ライフサイエンスコーパス: indirect calorimetry

1 he estimates from conventional respirometry (indirect calorimetry).

2 REE was measured by using indirect calorimetry.

3 response to the test meal was ascertained by indirect calorimetry.

4 iture was measured during hospital course by indirect calorimetry.

5 hermic effect of food were measured by using indirect calorimetry.

6 Resting metabolic rate (RMR) was measured by indirect calorimetry.

7 , and substrate oxidation was determined via indirect calorimetry.

8 RMR was determined with the use of indirect calorimetry.

9 the thermic effect of food were measured by indirect calorimetry.

10 RMR was determined by using indirect calorimetry.

11 ted tomography, and REE by ventilated-canopy indirect calorimetry.

12 y a treadmill test to exhaustion, and RMR by indirect calorimetry.

13 ated in each case for a 30-min period, using indirect calorimetry.

14 24-h EE and SEE were measured by whole-room indirect calorimetry.

15 using the equations of Schofield et al or by indirect calorimetry.

16 ck method and other prediction equations and indirect calorimetry.

17 resting energy expenditure was determined by indirect calorimetry.

18 of nutrient infusion and EE was measured by indirect calorimetry.

19 the values obtained with those calculated by indirect calorimetry.

20 th measured energy expenditure determined by indirect calorimetry.

21 xperiment, we measured energy expenditure by indirect calorimetry.

22 asive hemodynamics, and treadmill coupled to indirect calorimetry.

23 treadmill, with ground-truth EE measured via indirect calorimetry.

24 ermining the respiratory quotient (RQ) using indirect calorimetry.

25 ing radiolabeled palmitate and in mice using indirect calorimetry.

26 ydrate-dependent metabolism as determined by indirect calorimetry.

27 during rest and cold stress was measured by indirect calorimetry.

28 Substrate oxidation was measured by indirect calorimetry.

29 rgy expenditure was measured with the use of indirect calorimetry.

30 th-by-breath oxygen uptake was determined by indirect calorimetry.

31 with dual-tracer glucose administration and indirect calorimetry.

32 Energy expenditure was assessed by indirect calorimetry.

33 d cold (15.5 degrees C [60 degrees F]) using indirect calorimetry.

34 Energy expenditure was measured by indirect calorimetry.

35 The REE was measured by indirect calorimetry.

36 ng rest and mild cold stress was measured by indirect calorimetry.

37 ptiometry, and resting energy expenditure by indirect calorimetry.

38 liance on lipid as an energy source based on indirect calorimetry.

39 REE was measured by indirect calorimetry.

40 d substrate oxidation were measured by using indirect calorimetry.

41 mic effect of feeding (TEF) were measured by indirect calorimetry.

42 o of CLA supplementation by using whole-room indirect calorimetry.

43 and locomotor activity were monitored using indirect calorimetry.

44 Measurement of metabolic rates by indirect calorimetry after chronic high-fat diet challen

45 water and for 36 hours in the laboratory by indirect calorimetry along with detailed cognitive and c

46 done to compare predictive equations against indirect calorimetry among critically ill patients at di

47 mean resting energy expenditure measured by indirect calorimetry among the three phases.

48 Indirect calorimetry analyses revealed that the deletion

49 Indirect calorimetry analysis showed that Cc1(-/-) mice

50 their resting energy expenditure measured by indirect calorimetry and 1.5 g/kg/day protein of TPN.

51 ycemic hyperinsulinemic) in combination with indirect calorimetry and [6,6-2H2]glucose.

52 21 Pima Indians characterized in vivo using indirect calorimetry and a euglycemic hyperinsulinemic c

53 emic clamp studies and energy expenditure by indirect calorimetry and biotelemetry in male Wistar and

54 sured by doubly-labeled water and whole-room indirect calorimetry and body composition as 3-compartme

55 ing energy expenditure (REE) was measured by indirect calorimetry and body composition by dual x-ray

56 REE was determined by indirect calorimetry and body composition by dual-energy

57 perinsulinemic-euglycemic clamp analysis and indirect calorimetry and body fat composition was measur

58 PN) were measured for > or = 15 min by using indirect calorimetry and compared with REEs calculated f

59 sured resting metabolic rate with the use of indirect calorimetry and daily energy expenditure by the

60 Indirect calorimetry and dual-energy x-ray absorptiometr

61 ]palmitate infusion techniques combined with indirect calorimetry and euglycemic insulin clamp.

62 patients have been estimated primarily from indirect calorimetry and from nitrogen balance studies.

