Effect of topical betaxolol on acute rise of aqueous flare induced by prostaglandin E(2) in pigmented rabbits.

PURPOSE: To evaluate the effects of topical betaxolol on experimental ocular inflammation. METHODS: Transcorneal diffusion of 25 microg/mL (7.09 x 10(-2) mmol/L) of prostaglandin E(2) (PGE(2)), placed in a glass cylinder, was employed to induce aqueous flare elevation in pigmented rabbits. Betaxolol was administered topically before PGE(2) application. Aqueous flare was measured with a laser flare cell meter. RESULTS: Four-, two-, and one-time topical instillations of betaxolol inhibited the PGE(2)-induced aqueous flare elevation by 44% +/- 8%, 32 +/- 7%, and 8 +/- 6%(mean +/- SD), respectively. The inhibition of flare elevation was dependent on the number of betaxolol instillations. CONCLUSION: Topical betaxolol has an inhibitory effect on PGE(2)-induced aqueous flare elevation in rabbit eyes.     

Effects of topical corticosteroids and nonsteroidal anti-inflammatory drugs on prostaglandin e2-induced aqueous flare elevation in pigmented rabbits

We evaluated the effects of anti-inflammatory potency of corticosteroids and nonsteroidal anti-inflammatory drugs on prostaglandin E2 (PGE2)-induced aqueous flare elevation in pigmented rabbits. Transcorneal diffusion of PGE2, 25 microg/ml (7.09 x 10(-2) mmol/l), with the use of a glass cylinder was achieved to produce aqueous flare elevation. Anti-inflammatory drugs were topically administered once before PGE2 application. Aqueous flare was measured with a laser flare-cell meter. Topical single instillation of dexamethasone sodium metasulfobenzoate 0.1%, dexamethasone sodium phosphate 0.1%, and fluorometholone 0.1% 6 h before PGE2 application inhibited 56, 59, and 43% of flare elevation, respectively. Topical single instillation of bromfenac sodium 0.1% and pranoprofen 0.1% 1 h before PGE2 application inhibited 33 and 15% of flare elevation, respectively. Indomethacin 0.5% did not inhibit flare elevation. Corticosteroid eyedrops needed several hours from topical instillation to exhibit inhibition of flare elevation. Most nonsteroidal anti-inflammatory drug eyedrops inhibited aqueous flare elevation when instilled 1 h before PGE2 application.     

Effects of alpha(2)-adrenergic agonists on lipopolysaccharide-induced aqueous flare elevation in pigmented rabbits

PURPOSE: To evaluate the effects of the alpha(2)-adrenergic agonists (clonidine, apraclonidine, and guanfacine) on lipopolysaccharide (LPS)-induced aqueous flare elevation in pigmented rabbits. METHODS: Anterior uveitis was induced with an intravenous injection of LPS (0.5 microg/kg) in an ear vein. The reproducibility of experimental uveitis induced by LPS (0.5 microg/kg) was also determined. Clonidine (0.01, 0.05, 0.25, or 1%), apraclonidine (1%), or guanfacine (1%) was topically instilled in the right eye 30 and 5 minutes before and 30 minutes after LPS application (N = 6 animals, respectively). Clonidine (0.25%) was topically administered three times at 30-minute intervals from 240 or 120 minutes before, or 120 or 240 minutes after LPS application (N = 6 animals, respectively). Then 1 mg/kg of yohimbine was injected into an ear vein 30 minutes before each topical three-time instillation of clonidine 1%, apraclonidine 1% or guanfacine 1% (N = 6 animals, respectively). Aqueous flare was measured with a laser flare-cell meter. Aqueous flare elevation was expressed as the area under the curve (AUC) in arbitrary units. Rabbits received the first LPS intravenous injection, and the control values of the AUC were obtained. Three months later, the alpha(2)-agonist and the second LPS administration were given to the same animals. RESULTS: The AUCs (5,184 +/- 1,255 units) after the first application of LPS were similar to those (5,033 +/- 1,290) after the second application 3 months after the first administration. Topical instillation of clonidine inhibited LPS-induced aqueous flare elevation in a dose-dependent manner (0.01-0.25%). Topical instillation of clonidine 1%, apraclonidine 1% or guanfacine 1% inhibited LPS-induced aqueous flare elevation by 98 +/- 2.0% (mean +/- SD), 86 +/- 14% and 94 +/- 5.7%, respectively. Pretreatment with intravenous yohimbine prevented the inhibitory effect on flare elevation induced by each agent. CONCLUSION: The present findings suggested that topical instillation of some alpha(2)-agonists may have an inhibitory effect on ocular inflammation, which is mediated in part by alpha(2)-receptors.     

