Influence of corneal epithelial integrity on the penetration of timolol prodrugs

Development of eye drops containing antihypertensive drugs: formulation of aqueous irbesartan/γCD eye drops

Aqueous nanoparticulated eye drop formulations based on γ-cyclodextrin (γCD) complexes were developed and tested in vitro. Three antihypertensive drugs, i.e. enalapril maleate, irbesartan and verapamil HCl, that have been shown to possess IOP-lowering activity were selected for this study. All three drugs displayed Bs-type phase-solubility diagrams in aqueous γCD solutions and had relatively low affinity for γCD. Irbesartan was selected for further formulation development. The drug was relatively stable at pH 4.5 but somewhat less stable at physiologic pH. However, presence of γCD in the aqueous media enhanced the chemical stability of irbesartan. Aqueous γCD-based eye drop formulations containing 1% and 2% (w/v) irbesartan were prepared and the effect of pH on the particles size distribution and drug release investigated. Only ∼2% of the drug was in solution in the pH 4.5 formulations but up to 45% in the pH 7 formulations. The pH 7 formulations, where larger fraction of the drug was in solution, displayed somewhat greater drug permeation flux but much lower drug permeation coefficients than the pH 4.5 formulations. Dynamic light scattering studies indicated the faster permeation was due to formation of smaller particles in presence tyloxapol.

Penetration of β-Blockers through Ocular Membranes in A1bino Rabbits

The purpose of this study was to investigate the barrier properties of ocular membranes for controlling the extent and pathway of ocular absorption of instilled β-blockers.

The penetration of β-blockers was measured across the isolated corneal, conjunctival and scleral membranes of the albino rabbit using a two-chamber glass diffusion cell. β-Blockers tested were atenolol, carteolol, tilisolol, timolol and befunolol.

Corneal penetration of befunolol was much higher than that of atenolol. Scraping the epithelium increased corneal penetration of β-blockers. Conjunctival membranes showed higher permeability than corneal and scleral membranes. The penetration parameters were estimated according to Fick's equation. The corneal permeability coefficient showed an apparent linear relationship with penetrant lipophilicity. The lipophilic character of the corneal barrier was determined by the partition coefficient of drug to corneal surface, not by the diffusion coefficient. Conjunctival and scleral permeability coefficients were not determined by the lipophilicity of β-blockers.

These results indicate that the conjunctiva, sclera and cornea of the rabbit eye are sufficiently different in permeation character to control the extent and pathway for ocular absorption.

Evaluation of aqueous humor concentrations of Istalol and Betimol following a single ocular instillation in rabbit eyes

PURPOSE

The aim of this study was to evaluate the pharmacokinetic absorption profiles of two commercially available ophthalmic solutions following a single instillation into each eye of New Zealand white rabbit eyes.

METHODS

A single dose of either timolol maleate with potassium sorbate (TLA) or timolol hemihydrate (THH) was instilled into each eye of New Zealand white rabbits (15 rabbits/drug preparation, 50-microL dose). Animals were euthanized 15, 30, 60, 120, and 180 min after instillation, with 3 animals/drug/time intervals. Aqueous humor from both eyes of each animal was pooled and analyzed for timolol concentration, using the high-performance liquid chromatography method.

RESULTS

TLA reached a mean peak concentration of 3.705 +/- 0.3012 microg/mL at 15 min, tapering to 0.539 +/- 0.1431 microg/mL by 180 min. THH reached a mean peak concentration of 2.239 +/- 0.1430 microg/mL at 15 min postinstillation, tapering to 0.148 +/- 0.0282 microg/mL by 180 min.

CONCLUSIONS

TLA containing potassium sorbate demonstrated an absorption profile of more rapid absorption (1.7 fold greater at 15 minutes) and longer residences time (3.6 fold greater at 180 minutes) than the THH. At every time point throughout the study, TLA demonstrated greater drug concentration than THH.

Molecular design for enhancement of ocular penetration

Over the past two decades, many oral drugs have been designed in consideration of physicochemical properties to attain optimal pharmacokinetic properties. This strategy significantly reduced attrition in drug development owing to inadequate pharmacokinetics during the last decade. On the other hand, most ophthalmic drugs are generated from reformulation of other therapeutic dosage forms. Therefore, the modification of formulations has been used mainly as the approach to improve ocular pharmacokinetics. However, to maximize ocular pharmacokinetic properties, a specific molecular design for ocular drug is preferable. Passive diffusion of drugs across the cornea membranes requires appropriate lipophilicity and aqueous solubility. Improvement of such physicochemical properties has been achieved by structure optimization or prodrug approaches. This review discusses the current knowledge about ophthalmic drugs adapted from systemic drugs and molecular design for ocular drugs. I propose the approaches for molecular design to obtain the optimal ocular penetration into anterior segment based on published studies to date.

