ライフサイエンスコーパス: respiratory cycle

1 r NO (thus maximizing oxygen delivery in the respiratory cycle).

2 m of PB is different from that of the normal respiratory cycle.

3 thoracic pressure are all varying during the respiratory cycle.

4 interface and the adjacent fluid during the respiratory cycle.

5 wave speed remained unchanged throughout the respiratory cycle.

6 eartbeats increasing and decreasing within a respiratory cycle.

7 bursts are coupled to specific phases of the respiratory cycle.

8 eliminated the post-inspiration phase of the respiratory cycle.

9 cidence data to reconstruct any phase of the respiratory cycle.

10 eventing alveolar collapse at the end of the respiratory cycle.

11 orants and active at different phases of the respiratory cycle.

12 cquires multiple low-dose CT images during a respiratory cycle.

13 ropharyngeal levels at each increment of the respiratory cycle.

14 , and postinspiratory (post-I) phases of the respiratory cycle.

15 d exclusively to the expiratory phase of the respiratory cycle.

16 n and hyperoxic vasconstriction in the human respiratory cycle.

17 tions in PaO2 as shunt varies throughout the respiratory cycle.

18 ion management (RPM), is used to monitor the respiratory cycle.

19 ty analysis was confined to one phase of the respiratory cycle.

20 ons that varied as a function of time in the respiratory cycle.

21 h and terminate the inspiratory phase of the respiratory cycle.

22 ion would alter the inspiratory phase of the respiratory cycle.

23 ive of fluctuations in inhibition during the respiratory cycle.

24 fire during the late expiratory phase of the respiratory cycle.

25 of inspiratory and expiratory phases of the respiratory cycle.

26 lar filling and ejection dynamics during the respiratory cycle.

27 tor activity was recorded as an index of the respiratory cycle.

28 were higher than values averaged across the respiratory cycle.

29 icular system and in the spinal canal during respiratory cycles.

30 he variability of RR intervals in individual respiratory cycles.

31 e synchronization of heartbeat intervals and respiratory cycles.

32 tory cycle, whereas PET occurs over multiple respiratory cycles.

33 ntragastric pressures were measured over 6-8 respiratory cycles.

34 cardiac images through multiple cardiac and respiratory cycles.

35 that allowed resolution of both cardiac and respiratory cycles.

36 rcise to that recorded during the first five respiratory cycles after the abrupt cessation of exercis

37 ory activity would be entrained to the human respiratory cycle, albeit at the much slower rhythm of a

38 to account for variability in the number of respiratory cycles analyzed per patient.

39 eir maximum firing rates, start times in the respiratory cycle and axonal destination.

40 lies are transiently reconfigured during the respiratory cycle and baroreceptor stimulation.

41 that Dbx1(+) neurons activate earlier in the respiratory cycle and discharge greater magnitude inspir

42 x-evoked prolongation of the PI phase of the respiratory cycle and excitation of PI neurones includin

43 In summary, we demonstrate how tuning to the respiratory cycle and integration of respiratory-cardiac

44 gnals that recurred on the time scale of the respiratory cycle and whose range was approximately one

45 us work has demonstrated an influence of the respiratory cycle and, more specifically, rhythmic nasal

46 ith no activity related to either cardiac or respiratory cycles and their conduction velocity was 0.8

47 ate mechanisms underlying NO function in the respiratory cycle, and provide insight into the aetiolog

48 uantify how much the airway moves during the respiratory cycle, and to determine how much this motion

49 distinct portions of the centrally generated respiratory cycles; and (c) phasic synaptic inhibition,

50 SNO-based NO bioactivity by Hb redefines the respiratory cycle as a triune system (NO/O2/CO2).

51 necting distant brain regions, and posit the respiratory cycle as an important reference for neuronal

52 ervals for slightly longer (1 s) than a full respiratory cycle at each couch position.

53 d a significant HR change in the first three respiratory cycles at 40 % of maximum voluntary contract

54 ratory regime associated to each state and a respiratory cycle based analysis, we evidenced that the

55 e baroreceptors (BRs) across the cardiac and respiratory cycle can modulate cortical excitability and

56 le coupled oscillators underlie a three-part respiratory cycle composed from inspiratory, postinspira

57 Standardized respiratory cycles consisted of a deep standardized insp

58 gorithm, modulates stimulation intensity and respiratory cycle duration to evoke this ventilatory pat

59 re active during the expiratory phase of the respiratory cycle during exercise.

