ライフサイエンスコーパス: rhythmical

1 We demonstrate that observation of everyday rhythmical actions biases subsequent motor execution of

2 These features may favor occurrence of rhythmical activities in thalamocortical networks.

3 The recovery of rhythmical alternating movements, such as locomotion, is

4 rodents is a behavior in which animals make rhythmical body, head, and bilateral forearm as well as

5 invasive brain stimulation we show that fast rhythmical brain activity at posterior sites are nested

6 This change in rhythmical brain activity leads to modulation of visual

7 ribed subthreshold membrane oscillations and rhythmical burst discharge in Mes V neurons from rats ag

8 ection, which has been suggested to underlie rhythmical bursting in Parkinson's disease, we first mea

9 from an irregular discharge to a pattern of rhythmical bursting in synchrony with hippocampal theta

10 to the MS/DB may normally act to inhibit the rhythmical bursting of MS/DB neurons, thereby producing

11 Spontaneous rhythmical [Ca2+]i oscillations were observed in ICCs af

12 t the same rate, yet with their own distinct rhythmical context model (RCM).

13 g normal excitation-contraction coupling and rhythmical contraction.

14 in cued gait performance with three external rhythmical cues (ERC) (auditory, visual and somatosensor

15 ocimetry, we show that fertilization induces rhythmical cytoplasmic movements that coincide with puls

16 Spontaneous rhythmical depolarizations with superimposed action pote

17 Consequently, we suggest that such rhythmical discharges are neither a 'local sign' sympath

18 We suggest that the rhythmical discharges following the initial excitatory r

19 The characteristic rhythmical discharges of single postganglionic sympathet

20 a period of reduced discharge and subsequent rhythmical discharges seemingly phase-locked to the stim

21 inal ganglia responded to CCAP by generating rhythmical ecdysis bursts.

22 resulting in dissociation of the average and rhythmical effects of sympathetic activity.

23 the retrogradely labeled pTRG neurons showed rhythmical excitatory currents in tune with respiratory

24 In vivo, XIIts MNs displayed rhythmical, expiratory-related activity.

25 and coherence analyses demonstrated that the rhythmical firing pattern of MS/DB neurons strongly corr

26 rn of MS/DB neurons strongly correlated with rhythmical fluctuations in the hippocampal EEG during pe

27 e water reabsorption were counterbalanced by rhythmical glucocorticoid release, with excretion of end

28 mical mineralocorticoid release and elevated rhythmical glucocorticoid release.

29 aptic input to trigeminal motoneurons during rhythmical jaw movements.

30 ctivity of CVC(like) SPNs was underpinned by rhythmical membrane potential oscillations suggestive of

31 umans regulate osmolyte and water balance by rhythmical mineralocorticoid and glucocorticoid release,

32 crease in salt intake decreased the level of rhythmical mineralocorticoid release and elevated rhythm

33 evels of salt intake, half-weekly and weekly rhythmical mineralocorticoid release promoted free water

34 and to refractory periods which control the rhythmical motility of many hollow organs.

35 muscle homologues were induced to express a rhythmical motor pattern by experimental methods that ac

36 te oviposition were found to also activate a rhythmical motor pattern in pregenital abdominal segment

37 of the intestinal lumen, thereby triggering rhythmical movement of the pharynx, referred to as the p

38 A release channel with a rhythmical nature is discussed as a possible molecular p

39 the mollusc Lymnaea, one of the best-studied rhythmical networks, intracellular stimulation of either

40 lting we used calcium imaging and found that rhythmical potential 1 (RP1) neurons activate before som

41 nd perhaps myenteric neuronal activity, into rhythmical, propagated motor programs, such as swallowin

42 roscience often focusses either on intrinsic rhythmical properties of motor circuits or extrinsic sen

43 Human and non-human primates produce rhythmical sounds as soon as they are born.

44 escale invariance, multisensory integration, rhythmical structure, and attentional time-sharing.

45 ulation during action patterns that required rhythmical unimanual or bimanual (iso-directional/anti-d

46 orofacial movements necessary for producing rhythmical vocalizations differentiate from a larger mov

47 he KaiB and KaiC protein levels are robustly rhythmical, whereas the KaiA protein abundance undergoes

48 uring the mid-flexion phase of contralateral rhythmical wrist flexion-extension.