ライフサイエンスコーパス: cardiac work

1 sease, hypertension, or obesity) increase in cardiac work.

2 repair and may have the capacity to perform cardiac work.

3 s and reducing apical cavity compression and cardiac work.

4 consumption for comparable levels of CBF and cardiac work.

5 nic phosphate concentrations as functions of cardiac work and age in the adult female population.

6 Despite similar increases in cardiac work and comparable sympathetic stimulation in C

7 correlated significantly with both increased cardiac work and degree of stenosis.

8 During exercise, blood pressure, cardiac work and global oxygen delivery increased simila

9 E), which is the energetic ratio of external cardiac work and left ventricular (LV) oxygen consumptio

10 The beta 1 receptor blockade reduces cardiac work and may thereby lower myocardial blood flow

11 , because it shifts the relationship between cardiac work and myocardial oxygen consumption, suggesti

12 blood viscosity can increase blood pressure, cardiac work and reduce aerobic capacity.

13 itions, recapitulating the linearity between cardiac work and respiration in the heart.

14 drenoceptor antagonist propranolol decreases cardiac work and resting energy expenditure while increa

15 butamine infusion and to correlate flow with cardiac work and severity of coronary artery disease.

16 spectroscopy) at baseline, during increased cardiac work, and during recovery.

17 in controls (5 ml/g SEM 0.6) after 5 min of cardiac work, and prolonged survival times up to 120 min

18 ute and chronic systolic function, increases cardiac work, and reduces mortality.

19 lowered below a certain level, increases in cardiac work become more "energetically costly" in terms

20 Furthermore, we assessed total cardiac work between 21 and 7 days before space flight a

21 kJ/mol in M/MtCK-/- hearts during increased cardiac work but only slightly in wild-type (1.7 kJ/mol)

22 Resting MBF declined in proportion to cardiac work by approximately 20% from 0.61 +/- 0.09-0.5

23 c patient's inability to cope with increased cardiac work demand largely stems from mitochondrial red

24 volume, despite overall reductions in total cardiac work, during prolonged space flight.

25 R Imaging, PET, Radionuclide Studies, SPECT, Cardiac, Work Force Issues Supplemental material is avai

26 s the proceedings and recommendations of the Cardiac Working Group.

27 ess correlated significantly with changes in cardiac work in healthy volunteers (r = 0.77; P < 0.001)

28 Despite higher levels of cardiac work in the Kv1.5(-/-) mice (versus WT mice at b

29 A high rate of cardiac work increases citric acid cycle (CAC) turnover

30 elating myocardial oxygen consumption to the cardiac work indices, stroke work, and pressure-volume a

31 We have previously shown that increased cardiac work initially caused a rapid Ca(2+)-independent

32 The response to a decrease in cardiac work is not known.

33 sents both an adaptive response to increased cardiac work load and a precursor state of heart failure

34 cantly diminished, indicating improvement of cardiac work load by RD.

35 h fibers, this new muscle may be suited to a cardiac work load.

36 aturation process that is independent of the cardiac working load.

37 The cardiac work-loop technique closely mimics the intrinsic

38 t becoming less efficient (ie, a decrease in cardiac work/O(2) consumed).

39 stem is required for situations of increased cardiac work or acute stress.

40 rdiac output (r = 0.73; P = 0.015) and total cardiac work (r = 0.53; P = 0.112).

41 flow increased appropriately for the greater cardiac work, there was a redistribution of regional blo

42 At high levels of cardiac work, tissue oxygen tension dropped significantl

43 ix Ca(2+) content, rapidly enough to support cardiac work transitions in vivo.

44 based on all information available including cardiac work-up and 1-year follow-up, was the diagnostic

45 Cardiac work was estimated as the product of mean arteri

46 Total cardiac work was lower during space flight (P = 0.008);

47 Cardiac work was measured by echocardiography, and effic

48 Energy substrate metabolism and cardiac work were determined ex vivo in a sequential pro

49 ed to the rate-pressure product, an index of cardiac work, were similar in both the patients with Kaw

50 ts the systolic pressure further, increasing cardiac work while reducing the diastolic pressure, on w

51 hysiologic characteristics include increased cardiac work with normal peripheral resistance, diffuse