Gui Lin Zhan

Potential mechanism for the additivity of pilocarpine and latanoprost

PURPOSE To determine the ocular hypotensive mechanism underlying the additivity of latanoprost and pilocarpine. METHODS This randomized, double-masked study included 30 patients with ocular hypertension on no ocular medications for at least 3 weeks. On each of six visits to the clinic, measurements were taken of aqueous flow and outflow facility by fluorophotometry, intraocular pressure by tonometry, and episcleral venous pressure by venomanometry. Uveoscleral outflow was calculated. Clinic visits were scheduled on baseline day; on day 8 of four times daily pilocarpine (2%) to one eye and vehicle to the other; on day 8 of continued pilocarpine/vehicle treatment plus latanoprost (0.005%) once daily to both eyes; after a 3-week washout period; on day 8 of once-daily latanoprost to one eye and vehicle to the other; and on day 8 of continued latanoprost/vehicle treatment plus pilocarpine four times a day to both eyes. Drug-treated eyes were compared with contralateral vehicle-treated eyes and with baseline day by paired t tests. Combined pilocarpine and latanoprost-treated eyes were compared with individual drug-treated eyes and with baseline day using the Bonferroni test. RESULTS Compared with baseline, pilocarpine reduced intraocular pressure from 18.9 to 16.2 mm Hg (P =.001) and increased outflow facility from 0.18 to 0.23 microl per minute per mm Hg (P =.03). No other parameters were affected. Adding latanoprost further reduced intraocular pressure to 13.7 mm Hg (P <.001) and increased uveoscleral outflow from 0.82 to 1.36 microl per minute (P =.02). Latanoprost alone reduced intraocular pressure from 17.6 to 14.3 mm Hg (P <.0001) and increased uveoscleral outflow from 0.89 to 1.25 microl per minute (P =.05). Adding pilocarpine to the latanoprost treatment further reduced intraocular pressure to 12.7 mm Hg (P <.001) and increased outflow facility from 0.21 to 0.30 microl per minute per mm Hg (P =.03). CONCLUSIONS Latanoprost and pilocarpine predominantly increase uveoscleral outflow and outflow facility, respectively, when given alone. These drugs are additive because pilocarpine does not inhibit the uveoscleral outflow increase induced by latanoprost.

Effects of travoprost on aqueous humor dynamics in monkeys.

Purpose:To determine the mechanism by which travoprost, a prodrug of a prostaglandin F2α analog, reduces intraocular pressure (IOP) in cynomolgus monkey eyes. Methods:One eye each of 12 monkeys was treated with laser burns to the trabecular meshwork to elevate IOP. At least 4 months later (Baseline Day), IOP was measured by pneumatonometry (9:00 AM and 11:45 AM), and aqueous flow and outflow facility were determined by a fluorophotometric method. Uveoscleral outflow was calculated. Both eyes were treated with travoprost 0.004% at 9:00 AM and 5:00 PM for two days and at 9:30 AM on the third day (Treatment Day), when measurements were repeated as on Baseline Day. Statistical analyses were performed using two-tailed, paired t tests. Results:On Treatment Day compared with Baseline Day, IOP in hypertensive eyes was reduced at 2.25 hours (25.8 ± 11.2 vs 33.7 ± 13.2 mm Hg; mean ± standard error of the mean [SEM]; P = 0.02) and 16 hours (26.3 ± 10.2 vs 35.1 ± 13.6 mm Hg; P = 0.02) after treatment. The increase in uveoscleral outflow was not significant. In normotensive eyes, IOP was reduced at 2.25 hours (19.0 ± 3.7 vs 23.0 ± 4.0 mm Hg; P = 0.03) and 16 hours (20.7 ± 5.4 vs 23.4 ± 5.3 mm Hg; P = 0.01) after treatment, and uveoscleral outflow was significantly (P = 0.02) increased (1.02 ± 0.43 vs 0.35 ± 0.72 μL/min). Conclusion:Travoprost reduces IOP in normotensive monkey eyes by increasing uveoscleral outflow. The IOP reduction in hypertensive eyes is probably via the same mechanism, although the increased uveoscleral drainage did not reach statistical significance. Travoprost had no effect on aqueous flow or outflow facility.

