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1 ucose provided 50% of the patient's measured resting energy expenditure.
2              Amino acids provided 20% of the resting energy expenditure.
3 on a treadmill for 5.5 h at approximately 3x resting energy expenditure.
4 r, and water, which may increase satiety and resting energy expenditure.
5 which was objectively measured as a ratio to resting energy expenditure.
6  was used to assess respiratory quotient and resting energy expenditure.
7  higher DIT ( approximately 30 kJ/2.5 h) and resting energy expenditure (243 kJ/d) and an anorexigeni
8                                              Resting energy expenditure, although very low in low-wei
9  determine the pattern of anabolic hormones, resting energy expenditure and cytokines in severely the
10 gy expenditure resulting from both increased resting energy expenditure and locomotor activity.
11 n of ALS patients possesses higher levels of resting energy expenditure and lower fat-free mass compa
12  stimulation with propranolol would decrease resting energy expenditure and muscle catabolism in pati
13 A copy number increased significantly; also, resting energy expenditure and natural running speed imp
14 e role of hemodialysis on energy metabolism, resting energy expenditure and respiratory quotient in t
15                                              Resting energy expenditure and respiratory quotient were
16 t calorimetry was used to determine systemic resting energy expenditure and respiratory quotient.
17                                              Resting energy expenditure and sepsis were also strong p
18                                              Resting energy expenditure and skeletal-muscle protein k
19      The average difference between measured resting energy expenditure and the Harris-Benedict predi
20      The average difference between measured resting energy expenditure and the Talbot prediction wit
21 energy they contain, a possible increment in resting energy expenditure, and an augmentation of fat o
22                            Body composition, resting energy expenditure, and concentrations of muscle
23 uted to strong satiety properties, increased resting energy expenditure, and limited lipid bioaccessi
24  index, body composition, hip circumference, resting energy expenditure, and respiratory quotient.
25  muscle size and strength, body composition, resting energy expenditure, and skeletal muscle creatine
26 olanzapine on body weight, body composition, resting energy expenditure, and substrate oxidation as w
27 wer, and nitrogen balance and an increase in resting energy expenditure as death approached.
28 duction of adiposity resulted from increased resting energy expenditure associated with increased exp
29 oxidation, oxidative glucose metabolism, and resting energy expenditure at baseline and at high level
30 activity level (ie, total energy expenditure/resting energy expenditure); baseline anthropometric mea
31 body mass index support a role for increased resting energy expenditure before clinical onset of ALS.
32                     Outcome measures such as resting energy expenditure, body composition data (measu
33 S patients are hypermetabolic with increased resting energy expenditure, but if and how hypermetaboli
34           The KE group exhibited 14% greater resting energy expenditure, but the total energy expendi
35      Caloric prescription exceeded predicted resting energy expenditure by 30%-100%.
36 king annual measures of body composition and resting energy expenditure (by indirect calorimetry) and
37 ytokine or counterregulatory hormone levels, resting energy expenditure, caloric intake, pulmonary fu
38                                   Changes in resting energy expenditure, cardiac function, and body c
39 t, weight, body composition, serum hormones, resting energy expenditure, cardiac function, muscle str
40                                              Resting energy expenditure declined by 10.5% during the
41                                              Resting energy expenditure decreased less with the low-g
42                                 Sleeping and resting energy expenditures decreased in proportion to c
43 d heart rate and percentage of the predicted resting energy expenditure, decreased accumulation of ce
44 xpenditure as these mice exhibited decreased resting energy expenditure, decreased body temperature,
45                                   Changes in resting energy expenditure did not differ significantly
46 cantly lower in the EB period (P=0.001), and resting energy expenditure did not differ significantly
47 ngle-bout control groups, SIT did not affect resting energy expenditure (EE: ventilated hood techniqu
48 ces were seen between measured and predicted resting energy expenditure either within or between grou
49  0.002) and less closely with their measured resting energy expenditure expressed as kcal/d (r = 0.69
50 enditure from doubly labeled water minus the resting energy expenditure from indirect calorimetry, wa
51                                              Resting energy expenditure further increased significant
52  by using a stress-related correction to the resting energy expenditure grossly overestimate MEE.
53 ectations, fasting, a condition that reduces resting energy expenditure, has been reported to increas
54 hondrial oxidative capacity while decreasing resting energy expenditure in severely burned children.
