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ABSTRACT: Unoprostone isopropyl ester (unoprostone) -induced iris color darkening was evaluated in a rabbit model using a cyclooxygenase inhibitor, an alpha(1)-adrenergic antagonist, and sympathetic denervation.
Dutch-belted rabbits were divided into five groups based on type of surgery and eyedrop treatment to both eyes: (1) sham surgery (n = 7); (2) bilateral superior cervical ganglionectomy (SCGx, n = 7); (3) SCGx plus flurbiprofen 0.03% (n = 7); (4) SCGx plus thymoxamine 0.5% (n = 6); and (5) SCGx plus flurbiprofen and thymoxamine (n = 6). All rabbits were treated with unoprostone 0.12% to one eye and its vehicle to the contralateral eye twice daily for 43 weeks after SCGx. Periodic color photographs of paired eyes were scored for difference in eye color. Iris melanin and aqueous humor protein were measured at week 43.
Twenty-three of the 26 rabbits with bilateral SCGx and unilateral unoprostone treatment demonstrated a darker iris color on the unoprostone-treated side. The average scores (demonstrating difference in iris color) comparing photographs of treated versus control eyes in the four SCGx groups were higher than those in the sham surgery group (P < 0.03), and higher than at week 0 (P < 0.001). The group pretreated with flurbiprofen and thymoxamine had the highest score of all groups. The aqueous humor protein in unoprostone-treated eyes was higher (P < or = 0.0001) than in vehicle-treated eyes. The melanin content of irides of the denervated groups was higher (P < or = 0.01) in unoprostone-treated than in vehicle-treated eyes.
Unoprostone produced iris color darkening in pigmented rabbit eyes with sympathetic denervation. Pretreatment with flurbiprofen and thymoxamine appeared to enhance this effect but this was not statistically demonstrated by the study.
Journal of Glaucoma 09/2003; 12(4):383-9. · 1.78 Impact Factor
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ABSTRACT: Latanoprost, a prodrug of a prostaglandin F(2alpha) analog, is a potent ocular hypotensive agent, reducing intraocular pressure (IOP) primarily by increasing aqueous humor drainage through the uveoscleral outflow pathway. Initial assessments in animals found that high concentrations of cholinergic agonists reduced drainage through this pathway and attenuated the effects of a PGF(2alpha) analog. This raised the question of whether latanoprost would be effective when added to the treatment regimen of patients on pilocarpine or strong miotics. In published clinical studies, latanoprost was additive to the maximally tolerated medical therapy (which included cholinergic agonists) of glaucoma patients. Multiple doses of physostigmine in healthy volunteers did not block the effect of a single drop of latanoprost during a 1-day study. One study attempting to find the optimal timing of administration of latanoprost and pilocarpine claimed to show that additivity was best when pilocarpine was given one hour after latanoprost in the evening. Two other studies found that the timing of the doses was not important. To explain the additivity of latanoprost and pilocarpine, aqueous humor dynamics were assessed in ocular hypertensive patients treated for 1 week with each drug alone and then for one week in combination. The results showed that latanoprost increased uveoscleral outflow, pilocarpine increased outflow facility, and pilocarpine did not block or attenuate the uveoscleral outflow effect of latanoprost. The result was greater IOP reduction when these drugs were used in combination than when either drug was used alone. All available evidence demonstrates that addition of latanoprost to the treatment regime of patients already taking cholinergic agonists is an effective, although not necessarily the preferred, combination of medications for the treatment of elevated IOP.
Survey of Ophthalmology 09/2002; 47 Suppl 1:S141-7. · 2.35 Impact Factor
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ABSTRACT: Bimatoprost (Lumigan [Allergan, Inc, Irvine CA]) and travoprost (Travatan [Alcon, Ft Worth, TX]) are two new intraocular pressure (IOP)-lowering drugs for use in patients with glaucoma and ocular hypertension. This review evaluates recent studies comparing these new drugs with timolol and with latanoprost. In each study, the statistical analyses support the conclusion that these agents were more effective than timolol and as effective as latanoprost in terms of their ability to reduce IOP. The side effect profiles for bimatoprost, latanoprost, and travoprost were similar, but with statistically higher occurrences of hyperemia and eyelash growth for bimatoprost or travoprost versus latanoprost or timolol.
Survey of Ophthalmology 09/2002; 47 Suppl 1:S105-15. · 2.35 Impact Factor
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ABSTRACT: This study investigates the time-dependent effects of superior cervical ganglionectomy (SCGx) on aqueous humor dynamics and ocular blood flow in rabbits.