Effects of topical antiglaucoma eye drops on prostaglandin E(2)-induced aqueous flare elevation in pigmented rabbits

PURPOSE: To evaluate the role of topical instillation of some antiglaucoma agents on experimental elevation of aqueous flare induced by prostaglandin E(2) (PGE(2)) in pigmented rabbits. METHODS: Transcorneal diffusion of PGE(2) (25 microg/mL or 7.09 x 10(-2) mM) with the use of a glass cylinder was achieved to produce aqueous flare elevation in pigmented rabbits. An antiglaucoma agent was topically administered before application of PGE(2). Aqueous flare was measured with a laser flare cell meter. RESULTS: A single instillation of apraclonidine 1.15%, two instillations of epinephrine 1.25%, two instillations of dipivefrin 0.1%, and two instillations and one instillation of dipivefrin 0.04% eye drops inhibited 98%, 96%, 87%, 73%, and 47% of PGE(2)-induced aqueous flare elevation, respectively. Timolol 0.5%, nipradilol 0.25%, dorzolamide 1%, and pilocarpine 2% eye drops had no effects on the increase of PGE(2)-induced flare. CONCLUSIONS: Apraclonidine, epinephrine, and dipivefrin eye drops inhibit PGE(2)-induced elevation of aqueous flare in pigmented rabbits.     

Effects of topical mydriatics and vasoconstrictors on prostaglandin-E2-induced aqueous flare elevation in pigmented rabbits

We evaluated the effects of topical instillation of mydriatics and vasoconstrictors on prostaglandin E2 (PGE2) induced aqueous flare elevation in pigmented rabbits. Transcorneal diffusion of PGE2 (25 microg/ml) by means of a glass cylinder produced aqueous flare elevation. Mydriatics (atropine sulfate, tropicamide, tropicamide plus phenylephrine hydrochloride, phenylephrine hydrochloride, and cyclopentolate hydrochloride) or vasoconstrictors (naphazoline nitrate and tramazoline hydrochloride) were topically administered before PGE2 application. Aqueous flare was measured with a laser flare-cell meter. One or two instillations of atropine sulfate 1.0%, tropicamide 0.4%, tropicamide 0.5% plus phenylephrine hydrochloride 0.5%, phenylephrine hydrochloride 5.0%, cyclopentrate hydrochloride 1.0%, and naphazoline nitrate 0.05% did not inhibit PGE2-induced aqueous flare elevation. Tramazoline hydrochloride 0.118% inhibited significantly (p < 0.05) PGE2-induced aqueous flare elevation. It is possible that vasoconstriction may be involved partly in inhibition of PGE2-induced aqueous flare elevation by some drugs in pigmented rabbits.     

Effect of topical iganidipine on experimental elevation of aqueous flare induced by prostaglandin E(2) and EP agonists in pigmented rabbits

We evaluated the role of topical iganidipine on experimental aqueous flare elevation in rabbits. Transcorneal diffusion of prostaglandin E(2) (PGE(2)), 25 microg/ml or 7.09 x 10(-2) mmol/l, or highly selective agonists for prostaglandin E(2) receptor subtypes (EP), 25 microg/ml, was achieved with the use of a glass cylinder to produce aqueous flare elevation in pigmented rabbits. Iganidipine was topically administered before application of PGE(2) or EP agonists. Aqueous flare was measured with a laser flare cell meter. Topical instillation of 0.1% iganidipine once or twice inhibited 64 +/- 8% (p < 0.01) and 84 +/- 9% (p < 0.01) of PGE(2)-induced aqueous flare elevation, respectively. Two instillations of 0.1% iganidipine inhibited 95 +/- 5% (p < 0.01) of EP2-agonist(ONO-AE1-259-01)-induced flare elevation and 98 +/- 3% (p < 0.01) of EP4-agonist(ONO-AE1-392)-induced flare rise. Topical iganidipine may have anti-inflammatory activity in the eye.     