Effects on aqueous flow of dorzolamide combined with either timolol or acetazolamide.

Purpose:To determine the effect on aqueous flow of topical dorzolamide 2%, topical timolol 0.5%, or oral acetazolamide 250 mg when used alone or when dorzolamide is combined with either timolol or acetazolamide. Methods:In 30 patients with ocular hypertension, aqueous flow and intraocular pressure (IOP) were determined at baseline and on the following combinations of drugs in a crossover design: (1) vehicle alone, (2) dorzolamide alone, (3) acetazolamide alone, (4) timolol alone, (5) dorzolamide + acetazolamide, and (6) dorzolamide + timolol. Treated eyes were compared with control eyes and comparisons were made between treatments. Results:Compared with baseline, significant (P < 0.04) IOP reductions in the order of efficacy were: dorzolamide + timolol > dorzolamide + acetazolamide = acetazolamide = timolol > dorzolamide. Aqueous flow was reduced more by dorzolamide + timolol than by each drug alone (P < 0.04) and more by dorzolamide + acetazolamide than by dorzolamide alone (P < 0.04). Conclusion:The combination of dorzolamide and timolol demonstrated significant aqueous flow additivity and had greater IOP efficacy than the combination of dorzolamide and acetazolamide.

Cabergoline: Pharmacology, ocular hypotensive studies in multiple species, and aqueous humor dynamic modulation in the Cynomolgus monkey eyes.

The aims of the current studies were to determine the in vitro and in vivo ocular and non-ocular pharmacological properties of cabergoline using well documented receptor binding, cell-based functional assays, and in vivo models. Cabergoline bound to native and/or human cloned serotonin-2A/B/C (5HT(2A/B/C)), 5HT(1A), 5HT(7), alpha(2B), and dopamine-2/3 (D(2/3)) receptor subtypes with nanomolar affinity. Cabergoline was an agonist at human recombinant 5HT(2), 5HT(1A) and D(2/3) receptors but an antagonist at 5HT(7) and alpha(2) receptors. In primary human ciliary muscle (h-CM) and trabecular meshwork (h-TM) cells, cabergoline stimulated phosphoinositide (PI) hydrolysis (EC(50)=19+/-7 nM in TM; 76 nM in h-CM) and intracellular Ca(2+) ([Ca(2+)](i)) mobilization (EC(50)=570+/-83 nM in h-TM; EC(50)=900+/-320 nM in h-CM). Cabergoline-induced [Ca(2+)](i) mobilization in h-TM and h-CM cells was potently antagonized by a 5HT(2A)-selective antagonist (M-100907, K(i)=0.29-0.53 nM). Cabergoline also stimulated [Ca(2+)](i) mobilization more potently via human cloned 5HT(2A) (EC(50)=63.4+/-10.3 nM) than via 5HT(2B) and 5HT(2C) receptors. In h-CM cells, cabergoline (1 microM) stimulated production of pro-matrix metalloproteinases-1 and -3 and synergized with forskolin to enhance cAMP production. Cabergoline (1 microM) perfused through anterior segments of porcine eyes caused a significant (27%) increase in outflow facility. Topically administered cabergoline (300-500 microg) in Dutch-belted rabbit eyes yielded 4.5 microMM and 1.97 microM levels in the aqueous humor 30 min and 90 min post-dose but failed to modulate intraocular pressure (IOP). However, cabergoline was an efficacious IOP-lowering agent in normotensive Brown Norway rats (25% IOP decrease with 6 microg at 4h post-dose) and in conscious ocular hypertensive cynomolgus monkeys (peak reduction of 30.6+/-3.6% with 50 microg at 3h post-dose; 30.4+/-4.5% with 500 microg at 7h post-dose). In ketamine-sedated monkeys, IOP was significantly lowered at 2.5h after the second topical ocular dose (300 microg) of cabergoline by 23% (p<0.02) and 35% (p<0.004) in normotensive and ocular hypertensive eyes, respectively. In normotensive eyes, cabergoline increased uveoscleral outflow (0.69+/-0.7 microL/min-1.61+/-0.97 microL/min, n=13; p<0.01). However, only seven of the eleven ocular hypertensive monkeys showed significantly increased uveoscleral outflow. These data indicate that cabergolines most prominent agonist activity involves activation of 5HT(2), 5HT(1A), and D(2/3) receptors. Since 5HT(1A) agonists, 5HT(7) antagonists, and alpha(2) antagonists do not lower IOP in conscious ocular hypertensive monkeys, the 5HT(2) and dopaminergic agonist activities of cabergoline probably mediated the IOP reduction observed with this compound in this species.

