ライフサイエンスコーパス: arterial pulse

1 ng assisted ventilation presented without an arterial pulse.

2 The arterial pulse and breathing can be quantified as a comp

3 Abnormalities of arterial pulse and limb growth after retrograde femoral

4 to characterize the relationships among the arterial pulse (AP) and the cardiac-related and 10-Hz rh

5 (SND) relative to the systolic phase of the arterial pulse (AP) and thus pulse-synchronous barorecep

6 e levels above which coherence of SND to the arterial pulse at the frequency of the heart beat became

7 al hemodynamic action could be identified by arterial pulse contour analysis.

8 The last QRS complex coincided with the last arterial pulse in 19% of the patients.

9 ctive report of the throbbing rhythm and the arterial pulse in human subjects of either sex with thro

10 Textile MEG was demonstrated to convert the arterial pulse into electrical signals with a low detect

11 he magnitude and statistical significance of arterial pulse-modulated activity of single neurones and

12 ed aortic flow monitoring devices, one using arterial pulse power (LiDCOplus) and the other esophagea

13 the normotensive participants, elevation of arterial pulse pressure (a surrogate of arterial stiffne

14 dy was to examine the progression of central arterial pulse pressure (cPP) in women and the degree to

15 We compared the accuracy of measured arterial pulse pressure and estimated left ventricular s

16 Dynamic changes in arterial pulse pressure closely tracked left ventricular

17 ation (PPV), which quantifies the changes in arterial pulse pressure during mechanical ventilation, i

18 cular outflow through the bypass widened the arterial pulse pressure from 41 to 115 mm Hg at similar

19 et al. found that an analytical method using arterial pulse pressure recording (pressure recording an

20 Measures of arterial pulse pressure variation and left ventricular s

21 Arterial pulse pressure was unaffected in both groups.

22 Arterial pulse pressure, as well as, left ventricular st

23 ubstantially from LV pacing (18+/-4% rise in arterial pulse pressure, which correlates with cardiac o

24 and randomly assigned subjects with resting arterial pulse pressures >60 mm Hg and systolic pressure

25 The arterial pulse recording morphology was compared against

26 hat reconstructs an accurate estimate of the arterial pulse signal independent of sensing location fr

27 del which maps the features of the estimated arterial pulse signal to systolic and diastolic BP readi

28 Simultaneous indirect arterial pulse tracing, phonocardiogram, electrocardiogr

29 f her irregular heart action by using radial arterial pulse tracings and experimental atrial and vent

30 Continuous monitoring of an arterial pulse using a pressure sensor attached on the e

31 Arterial pulse wave velocity (PWV) correlates with the l

32 Secondary outcomes included decreases in arterial pulse wave velocity and carotid artery echodens

33 Baseline vascular stiffness, indexed by arterial pulse-wave velocity (Doppler) and augmentation

34 The arterial pulse waveform was obtained from an arterial te

35 is important to the formation of solitons in arterial pulse waves.

36 All proximal and distal arterial pulses were felt.