Effects of intravenous administration of FR122047 (a selective cyclooxygenase 1 inhibitor) and FR188582 (a selective cyclooxygenase 2 inhibitor) on prostaglandin-E2-induced aqueous flare elevation in pigmented rabbits

PURPOSE: Two isoforms of cyclooxygenase (COX-1 and COX-2) exist. To determine in vivo effects of the intravenous administration of FR122047 (a selective COX-1 inhibitor), FR188582 (a selective COX-2 inhibitor), diclofenac sodium or dexamethasone phosphate disodium on prostaglandin-E2 (PGE2)-induced aqueous flare elevation and mRNA levels for COX-1 and COX-2 in pigmented rabbits. METHODS: To produce aqueous flare elevation in rabbits, PGE2, 25 microg/ml, was applied to the cornea with the use of a glass cylinder. FR122047, FR188582, diclofenac sodium or dexamethasone phosphate disodium was intravenously injected before PGE2 application. Aqueous flare was measured with a laser flare-cell meter. The mRNA levels for COX-1 and COX-2 in the iris-ciliary body were determined by real-time polymerase chain reaction. RESULTS: FR122047, FR188582 and diclofenac sodium (15 micromol/kg each) injected intravenously 30 min before PGE2 application inhibited 29 +/- 5, 40 +/- 12 and 50 +/- 9% of aqueous flare elevation, respectively. Simultaneous injection of FR122047 (15 micromol/kg) and FR188582 (15 micromol/kg) 30 min before PGE2 application inhibited 61 +/- 8% of flare elevation. Dexamethasone phosphate disodium (15 micromol/kg) injected intravenously 300 min before PGE2 application inhibited 68 +/- 8% of aqueous flare elevation. Less than 3-fold changes in mRNA levels for COX-1 and COX-2 in the iris-ciliary body were noted after PGE2, FR122047, FR188582, diclofenac sodium or dexamethasone phosphate disodium treatment. CONCLUSION: It is possible that enzyme activities of both COX-1 and COX-2 may be involved in the mechanism of PGE2-induced aqueous flare elevation in pigmented rabbits.     

Effects of isopropyl unoprostone, latanoprost, and prostaglandin E(2) on acute rise of aqueous flare in pigmented rabbits

PURPOSE: To evaluate the effect of isopropyl unoprostone, latanoprost, and prostaglandin E(2) (PGE(2)) on aqueous flare elevation. METHODS: Isopropyl unoprostone (0.12%) or latanoprost (0.005%) was topically instilled. Transcorneal diffusion of PGE(2), 25 microg/ml, using a glass cylinder, was achieved in pigmented rabbits. Aqueous flare was measured with a laser flare cell meter. RESULTS: Topical instillation of isopropyl unoprostone induced aqueous flare elevation in rabbit eyes. Also, topical isopropyl unoprostone additionally induced aqueous flare elevation in eyes with transcorneal diffusion of PGE(2). Latanoprost did not induce flare elevation. CONCLUSION: Isopropyl unoprostone induced aqueous flare elevation in rabbits, and latanoprost did not produce aqueous flare elevation.     

Effects of topical instillation of traditional herbal medicines,herbal extracts,and their components on prostaglandin E2-induced aqueous flare elevation in pigmented rabbits

