University of Groningen Reflections on Flurbiprofen Eyedrops Van Sorge

University of Groningen Reflections on Flurbiprofen Eyedrops Van Sorge

University of Groningen Reflections on flurbiprofen eyedrops van Sorge, Adriaan Alastair IMPORTANT NOTE: You are advised to consult the publisher's version (publisher's PDF) if you wish to cite from it. Please check the document version below. Document Version Publisher's PDF, also known as Version of record Publication date: 2002 Link to publication in University of Groningen/UMCG research database Citation for published version (APA): van Sorge, A. A. (2002). Reflections on flurbiprofen eyedrops. s.n. Copyright Other than for strictly personal use, it is not permitted to download or to forward/distribute the text or part of it without the consent of the author(s) and/or copyright holder(s), unless the work is under an open content license (like Creative Commons). Take-down policy If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim. Downloaded from the University of Groningen/UMCG research database (Pure): http://www.rug.nl/research/portal. For technical reasons the number of authors shown on this cover page is limited to 10 maximum. Download date: 25-09-2021 REFLECTIONS ON FLURBIPROFEN EYEDROPS REFLECTIONS ON FLURBIPROFEN EYEDROPS RIJKSUNIVERSITEIT GRONINGEN REFLECTIONS ON FLURBIPROFEN EYEDROPS REFLECTIONS ON FLURBIPROFEN EYEDROPS PROEFSCHRIFT ter verkrijging van het doctoraat in de Wiskunde en Natuurwetenschappen aan de Rijksuniversiteit Groningen, op gezag van de Rector Magnificus, dr. F. Zwarts, in het openbaar te verdedigen op maandag 2 december 2002 om 14.15 uur door Adriaan Alastair van Sorge geboren op 28 oktober 1944 te New Rochelle, New York, USA PROMOTORES Prof. dr. J. Zaagsma Prof. dr. W.J. Quax Prof. dr. H.W. Frijlink CO-PROMOTOR Dr. N.J. van Haeringen BEOORDELINGSCOMMISSIE Prof. dr. P.T.V.M. de Jong Prof. dr. J.R.B.J. Brouwers Prof. dr. H.V. Wikström ISBN: 90-9016364-6 Verzorging proefschrift: B-Point, Karin Scheele PARANIMFEN Dr. R.F.A. Weber Dr. A.J.P.F. Lombarts My parents, who got me started Aty, Nina, Joline and Arlette, who let me go on Eelco, who wouldn't let me quit CONTENTS Preface A historical introduction 9 Scope of thesis Chapter 1 General introduction 17 1.1 Flurbiprofen, an overview 1.2 Cataract and caractogenesis 1.3 Cystoid macular edema 1.4 Prostanoids Chapter 2 Rationale for using a phosphate buffer for S(+) flurbiprofen eyedrops. 43 Chapter 3 Flurbiprofen, S(+), eyedrops: formulation, enantiomeric assay, shelflife and pharmacology (1). 49 Chapter 4 Specificity of flurbiprofen and enantiomers for inhibition of prostaglandin synthesis in bovine iris/ciliary body (2). 63 Chapter 5 Flurbiprofen and enantiomers in ophthalmic solution tested as inhibitors of prostanoid synthesis in human blood (3). 73 Chapter 6 Constitutive cyclooxygenase-1 and induced cyclooxygenase-2 in isolated human iris inhibited by S(+) flurbiprofen (4). 83 Chapter 7 99mTc-Diflunisal and the human iris: topical application reveals localization (5). 95 Chapter 8 S(+) flurbiprofen and R(-) flurbiprofen. 99mTc-labeling reveals difference in stereochemistry (6). 107 Chapter 9 Alternative splicing of cyclooxygenase-1 mRNA in the human iris (7). 115 Summary/Samenvatting 123 List of publications 135 Dankwoord 137 Curriculum Vitae 143 Color pictures 147 Addendum 151 REFERENCES 1. van Sorge AA, Wijnen PH, van Delft JL, Carballosa Coré-Bodelier VMW, van Haeringen NJ. Flurbiprofen, S(+), eyedrops: formulation, enantiomeric assay, shelflife and pharmacology. Derived from Pharm World Sci 1999;21:91-5. 2. Sorge van AA, Delft van JL, Bodelier VMW, Wijnen PH, Haeringen van NJ. Specificity of flurbiprofen and enantiomers for inhibition of prostaglandin synthesis in bovine iris/ciliary body. Prostaglandins Other Lipid Mediat 1998;55:169-77. 3. Haeringen van NJ, Sorge van AA, Delft van JL, Carballosa Coré-Bodelier VMW. Flurbiprofen and enantiomers in ophthalmic solution tested as inhibitors of prostanoid synthesis in human blood. J Ocular Pharmacol 2000;16:345-52. 4. Haeringen van NJ, Sorge van AA, Carballosa Coré-Bodelier VMW. Constitutive cyclooxygenase-1 and induced cyclooxygenase-2 in isolated human iris inhibited by S(+) flurbiprofen. J Ocular Pharmacol 2000;16:353-61. 5. Sorge van AA, Etten van RJ, Rehmann CJ, Rijnders AJM, Haeringen van NJ. 99mTc- Diflunisal and the human iris: topical application reveals localization. J Ocular Pharmacol 2002;18:185-95. 6. Sorge van AA, Ruiken IWM, Janssen HWM, Haeringen NJ. S(+) flurbiprofen and R(-) flurbiprofen. 99mTc-labeling reveals difference in stereochemistry. Enantiomer 2002; Accepted pending suitable revision. 7. Dröge MJ, van Sorge AA, van Haeringen NJ, Quax WJ, Zaagsma J. Alternative splicing of cyclooxygenase-1 mRNA in the human iris. Submitted. 