Göran Selén

Prostaglandin-induced iridial pigmentation in primates

Latanoprost, a new ocular hypotensive prostaglandin F2 alpha analogue prodrug, was found to induce increased pigmentation of monkey irides in chronic toxicity studies. This prompted us to investigate the effect of naturally occurring prostaglandins on the monkey iris to determine whether this pigmentary effect is unique for latanoprost or whether it is a class effect of prostaglandins. PGF2 alpha-isopropyl ester (IE), PGE2-IE and latanoprost were applied topically to cynomolgus monkey eyes for 18-44 weeks. One eye of each animal was treated, while the other served as control. In addition, latanoprost was applied to sympathectomized monkey eyes. PGF2 alpha-IE, PGE2-IE, as well as latanoprost, induced increased pigmentation in the monkey eye. The first signs of this effect were seen after about two months of treatment. Latanoprost also induced increased pigmentation in sympathectomized eyes. It is concluded that both naturally occurring prostaglandins and their synthetic analogues can induce increased iridial pigmentation in cynomolgus monkeys, and that the effect does not require the presence of sympathetic nerves.

Structure-activity relationships and receptor profiles of some ocular hypotensive prostanoids

A novel series of prostaglandin F (PGF) analogues have been prepared and evaluated in vivo and in vitro. Their intraocular pressure (IOP) lowering effects and potential side-effects, as prodrug eye drops, have been tested in cats, monkeys and rabbits. Furthermore, the PGF-analogues were tested as free acids for FP-receptor agonistic activity on cat iris sphincter. The results were compared to that of PGF2 alpha (C#1). Based on the structure-activity relationship investigations, inversion of the configuration, at carbon-9 (C#3) or carbon-11 (C#4), changes the potency and the receptor profile of PGF2 alpha. Replacement part of the omega-chain of PGF2 alpha with a benzene ring changes the potency and receptor profile of PGF2 alpha. The optimal position of the benzene ring is on carbon-17, 17-phenyl-18,19,20-trinor PGF2 alpha-isopropyl ester (C#8), and exhibited a much higher therapeutic index in the eye than PGF2 alpha or its ester. The biological activity of different substituents on the C#8 benzene ring have also been studied. Interestingly, introduction of a methyl group at positions 2 or 3 of the benzene ring (C#16 or C#17) affords compounds which are biologically more active than the methyl group at the 4-position (C#18). Furthermore, one of the analogues 13,14-dihydro-17-phenyl-18,19,20-trinor PGF2 alpha-isopropyl ester (latanoprost), has been found in clinical studies to be a highly potent and efficacious IOP-reducing agent for the treatment of glaucoma.

Microvascular effects of selective prostaglandin analogues in the eye with special reference to latanoprost and glaucoma treatment

Prostaglandin F(2alpha) analogues have recently been introduced on the market for glaucoma treatment. While these drugs have a well-documented intraocular pressure reducing effect only a limited number of studies have been published regarding their effects on the microvasculature in the eye. Since many naturally occurring prostaglandins have marked effects on the cardiovascular system it is conceivable that synthetic prostaglandins used as glaucoma drugs may exert microvascular effects in the eye, even if they exhibit receptor selectivity. Latanoprost, the active principle of Xalatan((R)) eye drops, is a selective FP prostanoid receptor agonist, and much of the paper is focused on the microvascular effects of latanoprost and some closely related prostaglandin analogues. The purpose of the paper is to review the literature on the microvascular effects of prostaglandins in the eye, and to present some unpublished data on the effects of selective prostaglandin analogues. Most of the prostaglandin analogues studied exhibit selectivity for the FP prostanoid receptor. Results from studies with the following prostaglandin analogues are presented in the paper: PGF(2alpha)-isopropyl ester (PGF(2alpha)-IE), 17-phenyl-18,19,20-trinor-PGF(2alpha)-isopropyl ester (17-phenyl-PGF(2a)-IE), 15-keto-17-phenyl-18,19, 20-trinor-PGF(2alpha)-isopropyl ester (15-keto-17-phenyl-PGF(2a)-IE), 13,14-dihydro-17-phenyl-18,19,20-trinor-PGF(2alpha)-isopropy l ester (latanoprost), 13,14-dihydro-15R,S-17-phenyl-18,19, 20-trinor-PGF(2alpha)-isopropyl ester (PhXA34), 17-phenyl-18,19, 20-trinor-PGE(2)-isopropyl ester (17-phenyl-PGE(2)-IE), and 19R-hydroxy-PGE(2) (19R-OH-PGE(2)). The regional blood flow has been determined with radioactively labelled microspheres, the blood volume with (51)Cr labelled erythrocytes and the capillary permeability to albumin with (125)I and (131)I labelled albumin. PGF(2alpha)-IE has been shown to exert marked microvascular effects in the rabbit anterior segment including vasodilatation, increased capillary permeability, and a breakdown of the blood-aqueous barrier. 17-phenyl-PGF(2alpha)-IE, 15-keto-17-phenyl-PGF(2alpha)-IE, and PhXA34/latanoprost exerted significantly less vasodilatory effect, and little effect on capillary permeability was seen with the FP receptor agonists when studied with Evans blue. Intravenous administration of PhXA34 at a dose range of 1-100 microg/kg b.w. had no consistent effect on the regional blood flow in the eye indicating that FP receptors in the ocular blood vessels are not expressed in the rabbit, or alternatively are not functionally coupled to regulation of vascular tone. In cats topical application of PGF(2alpha)-IE had no significant effect the on the regional blood flow in cannulated eyes. No blood flow experiments were performed in intact eyes with PGF(2alpha)-IE. 17-phenyl-PGF(2alpha)-IE and latanoprost caused some vasodilation in the anterior segment. None of the analogues had any significant effect on the blood volume in the ocular tissues, but an increase in capillary permeability to albumin was seen in several tissues of the eye. However, in the eyelid, nictitating membrane and conjunctiva exposed to high concentrations of the prostaglandins no or only little leakage of albumin was detected. It appears that the intraocular microvasculature in the cat exhibits some sensitivity to FP prostanoid receptor agonists. (ABSTRACT TRUNCATED)

Indomethacin Inhibits Renal Functional Adaptation to Nephron Loss

Immediately after unilateral nephrectomy, the glomerular filtration rate (GFR) and urinary excretion rate increase in the remaining transplanted rat kidney. In a previous study, we found that GFR in a transplanted kidney was reduced through an activation of the tubuloglomerular feedback control. Excision of the rats own remnant kidney then reduced feedback sensitivity and thereby allowed GFR to rise. The present study aimed at investigating whether prostaglandins are involved in this functional adaptation. Clearance and micropuncture experiments were performed before and after administration of indomethacin and after subsequent unilateral nephrectomy. GFR and the urinary excretion rate of electrolytes and water were measured. From proximal tubular stop-flow pressure (PSF) measurements the feedback characteristics were determined as the maximal stop-flow pressure response (delta PSF) to an increase in distal flow and the turning point (TP), i.e. the end proximal flow rate that caused 50% reduction of delta PSF. The results showed that following nephrectomy the tubuloglomerular feedback sensitivity was decreased, with an increased TP and reduced delta PSF. Pretreatment with indomethacin (2 mg/kg BW) prevented not only the change in feedback sensitivity at nephrectomy but also the rise in GFR. These results suggest that the prostaglandins play a possible role as one link in the chain of adaptive events occurring immediately after nephron loss.