PURPOSE: To evaluate the effect of topical instillation of traditional herbal medicines, herbal extracts, and their components on the elevation of aqueous flare induced by prostaglandin E(2) (PGE(2)) in pigmented rabbits. METHODS: Transcorneal diffusion of 25 micro g/mL of PGE(2) was carried out through a glass cylinder placed on the cornea to induce aqueous flare elevation in pigmented rabbits. Traditional herbal medicines, herbal extracts, and their components were topically instilled before the PGE(2) application. Aqueous flare was measured with a laser flare-cell meter. RESULTS: Two instillations, 60 and 30 minutes before PGE(2), of Kakkon-to, Sairei-to, Orengedoku-to, Senkanmeimoku-to, Scutellariae radix extract, Coptidis rhizoma extract, Gardeniae fructus extract, Phellodendri cortex extract, baicalein, baicalin, wogonin, crocetin, berberine, or glycyrrhizine did not inhibit the elevation induced by PGE(2). Two instillations, 60 and 30 minutes before PGE(2), of a Ligusticum wallichii extract (100 mg/mL) inhibited the elevation by 20%. Two instillations (5 and 3 hours before PGE(2)) of baicalein (1 mg/mL) or baicalin (5 mg/mL) inhibited the elevation by 16% and 24%, respectively. Two instillations, 5 and 3 hours before PGE(2), of wogonin, crocetin, berberine, or glycyrrhizine did not inhibit the elevation. CONCLUSION: Two instillations of Ligusticum wallichii extract 60 and 30 minutes before the PGE(2), and two instillations of baicalein or baicalin, 5 and 3 hours before the PGE(2), inhibited the PGE(2)-induced aqueous flare elevation in pigmented rabbits.     

Effects of tetramethylpyrazine on prostaglandin E(2)- and prostaglandin E(2) receptor agonist-induced disruption of blood-aqueous barrier in pigmented rabbits

PURPOSE: To evaluate the effect of tetramethylpyrazine on the elevation of aqueous flare and intraocular pressure (IOP) induced by prostaglandin (PG) E(2) and PGE(2) receptor (EP) agonists. METHODS: PGE(2) or EP agonists (11-deoxy PGE(1), EP(2) agonist; 17-phenyl trinor PGE(2), EP(1) and EP(3) agonist; or sulprostone, EP(1) and EP(3) agonist), 25 microg/mL, were transcorneally administered to pigmented rabbits. Animals were pretreated with tetramethylpyrazine intravenously (10 or 30 mg/kg) or topically (0.1% solution). Aqueous flare was measured using a laser flare-cell meter, and the intensity was expressed as the area under the curve (AUC). Intraocular pressure was measured using a noncontact tonometer. RESULTS: After administration of PGE(2), aqueous flare and IOP increased and then gradually decreased. The AUC of eyes pretreated with tetramethylpyrazine, 10 or 30 mg/kg, intravenously, or topical 0.1% solution, was significantly smaller than that of the controls. The mean Delta IOP of eyes pretreated with tetramethylpyrazine, 30 mg/kg intravenously, was significantly lower than that of the controls. After administration of 11-deoxy PGE(1), aqueous flare increased and then gradually decreased. 17-phenyl trinor PGE(2) and sulprostone did not disrupt the blood-aqueous barrier. The AUC of eyes pretreated with tetramethylpyrazine, 10 or 30 mg/kg, intravenously, before 11-deoxy PGE(1) application was significantly smaller than that of the controls. CONCLUSION: The results indicated that tetramethylpyrazine inhibited PGE(2)- or 11-deoxy PGE(1)-induced elevation of aqueous flare and IOP.     

Effects of scutellariae radix extract and its components (baicalein, baicalin, and wogonin) on the experimental elevation of aqueous flare in pigmented rabbits

PURPOSE: To evaluate the possible inhibitory effects of hot water extract of Scutellariae radix and its major components (baicalein, baicalin, and wogonin) on experimental elevation of aqueous flare in pigmented rabbits. METHODS: To produce aqueous flare elevation in rabbits, prostaglandin E(2) (PGE(2)), 25 microg/mL, was applied to the cornea with the use of a glass cylinder, or lipopolysaccharides (LPS), 0.5 microg/kg, were injected into an ear vein. Animals were pretreated by the oral administration of 150 g/day of food containing 0.02%, 0.07%, or 0.2% (w/w) extract of Scutellariae radix for 5 days, or by intravenous injection of baicalein, baicalin, or wogonin, 60 microg/kg or 600 microg/kg, 30 minutes before experimental uveitis was induced. Aqueous flare was measured with a laser flare-cell meter. Aqueous flare intensity was expressed as the area under the curve (AUC) in arbitrary units. RESULTS: The AUC of PGE(2)- and LPS-induced aqueous flare elevation was 1,343 and 5,066 arbitrary units, respectively. Pretreatment by oral administration of 0.07% or 0.2% extract of Scutellariae radix did not inhibit PGE(2)-induced aqueous flare elevation (AUC: 1,252 and 1,210, respectively), but it did inhibit LPS-induced aqueous flare elevation (AUC: 2,248 and 1,973, respectively). Pretreatment by intravenous injection of 600 microg/kg of baicalein, baicalin, or wogonin inhibited LPS-induced aqueous flare elevation (AUC: 2,289, 2,163, and 1,509, respectively). Pretreatment with 60 microg/kg of wogonin also inhibited LPS-induced aqueous flare elevation (AUC: 1,980). CONCLUSION: Hot water extract of Scutellariae radix may have an inhibitory effect on experimental anterior uveitis induced by LPS in pigmented rabbits.     