63 n = 61 SQCP; n = 37 control group) by using indirect calorimetry and from total energy expenditure (

64 and insulin sensitivity were assessed using indirect calorimetry and hyperinsulinemic-euglycemic cla

65 Simultaneous measurement of indirect calorimetry and leg net balance of phenylalanin

66 Resting energy expenditure was determined by indirect calorimetry and skeletal muscle protein kinetic

67 Using a combination of indirect calorimetry and stable-isotope flux phenotyping

68 calculated whole-body net fat synthesis from indirect calorimetry and substrate balance data from fiv

69 resting energy expenditure (REE) measured by indirect calorimetry and TEE by doubly labeled water.

70 Resting metabolic rate was measured using indirect calorimetry and the thermic effect of meals was

71 rmed hyperinsulinemic-euglycemic clamps with indirect calorimetry and vastus lateralis muscle biopsie

72 derwent assessments of oxygen uptake (Vo(2); indirect calorimetry) and cardiac output (acetylene rebr

73 lin deprivation on energy expenditure (using indirect calorimetry) and protein metabolism (using L-[1

74 mposition and resting energy expenditure (by indirect calorimetry) and two annual measures of total e

75 tion (DXA), resting energy expenditure (REE; indirect calorimetry), and cardiometabolic risk factors.

76 and triglycerides), lipid oxidation (LOx; by indirect calorimetry), and ketogenesis (from circulating

77 al (NOGD), oxidative glucose disposal (OGD) (indirect calorimetry), and splanchnic glucose output (SG

78 ing energy expenditure was measured by using indirect calorimetry, and an accelerometer was also used

79 Energy expenditure was registered by indirect calorimetry, and blood was repeatedly sampled t

80 the use of dual-energy X-ray absorptiometry, indirect calorimetry, and ELISA.

81 nd the respiratory quotient were measured by indirect calorimetry, and energy expenditure (MEE) was c

82 , exogenous lipid oxidation with breath-test/indirect calorimetry, and fecal excretion.

83 t-weighing, sleeping metabolic rate (SMR) by indirect calorimetry, and FFM, FM, and total energy expe

84 t, height, dual-energy x-ray absorptiometry, indirect calorimetry, and hormone values were measured a

85 -body resting energy expenditure measured by indirect calorimetry, and T(i) is the mass of individual

86 perinsulinemic clamp technique combined with indirect calorimetry, and the rate of glycogen synthesis

87 g metabolic rate (RMR) was measured by using indirect calorimetry, and the thermic effect of meals wa

88 18O and 2H), resting metabolic rate (RMR) by indirect calorimetry, and total energy expenditure (TEE)

89 Indirect calorimetry appears to be the only useful way o

90 t loss and metabolic alterations measured by indirect calorimetry, as well as impaired thermoregulati

91 Indirect calorimetry at 2 months post-CI showed no metab

92 nd white girls and boys aged 6-11 y by using indirect calorimetry at 4 US sites.

93 REE was measured by indirect calorimetry at admission, discharge, 14-and-45-

94 e resting energy expenditure was measured by indirect calorimetry at ambient temperatures of 22, 28,

95 Resting energy expenditure was measured by indirect calorimetry at baseline and during infusion.

96 ainst resting energy expenditure measured by indirect calorimetry at different phases.

97 EE was determined by indirect calorimetry, at rest and during a 30-min cycle-

98 emic clamp with skeletal muscle biopsies and indirect calorimetry before and after a 5-day HFHC diet.

99 Fat oxidation was determined by indirect calorimetry before and after consumption of fou

100 HFMM) lipid metabolism was assessed by using indirect calorimetry, blood sampling, and microdialysis.

101 ch study phase, assessments included RMR (by indirect calorimetry), body composition (by hydrostatic

102 These data include RMR (indirect calorimetry), body composition (dual-energy X-r

103 From days 7-10, animals were housed in indirect calorimetry chambers after which soleus muscle

104 with resting energy expenditure measured by indirect calorimetry compared with predictive equations

105 ew in Nature Metabolism by the International Indirect Calorimetry Consensus Committee (IICCC) address

106 of de novo lipogenesis (DNL), and changes in indirect calorimetry consistent with increased whole-bod

107 Indirect calorimetry demonstrated increased oxygen consu

108 blood metabolite and hormone concentrations, indirect calorimetry, determination of body-composition

109 Indirect calorimetry determines energy expenditure by me

110 bolism is measured by powerful and sensitive indirect calorimetry devices.