Measurements were made at various times between 24 hours and 12 months after SCGx. Intraocular pressure (IOP) was measured by pneumatonometry, aqueous flow by fluorophotometry and outflow facility by tonography. Uveoscleral outflow was determined by an intracameral tracer infusion technique and blood flow to the choroid was evaluated with fluorescent microspheres. Values in denervated eyes were compared with the contralateral, normally-innervated eyes using a paired Student's two-tailed t-test.
At 24 hours after SCGx, IOP in denervated eyes was less than in normally-innervated eyes (14.6 +/- 0.8 vs 20.1 +/- 1.5 mmHg, 27%, p < 0.002). At one month, IOPs were not different between eyes. Compared with normally-innervated eyes at 10-12 months, IOP in denervated eyes was greater (20.4 +/- 0.7 vs 17.2 +/- 0.9 mmHg, 19%, p < 0.001), outflow facility was less (0.15 +/- 0.02 vs 0.21 +/- 0.01 microl/min/mmHg, 29%, p < 0.01) and blood flow to the choroid was less (12.1 +/- 5.0 vs 16.2 +/- 6.0 ml/min/gm tissue, 25%, p < 0.05). Aqueous humor flow was not significantly altered by SCGx at any time.
The reduction in IOP at 24 hours after SCGx was not due to any change in aqueous flow or uveoscleral outflow (current study) but rather to an increase in outflow facility (previous studies). At 10-12 months, IOP was elevated because outflow facility was significantly reduced. The reduction in choroidal blood flow at 10-12 months may have occurred because of the increased IOP.
Current Eye Research 08/2002; 25(2):99-105. · 1.28 Impact Factor
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ABSTRACT: To explore recent studies and clinical experience involving the importance of 24-hour control of intraocular pressure (IOP) in patients with glaucoma.
Roundtable discussion.
During the discussion, the following concepts were identified: 1. Although the effect of IOP is continuous, IOP is infrequently measured in clinical practice. 2. Within an individual patient, measurements of IOP have considerable variability throughout 24 hours. 3. Recent studies have shown that healthy subjects and glaucoma patients may experience their highest IOP at night once they have lain down to sleep. 4. Low blood pressure levels related to an individual's circadian rhythm can occur simultaneous with high IOPs at night, reducing blood flow to the optic nerve head below critical levels and thus resulting in optic nerve damage. 5. Glaucoma medications that can maximally reduce IOP over 24 hours and minimally influence blood pressure should have theoretical and practical advantages for glaucoma management.
The new knowledge about peak night-time IOPs is changing how physicians manage their patients in terms of drug selection and targeted IOP levels aimed at halting progression of glaucomatous optic nerve damage and visual field loss. Physicians are also taking into consideration the troublesome relationship between lowered systemic blood pressure and elevated IOP during the nighttime period.
American Journal of Ophthalmology 07/2002; 133 Suppl:S1-10. · 4.22 Impact Factor
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ABSTRACT: To evaluate the mechanism of the intraocular pressure (IOP) elevation in ocular hypertension (OHT), aqueous humor dynamics were compared in patients with OHT versus age-matched ocular normotensive (NT) volunteers.
In this retrospective study, one group included patients diagnosed with OHT (IOPs > 21 mm Hg, n = 55) for at least six months. All eye medications were discontinued for at least three weeks before the study visit. A second group included age-matched NT subjects (n = 55) with no eye diseases. The study visit included measurements of IOP by pneumatonometry, aqueous flow and outflow facility by fluorophotometry, anterior chamber depth and corneal thickness by pachymetry and episcleral venous pressure by venomanometry. Uveoscleral outflow and anterior chamber volume were calculated mathematically.
Significant differences in the OHT versus the NT groups were as follows: increased IOP (21.4 +/- 0.6 versus 14.9 +/- 0.3 mm Hg, respectively; P < 0.0001), reduced uveoscleral outflow (0.66 +/- 0.11 versus 1.09 +/- 0.11 microL/min; P = 0.005) and reduced fluorophotometric outflow facility (0.17 +/- 0.01 versus 0.27 +/- 0.02 microL/min/mm Hg; P < 0.0001). With respect to age, anterior chamber volume decreased in both groups at a rate of 2.4 +/- 0.3 microL/year (r(2) = 0.5, P <.001) and aqueous flow decreased at a rate of 0.013 +/- 0.005 microL/min/year (r(2) = 0.07, P = 0.005).
The increased IOP in ocular hypertensive patients is caused by a reduction in trabecular outflow facility and uveoscleral outflow. Aqueous flow remains normal. When both ocular normotensive and hypertensive groups are combined, aqueous flow and anterior chamber volume decrease slightly with age.
Journal of Glaucoma 06/2002; 11(3):253-8. · 1.78 Impact Factor
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