ライフサイエンスコーパス: bronchopneumonia

1 lternative macrophage activation, and severe bronchopneumonia.

2 bacterial growth and development of primary bronchopneumonia.

3 ic lung flora in lambs with early lesions of bronchopneumonia.

4 at CT histologically corresponded with acute bronchopneumonia.

5 , although the index case recently died from bronchopneumonia.

6 imilar to that of human infants that develop bronchopneumonia.

7 f death were pulmonary emboli and infectious bronchopneumonia.

8 supported the association of this agent with bronchopneumonia (16/34 pneumonic versus 0/17 nonpneumon

9 by microthrombi (27/70), superimposed acute bronchopneumonia (17/70), and leukocytoclastic vasculiti

10 tients were most likely to be diagnosed with bronchopneumonia (20% adults; 13% children) and/or malar

11 characterized by subacute lymphohistiocytic bronchopneumonia and persistent elevation of tumor necro

12 plicated in the pathogenesis of pneumococcal bronchopneumonia and septicemia.

13 highly permissive to SARS-CoV-2 and develop bronchopneumonia and strong inflammatory responses in th

14 ial lung disease and pulmonary embolism, one bronchopneumonia, and one pulmonary embolism) and one in

15 Half also had bronchopneumonia, and one-third had acute lung injury.

16 iated TRAIL-R-/- animals showed hallmarks of bronchopneumonia as well as tumor formation with increas

17 diseases, including cystic fibrosis, severe bronchopneumonia, chronic obstructive pulmonary disease,

18 hologic evidence of suppurative neutrophilic bronchopneumonia, cyst formation, and alveolar damage.

19 associated with infarction in 8 patients and bronchopneumonia in 6 patients.

20 culls pathological signs of mild multifocal bronchopneumonia in approximately 5-15% of the lung is s

21 wed areas of bronchiolitis, with surrounding bronchopneumonia in five of seven animals.

22 M. ovipneumoniae is strongly associated with bronchopneumonia in free-ranging bighorn sheep and is a

23 produce the lesions of turbinate atrophy and bronchopneumonia in pigs infected with this organism.

24 which produces a chronic, lymphohistiocytic bronchopneumonia in pigs, was found to potentiate the se

25 t M. hyopneumoniae, which produces a chronic bronchopneumonia in swine, potentiates a viral pneumonia

26 ergent adverse event that resulted in death (bronchopneumonia in the D-RVd group; cause unknown in th

27 Higher doses produced a rapidly fatal bronchopneumonia in X-CGD mice, whereas progression of d

28 Bronchopneumonia is a population-limiting disease in big

29 matic accident, one cerebral hemorrhage, two bronchopneumonia, one peritonitis).

30 seizures (PMRc = 9.5, each) and unspecified bronchopneumonia (PMRc = 5.0) were notable.

31 e occurrence of current or recent historical bronchopneumonia problems (seropositive animals detected

32 A clear conceptualisation of bronchopneumonia resulting from viral-bacterial interact

33 Early lesions of bronchopneumonia soon progressed to more severe bronchoi

34 ed to a purulent multifocal severe exudative bronchopneumonia that closely resembles the disease obse

35 a pestis causes pneumonic plague, a necrotic bronchopneumonia that is rapidly lethal and highly conta

36 Lung samples from patients with bronchopneumonia were analyzed by immunofluorescence.

37 Moderate turbinate atrophy and bronchopneumonia were found in most pigs given the paren

38 ar pathogen of macrophages and causes severe bronchopneumonia when inhaled by susceptible foals.

39 hamsters with Ad14p1 caused a marked, patchy bronchopneumonia, whereas hamster infection with wt Ad14

40 loped a severe neutrophil-dominated purulent bronchopneumonia with interstitial and alveolar edema an

41 A diagnosis of bronchopneumonia with pleuritis was made.

42 All the RMs and AGMs had various degrees of bronchopneumonia, with inflammation consisting of numero