ライフサイエンスコーパス: stretch reflex

1 ceptive afferents to prevent recovery of the stretch reflex.

2 -reflex, the electrical analog of the spinal stretch reflex.

3 a strong peripheral amplifier of the spinal stretch reflex.

4 jor contribution to the phase advance of the stretch reflex.

5 H-reflex, an electrical analog of the spinal stretch reflex.

6 motoneuron connections and an absence of the stretch reflex.

7 SPs in motoneurons, and the disappearance of stretch reflexes.

8 e input favours relatively tonic and diffuse stretch reflexes.

9 limb position sensation (proprioception) and stretch reflexes.

10 to influence the gain of artificially evoked stretch reflexes.

11 e 'natural' inputs involved in transcortical stretch reflexes.

12 contribute to maintain or even increase the stretch reflex after nerve crush and by difference to ne

13 lly replicating the concomitant reduction in stretch reflex amplitude.

14 n of muscle stretch differs from that of the stretch reflex amplitude.

15 gests that twitches trigger the monosynaptic stretch reflex and, by doing so, contribute to its activ

16 This pattern cannot be produced by muscle stretch reflexes and can only arise from the anticipator

17 ioceptors (muscle spindles) are required for stretch reflexes and locomotor control.

18 are likely to convey long-latency jaw-muscle stretch reflexes and may contribute to stiffness regulat

19 nerve transection, Ia afferent synapses and stretch reflexes are permanently lost, even after regene

20 he first demonstration that the long-latency stretch reflex can be modified by repeated, precisely ti

21 Alternatively, before movement onset, stretch reflexes can assist an imposed stretch, opposite

22 We found that velocity-dependent stretch reflex caused movement-specific, typically large

23 otoneurons (MNs), the central portion of the stretch reflex circuit, are highly specific, but the mec

24 connectivity in the cutaneous maximus muscle stretch reflex circuit.

25 responsible for synaptic selectivity in the stretch reflex circuit.

26 naptic connections with motoneurons form the stretch reflex circuit.

27 Stretch reflex circuits are a prime example of wiring sp

28 A common proposal is that stretch reflexes contribute to the regulation of limb st

29 ese findings are difficult to reconcile with stretch reflex control of the pendulum and are of partic

30 -reflex, the electrical analog of the spinal stretch reflex, creates a memory trace that includes cha

31 on, however, the extent to which unmodulated stretch reflexes disrupt voluntary movement, and whether

32 LUT1 synapses are not re-established and the stretch reflex does not recover; however, electrically e

33 velocity dependent, increase in muscle tonic stretch reflexes, due to the amplified reactivity of mot

34 sms responsible for spinal modulation of the stretch reflex during human locomotion.

35 s an electrical analogue of the monosynaptic stretch reflex, elicited by bypassing the muscle spindle

36 However, their interaction with stretch reflexes evoked in the context of unimpeded natu

37 that reinnervated muscles failed to generate stretch reflexes, extending observations of areflexia to

38 Evidence of stretch reflex facilitation post-SCI may reflect changes

39 y reduced when modulating velocity-dependent stretch reflex feedback (i) as per the commonly proposed

40 ands only, and with added velocity-dependent stretch reflex feedback.

41 s make a large contribution in restoring the stretch reflex following nerve crush.

42 he swing phase are integrated with a generic stretch reflex for each muscle.

43 limb muscles disrupted the modulation of the stretch reflex for force generation and sensory feedback

44 hesis that unpredicted motor events increase stretch reflex gain.

45 Descending pathways can modify H- and stretch-reflex gain in man.

46 The pathway mediating the monosynaptic stretch reflex has served as an important model system f

47 icance Statement Spinal cord injury leads to stretch reflex hyperexcitability, which underlies the cl

48 However, hyperactive stretch reflexes, hypertonicity, and the Babinski reflex

49 ctions of proprioceptive axons mediating the stretch reflex (Ia afferents).

50 s on locomotion, the phase-dependency of the stretch reflexes implies a dynamically fluctuating role

51 eparate studies, we examined recovery of the stretch reflex in decerebrate cats, and found that it re

52 trate a previously uncharacterized nonneural stretch reflex in gastric muscles and provide physiologi

53 Stretch reflexes in all four muscles were found to be mo

54 s would manifest as temporal facilitation of stretch reflexes in human SCI.

55 such fundamental input is velocity-dependent stretch reflexes in lengthening muscles, which should be

56 The amplitude of biceps phasic stretch reflex increased with muscle contraction in a si

57 The stretch reflex is a fundamental component of the motor s

58 We used a landing movement, for which a stretch reflex is an integral part of the natural action

59 The human stretch reflex is known to produce a phase advance in th

60 The enhancement of stretch reflexes is suggestive of spasticity.

61 l disparity in recovery between strEPSPs and stretch reflex led us to conclude that factors in additi

62 The long-latency stretch reflex (LLSR) in human elbow muscles probably de

63 The model in this paper includes stretch reflex loop with feedback delay and tonically co

64 Here we show that stretch reflex modulation in tasks that require changes

65 evels (1 microM) decreased the monosynaptic "stretch" reflex (MSR) amplitude in WT animals and increa

66 bthreshold corticospinal conditioning of the stretch reflex of biceps and quadriceps was abnormal in

67 The amplitude of the long-latency stretch reflex of the contralesional hand decreased afte

68 loops appear to add flexibility to the human stretch reflex, once considered to be immutable, allowin

69 Operant conditioning of the spinal stretch reflex or its electrical analog, the H-reflex, p

70 etch of the calf muscles may be augmented by stretch reflexes or by central control.

71 mechanisms, such as recurrent inhibition and stretch reflex, probably play a major role in the synerg

72 tap to Tri evoked its own homonymous phasic stretch reflex, providing neurophysiological evidence fo

73 udy was designed to estimate the fraction of stretch reflex recovery attributable to functional recov

74 anding, and they produced no evidence of any stretch reflex response in soleus, or gastrocnemius.

75 o how the nervous system centrally modulates stretch reflex responses.A common measure of H-reflex ga

76 -and-hold perturbations used to elicit tonic stretch reflexes revealed significantly prolonged EMG re

77 In the stretch-reflex system, proprioceptive sensory neurons ma

78 tryptamine) from enterochromaffin cells, and stretch reflexes that determine the site of origin and p

79 Four weeks following SCI, the stretch reflex, the non-nociceptive cutaneous reflex pat

80 Unlike the monosynaptic "stretch" reflex, the exact neuronal pathway for a simple

81 s the amplitudes of physiological tremor and stretch reflex to be decoupled.

82 implicit motor adaptation, and for segmental stretch reflexes to operate in joint space.

83 ted that rapid motor responses (i.e., muscle-stretch reflexes) to mechanical perturbations can be mod

84 stationarity the amplitude of biceps phasic stretch reflex varied <10% in the first six repeats of t

85 both methods the magnitude of biceps phasic stretch reflex varied linearly with tap force over the r

86 troke the threshold of the homonymous phasic stretch reflex was low, but it had a normal onset latenc

87 elements in the sensorimotor circuit of the stretch reflex were examined in both the PNS and CNS.

88 Spinal stretch reflexes were measured following solid floor con

89 Approximately 7 h later, they returned, and stretch reflexes were remeasured.

90 ent low thresholds for the homonymous phasic stretch reflex, which had abnormally short onset latenci

91 as calf muscles shortened in contrast to the stretch reflex whose amplitude decreases as muscle short

92 exes, such as the vestibulo-ocular reflex or stretch reflex, whose gains adapt in response to novel a

93 Paradoxical movements cannot be generated by stretch reflexes with constant intrafusal drive but migh