ライフサイエンスコーパス: calorimeter

1 eding were measured in a whole-room indirect calorimeter.

2 eding were measured in a whole-room indirect calorimeter.

3 vidin, are measured by the paper-based micro-calorimeter.

4 and SPA were measured for 24h in an indirect calorimeter.

5 s (n = 23) for 24 h in a whole-room indirect calorimeter.

6 esting that subjects were less active in the calorimeter.

7 er 24 h in a purpose-built 1.4 m3 whole-body calorimeter.

8 d in this study, using a whole-room indirect calorimeter.

9 ermal absorber material for high-power laser calorimeters.

10 lysis, which is challenging for conventional calorimeters.

11 the low-energy events observed in cryogenic calorimeters.

12 n addition, we placed animals in an indirect calorimeter after an IP injection of C75.

13 Differential Scanning Calorimeter analysis showed that the transition temperat

14 nts performed with a primary-standard proton calorimeter and derivation of the required correction fa

15 ility were measured by differential scanning calorimeter and Englyst's method, respectively.

16 SEE and REE were measured in a room calorimeter and f1.gif" BORDER="0">O(2)max was measured

17 subjects spent 23 h in a whole-room indirect calorimeter and were fed a diet similar to that consumed

18 , but no comprehensive review of the various calorimeters and methods has been done previously.

19 (Avena sativa) were studied in an isothermal calorimeter at -3 degrees C.

20 rgy expenditure, measured for 24 h in a room calorimeter at the end of each 8-wk period, was the same

21 pmol) were determined using an open-circuit calorimeter by measuring the volumes of oxygen consumed

22 We demonstrate performance of these calorimeters by resolving measurements of the heat of re

23 Silicon micromachined calorimeters ("calorimeter on a chip") are used to measu

24 Here, we report chip-based microfluidic calorimeters capable of characterizing the heat of react

25 ength of time needed detect heat flow in the calorimeter cell.

26 erformed by using a high-precision, indirect calorimeter connected to the subject via a transparent,

27 When used in a differential calorimeter containing a dilute solution of solute in th

28 The model was used to determine the optimum calorimeter design (membrane size and thickness, junctio

29 s comprising five cantilever, capacitor, and calorimeter devices coated with five different sorptive-

30 The Differential Scanning Calorimeter (DSC) analysis showed that the apo- and holo

31 ed oil samples through differential scanning calorimeter (DSC) analysis.

32 A differential scanning calorimeter (DSC) analyzed phase transitions in bulk sam

33 were determined with a differential scanning calorimeter (DSC) and a thermogravimetric analyzer (TGA)

34 Differential Scanning Calorimeter (DSC) showed better thermal stability of res

35 e investigated using a differential scanning calorimeter (DSC).

36 chelation using a nano-differential scanning calorimeter (DSC).

37 abolic rate (SLEEP) in a whole-room indirect calorimeter during 24-h fasting at thermoneutrality (24

38 nd respiratory quotient (RQ) in a whole-room calorimeter during energy balance (EBL) (50% carbohydrat

39 ally measured at low coverage using a Calvet calorimeter equipped with a customized dosing manifold.

40 ght, subjects lived in a whole-room indirect calorimeter for 3 days.

41 ent, they resided in the whole-body indirect calorimeter for the 7 d and had ad libitum access to a m

42 antitative comparison of the capabilities of calorimeters for simultaneous determination of equilibri

43 ducting qubits and low threshold dark matter calorimeters have observed excess bursts of quasiparticl

44 A microfabricated titration calorimeter having nanowatt sensitivity is presented.

45 levels (PALs) by using a whole-room indirect calorimeter in 10 adult women as they transitioned from

46 e (RMR) and 24-h EE assessed in a whole-room calorimeter in 507 and 419 Pima Indians, respectively.

47 rient content while in a whole-room indirect calorimeter in 64 healthy subjects with normal glucose r

48 ions are carried out by isothermal titration calorimeter in dimethylsulfoxide.

49 ing a high sensitivity differential scanning calorimeter in isothermal mode, we directly measured hea

50 A new ultrasensitive differential scanning calorimeter is described, having a number of novel featu

51 calorimeter operations; one example, a flow calorimeter, is described.

52 a compact (7.5 x 7.5 x 15 cm), modular X-ray calorimeter made of alternating layers of absorbing mate

53 eatment were monitored using an open-circuit calorimeter measuring the volume of oxygen consumed (VO2

54 An isothermal titration calorimeter of the perfusion type (MicroCal model VP-ITC

55 The pyroelectric thin-film calorimeter offers submillisecond temporal resolution th

56 Silicon micromachined calorimeters ("calorimeter on a chip") are used to measure heat capacit

57 y to enable a wide variety of other standard calorimeter operations; one example, a flow calorimeter,

58 xpenditures were assessed by using a chamber calorimeter, physiologic stress of exercise and exercise

59 been challenging to realize microchip-based calorimeters possessing both high sensitivity and precis

60 500-fold improvement over the most sensitive calorimeter previously used for measuring the metabolic

61 High-sensitivity microfluidic calorimeters raise the prospect of achieving high-throug

62 The dose-per-pulse measured by the calorimeter ranged between 0.03 Gy/pulse and 5.26 Gy/pul

63 of-concept, we demonstrate how the molecular calorimeters report heat changes generated in water/prop

64 electrical calibration of power compensation calorimeters require validation of the calorimetric fact

65 ntestinal fat absorption and an open circuit calorimeter, respectively.

66 doubly labeled water and whole-room indirect calorimeter, respectively.

67 Differential scanning calorimeter scans of the sequence in solution exhibited

68 esigning molecular sensors, that function as calorimeters: sensors based on memory.

69 The time constant of the calorimeter system was determined experimentally using a

70 and/or high temperatures) in a modified cone-calorimeter system.

71 ngth necessary to construct high-sensitivity calorimeters that can be scaled to automated, highly mul

72 When the frozen tissue was placed in the calorimeter, the pressure increased within 4 d to 25 and

73 ed T(m) during the first heating scan in the calorimeter, then lowered it below T(o) in subsequent sc

74 Here, we use a recently developed picowatt calorimeter to experimentally measure the energetics of

75 Here, we have repurposed an isothermal calorimeter to measure heat flow between developing zebr

76 management problems, ranging from nanoscale calorimeters to microelectronic processors to macroscopi

77 microfabricated suspended-membrane titration calorimeters to nanoliter droplets and improved the sens

78 a group of 5 cantilever, 5 capacitor, and 5 calorimeter transducers coated with 1 of 5 different sor

79 Using this calorimeter, we demonstrate time-resolved metabolic meas

80 e pressure was released, the output from the calorimeter went from -194 to 229 microW within 1 h, sug

81 pid visco-analyzer and differential scanning calorimeter were observed after SFE.

82 pounds was analysed by differential scanning calorimeter, where decreased DeltaH inferred potential c

83 of UCN were monitored using an open circuit calorimeter which measured oxygen consumption (V(O2)) an

84 rimental platform that comprises a heat-flow calorimeter with a resolution of about 100 pW, we experi

85 ing accurate results with nanowatt titration calorimeters with overflow cells requires mass calibrati

86 man subjects utilizing a whole room indirect calorimeter (WRIC).

87 Whole-room indirect calorimeters (WRICs) have traditionally been used for re