55 es could explain > 45% of the variability of resting energy expenditure in subjects 130-159% of ideal
56                                              Resting energy expenditure in the fed and fasting states
57  Beta-blockade decreased the heart rates and resting energy expenditure in the propranolol group, bot
58 a rebound increase in oxygen consumption and resting energy expenditure in the recovery phase of seps
59 ars to be the only useful way of determining resting energy expenditure in these patients.
60 sed fasting fat oxidation (P < 0.01), whilst resting energy expenditure increased after HA and HP com
61             Overall, insulin sensitivity and resting energy expenditure increased and serum gamma-glu
62 ric (kcal/kg/day) prescription and predicted resting energy expenditure (kcal/kg/day).
63 One key characteristic of cachexia is higher resting energy expenditure levels than in healthy indivi
64 emodialysis patients have higher than normal resting energy expenditure levels, which is further incr
65 cal Activity Level (total energy expenditure/resting energy expenditure &lt;/= 1.75), only 17% (n=7) of
66 ) with caloric intake 20% to 30% above their resting energy expenditure measured by indirect calorime
67  Sigma(K(i) x T(i)), where REE is whole-body resting energy expenditure measured by indirect calorime
68                                              Resting energy expenditure, measured by indirect calorim
69 fter burn, height, weight, body composition, resting energy expenditure, muscle strength, and serum h
70                                      Neither resting energy expenditure nor respiratory quotient were
71                                 In contrast, resting energy expenditure (normal protein diet: 160 kca
72 y when a standard 1.5 g/kg/day protein and a resting energy expenditure of 120% to 130% of calories i
73    Because this process requires energy, the resting energy expenditure of ill patients increases.
74 ialysis patients have a significantly higher resting energy expenditure on a nondialysis day (1.18 +/
75          These mice also exhibited increased resting energy expenditure on both chow and high fat die
76 ntake, greater lipid fuel preference and non-resting energy expenditure, one-half the body fat, and b
77 tation also had no effect on blood pressure; resting energy expenditure; oxidation rates of lipid; ec
78  the postdialysis period and nondialysis day resting energy expenditure (P < 0.001 for both).
79 mpared to controls (P = 0.002) and increased resting energy expenditure (P = 0.045) and total energy
80 ased serum IL-1beta and TNF-alpha as well as resting energy expenditure, P < 0.05.
81                                              Resting energy expenditure (PBMR), predicted energy expe
82 showing decreases in weight, blood pressure, resting energy expenditure, percentage body fat, free tr
83                                              Resting energy expenditure rates and those after meal in
84                                 The combined resting energy expenditure (REE) and handgrip strength p
85                        Weight change affects resting energy expenditure (REE) and metabolic risk fact
86    This was a cross-sectional study in which resting energy expenditure (REE) and NB were measured an
87 energy expenditure (TEE) and its components, resting energy expenditure (REE) and physical activity e
88  determined the reproducibility of measuring resting energy expenditure (REE) and the effect on REE o
89                                              Resting energy expenditure (REE) and the thermic effect
90 ntake from a 9835-kcal food array (n = 185), resting energy expenditure (REE) by using indirect calor
91                                              Resting energy expenditure (REE) can be depressed in aff
92                              Measurements of resting energy expenditure (REE) can be used to determin
93                                Lean mass and resting energy expenditure (REE) decrease with age.
94                         Body composition and resting energy expenditure (REE) have not been examined
95 d feeding studies and measures of short-term resting energy expenditure (REE) have suggested that the
96 lop a clinically useful equation to estimate resting energy expenditure (REE) in adolescents with SCA
97                                              Resting energy expenditure (REE) in adults with untreate
98                                        Lower resting energy expenditure (REE) in African American wom
99 o analyze the influence of age and gender on resting energy expenditure (REE) in severely burned chil
100                                              Resting energy expenditure (REE) is commonly measured in
101                      Accurate measurement of resting energy expenditure (REE) is helpful in determini
102            Accurate estimation of children's resting energy expenditure (REE) is important for planni
103                 Previous studies showed that resting energy expenditure (REE) is lower in obese Afric
104  rate organs (HMROs) mediates variability in resting energy expenditure (REE) is unknown.
