ライフサイエンスコーパス: ergometer

1 est and exercise (100 W on a recumbent cycle ergometer).

2 to exhaustion on a custom-built supine cycle ergometer.

3 eks of aerobic training performed on a cycle ergometer.

4 ded exercise test was performed on a bicycle ergometer.

5 ng progressive intensity exercise on a cycle ergometer.

6 at rest and at peak exercise using the cycle ergometer.

7 ve exertions (Ex1, Ex2) using a supine cycle ergometer.

8 supine position, on a lower extremity cycle ergometer.

9 p after performing a bout of HIIT on a cycle ergometer.

10 formance by power output on an indoor rowing ergometer.

11 sing a 15-km time trial conducted on a cycle ergometer.

12 formed a maximal exercise test using a cycle ergometer.

13 ed incremental exercise using a supine cycle ergometer.

14 ental CPET on an electronically braked cycle ergometer.

15 ess test on an electronically braked bicycle ergometer.

16 Protocol 2, exercise with a lower extremity ergometer.

17 xercised to exhaustion, using a graded cycle ergometer.

18 nergy expenditure than the Airdyne and cycle ergometer.

19 with use of the stair stepper and the rowing ergometer.

20 se echocardiography on a semirecumbent cycle ergometer.

21 se during a fixed workload (50 W) on a cycle ergometer.

22 imited CPET on a treadmill (n=3330) or cycle ergometer.

23 ntensity interval training (HIIT) on a cycle ergometer.

24 exercise using a magnetic resonance imaging ergometer.

25 pulmonary exercise testing (CPET) on a cycle ergometer.

26 ercise echocardiography using a supine cycle ergometer.

27 2 races (black and white) exercised on cycle ergometers 3 d/wk for a total of 60 exercise sessions st

28 All subjects trained on cycle ergometers 5 d/wk for 4 wk, beginning on week 3 of the s

29 All subjects trained on cycle ergometers 5 d/wk for the last 4 wk of the study.

30 e, a cross-country skiing simulator, a cycle ergometer, a rowing ergometer, a stair stepper, and a tr

31 kiing simulator, a cycle ergometer, a rowing ergometer, a stair stepper, and a treadmill.

32 xercised using a previously calibrated cycle ergometer and a 3-min incremental cycle exercise protoco

33 k work capacity, determined by using a cycle ergometer and a graded, progressive protocol, and a prol

34 come was aerobic fitness assessed on a cycle ergometer and quantified as peak absolute oxygen consump

35 10 adult participants rotating an upper limb ergometer, and EMG-EMG coherence, EMG amplitude correlat

36 pe relationship, and unaffected by the site, ergometer, and gas exchange measurement systems.

37 exercises were performed on an MR-compatible ergometer, and oxygen uptake was continuously acquired u

38 ental exercise test was performed on a cycle ergometer, and relative abdominal and chest wall displac

39 The cross-country skiing simulator, rowing ergometer, and stair stepper induced higher (P < .05) ra

40 ed an incremental exercise test on the cycle ergometer, and target values were calculated at approxim

41 on three occasions for 120 min on a bicycle ergometer at 50 % maximum velocity of O2 uptake and inge

42 min of steady-state exercise (Ex) on a cycle ergometer at 50% of individual working capacity, during

43 derwent 90 min of exercise on a static cycle ergometer at 80% of their anaerobic threshold (approxima

44 od gas variables at peak exercise on a cycle ergometer at approximately 4200 m.

45 Subjects pedalled a modified ergometer at different body orientations (from horizonta

46 ho had right heart catheterization and cycle ergometer CPET studies to maximum tolerance as part of t

47 ith PPH can safely undergo noninvasive cycle ergometer CPET to their maximal tolerance.

48 nts performed an Eriksen flanker task during ergometer cycling at moderate intensity (in EXP.

49 erface during constant work rate (CWR) cycle ergometer exercise and associated effects on dyspnea, re

50 ut ( QT ) at rest and during recumbent cycle ergometer exercise at 760 Torr (SL) and at 410 Torr (ALT

51 hy non-endurance-trained men performed cycle ergometer exercise at ~60 % of peak oxygen uptake while

52 rtery catheters and performed moderate cycle ergometer exercise for 6 to 7 minutes while submersed in

53 4-7) 30 s bouts of very high-intensity cycle ergometer exercise over 14 days; (2) sedentary control (

54 Training consisted of three 40-minute cycle ergometer exercise sessions per week for 8 weeks.

55 fitness was determined by progressive cycle ergometer exercise testing with breath-by-breath measure

56 were provided daily by increases in bicycle ergometer exercise time.