8 PREFACE Preface A HISTORICAL INTRODUCTION A simple question put forward in 1980 by one of the ophthalmologists to the hospi- tal pharmacist led to a chain of events culminating in this thesis. The question was: "Is it possible to prepare indomethacin eyedrops?". The principal reason for the question were reports on eye research, mainly of Japanese origin (1, 2, 3, 4, 5), indicating that use of topically applied indomethacin could prevent cystoid macular edema after lens extraction, required e.g. when a patient had acquired a senile cataract. The incidence of this complication varied between 2 and 50% but reports of 70% were known as well. The complication had been reported earlier as a newly defined vitreous syndrome following cataract sur- gery and was described in 1953 (6). Just over 65 years ago it was postulated by Selye (7) that our physiological system, activated by stress, not only will try to protect and restore itself but also can derail and afflict damage. The most common responses to stress are activation of the sympathetic nervous system and of the hypothalamic-pituitary-adrenal (HPA) axis, resulting in or accompanied by immunological changes. The immunological defense mechanisms of the ocular surface have been reviewed in detail in 1983 (8). A review ten years earlier (9) refers to the finding by Ambache of a physiological smooth muscle stimulant as a constituent of the rabbit iris ("Irin") in 1957, and the further elucidation of its nature in 1959 (10,11). In 1967 the synthesis of prostaglandins in the pig iris was reported (12) and in 1968 their release from bovine iris (13). Subsequently, prostaglandins were related to various ocular functions indeed (14). In 1971 a pivotal study was reported by Vane (15) demonstrating the inhibiting effect on prostaglandin synthesis as the mechanism of action of non-steroidal anti- inflammatory drugs (NSAIDs). Release of prostaglandins in the rabbit eye was shown following an acute immunological inflammatory reaction induced by a single intravitreal injection of sterile crystallized bovine serum albumin (16). This report preceded a study, also in rabbits, demonstrating that an acutely traumatized eye shows an irritative response characterized by hyperaemia of the conjunctiva and iris, miosis and disruption of the blood-aqueous barrier. One of the signs of blood-aqueous barrier disruption is an increased concentration of blood proteins in the aqueous humour. Using a rele- vant pharmacological model a significant reduction in protein concentration in the aqueous humour could be demonstrated by pretreating the animal with a rectal 10 Preface dose of acetosal (acetylsalicylic acid; 600mg) (17). Stabilization of the blood-aque- ous barrier in the human eye with acetosal administered orally (4 doses of 650mg; 3 before and one on completion of ocular surgery) was reported in 1975 (18). Levels of prostaglandin-like activity in aqueous humour samples correlated well with the clinical intensity of uveitis. This in contrast to patients with cataract whose aqueous humour was essentially devoid of activity when the eyes were uninflamed, and low in activity when treated with corticosteroids (19). In vitro inhibition of rabbit prostaglandin synthase systems of various organs, including the eye, by indomethacin was reported in 1974 (20). Tissue homogenates of the iris and the ciliary body (anterior uvea), the conjunctiva, the cornea and reti- na were prepared; spleen and kidney (medulla) were also investigated. The inhibitory effect of indomethacin was clearly demonstrated and the compound showed differential inhibitory capacity. The retinal enzymes were least susceptible to inhibition followed by iris and ciliary body (twofold more) and the conjunctiva (six fold more). This also raised the possibility that prostaglandins are involved both in external as well as internal ocular inflammation. The potential complication reported by our ophthalmologists that could arise after cataract surgery, cystoid macular edema, seemed linked to the release of prostaglandins. Thus, in the event of adequate permeation of indomethacin through the cornea, the edema should be prevented by topical administration of eyedrops. In 1972 it has been demonstrated by application of 100 microgram radiolabelled indomethacin to the cornea (either in aqueous suspension form or in oily solution) that the drug could be detected in the cornea, aquous humor, iris, choroids and reti- na of the rabbit eye (21). An inflamed eye gave rise to enhanced penetration. In 1983 it was subsequently shown, by use of topically applied radiolabelled indomethacin (2% suspension in sesame oil, including 17% ethanol) on phakic and aphakic rabbit eyes, that penetration into the vitreous took place; the concentration in the vitreous was higher for the aphakic eye. Concentrations in retina and choroid were the same for both conditions, suggesting a pathway other than diffusion through the vitreous to reach these tissues. Aqueous humour concentrations were sufficient to inhibit prostaglandin synthesis in either situation (22). Indomethacin, [1-(4-chlorobenzoyl)-5-methoxy-2-methylindol-3-yl]acetic acid, molec- ular weight 357.8 dalton, pKa 4.5, is practically insoluble in water. In aqueous buffers at pH 7.5 - 8.0 it can be rendered soluble (23). In basic solutions hydrolysis of indomethacin occurs into 5-methoxy-2-methylindolyl-3-acetic acid and 4-chloroben- zoic acid (24,25,26).

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