ライフサイエンスコーパス: crackle

1 Physical examination revealed fine bibasilar crackles.

2 in Klebsiella and other Enterobacteriaceae (CRACKLE-1), a prospective, observational study conducted

3 normal CXRs to have hypoxemia (45% vs 26%), crackles (69% vs 62%), tachypnea (85% vs 80%), or fever

4 with cough (99% vs 92%), fever (80% vs 58%), crackles (89% vs 76%), hypoxia (50% vs 36%), and letharg

5 the fifth percentile for the patient's age, crackles, clubbing, family history of ILD, symptom durat

6 Among the observational studies, CRACKLE (Consortium on Resistance Against Carbapenems in

7 Compressed nano-pillars crackle from moving dislocations, which reduces plastic

8 f the anterior neck, expiratory wheezes, and crackles heard at auscultation of bases of both lungs.

9 Building on this success, CRACKLE II will expand the network to hospitals across t

10 ted with erythematous, dry plaques with fine crackling involving hypoesthetic skin.

11 lass of scale-free physical processes termed crackling noise and suggest that the resumption of healt

12 Crackling noise arises when a system responds to changin

13 wide variety of physical systems exhibiting crackling noise have been studied, from earthquakes on f

14 hese ideas by using results for our model of crackling noise in magnets, explaining the use of the re

15 Crackling noise is a scale-invariant phenomenon found in

16 Crackling noise is characterized by stress drops or stra

17 Here, we demonstrate a method for nanoscale crackling noise measurements based on AFM nanoindentatio

18 dual nanoscale features, a technique we call crackling noise microscopy.

19 m and 2 mum) with power law distributions of crackling noise P(s) ~ s(-tau) with tau ~ 2 in the defec

20 mean field theoretical models and with other crackling noise systems, and the measured Lyapunov expon

21 ous to the dynamics of earthquakes and other crackling noise systems.

22 In contrast, the common 'crackling noise' approach fails to determine chi under s

23 iors, such as enhanced rigidity, emission of crackling noise, slow relaxations, and memory retention.

24 ture of this nonlinear zone maps directly to crackling noises.

25 t opens the possibility of investigating the crackling of individual nanoscale features in a wide ran

26 where the AFM probe can be used to study the crackling of individual nanoscale features, a technique

27 d is successfully applied to investigate the crackling of individual topological defects, i.e. ferroe

28 ostructural defects is key to understanding "crackling" phenomena during the deformation of solid mat

29 th headaches, earache, clicking, popping, or crackling sounds in the temporomandibular joint, and imp

30 tection of the mechanical cellular injury as crackling sounds.

31 gainst Carbapenems in Klebsiella pneumoniae (CRACKLE) was constructed of patients with infection, or

32 he corresponding respiration phase to detect crackle, wheeze and normal breath sound features.

33 ed diagnoses of four types of lung diseases: crackle, wheeze, stridor, and rhonchi, with a 95% accura

34 Adventitious lung sounds including crackles, wheezes, rhonchi, bronchial breath sounds, str

35 normal and/or adventitious lung sounds like crackles, while simultaneously recording respiration rat

36 bdominal expiration, and bilateral pulmonary crackles without chest pain, hemoptysis, clubbing, or si

37 ve abdominal expiration, bilateral pulmonary crackles without chest pain, hemoptysis, clubbing, or si