Ocular pharmacokinetic models of clonidine-3H hydrochloride

A single topical instillation of clonidine-3H HCl solution (0.2%) was administered to the rabbit eye (30 microliter) in order to study the drug's ocular pharmacokinetics. Seven different tissues and plasma were excised and assayed for drug over 180 min. By 45-60 min pseudoequilibrium is reached for the cornea, iris/ciliary body, and aqueous humor. Thereafter, drug levels in these tissues decline in parallel. The data are fit separately to a physiological model and a classical diffusion model for which seven ocular tissue compartments and a plasma reservoir are constructed for each model. Clearance terms and distribution equilibrium coefficients are determined from the tissue level data and used as parameters in fitting the mass balance differential equations representing the physiological model. The model parameters can also be fit to a 0.4% single dose. In a separate experiment, a topical infusion technique was designed to provide a constant rate input to the cornea until an apparent steady state was reached in aqueous humor at 55 min. Aqueous humor levels were assayed for clonidine over the infusion and postinfusion periods. The physiological model parameters are fit to the topical infusion data and show good agreement between the predicted and experimental data. The classical model is too complex to fit the data to integrated exponential equations primarily because the method of residuals is inadequate in determining a sufficient set of initial estimates. This is overcome by dividing the eight-compartment model into seven fragmental models, each representing one to five compartments. A stepwise procedure is developed in which initial estimates are obtained for each separate fragmental model and refined. The refined parameter values can then be used as initial estimates for the complex model. Differential equations for the complex model are fit simultaneously to tissue levels representing each compartment. By observation, the classical model fit the data more closely than the physiological model. Statistical moment theory is also applied to the topical infusion data to determine ocular pharmacokinetic parameters for clonidine. The calculated values are: corneal absorption rate constant ka, 0.00139 min-1, aqueous humor elimination rate constant k10, 0.0658 min-1; mean residence time MRTd, 35.6 min; apparent steady-state volume of distribution Vss, 0.530 ml; and ocular clearance Qe, 14.9 microliter/min. The fraction absorbed from the single instillation is estimated as 0.0163.     

Ocular pharmacokinetics of a novel tetrahydroquinoline analog in rabbit: absorption, disposition, and non-compartmental analysis

The pharmacologically active compound (33% reduction in rabbit intraocular pressure recovery rate assay) 1-ethyl-6-fluoro-1,2,3,4-tetrahydroquinoline (MC4), which showed ocular hypotensive action and had optimum physicochemical properties, was characterized for its ocular absorption and distribution properties to better understand its in vivo potency in comparison with an inactive compound, N-ethyl-1,4-benzoxazine (MC1). Tissue distribution to various ocular tissues was determined after absorption by both corneal and conjunctival-scleral routes, following administration by the "topical infusion" technique. The rank order of penetration for both the compounds was cornea > iris-ciliary body > aqueous humor > lens > conjunctiva-sclera. Overall, MC4 had significantly higher concentrations than MC1 in various ocular tissues, but particularly in the iris-ciliary body, which is the site of action (biophase). Ocular disposition studies of the active compound MC4 were then conducted to characterize its elimination kinetics, and the pharmacokinetic parameters were determined by non-compartmental and moment analysis using equations specific to "topical infusion" technique: first-order absorption rate constant, 4.1 × 10(-4) min(-1) ; elimination rate constant, 0.012 min(-1) ; mean residence time, 39.6 min; steady-state volume of distribution, 0.721 mL; and aqueous humor ocular clearance, 8.44 μL/min. The results were consistent with the conclusion that MC4 is well absorbed and distributed to the active site.     

Ocular absorption and disposition of phenylephrine and phenylephrine oxazolidine

The ocular bioavailability of phenylephrine oxazolidine (PO), a prodrug intended for rapid corneal penetration, was micronized and suspended in sesame oil (1 and 10 per cent) and compared in bioavailability to phenylephrine HC1 (PE) dissolved (10 per cent) in a buffered (pH 5.75), viscous (30 centipoise) vehicle. Cornea and aqueous humor of New Zealand rabbits were measured over time following 10 microliter instillation to the eye. Based upon AUC measurements, corneal and aqueous humor levels were approximately 6 and 8 times greater for 10 per cent PO versus 10 per cent PE, respectively. In addition, the ocular pharmacokinetic values were determined for PE applied in a constant concentration (1 per cent) to the cornea over 180 min to anesthetized rabbits. Cornea and aqueous humor were measured for drug content over time. Using moment analysis and an initial slope method, the absorption rate constant, ka, the steady state volume of distribution in the eye, Vss, and ocular clearance, Qe, were calculated. Values obtained for PE were 4.15 x 10(-5) min-1, 0.423 ml and 14.6 microliter min-1, respectively. The half-life for drug elimination ranged from 63-83 min depending on the tissue or route of administration.     

