ライフサイエンスコーパス: exhalation

1 ght ventricle pressure 10[15, 6] mmHg during exhalation.

2 ing at total lung capacity and during forced exhalation.

3 t around inhalation onset and largest during exhalation.

4 also results from altering the swiftness of exhalation.

5 ure (2 [1-2] cm H(2)O) and caused incomplete exhalation.

6 and 3 [2-3] cm H(2)O), and caused incomplete exhalation.

7 standardized inspiration followed by passive exhalation.

8 ar pressure (10 [95% CI, 15-6] mm Hg) during exhalation.

9 inhalation, (4) peak exhalation, and (5) end exhalation.

10 bles gas exchange during both inhalation and exhalation.

11 ccurring primarily during the latter part of exhalation.

12 with O(2)(+*) reagent ions in single breath exhalations.

13 rmined environmental factors affecting radon exhalation, achieving [Formula: see text] values of 0.79

14 ageal, and gastric pressures recorded at end-exhalation and end-inflation Pes averaged 17.5 +/- 5.7 c

15 by a modified N2 washout technique from end-exhalation and from +40 cm H2O inspiratory pressure, res

16 Protection factors and mask emissions for exhalation and inhalation were evaluated for masks of se

17 eak inhalation, (3) end inhalation, (4) peak exhalation, and (5) end exhalation.

18 in TI,vent causes tachypnea, prolongation of exhalation, and a decrease in intrinsic positive end-exp

19 gh most of inhalation and the early phase of exhalation, and pupil constriction occurring primarily d

20 sual awareness negativity) for high (systole/exhalation) BR activity, indicating that BR signals inte

21 nation via urinary excretion and respiratory exhalation can be judged on the basis of the octanol-wat

22 onfidence interval [CI] -11.94 to -1.71) and exhalation delivery system (EDS) (MD -7.86, 95% CI -14.6

23 twice-daily EDS-FLU (93, 186, or 372 mug) or exhalation delivery system (EDS)-placebo for 24 weeks (1

24 We sought to assess whether an exhalation delivery system with fluticasone (EDS-FLU) ca

25 n respiratory pattern and to maintain forced exhalation during pressure-support ventilation may have

26 ract responsible for aerosol production from exhalation events.

27 apse greater than 50% of luminal area during exhalation (expiratory central airway collapse [ECAC]) i

28 While studies have examined radon exhalation, few have focused on modeling its behavior in

29 e on respiratory particle size distribution; exhalation flow physics; leakage from face masks of vari

30 non-invasively at the mouth-as a function of exhalation flow rate and parameters representing airway

31 lat)) is nonspecific and requires a constant exhalation flow rate.

32 l exhaled NO (FeNO(50)) measured at multiple exhalation flow rates in 132 children (aged 4-18 yr) wit

33 h CF are not statistically different at both exhalation flow rates of 50 ml/s (17.5 +/- 11.5 and 11.5

34 eeze-out of unsaturated phospholipids during exhalation, forming a film enriched in saturated phospho

35 easured by pneumotachograph during a passive exhalation from +40 cm H2O to FRC measured by N2 washout

36 imulations while patients performed a gentle exhalation from FRC.

37 In contrast, unilateral LVRS did not affect exhalation from the unoperated lung (2% reduction in RV,

38 .1 +/- 1.6 breaths/min (p < 0.001), time for exhalation, from 2.0 +/- 0.2 to 2.6 +/- 0.3 s (p < 0.001

39 .8 +/- 1.5 breaths/min (p < 0.001), time for exhalation, from 2.1 +/- 0.2 to 2.3 +/- 0.2 s (p < 0.025

40 important isoform contributing to exhaled NO exhalation in healthy mice.

41 e studied respiratory droplet generation and exhalation in human and nonhuman primate subjects with a

42 ma, in the alveoli to drop to nearly zero on exhalation; in the upper airways gamma is approximately

43 rse triggering (occurring exclusively during exhalation) increased mean expiratory transpulmonary pre

44 lected during a flow and pressure-controlled exhalation into a reservoir discarding dead space air co

45 Radon exhalation is a natural process by which atoms of the ra

46 n patients incapable of performing necessary exhalation maneuvers (e.g., infants) or immobile (e.g.,

47 nct approaches were developed based on radon exhalation measurements from four Peruvian agricultural

48 Exhalation of a single breath near the source interface

49 gh-frequency, highly rhythmic inhalation and exhalation of air through the nose, plays an important r

50 An estimated total daily exhalation of ca. 20 mug day(-1) was calculated for the

51 ractions and poor delivery efficiency due to exhalation of low-inertia nanoparticles.

52 the clearing of hemolymph nicotine or in the exhalation of nicotine from hemolymph.

53 blocking large droplets and aerosols during exhalation or inhalation.

54 le/diastole) and the respiratory (inhalation/exhalation) phase on awareness-related ERPs.

55 the mask (Facial-MEP) or the same mask with exhalation port in the ventilator circuit (Facial-WS) an

56 tudy was conducted to evaluate the effect of exhalation port location and mask design on CO2 rebreath

57 A facial mask (inner volume of 165 mL) with exhalation port within the mask (Facial-MEP) or the same

58 rcuit (Facial-WS) and a total face mask with exhalation port within the mask (inner volume 875 mL, To

59 Facial-MEP with its exhalation port within the mask and the smallest mask vo

60 action: monitoring respiration revealed that exhalation preceded odor-evoked activity and reversible

61 ncentration levels, possibly from high radon exhalation rate levels, can generate an impact on public

62 There was a strong correlation between exhalation rates and radium values.

63 th of which were paced with equal inhalation:exhalation ratios.

64 id air on the paper-sensor during the forced exhalation reduced the electrical resistance of the sens

65 consumption, stimulating the epithelium upon exhalation (retronasal olfaction).

66 sed by a continuous series of inhalation and exhalation sections, and an extremely low fundamental fr

67 The maximal exhalation spread was 0.99, 2.18, 2.92, and 4.1 m during

68 ost vocalization types follows deviations in exhalation that appear to be generated by the re-activat

69 In contrast, during exhalation, the flow preferentially sweeps through this

70 During exhalation, the surfactant film of lipids and proteins t

71 A basic tone is created by exhalation through a constricted laryngeal voice box, an

72 humidity caused by cycles of inhalation and exhalation to electrical signals.

73 nditions experienced by Mtb before and after exhalation using a model aerosol fluid (MAF) based on th

74 g and the sensor recovered rapidly after the exhalation was complete by rapid desorption of water mol

75 ing the molecular ratio (R) of inhalation to exhalation, we investigated the effect of high fraction

76 trate- and inhibitor-regulated changes of NO exhalation, we suggest that NOS 2 is an important isofor

77 tely 0.001 N/m) achieved in the lungs during exhalation when the surfactant film compresses.

78 ly silences respiration, trapping animals in exhalation, while stimulating Npy2r neurons causes rapid

79 caused tachypnea, yet prolonged the time for exhalation with consequent decrease in PEEP(i).

80 ing at total lung capacity and during forced exhalation, with 40 mAs, 120 kVp, and 0.625-mm detector

81 llmark of active expiration featuring forced exhalation, with increasing inhibition to KF, as reporte

82 t around inhalation onset and largest during exhalation, with pupil dilatation occurring through most