Effect of topical betaxolol on the acute rise of aqueous flare induced by highly selective agonists for prostaglandin E2 receptor subtypes in pigmented rabbits

PURPOSE: To evaluate the role of topical betaxolol on experimental ocular inflammation in rabbits. METHOD: Transcorneal diffusion of highly selective agonists for prostaglandin E2 receptor subtypes (EP), 25 microg/ml, with the use of a glass cylinder, was performed to produce aqueous flare elevation in pigmented rabbits. Betaxolol was topically administered before EP agonist application. Aqueous flare was measured with a laser flare cell meter. RESULTS: Performing topical instillation of 0.5% betaxolol 4 times inhibited 52 +/- 9% of EP2-agonist (ONO-AE1-259-01)-induced aqueous flare elevation. The inhibition of flare elevation was dependent on the number of betaxolol instillations. Betaxolol did not suppress the elevation induced by an EP4 agonist (ONO-AE1-392). CONCLUSION: Betaxolol inhibited EP2-agonist-induced aqueous flare elevation in pigmented rabbits.     

Effects of Kakkon-to and Sairei-to on experimental elevation of aqueous flare in pigmented rabbits.

PURPOSE: To evaluate the possible inhibitory effects of Kakkon-to and Sairei-to, traditional Sino-Japanese herbal medicines, on experimental aqueous flare elevation in pigmented rabbits. METHODS: Anterior uveitis was induced either by an application of prostaglandin E2 (PGE2), 10 microg/mL, to the cornea, or an intravenous injection of lipopolysaccharides (LPS), 0.5 microg/kg, in an ear vein. Dose dependency of experimental uveitis induced by LPS (0.1, 0.25, 0.5, or 1.0 microg/kg) was also determined. For pretreatment, about 150 g/day of food containing Kakkon-to (1% w/w) or Sairei-to (0.6% or 2% w/w) was given to two groups of animals for 5 days before experimental uveitis was induced. A third group of animals underwent pretreatment with betamethasone, 130 microg/kg, injection into an ear vein 4 hours before experimental uveitis was induced. A fourth group of rabbits with no herbal medicine or betamethasone pretreatment served as controls. Aqueous flare was measured using a laser flare-cell meter. Aqueous flare intensity was expressed as the area under the curve (AUC) in arbitrary units. RESULTS: The increase in aqueous flare induced by LPS was dose-dependent. The AUC of PGE2 (10 microg/mL) and LPS (0.5 microg/mL) induced aqueous flare elevations were 1,119 and 4,950 arbitrary units, respectively. Kakkon-to (AUC, 1,055) and Sairei-to (AUC, 965) did not inhibit the aqueous flare elevation induced by PGE2. Beta-methasone did inhibit the elevation (AUC, 271). Kakkon-to (AUC, 4,495) did not suppress the aqueous flare elevation induced by LPS. Both 0.6% and 2% Sairei-to (AUC, 2,478, and 978) and beta-methasone (AUC, 443) did suppress the aqueous flare elevation induced by LPS significantly (P < .05). CONCLUSION: Sairei-to could have an inhibitory effect on experimental anterior uveitis induced by LPS.     