Improvement of the Ocular Bioavailability of Carteolol by Ion Pair

Ocular bioavailability after instillation of carteolol was investigated by ion pair formation, taking into consideration a balance between lipophilicity and water solubility. The octanol/ water partition coefficient (PC(O/W)) and the aqueous humor concentration in rabbits after instillation of carteolol containing fatty acids having not more than 6 carbons were measured. The longer carbon chain fatty acid showed the higher PC(O/W) of carteolol. The aqueous humor concentration of carteolol increased with carbon chain length of fatty acid and was clearly correlated with logPC(O/W). The increment of counter ion also increased both the logPC(O/W) and aqueous humor concentration of carteolol. The findings suggested that the transcorneal absorption of carteolol would be designed by coordinating with quality and quantity of counter ions. The area under concentration (AUC) in aqueous humor applied by ion pair formulation containing 2% carteolol with sorbate was 2.6 times higher than that by 2% carteolol ophthalmic solution (control), whereas the AUC applied by 4% carteolol ophthalmic solution was 1.4 times higher. The plasma level after instillation of ion pair formulation was almost the same as that of 2% ophthalmic solution. The ratio of AUC (aqueous humor/ plasma) of ion pair formulation was markedly higher, as compared with those of 2% and 4% ophthalmic solution. These results showed that the ion pair formation with sorbate improved the ocular bioavailability of carteolol without enhancing systemic absorption.

Improvement of the ocular bioavailability of timolol by sorbic acid

The ocular bioavailability of timolol increased in sorbic acid solution due to ion pair formation. Its octanol/water partition coefficient also increased, suggesting the formation of a more lipophilic complex. The concentration of timolol in rabbit aqueous humor was determined after instillation of timolol ophthalmic solution containing sorbic acid. When the molar ratio of sorbic acid to timolol was two or higher, the concentration of timolol in the aqueous humor was higher than with timolol alone. In the presence of sorbic acid the maximal aqueous humor concentration and the area under the curve were more than two-fold higher than those of Timoptol, a timolol maleate ophthalmic solution, and similar in value to TIMOPTIC-XE, a gel-forming ophthalmic solution. To investigate the transcorneal absorption mechanism, in vitro permeation profiles across the intact and de-epithelialyzed cornea were analyzed on the basis of the bilayer diffusion model. The partition coefficient in the epithelium was about twice as high in the presence of sorbic acid than with timolol alone, although the diffusion coefficient in the epithelium did not change. We conclude that the improved ocular bioavailability in the presence of sorbic acid is due to increased partitioning of timolol in the corneal epithelium.

Permeability of chemical delivery systems across rabbit corneal (SIRC) cell line and isolated corneas: a comparative study

The purpose of this study was to investigate the corneal permeability of phenylephrone chemical delivery systems (CDS) across isolated cornea and to evaluate the utility of the SIRC cell line (epithelial cells originating from rabbit cornea) as an in vitro model for predicting the ocular permeability. The effect of benzalkonium chloride (BAC) on the drug permeability through SIRC cell layers was also studied. The transport of phenylephrone CDS across the isolated cornea of the albino rabbit was measured at various pH values using a two-chamber glass diffusion cell, and the results were compared with the reported permeability values across SIRC cells of rabbit origin. Corneal membranes showed lower flux values for compounds, especially for hydrophilic compounds, than the SIRC cell line. A significant correlation was observed between the permeability coefficients through corneal membranes and SIRC cells. When the pH of the transport medium was increased, the permeability coefficients increased and lag times decreased in both in vitro models. Furthermore, both in vitro models showed significant correlation between permeability coefficients and lipophilicities of the drugs. The three esters, having higher lipophilic characteristics, showed higher permeability than phenylephrine HCl. The phenylacetyl ester of phenylephrone showed a three-fold increase in penetration across SIRC cell layers in the presence of 0.01% BAC. These results suggest that the use of SIRC cell layers can reasonably predict the permeability of ophthalmic drugs across corneal membranes.

