1 by implantation using the cuff technique for bronchovascular anastomoses.

2                                              Bronchovascular architecture was assessed with quantitat

3 he marker MEOX2, includes fibroblasts in the bronchovascular bundle and the alveolar interstitium, wh

4 vely impacts mechanical coupling between the bronchovascular bundle and the lung parenchyma, decreasi

5 uid (BALF), and alveolar opacities along the bronchovascular bundles on chest CT scan.

6 eveloped features of T2 responses, including bronchovascular collagen deposition and IL-4 production.

7                                Der f-induced bronchovascular eosinophilia was modestly enhanced in th

8 ation of numerous DC and CD4+ T cells within bronchovascular infiltrates coincided with increased exp

9 tment of large numbers of conventional DC to bronchovascular infiltrates in mice mounting a T1 immune

10  CCR2, DC recruitment was markedly impaired, bronchovascular infiltrates were diminished, and mice de

11 y epithelium, along with marked eosinophilic bronchovascular inflammation.

12 c acceptability, and depiction of peripheral bronchovascular markings.

13  cough, hypotension, and prominent pulmonary bronchovascular markings.

14 racterized were: honeycombing, ground glass, bronchovascular, nodular, emphysemalike, and normal.

15  airway disease, ground-glass opacification, bronchovascular prominence, and ratio of small blood ves

16 esenchymal stromal cell population along the bronchovascular space in an adult lung and identify this

17 ardiac motion-related artefacts (blurring of bronchovascular structures and double-line artefacts) we

18                                  Analysis of bronchovascular structures revealed that this fissure wa

19 he fissure and its relationship to segmental bronchovascular structures were evaluated on transverse