ライフサイエンスコーパス: fibrovascular

1 tion was computed based on the percentage of fibrovascular A-scans.

2 observed significant differences in stromal fibrovascular abundance and composition accompanied by i

3 ted algorithm classified 14 as serous, 96 as fibrovascular, and 58 as drusenoid PEDs.

4 ere 88% and 100% for serous, 76% and 64% for fibrovascular, and 58% and 81% for drusenoid, respective

5 DIRC graders classified 16 as serous, 88 as fibrovascular, and 64 as drusenoid PEDs.

6 eta1 and type I collagen mRNA and protein in fibrovascular bundles was coincident but was also delaye

7 The fibrovascular bundles were also analyzed for TGF-beta1 a

8 o 21 days later for the presence of invasive fibrovascular bundles.

9 expressing the DeltaRG transgene developed a fibrovascular collagenoma in the dermis, which closely r

10 Leptin and leptin receptor were detected in fibrovascular epiretinal membrane of patients with diabe

11 hy, and retinal detachment and is present in fibrovascular epiretinal tissue.

12 s, as well as macular pucker attributable to fibrovascular formation in the central retinal region.

13 ter 2 weeks, the disks were removed, and the fibrovascular growth area was used as an index of angiog

14 and tube formation in vitro, and accelerated fibrovascular growth in vivo.

15 In the DAS, Del-1 doubled fibrovascular growth, as did basic fibroblast growth fac

16 near-confluent pattern in an effort to quell fibrovascular ingrowth and subsequent hemorrhage.

17 Fibrovascular ingrowth should be suspected as a relative

18 Fibrovascular ingrowth was documented during second glau

19 in irradiated tissues, may mediate radiation fibrovascular injury.

20 porous polyethylene shell allows for greater fibrovascular integration and a potential for decreased

21 endothelial cells then infiltrate to form a fibrovascular lesion.

22 formed immature delicate trabecular bone in fibrovascular marrow filled the space underneath the tit

23 rrow-derived perivascular cells and promoted fibrovascular membrane formation in the laser-induced ad

24 epithelium, (2) basal laminar deposits, (3) fibrovascular membrane, (4) fibrocellular scar, (5) hemo

25 ar endothelial cells obtained from human PDR fibrovascular membranes (FVMs) via transcriptomic analys

26 on of glial and vascular cells, resulting in fibrovascular membranes that detached the retina.

27 After cytologic verification of LSCD, the fibrovascular pannus of each cornea was removed.

28 We emphasise fibrovascular patterns (both in uveal and cutaneous mela

29 ars to be sensitive for detecting serous and fibrovascular PEDs.

30 mesenchymal originating tumor (most likely a fibrovascular polyp).

31 mesenchymal originating mass, most likely a fibrovascular polyp, even the pedicle was not detected.

32 ezoar or a pedunculated tumor, most likely a fibrovascular polyp, without exclusion of other mesenchy

33 disease and all eyes demonstrating extensive fibrovascular proliferation (> 3 clock hours) after lase

34 The presence of fibrovascular proliferation (FP), vitreous hemorrhage (V

35 ed for repeat laser treatment, and new-onset fibrovascular proliferation after laser treatment.

36 volving persistent, chronic inflammation and fibrovascular proliferation as key components.

37 angiography was possible in 2 probands with fibrovascular proliferation demonstrating phenotypic ove

38 disease, preretinal hemorrhage, pre-existing fibrovascular proliferation, tunica vasculosa lentis, la

39 ge and at the initial ridge and extraretinal fibrovascular proliferative complex (12/14 infants [85.7

40 Congenital fibrovascular pupillary membranes in infants are likely

41 g early retinal development and promotes the fibrovascular reaction in murine retinal ischemia after

42 reased numbers of CD14(+) macrophages in the fibrovascular repair tissue compared with normal, as det

43 had early onset of lesions and a pronounced fibrovascular response that included outgrowth of subcut

44 ant developmental angiogenesis that leads to fibrovascular retinal detachment.

45 The mice had microphthalmia; fibrovascular, retrolental tissue containing retinal pig

46 Cells of the fibrovascular scaffold express the proangiogenic factor

47 f macrophages inhibits the formation of this fibrovascular scaffold, and expression analysis reveals

48 In contrast, adults heal via fibrovascular scar, aberrant differentiation toward cart

49 cellular events that lead to formation of a fibrovascular scar.

50 ound healing response and the formation of a fibrovascular scar.

51 ding, multiple cell types interact to form a fibrovascular scar; the formation and cellular origins o

52 egular epithelial hyperplasia with increased fibrovascular stroma and involved from 3 to >10 hair fol

53 nd the replacement of bare area regions with fibrovascular synovial tissue in joints without inflamma

54 ted CNV as a component of the development of fibrovascular tissue (FVT).

55 ision followed by removal of subconjunctival fibrovascular tissue and application of 0.02% mitomycin

56 pe 3 regression pattern, pre- and subretinal fibrovascular tissue consistent with PVR, and reactive c

57 nsation of intraocular pressure secondary to fibrovascular tissue contraction in the anterior chamber

58 tion of 2 primary pupillary membranes showed fibrovascular tissue that did not stain for neuron-speci

59 ent pupillary membrane revealed collagenized fibrovascular tissue that was immunoreactive for smooth

60 nti-inflammatory agents, adequate removal of fibrovascular tissue) are based on known differences in

61 Fibrovascular tissues (FVT) were elicited in 12 maculae

62 treatment (P = .006), and new-onset limited fibrovascular traction (< 3 clock hours) after laser tre

63 s occurring after laser treatment, new-onset fibrovascular traction is associated significantly with

64 ut <60 or mean intensity >/=30 and SD >/=30 (fibrovascular type); or mean intensity >/=60 and SD < 30

65 into three categories--serous, drusenoid, or fibrovascular--via inspection of the B-scans.