ライフサイエンスコーパス: pulmonary ventilation

1 ., partial liquid breathing or intratracheal pulmonary ventilation).

2 s (such as hypercapnia and hypoxia) improves pulmonary ventilation.

3 CO(2) release from blood->increased VCO2 and pulmonary ventilation.

4 of a continual upward drift in (V(O(2))) and pulmonary ventilation.

5 serious potential side effect of mechanical pulmonary ventilation.

6 CO(2) release from blood increased VCO2 and pulmonary ventilation.

7 etabolic rate, afferent blockade compromised pulmonary ventilation and gas exchange efficiency, consi

8 elected MRI techniques for the assessment of pulmonary ventilation and perfusion.

9 Pulmonary ventilation and pulmonary arterial pressure bo

10 igh-resolution measurements of both regional pulmonary ventilation and regional blood flow (r ) have

11 To improve monitoring of pulmonary ventilation and support early diagnosis, we pr

12 tolic functional profiles (untwisting rate), pulmonary ventilation and systemic aerobic metabolism we

13 tration of aerosol particles in expired air, pulmonary ventilation, and aerosol particle emission at

14 ilation, inhaled nitric oxide, intratracheal pulmonary ventilation, and liquid ventilation.

15 The homeostatic regulation of pulmonary ventilation, and ultimately arterial PCO(2), d

16 Pulmonary ventilation, arterial blood gases and oxyhaemo

17 Purpose To compare the distribution of pulmonary ventilation assessed by a CT-based full-scale

18 During exercise, pulmonary ventilation can increase over 10-fold, and the

19 estigate the influencing factors of abnormal pulmonary ventilation function in occupational exposed p

20 l health examination, 1681 cases of abnormal pulmonary ventilation function were detected, resulting

21 be the optimal model for predicting abnormal pulmonary ventilation function.

22 study performed between May and August 2017, pulmonary ventilation in participants with COPD was comp

23 saving intervention used to provide adequate pulmonary ventilation in patients suffering from respira

24 When pulmonary ventilation in sham animals was controlled and

25 airway network flow model provided regional pulmonary ventilation information for chronic obstructiv

26 Pulmonary ventilation is accomplished by alterations in

27 al injury following short-term intratracheal pulmonary ventilation (ITPV) and conventional mechanical

28 intratracheal pulmonary ventilation (ITPV); hybrid ITPV; tracheal gas

29 c pulmonary vasoconstriction (HPV) optimizes pulmonary ventilation-perfusion matching in regional hyp

30 Pulmonary ventilation/perfusion (V/Q) mismatch measured

31 ical strain caused by hypertension or excess pulmonary ventilation pressure, lead to important clinic

32 tative and spatially localized assessment of pulmonary ventilation properties without tracer gas hype

33 output, increased heart rate, and increased pulmonary ventilation relative to metabolism.

34 cts of inhaled nitric oxide gas of improving pulmonary ventilation to perfusion matching and hemodyna

35 deflation with IND/GLY on PMBF and regional pulmonary ventilation using magnetic resonance imaging (

36 The rates of pulmonary ventilation (V(I)), O2 consumption (V(O2)) and

37 ecord electromyographic (EMG) activities and pulmonary ventilation (VI) at rest and at workload incre

38 Regional pulmonary ventilation was assessed with 100% oxygen as a

39 The modeled pulmonary ventilation was compared with functional imagi

40 Pulmonary ventilation was up to 20% lower across all int