60 We hypothesized that respiratory cycle fluctuations in upper airway cross-sec

61 A respiratory cycle for nitric oxide (NO) would involve th

62 Multivariate analysis of the respiratory cycle further differentiated between locatio

63 station that allows electrocardiographic and respiratory cycle gated image acquisition.

64 nerally presumed to remain constant within a respiratory cycle in the healthy lung.

65 d using cine MRI data captured over a single respiratory cycle in three subjects with OSA.

66 The inspiratory phase of the respiratory cycle in vitro results from preBotC neurons

67 ind that many neurons become phase-locked to respiratory cycles in a stage-dependent manner, emphasiz

68 ty shows detectable changes during nonapneic respiratory cycles in adults evaluated for sleep-disorde

69 by occluding the tracheal cannula for thirty respiratory cycles; in the second series of experiments,

70 sults suggest that C1 cells may regulate the respiratory cycle, including active expiration, under hy

71 The respiratory cycle introduces anatomic variability that p

72 Thus, tissue oxygenation in the respiratory cycle is dependent on S-nitrosohemoglobin.

73 Each respiratory cycle is divided into discrete bins triggere

74 ng pulmonary vascular pressures over several respiratory cycles is most often preferable.

75 n-inhibition balance is comodulated with the respiratory cycle, it remains unclear whether respiratio

76 In addition, respiratory cycle length variability was 214 % higher in

77 In addition, respiratory cycle length variability was 214% higher in

78 moter activity in both the cell division and respiratory cycles of the budding yeast Saccharomyces ce

79 ly 1 month of age, most Mecp2-/y mice showed respiratory cycles of variable duration; meanwhile, thei

80 onal mechanism for a direct influence of the respiratory cycle on memory function.

81 ient-echo cine images were acquired with one respiratory cycle performed per cardiac cycle.

82 ectroencephalographic power to vary with the respiratory cycle predicted next-day sleepiness as measu

83 aximum firing rate nor start time during the respiratory cycle predicted the occurrence of doublets.

84 Spectral analysis proved the existence of respiratory cycle-related electroencephalographic change

85 entilation, approximately 67,150 spontaneous respiratory cycles, represented by 3,592 16-sec epochs,

86 Motion of the tissue from the cardiac and respiratory cycles severely limits intravital microscopy

87 rate variation (sinus arrhythmia) across the respiratory cycle such that most frequent stimulation on

88 ns pushed swallow occurrence to later in the respiratory cycle, suggesting that excitatory neurons fr

89 al for tissue oxygenation by RBCs within the respiratory cycle that is required for both normal cardi

90 rbon dioxide, and nitric oxide-the three-gas respiratory cycle-that insures adequate oxygen and nutri

91 tructures relatively immobile throughout the respiratory cycle, the efficiency and safety of these pr

92 that cognitive performance varies along the respiratory cycle, the underlying neurophysiological mec

93 sured while the patient is performing forced respiratory cycles, the Forced Vital Capacity (FVC) and

94 preceding nontriggering efforts had shorter respiratory cycle times (p < 0.0005) and expiratory time

95 n this context, nitric oxide coordinates the respiratory cycle to acquire and deliver oxygen to targe

96 Participants adapted their respiratory cycle to expected stimulus onsets to prefere

97 e vagus nerve at specific time points of the respiratory cycle to slow the heart rate.

98 xpiratory time constants calculated from all respiratory cycles using an innovative procedure and vis

99 inputs during a portion of the lung or gill respiratory cycle was observed following a negative curr

100 By jointly analyzing multisite LFPs and respiratory cycles, we could distinguish three types of

101 PA and Ao measurements of ETs throughout the respiratory cycle were a simple, easily obtainable, and

102 A total of 1,485,405 respiratory cycles were analyzed from 26 ARDS patients (

103 e activity both lung and gill rhythm-related respiratory cycles were divided into three distinct phas

104 ical CT scan provides only a snapshot of the respiratory cycle, whereas PET occurs over multiple resp

105 visualization of the swallowing apnea in the respiratory cycle which provide additional information o

106 e motion of the heart due to the cardiac and respiratory cycles, which create image artifacts.

107 and the L1 root consisted of two bursts per respiratory cycle with a silent period during inspiratio

108 Simulations were performed for full respiratory cycles with 5 different wall boundary condit

109 The percentage of respiratory cycles with phasic inspiratory activity of g

110 performed for 10 seconds over a span of 2-3 respiratory cycles with supporting a continuous positive

111 the timing of SWR events is modulated by the respiratory cycle, with a significantly increased probab

112 aroresponsive neuronal assemblies during the respiratory cycle, without concomitant firing rate chang