Effects of nilvadipine, nicardipine and verapamil on acute rise of aqueous flare induced by iris photocoagulation or intravenous lipopolysaccharides in pigmented rabbits

The effects of nilvadipine, nicardipine and verapamil on the acute rise of aqueous flare induced by argon laser photocoagulation of the iris or by intravenous injection of lipopolysaccharides (LPS, 0.5 microg/kg) were investigated in pigmented rabbits. Nilvadipine, nicardipine and verapamil were injected intravenously. Aqueous flare was measured with a laser flare cell meter. Following photocoagulation, aqueous flare increased, reached its maximum at 45-75 min and then decreased. After administration of LPS, aqueous flare increased, reached its maximum at 4 h and then returned to baseline levels at about 24 h. Flare reactions were inhibited by nilvadipine in a dose-dependent manner. The elevations were maximally inhibited by nilvadipine 30 min before photocoagulation or intravenous LPS. Two hundred micrograms per kilogram of nilvadipine inhibited 81% of photocoagulation-induced flare elevation, while the same dose of nicardipine and verapamil inhibited 19 and 9% of the elevation, respectively. The same dose of nilvadipine inhibited 51% of LPS-induced flare elevation, while the same dose of nicardipine and verapamil inhibited 6 and 4% of the elevation, respectively. In conclusion, nilvadipine inhibited the experimental elevation of aqueous flare more effectively than did nicardipine and verapamil.     

The effect of polyphloretin phosphate on the aqueous flare response to alpha-melanocyte stimulating hormone

The breakdown of the blood aqueous barrier caused by topical prostaglandin E1 (PGE1), prostaglandin E2 (PGE2) or subcutaneous alpha-melanocyte stimulating hormone (alpha-MSH) was quantified by measurements of the aqueous flare seen in the anterior chamber. Polyphloretin phosphate (PPP) administration subcutaneously was found to effectively block the protein leakage caused by all three traumatic stimuli. The same dose of PPP given intravenously inhibited effectively the flare response to PGE1 and alpha-MSH, whereas the effect of PGE2 was only slightly decreased. Significant inhibition by subconjunctival PPP was not achieved for any of the three stimuli. Assuming that PPP is a specific PG-antagonist the present results support the eariler suggestion that PGs take part in the barrier damaging action of alpha-MSH. However, it cannot be excluded that PPP acts on a step subsequent to PG. This step might be common to PGs- and alpha-MSH-effects on the barrier, explaining why PPP inhibits both types of trauma.     

Interaction of adrenergic agents with alpha-melanocyte-stimulating hormone and infrared irradiation of the iris in the rabbit eye.

Breakdown of the blood aqueous barrier in the rabbit eye induces a protein leakage into the aqueous humor, seen as a flare in the anterior chamber. A barrier damage was induced by topical prostaglandin E2(PGE2), infrared irradiation of the iris, or alpha-melanocyte-stimulating hormone (alpha-MSH) given subcutaneously. The aqueous flare was measured quantitatively by means of a photoelectric instrument. The interference of adrenergic antagonists and agonists on the breakdown of the barrier was tested. The alpha-adrenergic antagonist phentolamine and the beta-adrenergic antagonist propranolol, given intravenously, had no effect on exogenously administered PGE2, but both antagonists reduced the flare response to infrared irradiation which is supposed to exert its effect via endogenous prostaglandin release. The alpha-MSH response was unaffected by phentolamine, whereas propranolol abolished the flare response to alpha-MSH totally. The PGE1 response was unaffected both by the alpha-adrenergic agonist noradrenaline and the beta-adrenergic agonist terbutalin sulfate, administered topically. Noradrenaline, however, inhibited the flare response to infrared irradiation and facilitated the flare response to alpha-MSH. Terbutalin sulfate worked synergistically with both infrared irradiation and alpha-MSH. It is assumed that alpha-MSH exerts its effect on the barrier via enhanced beta-adrenergic activity, whereas the effects caused by infrared irradiation seem conditioned by intact alpha- as well as beta-adrnergic receptor sites.     

The effects of 3-isobutyl-methyl-xanthine on experimentally induced ocular inflammation in the rabbit

The effect of topical administration of 3-isobutyl-methyl-xanthine (IBMX), a potent phosphodiesterase inhibitor, was studied on an experimentally provoked uveitis in rabbits. After presensitization with an intravitreal injection of human serum albumin (HSA), intravenous antigenic challenge induces blood-aqueous barrier breakdown and leukocyte infiltration. The effect of IBMX on the blood-aqueous barrier was determined by scoring the severity of the flare in the anterior chamber and by determination of the levels of ascorbic acid and protein in the aqueous. Treatment with IBMX 1% two times daily, significantly inhibited the breakdown of the blood-aqueous barrier and the increase in PGE2 level of the aqueous humor. There was no effect on leukocyte infiltration. The therapeutic effect of IBMX in blood-aqueous barrier protection is comparable with the effect of topical treatment with the corticosteroid medrysone.     