Evaluation of microdialysis sampling of aqueous humor for in vivo models of ocular absorption and disposition

The dynamics of β-adrenergic-associated reductions in aqueous humor production for treatment of elevated intraocular pressure are not well understood. In particular, the relationship between ocular pharmacokinetics and pharmacodynamics has yet to be established. This study was undertaken to develop a procedure for examining the ocular absorption and disposition of topically administered ophthalmic β-adrenergic antagonists in individual animals. Dogs were anesthetized with isoflurane and a microdialysis probe was implanted in the anterior chamber of one eye and perfused with 0.9% saline at a rate of 2 μl min⁻¹. ³H-propranolol was administered by intracameral injection or topically. Each dog received intracameral and topical propranolol, in alternate eyes on separate days, in a randomized cross-over fashion. Microdialysis probe effluent was collected every 5 min for ≥2.5 h; concentrations of propranolol were determined by liquid scintillation spectroscopy and were corrected for probe recovery of the substrate as determined by in vivo retrodialysis (∼46%) to estimate aqueous humor concentrations. In separate experiments in rabbits, microdialysis probes were implanted in each eye. ³H-propranolol was administered topically to one eye; the contralateral eye received intracameral ³H-propranolol. Model-independent pharmacokinetic parameters for each treatment phase were calculated. The mean±S.D. times to peak concentration of propranolol in aqueous humor were 86.6±47.6 min in the dog and 54.1±20.4 min in the rabbit. The terminal rate constant was 0.0189±0.00429 min⁻¹ in the dog vs. 0.00983±0.00546 min⁻¹ in the rabbit. Intraocular tissue availability of propranolol differed markedly between the dog (n=3) and rabbit (n=3) (∼0.056 in the dog vs. ∼0.55 in the rabbit). These results demonstrate the utility of microdialysis sampling for examination of ocular pharmacokinetics.     

Ocular pharmacokinetic models of clonidine-3H hydrochloride

A single topical instillation of clonidine-³H HCl solution (0.2%) was administered to the rabbit eye (30 μl) in order to study the drug's ocular pharmacokinetics. Seven different tissues and plasma were excised and assayed for drug over 180min. By 45–60 min pseudoequilibrium is reached for the cornea, iris/ciliary body, and aqueous humor. Thereafter, drug levels in these tissues decline in parallel. The data are fit separately to a physiological model and a classical diffusion model for which seven ocular tissue compartments and a plasma reservoir are constructed for each model. Clearance terms and distribution equilibrium coefficients are determined from the tissue level data and used as parameters in fitting the mass balance differential equations representing the physiological model. The model parameters can also be fit to a 0.4% single dose. In a separate experiment, a topical infusion technique was designed to provide a constant rate input to the cornea until an apparent steady state was reached in aqueous humor at 55 min. Aqueous humor levels were assayed for clonidine over the infusion and postinfusion periods. The physiological model parameters are fit to the topical infusion data and show good agreement between the predicted and experimental data. The classical model is too complex to fit the data to integrated exponential equations primarily because the method of residuals is inadequate in determining a sufficient set of initial estimates. This is overcome by dividing the eight-compartment model into seven fragmental models, each representing one to five compartments. A stepwise procedure is developed in which initial estimates are obtained for each separate fragmental model and refined. The refined parameter values can then be used as initial estimates for the complex model. Differential equations for the complex model are fit simultaneously to tissue levels representing each compartment. By observation, the classical model fit the data more closely than the physiological model. Statistical moment theory is also applied to the topical infusion data to determine ocular pharmacokinetic parameters for clonidine. The calculated values are: corneal absorption rate constantk _a , 0.00139 min^?1; aqueous humor elimination rate constantk ₁₀ , 0.0658min^?1; mean residence timeMRT _d , 35.6 min; apparent steadystate volume of distributionV _ss, 0.530 ml; and ocular clearanceQ _e , 14.9 =μl/min. The fraction absorbed from the single instillation is estimated as 0.0163.     

