ライフサイエンスコーパス: gallop

1 escape-like running and most particularly at gallop.

2 When quadrupedal mammals gallop, 1ratio1 stride per breath coupling is necessitat

3 troduce bubbles that spontaneously start to 'gallop' along horizontal surfaces inside a vertically-vi

4 ote left-right synchronization necessary for gallop and bound, whereas the V3 aLPNs promote synchroni

5 al gait transitions from walk to trot and to gallop and bound.

6 al changes of gaits from walk to trot and to gallop and bound.

7 endent gait changes from walk to trot and to gallop and bound.

8 t transition from walk, to trot, and then to gallop and bound; the homolateral LPN connections ensure

9 encing are the ba-da-dump pattern of a horse gallop and having push-off followed by heel-strike in hu

10 ammals; including asymmetrical gaits such as galloping and bounding.

11 comotor gaits in mammals, such as walking or galloping, are produced by coordinated activity in neuro

12 ses from walking to trotting to cantering to galloping, as they increase their movement rate.

13 The rich dynamics of galloping bubbles suggest exciting opportunities in heat

14 Through periodic body deformations, galloping bubbles swim leveraging inertial forces rather

15 ntly break their alveolar capillaries during galloping, causing hemorrhage.

16 entifiably common outputs, such as a trot or gallop, despite varations in intrinsic properties across

17 he commonly used vortex-induced vibration or galloping devices, the proposed energy harvesting system

18 ting gait at slow speeds but transition to a galloping gait as speed increases.

19 Rainstorms, insect swarms, and galloping horses produce "sound textures"--the collectiv

20 The muscular work of galloping in horses is halved by storing and returning e

21 showcase the technological potential of the galloping locomotion for applications involving bubble g

22 F and C sites two-by-two in a discontinuous "galloping" manner.

23 Similarly, maximum speed gallops may be great for escaping danger, but they precl

24 tio, 1.31; 95% CI, 1.13-1.52; P=0.001) or S3 gallop (odds ratio, 1.21; 95% CI, 1.06-1.40; P=0.006).

25 Whether animals that generate galloping or hopping gaits, characterized by synchronous

26 peed, were unable to move using stable trot, gallop, or bound, and predominantly used a lateral-seque

27 The stimulus is "heard" either as a galloping pattern (integration) or as two interleaved st

28 The galloping symmetry breaking provides a robust self-propu