The effect of vasopressin on ciliary blood flow and aqueous flow.

PURPOSE Previous experiments have shown that arginine-vasopressin (AVP) reduces intraocular pressure (IOP) dose-dependently. The present study investigated the relationships between IOP, ciliary blood flow (CilBF), and aqueous flow (AqF) responses to AVP in anesthetized rabbits. METHODS CilBF was measured by laser Doppler flowmetry and AqF by fluorophotometry. Mean arterial pressure (MAP) and IOP were monitored continuously and simultaneously. Perfusion pressure (PP) was varied mechanically. Four experimental protocols were performed: the dose-response (n = 11) and the pressure-flow relationship (n = 8) for CilBF and the effects on CilBF, and AqF at low (0.08 ng/kg/min; n = 14) and high AVP infusion rates (1.33 ng/kg/min; n = 12). RESULTS AVP decreased CilBF and IOP dose-dependently. At the low AVP infusion rate, AqF was reduced by 21.48% ± 2.52% without changing CilBF significantly. The high AVP infusion rate caused a 24.49% ± 3.53% decrease of AqF and a significant reduction in CilBF (35.60% ± 3.58%). IOP was reduced by 9.56% ± 2.35% at low and by 41.02% ± 3.19% at high AVP infusion rates. Based on the Goldmann equation, the decrease of AqF at the low AVP infusion rate accounted for 77.1% of the IOP reduction, whereas at the high AVP infusion rate, decreased AqF accounted for 28.4% of the IOP decline. CONCLUSIONS The results indicate that AVP can modulate IOP by different dose-dependent physiological mechanisms. The shifts of the CilBF-AqF relationship suggest that the reduction of AqF by the low AVP infusion rate is mainly provoked by inhibiting secretory processes in the ciliary epithelium. In contrast, at the high AVP infusion rate, the AqF reduction is caused by either reduced CilBF or more likely by a combined effect of reduced CilBF and secretory inhibition.

[1]  J. Miller,et al.  The effect of changes in intraocular pressure on the risk of primary open-angle glaucoma in patients with ocular hypertension: an application of latent class analysis , 2012, BMC Medical Research Methodology.

[2]  Jin-wei Cheng,et al.  Intraocular Pressure-Lowering Effects of Commonly Used Fixed-Combination Drugs with Timolol: A Systematic Review and Meta-Analysis , 2012, PloS one.

[3]  M. C. Leske,et al.  Intraocular pressure reduction with a fixed treatment protocol in the Early Manifest Glaucoma Trial , 2011, Acta ophthalmologica.

[4]  J. Kiel,et al.  The effect of vasopressin on choroidal blood flow, intraocular pressure, and orbital venous pressure in rabbits. , 2011, Investigative ophthalmology & visual science.

[5]  J. Kiel,et al.  Ciliary blood flow and aqueous humor production , 2011, Progress in Retinal and Eye Research.

[6]  J. Kiel,et al.  Effects of dorzolamide on choroidal blood flow, ciliary blood flow, and aqueous production in rabbits. , 2009, Investigative ophthalmology & visual science.

[7]  J. McLaren,et al.  Circadian variation of aqueous dynamics in young healthy adults. , 2008, Investigative ophthalmology & visual science.

[8]  J. Kiel,et al.  Paradoxical effect of phentolamine on aqueous flow in the rabbit. , 2007, Journal of Ocular Pharmacology and Therapeutics.

[9]  C. S. Gal,et al.  An overview of SR121463, a selective non-peptide vasopressin V2 receptor antagonist , 2006 .

[10]  J. Kiel,et al.  Effects of a topical alpha2 adrenergic agonist on ciliary blood flow and aqueous production in rabbits. , 2006, Experimental eye research.

[11]  J. Kiel,et al.  Relationship between ciliary blood flow and aqueous production in rabbits. , 2003, Investigative ophthalmology & visual science.

[12]  J. Kiel,et al.  A rabbit model to study orbital venous pressure, intraocular pressure, and ocular hemodynamics simultaneously. , 2002, Investigative ophthalmology & visual science.

[13]  J. Kiel,et al.  Effects of dopamine on ciliary blood flow, aqueous production, and intraocular pressure in rabbits. , 2002, Investigative ophthalmology & visual science.

[14]  T. Kurasawa,et al.  The effects of several vasopressin receptor antagonists on normal intraocular pressure and the intraocular distribution of vasopressin receptor subtypes. , 2002, Biological & pharmaceutical bulletin.

[15]  C. Camras,et al.  Time dependent effects of sympathetic denervation on aqueous humor dynamics and choroidal blood flow in rabbits , 2002, Current eye research.