105 30-150% of estimated energy expenditure, but resting energy expenditure (REE) may be lower than expec
106           We previously derived a whole-body resting energy expenditure (REE) prediction model by usi
107               African Americans have a lower resting energy expenditure (REE) relative to fat-free ma
108           African Americans may have a lower resting energy expenditure (REE) than do whites, althoug
109 fat-free mass (FFM)-independent reduction of resting energy expenditure (REE) to caloric restriction
110 o studies conducted in Pima Indians, in whom resting energy expenditure (REE) was found to be inverse
111                                              Resting energy expenditure (REE) was measured by indirec
112    Total daily energy expenditure (TDEE) and resting energy expenditure (REE) were measured and AEE w
113 erminants of total energy expenditure (TEE), resting energy expenditure (REE), and activity-related e
114 xyprogesterone acetate) affects food intake, resting energy expenditure (REE), and body weight in you
115 ences in energy balance [ie, dietary intake, resting energy expenditure (REE), and physical activity]
116 ion analyses, peak O2 consumption (VO2peak), resting energy expenditure (REE), and sex were independe
117                                              Resting energy expenditure (REE), body composition, and
118      The aim of this study was to assess the resting energy expenditure (REE), body composition, and
119                                              Resting energy expenditure (REE), but not body compositi
120                  To test the hypothesis that resting energy expenditure (REE), estimated total daily
121 has been shown that Black women have a lower resting energy expenditure (REE), factors affecting REE
122 ossover study included serial assessments of resting energy expenditure (REE), fat and carbohydrate o
123  We examined the relation of DEE to pretrial resting energy expenditure (REE), FFM, REE derived from
124                                              Resting energy expenditure (REE), oxygen consumption, an
125  (P < 0.01) and derived metabolic variables [resting energy expenditure (REE), respiratory quotient (
126 (SP) diets on weight loss, body composition, resting energy expenditure (REE), satiety and appetite,
127 ains unclear.We studied the relation between resting energy expenditure (REE), the estimated energy b
128   MAIN OUTCOME MEASURES: Primary outcome was resting energy expenditure (REE), with secondary outcome
129 cterized by loss of muscle mass and elevated resting energy expenditure (REE).
130 ect of prolonged elevation of epinephrine on resting energy expenditure (REE).
131 red continuously by using accelerometry) and resting energy expenditure (REE).
132 taneous fat and is associated with increased resting energy expenditure (REE).
133 syndromes are also associated with increased resting energy expenditure (REE).
134 s expressed as 1) unadjusted PAEE [TEE minus resting energy expenditure (REE); in MJ/d], 2) PAEE adju
135 ergy expenditure pattern was determined from resting energy expenditure (REE, n = 61 SQCP; n = 37 con
136 position (dual energy x-ray absorptiometry), resting energy expenditure (REE; indirect calorimetry),
137       Results were analyzed according to the resting energy expenditure (REE; Schofield formula).
138                                     The 24-h resting energy expenditure (respiratory chamber) measure
139                           In the short term, resting energy expenditure significantly decreased (p <
140                                              Resting energy expenditure significantly increased postt
141                                              Resting energy expenditure, total energy expenditure, an
142                                     Measured resting energy expenditure was 4.72 +/- 2.53 MJ/d.
143                                              Resting energy expenditure was determined by indirect ca
144 as estimated by using activity monitors, and resting energy expenditure was determined by indirect ca
145                                              Resting energy expenditure was determined daily for < or
146                                              Resting energy expenditure was lower (P < 0.0001) and le
147                                          The resting energy expenditure was measured by indirect calo
148                                              Resting energy expenditure was measured by indirect calo
149                                              Resting energy expenditure was measured by using indirec
150                                              Resting energy expenditure was measured during hospital
151 y dual-energy x-ray absorptiometry biweekly, resting energy expenditure was measured weekly by ventil
152                                              Resting energy expenditure was similar between control a
153            Mean physical activity level (TEE/resting energy expenditure) was 1.56 (SD 0.39) at age 3
154 ucose, lipid, and insulin concentrations and resting energy expenditure were measured before and afte
155 by using a 4-compartment model, sleeping and resting energy expenditures were assessed by using a cha
156 onist propranolol decreases cardiac work and resting energy expenditure while increasing peripheral l
157  included in the data analysis consisting of resting energy expenditure, whole body and liver insulin
158                   CE significantly increased resting energy expenditure, whole-body glucose disposal,
159 -Benedict nor the Talbot method will predict resting energy expenditure with acceptable precision for

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