Disposition of levobunolol after an ophthalmic dose to rabbits

The ocular and systemic disposition of levobunolol (LBUN), an antiglaucoma agent, was studied in albino rabbits. After topical administration to eyes, LBUN was rapidly adsorbed, with 2.5% of the dose bioavailable to the intraocular tissues as intact drug and 46% to the systemic circulation. On passage across the cornea, approximately 4.7% of a topically applied LBUN dose was biotransformed to dihydrolevobunolol (DHB), and subsequently became bioavailable to intraocular tissues. The major sites of ocular metabolism were the cornea epithelium and the iris-ciliary body. Another 12% of the topical LBUN dose entered the systemic circulation as DHB after presystemic biotransformation. Our study indicated a rapid absorption of LBUN into the aqueous humor after topical dosing. The tpeak was 15 min after dosing and the Cmax was 4 micrograms/mL. Dihydrolevobunolol (DHB) was formed steadily and reached a maximum in the aqueous humor 45 min after dosing. After distribution equilibrium had been reached, the aqueous humor concentrations of both LBUN and DHB declined. Six hours after dosing, the concentration of DHB in the aqueous humor was approximately 10 times higher than that of its parent compound. Because DHB is equivalent to its parent compound in beta-blocking activity, its formation in the rabbit eye may contribute to the pharmacodynamic effects observed after topical doses of LBUN.     

Ocular pharmacokinetics of acyclovir amino acid ester prodrugs in the anterior chamber: evaluation of their utility in treating ocular HSV infections

PURPOSE: To evaluate in vivo corneal absorption of the amino acid prodrugs of acyclovir (ACV) using a topical well model and microdialysis in rabbits. METHODS: Stability of L-alanine-ACV (AACV), L-serine-ACV (SACV), L-isoleucine-ACV (IACV), gamma-glutamate-ACV (EACV) and L-valine-ACV (VACV) prodrugs was evaluated in various ocular tissues. Dose-dependent toxicity of these prodrugs was also examined in rabbit primary corneal epithelial cell culture (rPCEC) using 96-well based cell proliferation assay. In vivo ocular bioavailability of these compounds was also evaluated with a combination of topical well infusion and aqueous humor microdialysis techniques. RESULTS: Among the amino acid ester prodrugs, SACV was most stable in aqueous humor. Enzymatic degradation of EACV was the least compared to all other prodrugs. Cellular toxicity of all the prodrugs was significantly less compared to trifluorothymidine (TFT) at 5mM. Absorption rate constants of all the compounds were found to be lower than the elimination rate constants. All the prodrugs showed similar terminal elimination rate constants (lambda(z)). SACV and VACV exhibited approximately two-fold increase in area under the curve (AUC) relative to ACV (p<0.05). Clast (concentration at the last time point) of SACV was observed to be 8+/-2.6microM in aqueous humor which is two and three times higher than VACV and ACV, respectively. CONCLUSIONS: Amino acid ester prodrugs of ACV were absorbed through the cornea at varying rates (ka) thereby leading to varying extents (AUC). The amino acid ester prodrug, SACV owing to its enhanced stability, comparable AUC and high concentration at last time point (Clast) seems to be a promising candidate for the treatment of ocular HSV infections.     

Relationship between the ocular and systemic disposition of flurbiprofen: the effect of altered protein dynamics at steady state

The differences in flurbiprofen disposition in the aqueous humor and the plasma were examined after systemic doses. Steady state plasma concentrations of flurbiprofen (20-60 micrograms/mL) were achieved via intravenous infusion to albino rabbits. Flurbiprofen demonstrated linear systemic kinetics throughout the dosing range, with constant body clearance and unbound fraction in plasma. At steady state, aqueous humor drug concentrations depended on the corresponding plasma drug concentration. Two clearance terms--CLS----O, the systemic clearance to ocular tissues, and CLO----S, the ocular clearance to systemic circulation--were used. After systemic doses, the drug concentration in the aqueous humor was related to that in the plasma as well as to the ratio of these two clearances. Flurbiprofen was extensively bound to plasma proteins and showed limited ocular distribution; its CLS----O to CLO----S ratio was very small. Thus, the concentration of flurbiprofen in the aqueous humor after systemic doses was lower than that obtained after ophthalmic doses. A plasmapheresis technique was utilized to lower the plasma protein concentrations to 60% of normal levels. As a consequence, flurbiprofen demonstrated reduced aqueous humor protein concentrations, increased unbound fractions in the plasma and the aqueous humor, elevated aqueous humor drug concentrations, and elevated total body clearance. The unbound body clearance stayed unchanged. Our study indicated that a drug should present a significant CLS----O/CLO----S ratio in order to achieve therapeutic concentrations in the eye via systemic doses. The drug-protein binding kinetics can be different between the plasma and the aqueous humor circulations. Because the ocular compartment is very small compared to the overall systemic distribution of flurbiprofen, it has little effect on the steady state systemic concentrations.     

