ライフサイエンスコーパス: experimental glaucoma

1 o elevate intraocular pressure as a model of experimental glaucoma.

2 ceptor subunit NR1 promoted axon survival in experimental glaucoma.

3 t both substrates were cleaved by calpain in experimental glaucoma.

4 nes of evidence that calpain is activated in experimental glaucoma.

5 lated-Stat3 levels were increased in RGCs in experimental glaucoma.

6 authors used a well-established rat model of experimental glaucoma.

7 ocation and character of early ONH change in experimental glaucoma.

8 m that CNTF can exert a protective effect in experimental glaucoma.

9 for normal eyes were applied to monkeys with experimental glaucoma.

10 at the onset of ONH surface change in early experimental glaucoma.

11 to the increase in Hsp27 and pHsp27 seen in experimental glaucoma.

12 change in young adult monkey eyes with early experimental glaucoma.

13 effective to reduce changes associated with experimental glaucoma.

14 he onset of detectable ONH surface change in experimental glaucoma.

15 h significant visual field defects caused by experimental glaucoma.

16 reduction of functional loss associated with experimental glaucoma.

17 tissues occurs early in the monkey model of experimental glaucoma.

18 resent in young adult monkey eyes with early experimental glaucoma.

19 trophic factor (BDNF) could be protective in experimental glaucoma.

20 asured in the untreated eyes of monkeys with experimental glaucoma.

21 yes with anatomic and functional damage from experimental glaucoma.

22 afferent input to the blobs were affected by experimental glaucoma.

23 affected by the duration and severity of the experimental glaucoma.

24 d RGCs and ameliorated visual dysfunction in experimental glaucoma.

25 After 1 to 6 weeks of experimental glaucoma, all treated eyes had significant

26 nd N95 were greatly reduced or eliminated by experimental glaucoma and by TTX.

27 onfirm previous reports of elevated Hsp27 in experimental glaucoma and extend them to the DBA/2J mous

28 We also show efficacy in experimental glaucoma and humanized tauopathy models.

29 ion cell survival, and visual function after experimental glaucoma and nerve crush.

30 Experimental glaucoma and TTX had similar effects on the

31 RG, and the actual PERG all were affected by experimental glaucoma and TTX, indicating that they cont

32 titatively identify proteomic alterations in experimental glaucoma, and highlight many immune mediato

33 Six monkeys had laser-induced experimental glaucoma, and two others received intravitr

34 orded from macaques with advanced unilateral experimental glaucoma, and were simulated by averaging O

35 uniform field and PERG responses produced by experimental glaucoma are related and are largely a cons

36 eactive astrocytes in optic nerve heads with experimental glaucoma but not in the optic nerve head of

37 Experimental glaucoma causes minimal change in amacrine

38 objective measurements in monkeys with early experimental glaucoma correlated highly, with a mean +/-

39 This procedure generated early experimental glaucoma, defined as the onset of CSLT-dete

40 total of 41 rhesus macaques with unilateral experimental glaucoma (EG) each had three or more weekly

41 lative axon loss was -14% on average for all experimental glaucoma (EG) eyes within 6% (measurement n

42 y normal monkey and three monkeys with early experimental glaucoma (EG) in one eye.

43 14 nonhuman primates (NHPs) with unilateral experimental glaucoma (EG).

44 Laser-induced experimental glaucoma (ExGl) in non-human primates (NHPs

45 was established and verified in monkeys with experimental glaucoma (ExpG).

46 Chronic experimental glaucoma for 6 weeks was produced in 2- to

47 Unlike experimental glaucoma, hemiretinal endodiathermy axotomy

48 onkey eyes, 7 human) and after laser-induced experimental glaucoma in monkeys (n = 8).

49 The relationships derived from experimental glaucoma in monkeys also accurately predict

50 Experimental glaucoma in monkeys reduces retinal input t

51 Experimental glaucoma in monkeys reduces visual afferenc

52 on of retinal ganglion cell losses caused by experimental glaucoma in monkeys.

53 tocoagulation was used to produce unilateral experimental glaucoma in monkeys.

54 k represents a useful and efficient model of experimental glaucoma in rats.

55 Inflammatory responses of astrocytes in experimental glaucoma included up-regulation of a number

56 Gene expression changes specific to experimental glaucoma injury were identified.

57 etina where oxidative damage associated with experimental glaucoma is known to be prominent.

58 Experimental glaucoma led to a dramatic and consistent p

59 Experimental glaucoma led to increases in axial length a

60 Thus, in rodent models of experimental glaucoma, lower levels of chronically eleva

61 rease of albumin in the retinas of eyes with experimental glaucoma may serve to protect the retina ag

62 We further examined an experimental glaucoma model and found that surviving RGC

63 and its phosphorylation were evaluated in an experimental glaucoma model in Brown Norway rats and in

64 IOP should be maintained below this level in experimental glaucoma models if selective ganglion cell

65 t IOPs (30-50 mmHg) commonly observed in rat experimental glaucoma models.

66 .3-3.8 mM, n = 3) or laser-induced monocular experimental glaucoma (n = 6), and from six normal human

67 The effects of experimental glaucoma on mfERG were assessed in the freq

68 As previously reported, severe experimental glaucoma or TTX eliminated photopic negativ

69 Experimental glaucoma reduced fast OP RMS in all locatio

70 oss and synaptic changes in animal models of experimental glaucoma remain highly debated.

71 Experimental glaucoma removed a cornea-negative response

72 Fits to data from experimental glaucoma required ganglion cell dysfunction

73 In this rat model of experimental glaucoma, selective RGC functional injury o

74 However, P50 was more reduced by experimental glaucoma than by TTX, indicating a nonspiki

75 ained from 10 rhesus monkeys with unilateral experimental glaucoma that was induced by argon laser tr

76 igate the neural and sensitivity losses from experimental glaucoma to establish the framework for a q

77 uthors studied RGC neurotrophin transport in experimental glaucoma using acute intraocular pressure (

78 A primate model of experimental glaucoma was combined with intracellular re

79 The monkey model of experimental glaucoma was combined with standard histolo

80 Unilateral experimental glaucoma was induced in 10 monkeys by argon

81 Monocular experimental glaucoma was induced in adult monkeys (Maca

82 Monocular experimental glaucoma was induced in monkeys (Macaca mul

83 Experimental glaucoma was induced in normal mice and tho

84 Two weeks later, experimental glaucoma was induced in the injected eye by

85 Experimental glaucoma was induced in the right eyes of 1

86 Experimental glaucoma was induced unilaterally in 174 Wi

87 Experimental glaucoma was induced unilaterally in eight

88 Monocular experimental glaucoma was produced by argon laser trabec

89 Eyes from monkeys with unilateral experimental glaucoma were also subjected to immunohisto

90 Rs that could be eliminated by TTX or severe experimental glaucoma were present in responses to brief

91 epends on spiking activity and is reduced in experimental glaucoma when visual sensitivity losses are

92 labeling were not significantly affected by experimental glaucoma, with a mean decrease of 15% compa