Researchers design new ocular insert to administer antioxidants in the eye
Reviewed by Emily Henderson, B.Sc.Oct 21 2020
Researchers from Valencia’s CEU Cardenal Herrera University have published their study on this new way to administer glutathione for the treatment of ocular diseases linked to oxidative stress in journal Pharmaceutics.
Due to their exposition to the sun and the oxygen of the air, eyes are especially susceptible to oxidative stress, which causes several ocular pathologies. One of the antioxidants that is most present in the eyes to fight this oxidative stress is glutathione, whose deficit is linked to several ophthalmologic diseases.
The research group of the CEU UCH of Valencia, headed by professor Alicia López Castellano and specialized in developing new pharmaceutic means for the administration of medicines in a transdermic or ophthalmic way, has designed a new ocular insert to administer antioxidants through the cornea and the sclera of the eye. Their study, published in international journal Pharmaceutics, analyses the benefits of this new method of administration compared to traditional ophthalmic drops.
As explained by CEU UCH professor María Sebastián, member of the research team, “the anatomic and physiologic structure of the eye represents, in itself, an important barrier for the administration of medicines. The amount of medicine that breaks through the cornea or sclera when using drops, gels or creams, is very limited, making it necessary to develop more efficient alternative methods.
This is why we have been working for several years on the development of bioadhesive ocular inserts to treat ocular diseases, increasing the time that the medicine remains in the eye, and so that it may be released gradually, thus penetrating the ocular tissues better.” Following their work on the administration of antibiotics through the cornea with this type of inserts, in this last study the team has tested the administration of an antioxidant, this time through the cornea and sclera, using the same type of inserts.
Ocular antioxidants, combined
As the CEU UCH researchers explain in the study, glutathione is the most available natural antioxidant in the eyes, and a lack of this substance is linked to pathologies of the retina, the human tissue that consumes the most oxygen: hence the need to be more protected against oxidative stress thanks to the production of glutathione.
The ability to generate this antioxidant decreases with age, which can favor the appearance of ocular pathologies such as diabetic retinopathy, glaucoma or macular degeneration linked to aging. The lack of glutathione is also associated to the appearance of cataracts and hereditary degenerative diseases, such as retinitis pigmentosa.
In this case, we have collaborated with the team headed at the CEU UCH by professor María Miranda, who had already studied the beneficial effect of glutathione to slow down the cellular death of the photoreceptors in an experimental model of this disease.”
María Sebastián, CEU UCH Professor
The insert as a new pharmacological method
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The study shows that the created ocular insert is able to release the antioxidant in the eye. One of the advantages of these inserts is that they can be applied less times than ophthalmic drops, as well as controlling the release of the medicine, providing a more comfortable administration for the patient. To design the best ophthalmic insert possible, the research team has studied the diffusion of glutathione through the cornea and sclera using a rabbit’s eye as an animal model. Furthermore, they have verified that glutathione does not cause an irritation of the ocular mucosa and that it can be stored preserving its properties for a month at 4ºC in the dark.
“We hope that in a very near future these new methods of administration with ocular inserts, in this case for antioxidants, reach the market and represent significative progress in the efficiency of treatments for ocular tissues,” conclude the authors of the study. Together with researchers María Sebastián, Alicia López and María Miranda, the team was also comprised by Adrián Alambiaga, Aracely Calatayud, Vicente Rodilla and Cristina Balaguer, all professors at the Faculty of Health Sciences at the CEU Cardenal Herrera University of Valencia.