ライフサイエンスコーパス: isometric contraction

1 etter effect during dynamic movement than in isometric contraction.

2 nits in the calf muscles during a submaximal isometric contraction.

3 tin-bound myosin heads is higher than during isometric contraction.

4 the actin layer lines are lower than during isometric contraction.

5 anism with the slowing of relaxation from an isometric contraction.

6 generated by a single myosin molecule during isometric contraction.

7 kinetics following a 24 s maximal voluntary isometric contraction.

8 cantly alter the magnitude of FBS-stimulated isometric contraction.

9 and temporalis muscles following a sustained isometric contraction.

10 d equivalent to 20% of the maximal voluntary isometric contraction.

11 fatiguing exercise test of a sustained 45-s isometric contraction.

12 ference in fatigability during intermittent, isometric contractions.

13 hase (<100 ms) of force development in rapid isometric contractions.

14 g dynamic oscillations and only investigated isometric contractions.

15 mass, strength, and force production during isometric contractions.

16 nnervating the hand and thigh muscles during isometric contractions.

17 , seven men and one woman) during submaximal isometric contractions.

18 pper limbs of older adults during submaximal isometric contractions.

19 increased energetic demand of dynamic versus isometric contractions.

20 d minimal impact on predicted fatigue during isometric contractions.

21 ons and, ultimately, fatigue during repeated isometric contractions.

22 y second before, during and after stimulated isometric contractions.

23 y second before, during and after stimulated isometric contractions.

24 contractile proteins and force production in isometric contractions.

25 training the ankle-dorsiflexor muscles with isometric contractions.

26 scles to maintain force during a protocol of isometric contractions.

27 elease superoxide or nitric oxide during the isometric contractions.

28 rength was assessed during maximal voluntary isometric contractions.

29 ontralateral hand and forearm muscles during isometric contractions.

30 work-loop contractions than in corresponding isometric contractions.

31 eraemic phase that followed a 30 s period of isometric contractions.

32 ngth sensitivity of force during ACh-induced isometric contractions.

33 ctivated FHS-myofibrils indicate that during isometric contraction 29% of the myosin heads are strong

34 In an isometric contraction, 54.7% of the attached heads were

35 tely estimated endurance times for sustained isometric contractions across a wide range of target lev

36 tion respectively improved maximum voluntary isometric contraction and reduced pain intensity (ES ran

37 ost of the lever arm rotation occurs between isometric contraction and the MgADP states, i.e., during

38 olution kernel compensation during voluntary isometric contractions and its application to contractio

39 was suppressed during unperturbed voluntary isometric contractions and reaching movements of the arm

40 es, however, was suppressed during voluntary isometric contractions and reaching movements of the arm

41 gascore for limb strength (maximum voluntary isometric contraction) and pulmonary function.

42 aks (N1-N3) at similar angles in relaxation, isometric contraction, and rigor.

43 ment axis was 100-110 degrees in relaxation, isometric contraction, and rigor.

44 s higher instantaneous stiffness than during isometric contraction, and yet consumes very little ATP.

45 (AM)) from cross-bridges during a maintained isometric contraction are similar, indicating that the A

46 exor muscles while participants performed an isometric contraction at 10% of the maximal voluntary co

47 ere identified from the ADM muscle during an isometric contraction at 15% of the maximal force (MVC)

48 ity varies among fiber states with rigor and isometric contraction at extremes where straight and ben

49 during ramp stretch compared to those during isometric contraction at physiological temperature using

50 re MUPs in the tibialis anterior (TA) during isometric contractions at 25% maximum voluntary contract

51 atigue development during repeated fatiguing isometric contractions at near-physiological, but not at

52 ne, or sag behavior, observed during unfused isometric contractions at the intermediate length under

53 upward for force enhancement during unfused isometric contractions at the intermediate length under

54 During the maximum isometric contraction before each stretch, the mean sarc

55 ric knee flexion at 20% of maximal voluntary isometric contraction, before and after a 10 x 30 m repe

56 oherence between cortex and periphery during isometric contraction builds on the presence of approxim

57 bly faster than dephosphorylated ones during isometric contraction but the duty cycle remained the sa

58 in crossbridges are attached to actin during isometric contraction, but a much smaller fraction is bo

59 During isometric contraction, but not during rigor, actin orien

60 obe had four peaks (C1-C4) in relaxation and isometric contraction, but only two of these (C2 and C4)

61 imilar in young and older adults during some isometric contractions, but less is known about potentia

62 tude of fluctuations in torque output during isometric contractions, but the effect of fatigue on the

63 neural drive were obtained during submaximal isometric contractions by decomposing high-density elect

64 was observed in the regulatory domain during isometric contraction, consistent with the substantial r

65 model predicted less fatigue during repeated isometric contractions, consistent with reports in the l

66 In isometric contractions during SR inhibition, isoprenalin

67 n heads in the fibre, suggesting that during isometric contraction either less than 17 % of the myosi

68 d only by eccentric contractions, but not by isometric contractions, even though the stress level of

69 We suggest that the SP released during isometric contractions excites an inhibitory pathway mod

70 (i.e. less than 1 min - e.g. sprints, jumps, isometric contractions) exhibits diurnal fluctuations, p

71 nits in the calf muscles during a submaximal isometric contraction, factor analysis was used to assig

72 maging eccentric contractions and repetitive isometric contractions (fatigue), while also improving f

73 t 5 MEPs that exceeded 20% maximal voluntary isometric contraction from 10 stimulations.

74 ordings were obtained during 10% and 25% MVC isometric contractions from the vastus lateralis (VL).

