone mineral content (BMC), and bone mineral density (BM
72  crestal bone width (CBW), bone volume (BV), bone mineral content (BMC), and bone mineral density (BM
73 ody and regional bone mineral density (BMD), bone mineral content (BMC), and T scores were assessed.
74 bgroup at 2 y of age : Bone mineral density, bone mineral content (BMC), area-adjusted BMC, and bone
75                                          The bone mineral content (BMC), bone area (BA), and bone min
76                                              Bone mineral content (BMC), bone area (BA), areal bone m
77                                              Bone mineral content (BMC), lean tissue mass (LTM), body
78                               Changes in the bone mineral content (BMC), lean tissue mass (LTM), fat
79 al bone cross-sectional area (CSA), cortical bone mineral content (BMC), periosteal circumference, an
80 asurements of bone mineral density (BMD) and bone mineral content (BMC).
81  (BMD; DXAdiff = 0.016 +/- 0.023 g/cm2), and bone mineral content (BMC; DXAdiff = 316 +/- 50 g) were
82 s in pregnancy is a suggested determinant of bone-mineral content (BMC) in offspring, but has been as
83 Similarly, changes in spine and femoral neck bone mineral contents (BMCs) were not significantly diff
84 ake, is associated with adult bone mass (ie, bone mineral content), bone mineral density, and the inc
85 ray absorptiometry was used to measure total bone mineral content, bone mineral density, body fat mas
86 se patients gained 21.0 to 65.3 g total body bone mineral content by 3 months after treatment or 45%
87                          PTH(1-34) increased bone mineral content (by dual energy x-ray absorptiometr
88              Height, weight, lean body mass, bone mineral content, cardiac function, and muscle stren
89                                              Bone mineral content continued to increase at a rate sim
90 an "ideal" body plan consisting of increased bone mineral content, density, and size as well as decre
91 further work is determining the relation of "bone mineral content" determined by dual energy X-ray ab
92                           Lean body mass and bone mineral content did not change.
93                                   Growth and bone mineral content did not differ by dosage.
94 ls of bone turnover markers and increases in bone mineral content did not differ by treatment.
95 -free mass (FFM) was > 0.99, indicating that bone mineral content did not provide independent informa
96 p had a greater increment in both whole-body bone mineral content (difference: 35 +/- 16 g; P = 0.03)
97 e animals also manifested fractures, reduced bone mineral content, expanded growth plates, and severe
98  long-term treatment with glucocorticoids on bone mineral content in children with glucocorticoid-sen
99 ificantly increased bone mineral density and bone mineral content in femurs and lumbar vertebrae when
100 sis of log-transformed values to compare the bone mineral content in patients with that in controls.
101  during pregnancy resulted in lower maternal bone mineral content in the subsequent lactation that pe
102 low calcium intake results in lower maternal bone mineral content in the subsequent lactation.
103  p=0.0088) and lumbar-spine (r=0.17, p=0.03) bone-mineral content in children at age 9 years.
104              The effect of GH replacement on bone mineral content is complex, and is dependent on the
105        Weight; body fat, lean body mass, and bone mineral content (measured by dual-energy x-ray abso
106                                   Total-body bone mineral content, measured with the use of dual-ener
107 sity, cortical bone geometry properties, and bone mineral content, muscle mass, and bone strength.
108 by using a 4-component (4C) model with total bone mineral content obtained from dual-energy X-ray abs
109 s during adolescence may underlie the higher bone mineral content of adult blacks than of adult white
110                                          The bone mineral content of infants fed the experimental for
111                       After 21 days of ULLS, bone mineral content of the peripheral portion of the ep
112 appear to be associated with deficits in the bone mineral content of the spine or whole body relative
113 ent for the z score for body-mass index, the bone mineral content of the spine was significantly lowe
114                                          The bone mineral content of the spine, adjusted for bone are
115  bone mineral content and maintenance of the bone mineral content of the spine.
116                            Bone area and the bone mineral content of the whole body and radius were a
117 ence is not sufficient to support the use of bone mineral content or parathyroid hormone concentratio
118 circumference, total tissue mass, lean mass, bone mineral content, or bone mineral density.
119 jective was to investigate whether the lower bone mineral content persists long term.
120 lues were negatively correlated with forearm bone mineral content (r = -0.18; P = 0.02).
121     All patients had increases in total body bone mineral content ranging from 21 to 29 grams (median
122 ns were observed between spine size-adjusted bone mineral content (SA-BMC) and fruit intake.
123                                Size-adjusted bone mineral content (SA-BMC) was greater at NPNL than a
124 tal-body bone mineral density (TBBMD), spine bone mineral content (SBMC), and spine bone mineral dens
125 t effects and explored the roles of FFM, FM, bone mineral content, sex, age, and circulating concentr
126 HAART is also associated with a reduction in bone mineral content, suggesting that HAART increases th
127                               The total-body bone mineral content (TBBMC), total-body bone mineral de
128 e scaling of weight, fat, fat-free mass, and bone mineral content to height.
129 r weaning, and, in several skeletal regions, bone mineral content ultimately exceeds that measured af
130                            The adjusted mean bone mineral content was 5.3 g lower (95% confidence int
131                    Among women aged 20-49 y, bone mineral content was 5.6% lower in those who consume
132                                              Bone mineral content was increased at 9 and 12 months; t
133 d body density (D(b)), total body water, and bone mineral content was used as the criterion for evalu
134 hole-body (dual-energy X-ray absorptiometry) bone mineral content (WBBMC) at 12 wk and 2) stool frequ
135                 Moreover, humerus length and bone mineral content were decreased, consistent with les
136   In men receiving HAART, total and regional bone mineral content were less than in the men not recei
137 otal body potassium (TBK), body density, and bone mineral content were measured by deuterium dilution
138 , bone turnover markers, and minerals and in bone mineral content were measured.
139                       The effects of sex and bone mineral content were not significant (P > 0.05).

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