Pharmacokinetics of topically applied pilocarpine in the albino rabbit eye.

The temporal and spatial pattern of [3H]-pilocarpine nitrate distribution in the albino rabbit eye following topical administration was determined. A four-compartment caternary chain model describing this disposition corresponds to the precorneal area, the cornea, the aqueous humor, and the lens and vitreous. Simultaneous computer fitting of data from tissue corresponding to some compartments in the model supported the proposed model. Additional support was provided by the excellent correlation between predicted and observed values in multiple-dosing studies. Several important aspects of ocular drug disposition are evident from the model. The extensive parallel elimination at the absorption site gives rise to an apparent absorption rate constant that is one to two orders of magnitude larger than the true absorption rate constant. In addition, aqueous flow accounts for most of the drug removal. Thus, major effects on absorption and elimination, independent of the drug structure, suggest the possibility of similar pharmacokinetics for vastly different drugs.     

Biopharmaceutical evaluation of ibufenac, ibuprofen, and their hydroxyethoxy analogs in the rabbit eye.

Two new structural analogs, 2-(4-hydroxyethoxyphenyl)acetic acid [R3] and 2-(4-hydroxyethoxyphenyl)propionic acid [R4], along with their parent compounds, ibufenac and ibuprofen, were evaluated for their biopharmaceutical properties. The analogs represented substitution of the lipophilic isobutyl side chains of ibufenac and ibuprofen with hydrophilic hydroxyethoxy side chains. Anti-inflammatory activity was evaluated by administering drugs topically to inhibit inflammation induced by using either clove oil or arachidonic acid. The rank order of activity was ibufenac approximately equal to ibuprofen > R3 approximately equal to R4. The new compounds, R3 and R4, were highly water soluble (> 60-fold) and partitioned less (< 1/1500-fold) into the lipid phase when compared to ibufenac and ibuprofen. R3 and R4 each had apparent corneal permeability coefficients of 6 x 10(-6) cm/sec, whereas ibufenac and ibuprofen yielded values of about 22 x 10(-6) cm/sec. In an ocular pharmacokinetic study in the rabbit eye, constant concentrations of each compound were maintained on the cornea in a cylinder or well fixed to the cornea, resulting in a constant input rate. This method circumvented parallel loss routes at the absorption site including nasolacrimal drainage. From area calculations the dispositions of the compounds within the eye were described by mean residence times, steady state volumes of distributions, and clearance rates. R3 and R4 were more slowly absorbed, retained within eye tissues longer, and were cleared more slowly from the eye than ibufenac and ibuprofen. The aqueous humor concentration-time profiles were also computer-fitted to equations representing classical pharmacokinetic models. For ibufenac and ibuprofen, the entire cornea was assumed to be the net barrier for entry into the anterior chamber. Whereas, for R3 and R4, the corneal epithelium and endothelium were presumed to be the diffusional barriers into and out of the stroma, the latter treated as a compartment. Aqueous humor concentrations of each drug fit the models reasonable well and agreed with conclusions made from the use of area calculations. The drop volume method was used to measure the surface tension of each compound. Both ibufenac and ibuprofen were considerably more surface active than R3 or R4. The greater surface tension measured for ibufenac and ibuprofen correlated to the subjective observations of ocular discomfort for these drugs.     

Effects of topically applied liposomes on disposition of epinephrine and inulin in the albino rabbit eye

By virtue of the biocompatibility of their constituent phospholipids and of their ability to influence cell membrane permeability, liposomes are an attractive system for topical ocular drug delivery. The objective of this study was to investigate whether the ocular disposition of epinephrine and inulin in the albino rabbit was similarly affected following their encapsulation in multilamellar liposomes. Drug concentrations in tears, conjunctiva, cornea, iris plus ciliary body and aqueous humor were monitored at 30 min post-instillation of various preparations of each drug using radiotracer techniques. Liposomal drug entrapment was found to have opposite effects on the corneal and conjunctival absorption of epinephrine and inulin, epinephrine absorption was reduced by 50% whereas inulin absorption was increased 10 times. Quite unexpectedly, although inulin was detected in the uveal tract, none of it was detected in the aqueous humor when presented in liposomal form. These preliminary data suggest that while the corneal and conjunctival absorption of a drug can be modified by its entrapment in liposomes, its disposition in the intraocular tissues is unlikely to be controlled entirely by liposomes, since few, if any, of the liposomes that may be absorbed are expected to maintain their integrity while permeating the cornea.     