Effects of marijuana on aqueous humor dynamics in a glaucoma patient.

Marijuana, endocannabinoids, and their congeners have been shown to reduce intraocular pressure (IOP) in animals, in healthy volunteers, and in patients with open angle glaucoma. The mechanism by which marijuana reduces IOP remains unclear. In rabbits, intravenous administration of 10 mg D -tetrahydrocannabinol (THC) increased total outflow facility when measured by the two level constant pressure perfusion method. However, in beagles, topical application of D-THC 0.1% produced no change in outflow facility when determined by tonography. Activation of cannabinoid receptors, CB1 and/or CB2, induces both direct effects on certain biochemical processes and perturbations in cell membranes. Immunofluorescence studies show that cannabinoids bind to CB1 receptors in rat, bovine, and human ciliary epithelial and trabecular meshwork cells, suggesting that cannabinoids may reduce IOP by either increasing outflow facility or reducing aqueous production. In this study, we had the rare opportunity to investigate the mechanism by which marijuana reduced IOP in one glaucoma patient receiving government-approved marijuana.

Effects of brinzolamide on aqueous humor dynamics in monkeys and rabbits

This study examines the mechanisms by which brinzolamide reduces intraocular pressure (IOP) in healthy rabbits and in monkeys with unilateral ocular hypertension. Intraocular pressures were measured by pneumatonometry and aqueous flow was determined by fluorophotometry before and after three twice-daily drops of 1% brinzolamide to both eyes per monkey and after similar treatment to one eye per rabbit. In monkeys, outflow facility was determined by fluorophotometry and uveoscleral outflow was calculated. In rabbits, outflow facility was determined by two-level constant pressure infusion and uveoscleral outflow was measured by an intracameral tracer technique. Compared with contralateral vehicle-treated rabbit eyes, IOP was reduced in brinzolamide-treated eyes by 2.5 +/- 1.9 mmHg (mean +/- standard deviation; p =.006) at four hours after the second dose. Aqueous flow was reduced by 0.50 +/- 0.65 microl/min (p =.02). This effect was found in rabbits previously treated with brinzolamide but not in naive rabbits. Treated hypertensive eyes of monkeys had a reduction in IOP of 7.3 +/- 8.8 mmHg (p = 0.01) and aqueous flow of 0.69 +/- 1.10 microL/min (p = 0.05) when compared with baseline. Brinzolamide did not affect outflow facility or uveoscleral outflow in either rabbits or monkeys. It is concluded that, in normotensive eyes of rabbits and hypertensive eyes of monkeys, brinzolamide reduces IOP by reducing aqueous flow and not by affecting aqueous humor drainage.

Time dependent effects of sympathetic denervation on aqueous humor dynamics and choroidal blood flow in rabbits

Purpose. This study investigates the time-dependent effects of superior cervical ganglionectomy (SCGx) on aqueous humor dynamics and ocular blood flow in rabbits. Methods. 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, normallyinnervated eyes using a paired Students two-tailed t-test. Results. At 24 hours after SCGx, IOP in denervated eyes was less than in normally-innervated eyes (14.6 ± 0.8 vs 20.1 ± 1.5mmHg, 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 ± 0.9mmHg, 19%, p < 0.001), outflow facility was less (0.15 ± 0.02 vs 0.21 ± 0.01µl/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. Conclusions. 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.

Unoprostone isopropyl ester darkens iris color in pigmented rabbits with sympathetic denervation.

PURPOSE 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. MATERIALS AND METHODS 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. RESULTS 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. CONCLUSION 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.