111 Resting energy expenditure, measured by indirect calorimetry, did not change.

112 ptiometry), resting energy expenditure (REE; indirect calorimetry), dietary intake (2-day dietary rec

113 e concentrations nor respiratory quotient by indirect calorimetry differed between men and women.

114 Metabolic phenotyping was performed using indirect calorimetry, dual energy x-ray absorptiometry,

115 te significantly with more subtle changes in indirect calorimetry due to walking with different shoe

116 surement of the respiratory quotient (RQ) by indirect calorimetry during the fasted to fed transition

117 ume, and respiratory rate were calculated by indirect calorimetry durng rest; a 30-min, low-to-medium

118 Indirect calorimetry experiments showed that apelin-trea

119 emic-euglycemic clamp), substrate oxidation (indirect calorimetry), first- and second-phase insulin s

120 r a 10-h overnight fast, RMR was measured by indirect calorimetry for 30 min before and 120 min after

121 rrelated significantly with large changes in indirect calorimetry from walking on different grades sh

122 energy expenditure (doubly labeled water and indirect calorimetry), glucose tolerance (oral glucose t

123 However, lipid oxidation (assessed by indirect calorimetry), glycerol, and NEFA responses were

124 l women had lower postprandial FA oxidation (indirect calorimetry), greater meal FA, and direct free

125 ured by body temperature, physical activity, indirect calorimetry, heart rate, and brain activity.

126 Here, in a series of neuroimaging and indirect calorimetry human studies, we examine the relat

127 examined as potential predictors of mREE by indirect calorimetry (IC) in 122 SMAI children consecuti

128 Indirect calorimetry (IC) is the gold standard for deter

129 Indirect calorimetry (IC) with metabolic monitors is wid

130 Fifty indirect calorimetry (IDC) measurements with and without

131 In critically ill patients receiving TPN, indirect calorimetry, if available, remains the most app

132 Each patient underwent indirect calorimetry immediately before establishment of

133 was measured by DXA and REE was assessed by indirect calorimetry in 201 healthy participants.

134 From 1995 to 2001, REE was measured by indirect calorimetry in 250 survivors of 10 to 99%TBSA b

135 text]O2 max) were determined with the use of indirect calorimetry in 305 healthy volunteers [150 men

136 RMR was measured with indirect calorimetry in 43 patients with HFpEF undergoin

137 and sleeping EE were measured by whole-room indirect calorimetry in 56 women.

138 early-stage HD and in 9 control subjects via indirect calorimetry in a human respiratory chamber.

139 nd survival.REE was measured with the use of indirect calorimetry in cancer patients before the initi

140 mean resting energy expenditure measured by indirect calorimetry in late phase (1,878 +/- 517 kcal)

141 umption determined by the Fick method and by indirect calorimetry in mechanically ventilated patients

142 continuous glucose monitoring approach, and indirect calorimetry in mice, to investigate the underly

143 e respiratory quotient (RQ) were measured by indirect calorimetry in the postabsorptive state at the

144 -body VO2 max during cycling (Body VO2 max , indirect calorimetry) in 10 endurance exercise-trained a

145 REE was measured, by indirect calorimetry, in 100 cirrhotic patients and 41 c

146 ycemic insulin clamp technique combined with indirect calorimetry (insulin infusion rate (1.5 mU x kg

147 ulinemic-euglycemic clamp), lipid oxidation (indirect calorimetry), insulin secretion (2-h hyperglyce

148 d to predict resting energy expenditure when indirect calorimetry is not available.

149 A method of indirect calorimetry is proposed that attempts to better

150 icality and high cost of direct calorimetry, indirect calorimetry is the major approach for modern me

151 was determined from doubly labeled water and indirect calorimetry, lipolysis from infusion of [1-13C]

152 ed in conjunction with leg balance and local indirect calorimetry measurements before and at the end

153 olled in a prospective study and followed by indirect calorimetry measurements.

154 sured, and dual-energy X-ray absorptiometry, indirect calorimetry (men only), and genotyping were con

155 onents are estimated using variations of the indirect calorimetry method.

156 ), resting energy expenditure (REE) by using indirect calorimetry (n = 302), or total daily energy ex

157 lucose, lactate, and pyruvate, combined with indirect calorimetry, needed characterization in a near-

158 ed while the subjects were inactive by using indirect calorimetry on day 15, and S(I) was measured by

159 re measured daily, with body composition and indirect calorimetry performed on day 11, and an insulin

160 We also measured oxygen consumption (indirect calorimetry); plasma levels of glucagon, bicarb

161 , and the respiratory quotient obtained from indirect calorimetry (r = .87; P < .001).