双氯酚酸钠脂质体的制备及其眼部药代动力学

目的研究双氯酚酸钠脂质体的制备方法并考察其在家兔眼部的药代动力学特征。方法采用逆相蒸发法制备双氯酚酸钠正电荷脂质体。脂质体和滴眼液滴眼后家兔采用高效液相色谱法测定角膜前、角膜和房水中药物浓度。结果制得的脂质体平均粒径为226.5 nm，多分散度为0.214，ζ电位为+18.1 mV，经均匀设计优化处方，包封率可达到63%。0.1%双氯酚酸钠脂质体和滴眼液两种制剂家兔局部滴眼后的药代动力学研究显示，脂质体可延缓药物在角膜前的清除，增加角膜中药物的浓度，药物在房水中半衰期延长，以滴眼液为参比制剂，相对生物利用度为211%。结论双氯酚酸钠正电荷脂质体可以增加药物在角膜前的滞留时间，提高角膜渗透性及药物在眼部的生物利用度，减少滴眼次数。     

Challenges and solutions in topical ocular drug-delivery systems

Vision significantly affects quality of life and the treatment of ocular disease poses a number of unique challenges. This review presents the major challenges faced during topical ocular drug administration and highlights strategies used to overcome the natural transport barriers of the eye. The circulation of tear fluid and aqueous humor decrease the residence time of topically delivered drugs, while ocular barriers in the corneal and conjuctival epithelia and the retinal pigment epithelium limit transport. Successful treatment strategies increase the residence time of drugs in the eye and/or enhance the ability of the drug to penetrate the ocular barriers and reach the target tissue. In this review, we discuss several drug-delivery strategies that have achieved clinical success or demonstrate high potential. We also draw attention to a number of excellent reviews that explore various ocular drug-delivery techniques in depth. Finally, we highlight cutting-edge drug-delivery technologies that improve the efficacy of current drug-delivery methods or use proven techniques to deliver novel therapeutics.     

Disposition of pilocarpine in the pigmented rabbit eye

The disposition of pilocarpine in the pigmented rabbit eye following instillation of a pilocarpine solution was studied using radiotracer techniques. The results suggest that a topically applied pilocarpine solution was removed as efficiently from the tear chamber of the pigmented rabbit as from that of albino rabbit. Nevertheless, a larger fraction of the applied dose was recovered in the pigmented rabbit eye, possibly due to the combined effect of improved corneal permeability, metabolism of the drug in the cornea, and metabolism and binding of the drug in the iris-ciliary body. Based on the area under the drug concentration vs time curve, about 10 times as much pilocarpine was found in the iris-ciliary body of the pigmented than the albino rabbit. Despite this drug accumulation in the iris-ciliary body, which presumably derived its drug supply from the aqueous humor, the pilocarpine concentration in the aqueous humor of the pigmented rabbit was virtually indistinguishable from that in the albino rabbit.     

Effect of different ointment bases on ocular disposition of ethylphenylephrine in rabbit eyes

The influence of vehicle composition on the ocular disposition of ethylphenylephrine, a mydriatic drug used for the treatment of wide-angle glaucoma, has been studied. The vehicles investigated consisted of a hydrocarbon base, an absorption base (10% lanolin in a paraffin base) and a water-soluble base (polyvinyl alcohol, PVA, 15% in water). The albino rabbit was chosen as the animal model. The disposition of the drug in conjunctiva, cornea, iris-ciliary body and aqueous humor of the rabbit was monitored at 1, 2 and 4 h post-installation using extraction technique. At the early time period (1 h post-administration) both oleaginous and water-soluble bases were judged to perform adequately in that they provided approximately the same drug concentrations in various ocular tissues at the aqueous vehicle. However, after 4 h, the oleaginous base provided the highest concentrations of drug in the conjunctiva. The water-soluble PVA formulation gave significantly lower levels in the conjunctiva and the cornea. At this same point, the absorption base containing lanolin produced the highest drug concentration in the cornea, iris-ciliary body and aqueous humor. Collectively, these data suggest that of the 3 bases studied, the oleaginous base and the absorption base show most promise as vehicles to extend the residence time of ethylphenylephrine in the eye. Obviously the final choice of vehicle will also be influenced by factors such as the physical and chemical stability of the drug in the formulation chosen and patient acceptance.     