Novel site-specific chemical delivery system as a potential mydriatic agent: formation of phenylephrine in the iris-ciliary body from phenylephrone chemical delivery systems

The objective of this study was to test the three novel ester derivatives of phenylephrone (isovaleryl, phenylacetyl, and pivalyl esters) as potential site-specific chemical delivery systems. The mydriatic effect and ocular distribution/metabolism of these compounds were studied by topical application to the eyes of normal rabbits. It was assumed that a reduction-hydrolysis sequence could produce the active phenylephrine in the iris-ciliary body tissues. All the derivatives showed a more pronounced mydriatic effect than that of phenylephrine, whereas phenylephrone was completely devoid of any mydriatic activity. Phenylacetyl ester was the most potent drug, with short duration of action, and showed maximum activity in the presence of 0.01% benzalkonium chloride without causing any visible irritation to the rabbit eye. Administration of the novel compounds to the eyes of the rabbits showed no traces of phenylephrine in the systemic circulation, contrary to topical administration of phenylephrine. Phenylephrone was detected in different compartments of the eye, whereas phenylephrine was present only in the iris-ciliary body tissues following administration of phenylacetyl ester. The conversion of phenylephrone esters to the active drug, phenylephrine, and thus their subsequent activity was dependent on the physicochemical characteristics of the drugs. The results suggest the potential use of phenylacetyl ester as a potent short-term mydriatic agent without systemic side effects.

How an increase in the carbon chain length of the ester moiety affects the stability of a homologous series of oxprenolol esters in the presence of biological enzymes

beta-Blockers including timolol and propranolol are administered in eye-drops for the treatment of glaucoma. Due to high incidence of cardiovascular and respiratory side-effects, their therapeutic value is limited. As a result of poor ocular bioavailability, many ocular drugs are applied in high concentrations, which give rise to both ocular and systemic side-effects. Therefore, some methods have been employed to increase ocular bioavailability such as (a) the development of drug delivery devices designed to release drugs at controlled rates, (b) the use of various vehicles that retard precorneal drug loss, and (c) the conversion of drugs to biologically reversible derivatives (prodrugs) with increased corneal penetration properties, from which the active drugs are released by enzymatic hydrolysis. A series of structurally related oxprenolol esters were synthesized and investigated as potential prodrugs for improved ocular use. The stability of each ester was studied in phosphate buffer (pH 7.4), also in the presence of (a) 30% human plasma, (b) aqueous humor, and (c) corneal extract at pH 7. 4 and at 37 degreesC. An account is given of how the stability of a homologous series of oxprenolol esters in the presence of biological enzymes is affected by an increase in the carbon chain length of the ester moiety.

Ocular drug delivery in veterinary medicine

This paper provides a comprehensive overview of the various approaches currently used in the development of ocular drug delivery systems for the treatment of ocular diseases in animals. It is obvious from the literature that most of the products that are currently available are derived from human medicine without consideration given to the differences which exist between the anatomy and physiology of the eye of various animal species which ultimately affect product design and performance. As a result, many of the products for animal use seem in many circumstances inappropriate for animal care. The article deals with some aspects of eye anatomy and physiology of different animals, and then provides an overview of the most commonly encountered pathologies. The paper then discusses the currently available drug products and finally reviews new delivery concepts. Several hundred references are included in the paper and provide access to further information on the subject.

Ocular penetration and bioconversion of prostaglandin F2alpha prodrugs in rabbit cornea and conjunctiva

The objective of this study was to identify prostaglandin F2alpha (PGF2alpha) prodrugs that have an optimal ocular absorption profile and therefore could be potentially useful for the treatment of glaucoma. Rabbit cornea, conjunctiva, and iris/ciliary body were mounted in a flow-through chamber to evaluate the permeability and bioconversion of PGF2alpha and its prodrugs. The prodrugs tested were PGF2alpha 1-isopropyl, 1,11-lactone, 15-acetyl, 15-pivaloyl, 15-valeryl, and 11,15-dipivaloyl esters. After 4 h in the donor or acceptor compartments, the products and formation of PGF2alpha were analyzed by HPLC. Effects on intraocular pressure and ocular surface hyperemia were also determined. All prodrugs penetrated the rabbit cornea faster than PGF2alpha by 4- to 83-fold. All prodrugs penetrated conjunctiva faster than PGF2alpha, except the 15-acetyl ester prodrug, which was equally permeable. No direct correlation between drug lipophilicity and permeability across the cornea or conjunctiva was apparent. The most metabolically stable prodrug was the 1,11-lactone, followed by the 11,15-dipivaloyl, 15-pivaloyl, 15-acetyl, 1-isopropyl, and the 15-valeryl esters, the latter of which was extensively converted to PGF2alpha. A separation index for various prodrugs was calculated from the ratio of the bioavailable PGF2alpha for ocular hypotension to the bioavailable PGF2alpha for hyperemia. The highest separation index was observed for the 1,11-lactone prodrug (2.33), followed by the 11,15-dipivaloyl ester prodrug (1.80). Thus the 1,11-lactone and 11,15-dipivaloyl ester prodrugs appeared to be superior to the others in providing bioavailable PGF2alpha for ocular hypotension, while minimizing hyperemia. The favorable separation index for these compounds appeared to be due to their metabolic stability at the corneal surface and conjunctiva combined with sufficient bioavailability for ocular hypotension.