57 Progressive cycle ergometer exercise to volitional exhaustion was performe

58 nonsmokers (52 +/- 3 yr) before and after an ergometer exercise training program for 30 min per day,

59 8 large PFO+, 7 small PFO+) completed cycle ergometer exercise trials on three separate days.

60 nervous system activation, induced by cycle ergometer exercise, would contribute to post-exercise re

61 the lactate threshold, > LT) intensity cycle ergometer exercise.

62 e subjects at rest and after 60 min of cycle ergometer exercise.

63 o exhaustion on an electrically braked cycle ergometer following the infusion of either l-NAME (4 mg

64 en; age range, 33-61 years) pedalled a cycle ergometer for 30 to 40 minutes a day, 4 days a week, for

65 and eight lean subjects exercised on a cycle ergometer for 40 min.

66 atched control subjects exercised on a cycle ergometer for 45 min at 70% of maximum workload.

67 icipants randomized to exercise cycled on an ergometer for approximately 12 minutes, with the final 3

68 All exercised on cycle ergometers for 45 minutes, 3 times per week for 7 weeks

69 how age, sex, size, fitness, and the type of ergometer influenced ventilatory efficiency in normal su

70 mic knee extension against various levels of ergometer load was simulated.

71 erate-intensity aerobic exercise (on a cycle ergometer) on cognition.

72 90-minute light- to moderate-intensity cycle ergometer or outdoor walk/jog aerobic exercise performed

73 We used an ergometer pedalling paradigm to relate abnormalities in

74 Maximal ergometer power output, whole body weight and compositio

75 n+/-s.d., age 27+/-6 years) performed 4 h of ergometer rowing.

76 ter patients performed supine exercise on an ergometer secured to the CT table.

77 ons of 4-8 bouts of 30 s duration on a cycle ergometer separated by 4 min of active recovery.

78 Exercise tolerance using a bicycle ergometer showed increased exercise endurance from 4.43

79 work-rate) using a single-leg knee-extensor ergometer situated inside the bore of a 1.5 T super-cond

80 t SIT (n = 9): one session of 4 x 30 s cycle ergometer sprints.

81 ol I subjects performed an incremental cycle ergometer test (60 W + 30 W/2 min; breathing room air, F

82 Following an incremental cycle ergometer test for the determination of VO2max, the subj

83 Fitness was determined by a maximal cycle-ergometer test in 1025 children (aged 9.5 +/- 0.4 y) and

84 sed with a standardized treadmill or bicycle ergometer test protocol at baseline and week 30: carbon

85 II, subjects performed an incremental cycle ergometer test until volitional exhaustion while continu

86 All underwent a supine cycle ergometer test with simultaneous right heart catheteriza

87 , predicted cardiorespiratory fitness (cycle ergometer test), obesity (body weight and height), and a

88 sumption, estimated using a submaximal cycle ergometer test.

89 years; 6 boys) performed two separate cycle ergometer tests in which gas exchange was measured on a

90 rier Social Stress Test (stress) and bicycle ergometer training (sport).

91 t of three per week 45-min sessions of cycle ergometer training for 6 wk with exercise intensity kept

92 tion for 3 hours during intermittent bicycle ergometer training in a randomized, crossover, double-bl

93 art Association class, beta-blocker use, and ergometer type.

94 e on a magnetic resonance imaging-compatible ergometer until calf exhaustion.

95 h well-controlled SLE were tested on a cycle ergometer until volitional exhaustion, and 25 women and

96 Maximal oxygen consumption on a cycle ergometer was examined in nine adult (mean age 38.8 year

97 om an exhaustive 1-2 min sprint on a bicycle ergometer with a workload of 400 W.

98 erwent upright exercise testing on a bicycle ergometer with analysis of respiratory gas exchange by c

99 Ergometer work increased 20 Watt every 2 min; expiratory

100 illary wedge pressure (PCWP) at a submaximal ergometer workload (25 W) after 13 weeks of SGLT-2i trea