Ocular and systemic bioavailability of ophthalmic flurbiprofen

Flurbiprofen, a nonsteroidal antiinflammatory agent which is not ocularly metabolized, was employed as a probe compound to investigate the drug kinetic relationship between systemic and ocular humoral circulation. The ocular and systemic bioavailabilities of topically applied flurbiprofen were also quantitated. Anesthetized albino female rabbits received flurbiprofen doses intracamerally, topically, and intravenously at 2 to 4 week intervals. Aqueous humor and plasma were used as the sampling compartments. Plasma clearance values of flurbiprofen were 6.77 and 7.87 ml/min, after 6-mg and 208-micrograms intravenous doses, respectively. These values were not significantly different and indicated no dose-dependent disposition kinetics over a 30-fold dose range. Both ocular and systemic flurbiprofen dispositions followed a biexponential pattern with a rapid distribution phase. The systemic and ocular distribution half-lives of flurbiprofen were 12 min and 15 min, respectively. The plasma elimination half-life was 74 min and the aqueous humor elimination half-life was 93 min. The latter approximated the turnover rate of aqueous humor and suggested that aqueous humor drainage was the major process of flurbiprofen elimination from the globe. About 99% of flurbiprofen is bound to plasma protein. At distribution equilibrium, the plasma and aqueous humor concentrations of flurbiprofen differed by a hundredfold, suggesting that only free drug entered the aqueous humor after the administration of a systemic dose. In the ophthalmic studies, right eyes were instilled with 50 microliters of 0.3% flurbiprofen in saline (dose = 150 micrograms), and left eyes were instilled with 50 microliters of 0.15% flurbiprofen in saline (dose = 75 micrograms). When the area of the aqueous humor concentration-versus-time curve values was normalized by the administration dose, the 75-micrograms dose was 30% more available to ocular tissues than was the 150-micrograms dose. This demonstrated a disproportionate relationship between the administered dose and the fraction absorbed. The intracameral dose was considered to be completely bioavailable for intraocular effects. The ocular bioavailability of the ophthalmic dose was defined by using intracameral administration as a standard measurement. The ocular bioavailabilities of the 75-micrograms and 150-micrograms topical flurbiprofen doses were 10% and 7%, respectively. Systemic bioavailability after topical administration of 225 micrograms of flurbiprofen was 74%.     

Employing a PLGA-TPGS based nanoparticle to improve the ocular delivery of Acyclovir

Delivering drugs via the ocular route has always been a challenge for poorly soluble drugs. The various anatomical and physiological barriers in the eye cavity hinder the residence of drugs within the corneal and precorneal regions. In this study, the nanosystem that could sufficiently deliver the poorly soluble Acyclovir topically via ocular route. Our nanosystem is composed of the biocompatible PLGA polymer stabilized with TPGS which possess a high emulsifying capacity and is also known as P-gp inhibitor. The optimized nanoparticles were prepared with 0.3% TPGS and had particle-size of 262.3?nm, zeta-potential of +15.14?mV. The physicochemical-characterization, ex vivo transcorneal permeation, ocular-irritation and Acyclovir ocular-availability, following topical ocular application of PLGA-NPs in rabbit eyes, were performed. The tested parameters and irritation by Draize’s test suggested the suitability and safety of PLGA-NPs for ocular use. An ultrahigh performance liquid chromatographic method was developed, validated, and applied to quantify Acyclovir in aqueous humor which was shown to be significantly higher (p?<?0.05) using the developed nanoparticles as compared to Acyclovir-aqueous suspension following their single topical ocular administration. Noticeable 2.78-, 1.71- and 2.2-times increased values of AUC_0–24h, t_1/2 (h) and MRT_0–24h were found, respectively, with the PLGA-TPGS-NPs as compared to ACY-AqS. These results demonstrate the superiority of delivering Acyclovir using a nanosystem compared to conventional methods.     

