ライフサイエンスコーパス: air breathing

1 different from the control (attached retina, air breathing).

2 he pulmonary artery during the transition to air breathing.

3 els of SatPC essential for the transition to air breathing.

4 inner retinal Po(2) in lesioned areas during air breathing.

5 fore birth and is required for adaptation to air breathing.

6 sion of moderately severe PAH in mice during air breathing.

7 eostasis that are critical for adaptation to air breathing.

8 SP-SAP-treated rats also slept less during air breathing.

9 - 1.9 ml/kg(0.75)/min, p < 0.05) during room air breathing.

10 Hg) was 8.9% from the mean amplitude during air breathing.

11 irregularity in respiratory rate during room-air breathing.

12 en), compared to values measured during room air breathing.

13 ent with existing definitions of synchronous air-breathing.

14 oxygen from air when in isolation, and group air-breathing.

15 The transition to air breathing after birth requires both anatomic and bio

16 Air-breathing allowed fishes at the water's edge to expl

17 ements that effect lung ventilation in other air-breathing amniotes.

18 onitored with a canopy apparatus during room-air breathing and 15 minutes of carbon dioxide exposure

19 antagonist, on ventilation (V E) during room air breathing and during hypoxic (10% O2) and hypercapni

20 bullfrogs acclimatized to semi-terrestrial (air-breathing) and aquatic-overwintering (no air-breathi

21 Tumor-cell survival for DDFP treatment with air-breathing animals was not significantly different fr

22 Although the lung is a defining feature of air-breathing animals, the pathway controlling the forma

23 In air-breathing animals, voluntary changes in respiratory

24 ous surface area, and enable gas exchange in air-breathing animals.

25 Adaptation to air breathing at birth is dependent on formation and fun

26 eostasis that is necessary for adaptation to air breathing at birth.

27 entiation that is required for transition to air breathing at birth.

28 l cell maturation required for transition to air breathing at birth.

29 fetal lung maturation and the transition to air-breathing at birth using isobaric hypoxic chambers w

30 preparation for the successful transition to air-breathing at birth.

31 preparation for the successful transition to air-breathing at birth.

32 r catfish in a laboratory arena and recorded air-breathing behaviour, activity and agonistic interact

33 content, and displayed temporally clustered air-breathing behaviour, consistent with existing defini

34 The cuvett-based air-breathing biobattery powered by isoamylase-treated s

35 ssure (RPP) was prevented from rising during air breathing by using an occluder on the dorsal aorta.

36 Within species, individual air-breathing can be influenced by metabolic rate as wel

37 d previously with a dry hydrogen feed and an air-breathing cathode.

38 zymatic fuel cells (EFCs), EFCs with laccase air-breathing cathodes prepared from TBA(+) modified Aqu

39 Under an air-breathing condition, mean P(O2) in the choroid, reti

40 ecreased compared with measurements under an air-breathing condition.

41 ents when compared with term and term + 2-mo air-breathing controls.

42 Hyperoxia is preferable to air breathing during retinal arterial occlusion not only

43 potheses that (1) hyperoxia is preferable to air breathing during retinal arterial occlusion, (2) hyp

44 olic pathway that comprises 13 enzymes in an air-breathing enzymatic fuel cell.

45 systemic blood before entering the heart of air-breathing fishes, lung ventilation may supply the my

46 usly breathed 12% O2 followed by a switch to air breathing for 20 min.

47 air-breathing) and aquatic-overwintering (no air-breathing) habitats.

48 Air-breathing has evolved in many fish lineages, allowin

49 ulus-response curves were defined during (i) air breathing, (ii) hypoxia (12% O(2) in N(2)), and (iii

50 Air breathing in CH rats induced hypoventilation, a 12%

51 nd tidal volume (V(T)) were decreased during air breathing in sleep and wakefulness (group 2; P < 0.0

52 We examined social air-breathing in African sharptooth catfish Clarias gari

53 Air breathing is an essential motor function for vertebr

54 For C. gariepinus, synchronous air-breathing is strongly influenced by agonistic intera

55 At birth, pulmonary vasodilation occurs as air-breathing life begins.

56 transition of an infant from intrauterine to air-breathing life is developmentally regulated, as the

57 some stem tetrapods suggests that spiracular air breathing may have been an important respiratory str

58 ss achieved by some fleets, the reduction of air-breathing megafauna bycatch is both an urgent and ac

59 the global nature of bycatch are lacking for air-breathing megafauna.

60 The spontaneously oxygen- or air-breathing mice were kept conscious or anesthetized w

61 ithin groups was the main factor influencing air-breathing of the entire group.

62 at SP-A and SP-D, which are ubiquitous among air breathing organisms, could contribute to the protect

63 Lung alveoli, which are unique to air-breathing organisms, have been challenging to genera

64 DPAT (30 mM) changed room air breathing pattern by increasing f and decreasing VT.

65 rior hyperventilation, caused a reduction in air-breathing PET,CO2 (P < 0.05, ANOVA), and a leftwards

66 During room-air breathing, probands had significantly larger minute

67 The ability of air breathing R2* measurements to reflect tissue hypoxia

68 oral surface electrode during eupnea or room air breathing (RA), hypercapnia (HYP), and CPAP applicat

69 DA increased lung edema clearance in room air breathing rats (from 0.50 +/- 0.02 to 0.75 +/- 0.06

70 EF5 binding of "moderately" hypoxic cells in air breathing rats was identified using these techniques

71 In air breathing rats, for a given radiation dose, a large

72 as personality, but the mechanisms of group air-breathing remain unexplored.

73 ia-exposed subjects (FIO2, 0.12); or c) room air breathing subjects whose dam food intake was matched

74 nvironmental conditions were unfavorable for air-breathing, terrestrial animals.

75 reous signal intensity on changing from room air breathing to oxygen inhalation (i.e., 5 minutes).

76 of predation, so some species perform group air-breathing, to reduce individual risk.

77 ous PO(2) measurements were made during room air breathing using (19)F magnetic resonance spectroscop

78 dothermic fishes, reproductive physiology of air breathing vertebrates, and endocrine physiology of r

79 low of oxygenated and de-oxygenated blood in air-breathing vertebrates.

80 By contrast, room-air breathing was unaffected, suggesting that the drive

81 ean (+/- SE) baseline Qaw during quiet (room air) breathing was 6.6 +/- 0.6 ml/min (range, 3.9 to 10.

82 Responses during air breathing were assessed both prior to and after eith

83 hat the diuresis and natriuresis seen during air breathing were mediated by the increase in RPP; neit

84 room air hyperventilation separated by room air breathing with continuous spirometry.