Ocular membrane permeability of hydrophilic drugs for ocular peptide delivery

The purpose of this study is to investigate the ocular membrane permeability and the permeation mechanism of hydrophilic drugs such as thyrotropin-releasing hormone (TRH), p-nitrophenyl beta-cellopentaoside (PNP) and luteinizing hormone-releasing hormone (LHRH). The penetration of hydrophilic drugs was measured across the isolated corneal and conjunctival membranes of albino rabbits using a two-chamber diffusion glass cell. The corneal permeabilities of hydrophilic drugs were much lower than those of beta blockers reported previously. The corneal penetration of TRH was the highest among the hydrophilic drugs studied. Scraping the corneal epithelium increased the penetration of hydrophilic drugs. Conjunctival membranes showed higher permeability to hydrophilic drugs compared with corneal membranes. The permeability of drugs was also analysed by Fick's equation. The partition parameter and diffusion parameter of TRH, PNP and LHRH in the cornea were lower than those in scraped cornea and conjunctiva. In addition to the data of fluorescein isothiocyanate-dextran reported previously, the permeability coefficient of hydrophilic drugs through the cornea, scraped cornea and conjunctiva correlated with molecular weight of the drugs. The diffusion parameters of hydrophilic drugs decreased with an increase of molecular weight for all ocular membranes. The extent of dependency of partition parameters on the molecular weights of drugs varied according to the ocular membrane. These results indicate that ocular membranes are sufficiently different in permeation character and mechanism to control the extent and pathway for ocular absorption of hydrophilic drugs.

Ocular permeability of FITC-dextran with absorption promoter for ocular delivery of peptide drug

The purpose of this study is to characterize an ocular permeability of FITC-dextran, as a model of peptide drug, and to evaluate the effects of absorption promoters on the ocular permeability of FITC-dextran. The in vitro penetrations of FITC-dextrans (average molecular weight 4400 and 9400: FD-4 and FD-10) were measured across the isolated corneal and conjunctival membranes of albino rabbits using a two-chamber glass diffusion cell. The corneal permeabilities of FD-4 and FD-10 were much lower than the conjunctival permeabilities. Scraping of corneal epithelium extremely increased the corneal permeabilities. The penetration parameters were estimated according to Fick's equation. Absorption promoters such as EDTA, taurocholic acid, benzalkonium chloride and saponin significantly increased corneal permeabilities of FD-4 and FD-10. Saponin showed the highest promoting activity. Conjunctival permeabilities of FD-4 and FD-10 were also enhanced by absorption promoters although the improvements of conjunctival permeabilities by absorption promoters were smaller than those of corneal permeabilities. Ratios of corneal to conjunctival permeabilities were enhanced by absorption promoters. These results indicate that an ocular delivery of instilled hydrophilic macromolecule is markedly low and a selective use of absorption promoter can improve the extent and pathway of its ocular absorption.

Role of enzymatic lability in the corneal and conjunctival penetration of timolol ester prodrugs in the pigmented rabbit

The main objective of this study was to investigate how enzymatic lability would affect the extent of corneal and conjunctival penetration of a series of alkyl, cycloalkyl, and aryl ester prodrugs of timolol in the pigmented rabbit. Enzymatic lability of the prodrugs was studied in corneal epithelial and conjunctival homogenates, while their corneal and conjunctival penetration was determined using the isolated tissues in the modified Ussing chamber. The straight-chain alkyl and the unsubstituted cycloalkyl esters were hydrolyzed more rapidly than their corresponding branched-chain and substituted analogues as well as the aryl esters. The corneal and conjunctival penetration of all prodrugs, regardless of enzymatic lability, varied parabolically with lipophilicity. Moreover, the enzymatically more labile straight-chain alkyl esters penetrated the cornea and the conjunctiva more readily than the more stable branched-chain esters of comparable lipophilicity. Enzymatic lability is, therefore, an additional factor that should be considered in designing alkyl ester prodrugs with improved ocular drug delivery characteristics. Enzymatic lability does not, however, play as important a role as lipophilicity in the corneal and conjunctival penetration of cycloalkyl and aryl ester prodrugs.