The effect of deacetylated gellan gum on aesculin distribution in the posterior segment of the eye after topical administration

The aim of the present work was to evaluate the effect of deacetylated gellan gum on delivering hydrophilic drug to the posterior segment of the eye. An aesculin-containing in situ gel based on deacetylated gellan gum (AG) was prepared and characterized. In vitro corneal permeation across isolated rabbit cornea of aesculin between AG and aesculin solution (AS) was compared. The results showed that deacetylated gellan gum promotes corneal penetration of aesculin. Pharmacokinetics and ocular tissue distribution of aesculin after topical administration in rabbit eye showed that AG greatly improved aesculin accumulation in posterior segmentsrelative to AS, which was probably attributed to conjunctivital/sclera pathway. The area-under-the-curve (AUC) for AG in aqueous humor, choroid-retina, sclera and iris-ciliary body were significantly larger than those of AS. AG can be used as a potential carrier for broading the application of aesculin.     

In vivo ocular pharmacokinetics of acyclovir dipeptide ester prodrugs by microdialysis in rabbits

In vivo corneal absorption of the dipeptide prodrugs of acyclovir (ACV) was evaluated using microdialysis in rabbits. A corneal well was placed on the cornea of the anesthetized New Zealand White rabbits with implanted linear probes into the aqueous humor. Two hundred microliters of a 1% solution of L-valine-ACV (VACV), glycine-valine-ACV (GVACV), valine-valine-ACV (VVACV), and valine-tyrosine-ACV (VYACV) was placed in the corneal well and was allowed to diffuse for a period of 2 h, following which the drug solution was aspirated and well removed. Samples were collected every 20 min throughout the infusion and postinfusion phases and were analyzed by HPLC to obtain the aqueous humor concentrations. Absorption rate constants of all the compounds were found to be lower than the elimination rate constants. GVACV exhibited highest absorption rate (ka) compared with other prodrugs, but all the prodrugs showed similar terminal elimination rate (lambda(z)). The time of maximum absorption (Tmax) of ACV after administration of VACV and the dipeptide prodrugs did not vary significantly (p < 0.05). GVACV exhibited the highest concentration (Cmax) and area under curve (AUC) upon absorption (p < 0.05) compared to VACV, VVACV, and VYACV. Dipeptide prodrugs of ACV were absorbed through the cornea at similar rates but to varying extents. The dipeptide prodrug GVACV owing to its enhanced absorption of ACV seems to be a promising candidate for the treatment of ocular HSV infections.     

In-vitro hydrolysis, permeability, and ocular uptake of prodrugs of N-[4-(benzoylamino)phenylsulfonyl]glycine, a novel aldose reductase inhibitor

To enhance the ocular uptake of N-[4-(benzoylamino)phenylsulfonyl]glycine (BAPSG), two ester (methyl and isopropyl) prodrugs were synthesized and evaluated for their stability in various buffers (pH 1-9), hydrolysis in rabbit ocular tissues (cornea, conjunctiva, iris-ciliary body, lens, aqueous humor, and vitreous humor), transport across cornea and conjunctiva, and in-vivo uptake following topical administration. Over the pH range of 1-9, the rate constants for degradation ranged from 5.67 to 218.9 x 10(-3) h(-1) for the methyl ester and from 3.14 to 4.45 x 10(-3) h(-1) for the isopropyl ester. At all pH conditions, the isopropyl ester was more stable when compared with the methyl ester. A change in buffer concentration at pH 7.4 did not influence the stability of the prodrugs. The prodrugs were rapidly hydrolysed in the tissue homogenates, with the rate constants for hydrolysis ranging from 1.98 to 7.2x 10(-3) min(-1) for the methyl ester and 3.32 to 6.53 x 10(-3) min(-1) for the isopropyl ester. The in-vitro permeability of the methyl ester was less than the parent drug across cornea and conjunctiva. Isopropyl ester levels were not detectable in the receiver chamber even at the end of the 4-h transport study. Following topical administration of BAPSG and the two prodrugs at a dose of 60 microg/eye, the lowest levels were seen in vitreous humor for parent compound and its methyl ester. In general, the tissue uptake of methyl ester was less than BAPSG. Isopropyl ester levels were below detection limits in all the ocular tissues. Lipophilic ester prodrugs of BAPSG showed good aqueous solution stability in tissue homogenates. However, these prodrugs lacking the free carboxylate anion exhibited reduced in-vitro permeability and in-vivo uptake, suggesting the importance of free carboxylate anion in the delivery of BAPSG.