Influence of drug release rate on systemic timolol absorption from polymeric ocular inserts in the pigmented rabbit

There is an expectation that ocular inserts, regardless of the nature of the polymer, will faithfully reduce systemic drug absorption. This may not necessarily be so, however, since not all polymers would release drug at the same rate and to the same extent. The objective of the present study was to determine how drug release rate from various polymeric ocular inserts may influence systemic timolol absorption in the pigmented rabbit. The inserts tested were made of polyvinyl alcohol (PVA), hydroxypropylcellulose (HPC), or partial ethyl ester of poly(vinyl methyl ether/maleic anhydride) (PVMMA), approximately 89.4% w/w in all cases. Some polyvinyl alcohol inserts contained timolol in salt form with Carbopol 940 (PVA-C940), 8.6% w/w. The time course of timolol in plasma over 6 hr was monitored using reversed phase HPLC. While all inserts reduced the peak timolol concentration in plasma (C(max)), only the PVA and HPC inserts, which released timolol rapidly in vitro, reduced the extent of systemic timolol absorption (AUC). On the other hand, both PVA-C940 and PVMMA inserts, which released timolol relatively slowly in vitro, increased the extent of systemic timolol absorption. Moreover, the time at which peak timolol concentration was achieved in the plasma was much delayed, raising the possibility of delayed timolol absorption until discharge of the presumably viscous and/or mucoadhesive solutions of PVA-C940 and PVMMA inserts into the nasal cavity. It may be concluded that not all polymeric ocular inserts reduce systemic timolol absorption. Whether an insert would do so depends on the interplay of residence time in the conjunctival sac and rate of drug release from the insert

The design of contact lens based ocular drug delivery systems for single-day use:part (I) structural factors, surrogate ophthalmic dyes and passive diffusion studies

The poor retention and efficacy of instilled drops as a means of delivering drugs to the ophthalmic environment is well-recognised. The potential value of contact lenses as a means of ophthalmic drug delivery, and consequent improvement of pre-corneal retention is one obvious route to the development of a more effective ocular delivery system. Furthermore, the increasing availability and clinical use of daily disposable contact lenses provides the platform for the development of viable single-day use drug delivery devices based on existing materials and lenses. In order to provide a basis for the effective design of such devices, a systematic understanding of the factors affecting the interaction of individual drugs with the lens matrix is required. Because a large number of potential structural variables are involved, it is necessary to achieve some rationalisation of the parameters and physicochemical properties (such as molecular weight, charge, partition coefficients) that influence drug interactions. Ophthalmic dyes and structurally related compounds based on the same core structure were used to investigate these various factors and the way in which they can be used in concert to design effective release systems for structurally different drugs. Initial studies of passive diffusional release form a necessary precursor to the investigation of the features of the ocular environment that over-ride this simple behaviour. Commercially available contact lenses of differing structural classifications were used to study factors affecting the uptake of the surrogate actives and their release under 'passive' conditions. The interaction between active and lens material shows considerable and complex structure dependence, which is not simply related to equilibrium water content. The structure of the polymer matrix itself was found to have the dominant controlling influence on active uptake; hydrophobic interaction with the ophthalmic dye playing a major role