ライフサイエンスコーパス: ciliary process

1 e, at the ciliary body, and particularly the ciliary process.

2 onths of age and anterior PFV with elongated ciliary processes.

3 essels and to the nonpigmented epithelium of ciliary processes.

4 ye and result in failure in formation of the ciliary processes.

5 linomimetics regulate its activity in bovine ciliary processes.

6 e anatomy of the angle region, including the ciliary processes.

7 re sensitive descriptors of the state of the ciliary processes.

8 om human iris sphincter, ciliary muscle, and ciliary processes.

9 in the pure epithelial bilayers and in whole ciliary processes.

10 ted from rabbit ciliary epithelium and human ciliary processes and from the anterior lens of rabbit,

11 een production of aqueous humour (AH) by the ciliary processes and hydrodynamic resistance to its out

12 in the nonpigmented epithelial cells of the ciliary processes and in the retina was noted.

13 The m1 receptor (7%) was detected in the ciliary processes and iris sphincter and the m5 receptor

14 es, intense fluorescence was observed in the ciliary processes and the ciliary muscle.

15 0 minutes was prominent in the iris root and ciliary processes and was of moderate intensity in the a

16 Eyes operated for PFV with elongated ciliary processes are unlikely to have a final visual ac

17 pigmented and nonpigmented epithelium at the ciliary process base were more discrete in TSNYC eyes.

18 may be partially due to visualization of the ciliary processes before applying laser energy, which al

19 s delivers reporter genes efficiently to the ciliary processes but penetrates poorly into the capsula

20 iris, trabecular meshwork, Schlemm's canal, ciliary processes, ciliary muscle, retina, choroid, cult

21 tripetal lens/capsule movements, centripetal ciliary process (CP) movements, and circumlental space w

22 at embryonic day 18.5 (E18.5), the onset of ciliary process formation.

23 asculature (PFV) with elongated or stretched ciliary processes have not been extensively studied and

24 esis and secretion by metabolically labeling ciliary processes in vitro with 35S-methionine, followed

25 o assess qualitative ultrastructural changes ciliary process microvessels at the site of aqueous form

26 s that this mechanism evolved from an innate ciliary process of releasing small extracellular vesicle

27 The intensity of the fluorescence within the ciliary processes of these eyes was substantially reduce

28 estigate the mechanisms underpinning complex ciliary processes, such as number control, the coordinat

29 with the potential for release of ET-1 from ciliary processes suggests that the lens could be expose

30 ules and their spatial relationship with the ciliary processes targeted during ECP and propose an ass

31 isolated from rhesus monkey ciliary muscle, ciliary processes, trabecular meshwork, and iris in the

32 ution of V-ATPase in specific regions of the ciliary process was altered profoundly by isoproterenol

33 ugs on the inositol phosphate (IP) levels in ciliary processes were also examined.

34 The automatically detected boundaries of the ciliary processes were analyzed to compute their periphe

35 noted in all patients; anteriorly displaced ciliary processes were noted in 4 of 5 patients who demo

36 ornea angle 108' / 114') and forward rotated ciliary processes were seen.