Benefits of Tafluprost and Timolol Fixed-Dose Combination for the Treatment of Glaucoma Are Confirmed by Studies on Experimental Animal Models.

PURPOSE: To assess the usefulness of 0.0015% tafluprost and 0.5% timolol fixed-dose combination (TT-FDC) for glaucoma, the ocular hypotensive effect of TT-FDC and concentration of tafluprost and timolol in the aqueous humor were compared with those of the concomitant administration of 0.0015% tafluprost and 0.5% timolol with or without an appropriate administration interval. METHODS: The ocular hypotensive effect was assessed by intraocular pressure (IOP) measurement in cynomolgus monkeys. Drug penetration into the aqueous humor was estimated by the concentrations of tafluprost acid (active metabolic form of tafluprost) and timolol, which were measured using liquid chromatography-tandem mass spectrometry after administration of tafluprost and timolol to Sprague Dawley rats. RESULTS: The ocular hypotensive effect of TT-FDC was equivalent to that of the concomitant administration of timolol and tafluprost at a more than 5-min interval in monkeys. However, the ocular hypotensive effect of the concomitant administration of timolol and tafluprost without an interval (-2.8 ± 0.2 mmHg at peak IOP reduction) was significantly weaker compared with TT-FDC (-4.3 ± 0.5 mmHg at peak IOP reduction, P = 0.008 vs. concomitant administration of timolol and tafluprost) in monkeys. The aqueous humor concentration of the second administered drug (tafluprost) was not affected by the dosing conditions, whereas the concentration of the first instilled drug (timolol) without the interval was lower than that with a 5-min interval (1,200 ng · h/mL vs. 1,890 ng · h/mL in AUC0-4) in rats. CONCLUSION: TT-FDC demonstrates a clear benefit by preventing efficacy loss without an appropriate interval in experimental animal models.

Ocular hypotensive efficacy of Src-family tyrosine kinase inhibitors via different cellular actions from Rock inhibitors.

We investigated the effects of Src-family tyrosine kinase (SFK) inhibitors on intraocular pressure (IOP) and trabecular meshwork (TM) cells. The SFK inhibitors, PP2, PP1, and damnacanthal, significantly lowered IOP from baseline following intracameral injection in ocular normotensive rabbits, and PP2 decreased trans-epithelial electrical resistance (TEER) of TM cell layers in a dose-dependent manner ranging from 0.1 µM to 100 µM. The maximal efficacy of PP2 on TEER was a reduction to 71.7% relative to the vehicle-treated group at 100 µM. PP2 decreased the adhesion of TM cells to culture surfaces either uncoated with specific ECM proteins dose-dependently or coated with extracellular matrix proteins such as laminin I, fibronectin, collagen type I and basement membrane extraction. Tyrosine phosphorylation of focal adhesion kinase and p130(cas) was decreased by PP2. On the other hand, major changes in actin staining of TM cells were not able to be detected after PP2 treatment, although quantitative analysis showed that PP2 induced some morphological changes which were in the different direction to those caused by Y-27632, a Rock inhibitor. Y-27632 at 10 µM increased the permeability of TM cell layers, but did not induce changes in the adhesion of TM cells. These results suggest that SFK inhibitors lower IOP, at least partly, by acting on TM cells in a manner that is distinct from Rock inhibitors.

[Effects of ocular hypotensive agents on the circadian rhythm in intraocular pressure in rabbits as measured by telemetry].

PURPOSE: To establish a telemetry system for measuring intraocular pressure (IOP) in rabbits and to evaluate the effects of topical application of ocular hypotensive agents on the circadian rhythm of IOP. SUBJECTS AND METHODS: We developed a telemetry system in rabbits housed under a 12-hour light-dark cycle (light and dark phases: 7:00-19:00, 19:00-7:00, respectively). The IOP resulting from a single topical application of ocular hypotensive agents was measured by telemetry during the light phase and the dark phase. RESULTS: The values measured by the telemetry were positively correlated to the value of the anterior chamber pressure measured by a transducer in range from 5 to 50 mmHg (r = 0.987). A single topical application of timolol maleate (0.5%), dorzolamide hydrochloride (1%), and dipivefrine hydrochloride (0.1%) caused no significant reduction in IOP in the light phase, but they did in the dark phase. A single topical application of bunazosin hydrochloride (0.01% or 0.1%) had significant ocular hypotensive effects in both phases. CONCLUSION: These findings indicate that the different effects of ocular hypotensive agents on circadian rhythms of IOP can be measured by the telemetry. Telemetry may be useful for evaluation of ocular hypotensive agents and the circadian rhythm of IOP.

Protective effects of timolol against the neuronal damage induced by glutamate and ischemia in the rat retina.

The purpose of this study was to determine whether timolol, an ocular hypotensive drug, has retinal neuroprotective effects in experimental in vitro and in vivo models. For in vitro studies, we used retinal neuron cultures from rat embryos and purified retinal ganglion cells (RGCs) from newborn rats. In the former, neurotoxicity was induced using 1 mM glutamate and cell viability was assessed. In RGCs, neurotoxicity was induced using 25 microM glutamate for 3 days and cell viability was assessed. For the in vivo study, we used a rat model of retinal ischemic injury induced by elevating intraocular pressure (IOP) by raising the hydrostatic pressure. The retinal damage was evaluated by counting the number of cells in the ganglion cell layer (GCL) and by examining the a- and b-waves in the electroretinogram (ERG). For the intraocular distribution study, 0.5% [3H]timolol was topically applied to rat eyes, and these were enucleated after various intervals and divided into parts. Each part was combusted and the radioactivity measured. Timolol (0.1 and 1 microM) markedly reduced the glutamate-induced neuronal cells in retinal neuron cultures and in RGCs. After ischemic-reperfusion, both the number of cells in the GCL and a- and b-waves in the ERG decreased; however, topically applied 0.5% timolol reduced these effects. Topically applied 0.5% timolol was detected at a concentration of approximately 1 microg/g wet tissue in retina-choroid at 30 min after its application. In conclusion, timolol was effective against retinal neuron damage both in vitro and in vivo. Furthermore, topically applied timolol reached the retina-choroid. These findings suggest that timolol has a direct neuroprotective effect against retinal damage.

Brain-derived neurotrophic factor inhibits changes in soma-size of retinal ganglion cells following optic nerve axotomy in rats.

To determine if optic nerve axotomy affects the cell soma size of retinal ganglion cells and to establish whether such quantitative analysis is useful as a new way of evaluating retinal ganglion cell damage, we measured the changes in both the number and soma size of retinal ganglion cells after optic nerve axotomy in rats. Retinal ganglion cells were retrogradely labeled by fluoro-gold injection into the superior colliculus, and the soma size was measured using image-analysis software. We detected a decrease in the proportion of large-sized retinal ganglion cells that was significant at 3, 5 and 7 days after the axotomy, and an increased proportion of small-sized ones that was significant at 5 and 7 days after the axotomy, indicating that retinal ganglion cells shrank following axotomy, that there was a shift away from the largest category of retinal ganglion cells towards the smallest category. On days 3 and 5 post-axotomy, there was no significant change in the proportion of medium-sized retinal ganglion cells. Intravitreal injection of brain-derived neurotrophic factor one hour before the axotomy significant inhibited the increase in the proportion of small-sized retinal ganglion cells otherwise seen at 3 days after the axotomy. These results may suggest that larger retinal ganglion cells are more sensitive to optic nerve axotomy than small- and medium-sized ones, and that a quantitative analysis of soma size is a useful way of detecting retinal ganglion cell damage in the early phase after axotomy.