[16]  J. Kiel,et al.  Effects of nitric oxide synthase inhibition on ciliary blood flow, aqueous production and intraocular pressure. , 2001, Experimental eye research.

[17]  N. Osborne,et al.  Flesinoxan, a 5-HT1A receptor agonist/a 1-adrenoceptor antagonist, lowers intraocular pressure in NZW rabbits , 2001, Current eye research.

[18]  R. Weinreb,et al.  Exogenous vasopressin influences intraocular pressure via the V1 receptors , 2001, Current eye research.

[19]  N. Toda,et al.  Receptor subtypes involved in relaxation and contraction by arginine vasopressin in canine isolated short posterior ciliary arteries. , 1997, Journal of vascular research.

[20]  Luis Monge,et al.  Regional differences in the arterial response to vasopressin: role of endothelial nitric oxide , 1996, British journal of pharmacology.

[21]  C. Balaban,et al.  Effects of angiotensin, vasopressin and atrial natriuretic peptide on intraocular pressure in anesthetized rats , 1995, Neuropeptides.

[22]  T. D. Duane,et al.  Duane's Clinical Ophthalmology , 1993 .

[23]  R. Brubaker,et al.  Effect of desmopressin on aqueous humor flow in humans. , 1993, American journal of ophthalmology.

[24]  R. Brubaker,et al.  Flow of aqueous humor in humans [The Friedenwald Lecture]. , 1991, Investigative ophthalmology & visual science.

[25]  R. Stone,et al.  Effects of systemic desmopressin on aqueous humor dynamics in rabbits. , 1988, Investigative ophthalmology & visual science.

[26]  M. Yablonski,et al.  Fluorophotometric study of intravenous carbonic anhydrase inhibitors in rabbits. , 1987, Investigative ophthalmology & visual science.

[27]  R. Hof Modification of vasopressin‐ and angiotensin II‐induced changes by calcium antagonists in the peripheral circulation of anaesthetized rabbits , 1985, British journal of pharmacology.

[28]  T. Krupin,et al.  Central effects of thyrotropin-releasing hormone and arginine vasopressin on intraocular pressure in rabbits. , 1984, Investigative ophthalmology & visual science.

[29]  S. Nagasubramanian Role of pituitary vasopressin in the formation and dynamics of aqueous humour. , 1977, Transactions of the ophthalmological societies of the United Kingdom.

[30]  W. Niederer,et al.  Hormonal control of aqueous humour production. , 1975, Experimental eye research.

[31]  M. Manning,et al.  Structural changes in the arginine vasopressin molecule that enhance antidiuretic activity and specificity. , 1974, Endocrinology.

[32]  D. Cole,et al.  Substances affecting active transport across the ciliary epithelium and their possible role in determining intraocular pressure. , 1973, Experimental eye research.

[33]  A. Bill,et al.  The role of ciliary blood flow and ultrafiltration in aqueous humor formation. , 1973, Experimental eye research.

[34]  L. Jampol,et al.  Aspirin Prevents the Disruption of the Blood–Aqueous Barrier in the Rabbit Eye , 1972, Nature.

[35]  N. Ambache,et al.  Effect of mechanical stimulation on rabbits' eyes: release of active substance in anterior chamber perfusates , 1965, The Journal of physiology.

[36]  M. Sears Miosis and intraocular pressure changes during manometry: mechanically irritated rabbit eyes studied with improved manometric technique. , 1960, Archives of ophthalmology.

[37]  R. E. Christensen,et al.  Beta hypophamine (vasopressin), its effect upon intraocular pressure and aqueous flow in normal and glaucomatous eyes. , 1956, A.M.A. archives of ophthalmology.

[38]  B. Becker,et al.  Experimental tonography. II. The effects of vasopressin, chlorpromazine, and phentolamine methanesulfonate. , 1956, A.M.A. archives of ophthalmology.

[39]  J. Kiel,et al.  Chapter 9 Effects of Circulatory Events on Aqueous Humor Inflow and Intraocular Pressure , 2008 .

[40]  M. Civan The eye's aqueous humor , 2008 .

[41]  C. Serradeil‐Le Gal An overview of SR121463, a selective non-peptide vasopressin V(2) receptor antagonist. , 2001, Cardiovascular drug reviews.

[42]  M. Leider Goodman & Gilman's The Pharmacological Basis of Therapeutics , 1985 .

[43]  J. McLaren,et al.  Measurement of aqueous humor flow with scanning ocular fluorophotometers. , 1984, Current eye research.

[44]  S. Nagasubramanian The Effect of Vasopressin on the Facility of Aqueous Humour Outflow in the Rabbit , 1974 .

[45]  D. Cole,et al.  The effect of natural and synthetic vasopressins and other substances on active transport in ciliary epithelium of the rabbit. , 1972, Experimental eye research.