The effect of timolol maleate on the disruption of the blood-aqueous barrier in the rabbit eye

A disruption of the blood-aqueous barrier in rabbit eyes was elicited by use of topical prostaglandin E2(PGE2), infrared irradiation of the iris, or by subcutaneous alpha-melanocyte-stimulating hormone (alpha-MSH). The aqueous flare provoked was measured quantitatively with a photoelectric instrument. The effect of the (topical) beta-adrenergic antagonist timolol maleate on the breakdown of the blood-aqueous barrier was tested. Timolol applied topically in very large doses had no effect on exogenously administered PGE2. However, even in a very small concentration applied topically, timolol reduced the flare response to both infrared irradiation and alpha-MSH. These results support the theory that the effect of alpha-MSH and infrared irradiation on the blood-aqueous barrier is dependent on intact beta-adrenergic receptor sites.     

Ocular hypotensive effect of alpha-adrenoceptor agonist and antagonist in the conscious pigmented rabbit]

It has been reported that some of the topically-used antiglaucomatics have a central ocular hypotensive effect. In this study, the influence of topical and intracerebroventricular (i.c.v.) administration of phenylephrine, clonidine, guanfacine, prazosin, yohimbine on the intraocular pressure (IOP) was investigated in the rabbit. Male pigmented rabbits were used throughout the experiments. For measurement of IOP, an applanation pneumatonograph was used. By unilateral topical administration of phenylephrine, an increase in IOP in the eye in which instillation was performed was observed. On the other hand, a slight decrease in IOP was observed by similar treatment of prazosin and yohimbine. No significant change of IOP in the contralateral eye was observed with these drugs. On the contrary, unilateral topical administration of clonidine or guanfacine decreased the IOP of both eyes. Furthermore, the decrease of IOP was more remarkable in the contralateral eye compared to the eye which received instillation. The IOP of both eyes was decreased in a dose-related fashion by i.c.v. administration of clonidine or guanfacine. The ocular hypotensive effects of clonidine were diminished by the pretreatment by i.c.v. administration with yohimbine. These results suggest that the ocular hypotensive effect of clonidine and guanfacine is due to their alpha 2-adrenoceptor stimulation in the central nervous system.     

Effects of prostaglandin D2 and its analogues on intraocular pressure in rabbits

Studies were carried out of the effects of topically applied prostaglandin (PG) D2 and its metabolites and analogues on the intraocular pressure (IOP) in rabbits, and the results were compared with those of studies using PGE2 and F2 alpha. The application of PGD2 (0.4-250 micrograms) reduced the IOP, in a dose-dependent manner without causing a hypertensive phase. The hypotensive effect was observed within 30 minutes after the application and lasted for over 7 hours. Higher doses of PGE2 (10, 50 micrograms) or PGF2 alpha (50 micrograms) caused initial IOP elevation followed by a prolonged hypotensive phase. Lower doses of PGF2 alpha (2, 10 micrograms) caused a prolonged (over 7 hours) reduction in the IOP following a latency of over 2 hours. The IOP reduction by 2 micrograms of PGE2 lasted for 5 hours. No miotic response followed the use of these PG's. Conjunctival and iridal hyperemia, aqueous flare, irritation (defined by lid-closing), and aqueous protein content were examined at equi-hypotensive doses of the three PG's (50 micrograms for PGD2, 2 micrograms for PGE2, and 10 micrograms for PGF2 alpha). PGE2 was the strongest in causing these side effects, followed by PGF2 alpha. PGD2 did not cause any of these responses except for some development of conjunctival hyperemia. All of the 4 PGD2 metabolites were ineffective in reducing IOP. Among 6 PGD2 analogues, BW245C, PGD3, and PGD2 methyl ester more effectively reduced IOP than did PGD2. PGD1 and 16,16-dimethyl PGD2 were not effective.