75 The rate of ATP utilisation during isometric contraction had a dependence on resting sarcom

76 The rate of ATP utilisation during isometric contraction had a Q10 of 3.6 throughout the te

77 Strong isometric contractions have been shown to limit vasodila

78 rtantly, ACE-083 also increased the force of isometric contraction in situ by the injected tibialis a

79 rate in non-COPD fibres; hence, the cost of isometric contraction in type I and type IIA COPD fibres

80 the brachioradialis muscles during voluntary isometric contractions in four subjects.

81 ng motor unit activity during torque-matched isometric contractions in male participants.

82 n rival those of cross-bridge cycling during isometric contractions in swine arterial smooth muscle.

83 thin filaments are highly disordered during isometric contraction, in contrast to their quasi-helica

84 bridge states observed from muscle fibers in isometric contraction, in the presence of MgADP, and in

85 Slow relaxation from an isometric contraction is characteristic of acutely fatig

86 er at the end of LR or at the plateau of the isometric contraction is estimated from the relation bet

87 s-1 (mean +/- S.E.M., n = 8 fibres); during isometric contraction it was 310 +/- 10 microM s-1 (mean

88 t studied as a slowing of relaxation from an isometric contraction, it has become apparent that this

89 During isometric contractions, less irNPYs were released from s

90 Prior to and after isometric contraction, measurements were made of tissue

91 We investigated ex vivo isometric contraction, mitochondrial respiration and cal

92 Ten minutes of 0.1-Hz isometric contraction more than doubled MBV (P < 0.05; n

93 The results suggest that in isometric contraction, most cross-bridges maintain tensi

94 ABSTRACT: During graded isometric contractions, motor unit (MU) firing rates inc

95 During graded isometric contractions, motor unit (MU) firing rates inc

96 ercise (5%, 15% and 25% of maximum voluntary isometric contraction; MVC) before and after local alpha

97 sure LM thickness at rest, maximum voluntary isometric contraction (MVIC), and NMES with MVIC.

98 During a 3 h isometric contraction neither the glucose utilization (R

99 ecovery between sexes following intermittent isometric contractions normalised to critical intensity.

100 nd long thumb abductor muscles during steady isometric contraction obtained while subjects abducted t

101 Isometric contraction of isolated rat left ventricular p

102 bitory circuits in terminating a 20% maximum isometric contraction of the first dorsal interosseous m

103 During half-maximal isometric contraction of the tissues with acetylcholine,

104 During half-maximal isometric contraction of the tissues with acetylcholine,

105 n consumption following a approximately 15 s isometric contraction of the vastus lateralis muscle.

106 Voluntary isometric contraction of triceps surae elicited a signif

107 ) (high), on force and ATP hydrolysis during isometric contractions of permeabilized white fibres fro

108 6 women) performed six intermittent maximal isometric contractions of the ankle dorsiflexors (12 s c

109 ysis of 180 experimental MUs detected during isometric contractions of the biceps brachii revealed a

110 e rostral brainstem in response to fatiguing isometric contractions of the hindlimb muscle of cats an

111 d variable fascicle gearing during voluntary isometric contractions of the medial gastrocnemius (MG)

112 e cortical and motor unit (MU) levels during isometric contractions of the tibialis anterior muscle.

113 +/- 63 per participant; n=8) muscles during isometric contractions of up to 80% of maximal force.

114 ilateral EEG and contralateral EMG during an isometric contraction or at rest.

115 ns such as the abnormally slow relaxation of isometric contractions or difficulties in halting a move

116 ) during the plateau phase of the submaximal isometric contractions (P < 0.001).

117 etic EMG signals generated during a range of isometric contraction patterns.

118 subjected to a preconditioning, non-damaging isometric contraction protocol in vivo.

119 decreased exponentially during the 4.5 h of isometric contraction (R2 = 0.990), despite more than a

120 Compared with an isometric contraction, rapid fibre shortening was associ

121 cheal smooth muscle ex vivo, in organ baths, isometric contractions recordings were done in order to

122 tes at <3 Hz frequencies, even during steady isometric contractions.SIGNIFICANCE STATEMENT Accurate m

123 ents and the segmental reflex pathway during isometric contractions, standing and stepping.

124 r function measured by the maximum voluntary isometric contraction strength.

125 on was slightly slower upon Ca activation of isometric contraction (taureff = 100 +/- 5 microseconds)

126 performed two types of submaximal fatiguing isometric contraction that required either force or posi

127 During active isometric contraction the intensity of the M3 reflection

128 The observations show that in isometric contraction the lever arm angles are dispersed

129 e employed to determine the GPCR function by isometric contraction, the expressions of GPCRs, and the

130 ermeabilized fibre segments during a maximum isometric contraction, the sarcomeres in the regions wit

131 During isometric contractions, the mean arterial blood pressure

132 of the rabbit occurs during transition from isometric contraction to shortening under low load.

133 t that adjustments in MUDR during submaximal isometric contractions to failure are contraction modali

134 mal muscle torque production capacity during isometric contractions to task failure are known to depe

135 ormed in a microfluidic chamber designed for isometric contraction, total internal reflection fluores

136 of electrically evoked submaximal intensity isometric contraction using a perfused hindlimb model.

137 igible effect in the presence of ADP, but in isometric contraction vanadate substantially reduced bot

138 extent of glycogen utilization during a 3 h isometric contraction varied linearly with the precontra

139 In addition, muscle force production in isometric contraction was increased in batimastat-treate

140 spend attached to the thin filaments during isometric contraction was similar in Tg-WT and Tg-D166V

141 mework to date of motor unit activity during isometric contractions, we identified the firing activit

142 Several weeks later isometric contractions were recorded, to determine the e

143 Both protocols featured steady-state isometric contractions with constant descending drive to

144 RFE state is structurally distinct from pure isometric contractions, with increased thick filament st

145 case, then a reduction in the ATP cost of an isometric contraction would be expected as the muscle fa