162 ence, anitisense RNA, mouse feeding studies, indirect calorimetry, real-time PCR, and Western blots.

163 were measured using doubly labeled water and indirect calorimetry, respectively.

164 change in RMR), armband accelerometers, and indirect calorimetry, respectively.

165 Indirect calorimetry revealed lipid oxidation as the pri

166 Indirect calorimetry revealed reduced energy expenditure

167 Moreover, indirect calorimetry revealed respiratory exchange ratio

168 Indirect calorimetry should be the preferred standard fo

169 Indirect calorimetry showed that 24-hr energy expenditur

170 Indirect calorimetry showed that Cyp2e1-null-mice fed FF

171 Accurate indirect calorimetry studies can be performed in both ve

172 Indirect calorimetry studies detected no difference in e

173 Pair-feeding and indirect calorimetry studies indicate that reduced food

174 ogical parameters were measured using Oxymax indirect calorimetry system in 12-week-old VAMP8 null mi

175 Mice were analyzed in vivo with the indirect calorimetry system, and tissues were analyzed b

176 REE was measured after an overnight fast by indirect calorimetry, TEE by heart rate monitoring, and

177 each condition, participants were studied by indirect calorimetry the following morning as well (D2).

178 To eliminate the need for indirect calorimetry, this randomized, double-blind, pro

179 y expenditure was measured by using portable indirect calorimetry throughout each experimental condit

180 able-isotope mass spectrometric methods with indirect calorimetry to establish the metabolic basis of

181 The application of doubly labeled water and indirect calorimetry to understand the etiology of wasti

182 intermediary metabolites, substrate flux via indirect calorimetry, tracer-determined glucose kinetics

183 espiratory quotient (RQ) by using whole-room indirect calorimetry under fixed-meal conditions.

184 Metabolic rates were measured by indirect calorimetry using the Comprehensive Lab Animal

185 m(-2) x min(-1)) clamp with [3-(3)H]glucose/indirect calorimetry/vastus lateralis muscle biopsies be

186 Indirect calorimetry, venous blood samples and video-ana

187 red the percentage increase in EE (DeltaEE%; indirect calorimetry, ventilated hood method) above rest

188 Mean REE by indirect calorimetry was 8381+/-1940 kJ/d and correlated

189 Indirect calorimetry was also used to determine metaboli

190 s and resting energy expenditure measured by indirect calorimetry was analyzed using intraclass corre

191 Indirect calorimetry was measured thrice during acute, l

192 e and for two hours after colonic infusions, indirect calorimetry was performed and blood samples wer

193 e for lipid profiles and insulin resistance, indirect calorimetry was performed and visceral white ad

194 NMB was then induced, and indirect calorimetry was repeated.

195 from resting energy expenditure measured by indirect calorimetry was used to assess accuracy.

196 Indirect calorimetry was used to assess respiratory quot

197 Indirect calorimetry was used to determine observed phen

198 Indirect calorimetry was used to determine systemic rest

199 Stable isotope tracer methodology and indirect calorimetry was used to determine the rates of

200 er minus the resting energy expenditure from indirect calorimetry, was assessed in 450 Women's Health

201 s, basal metabolic rate, measured at rest by indirect calorimetry, was significantly higher in knocko

202 ergy metabolism, which was assessed by using indirect calorimetry, was used to calculate PAL.

203 Resting EE--measured using indirect calorimetry--was not affected by GLP-1 infusion

204 Using indirect calorimetry, we measured lipid oxidation, oxida

205 Using indirect calorimetry, we observed that male Exoc5-SMKO m

206 Using indirect calorimetry, we uncovered that slight, but non-

207 n (V(O2) by the reverse Fick equation and by indirect calorimetry were performed every 6 hrs for 24 h

208 period, the mean V(O2) values determined by indirect calorimetry were significantly greater than the

209 with hyperinsulinemic-euglycemic clamps and indirect calorimetry were used to measure rates of hepat

210 eters (glucose tolerance, insulin tolerance, indirect calorimetry) were assessed.

211 d composition (4-compartment model) and RMR (indirect calorimetry) were measured after 4 wk of weight

212 cans on RMR and RQ phenotypes, obtained from indirect calorimetry, were performed in 169 families asc

213 ccurate clinical tool used to measure REE is indirect calorimetry, which is expensive, requires train

214 owed an increase in energy expenditure using indirect calorimetry, which was accompanied by increased

215 of this study was to compare REE measured by indirect calorimetry with REE calculated by using the Fi

216 minus resting metabolic rate (measured with indirect calorimetry), with adjustment for the thermic e