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Abstract

Purpose:

Development of a novel formulation for intravitreal administration, in which the endothelin_A receptor antagonist BQ123 is incorporated in a biodegradable and injectable polymer drug delivery system, poly(2-hydroxyoctanoic acid), aiming at a prolonged retinal vasodilator response.

Methods:

BQ123 was incorporated in poly(2-hydroxyoctanoic acid), leading to an easily injectable, homogenous mixture. In vitro release profiles were obtained in porcine vitreous humor (n=6). The ex vivo biocompatibility was studied by placing the formulation in contact with porcine retinal tissues and performing histology. In a pilot in vivo study, the change in retinal vessel diameter of mini pigs (n=2) was followed over 3 h after an intravitreal injection of the formulation, as well as the release of BQ123 from the polymer system for approximately 7 days (n=6).

Results:

In vitro, a constant release profile was obtained, releasing approximately 91% of BQ123 within 7 days. Histology on the porcine retinal tissues showed good ex vivo biocompatibility. In vivo, a vasodilative response was observed, with a retinal vessel diameter increase from 14% after 15 min, for approximately 39% after 3 h. At t=3 h, the BQ123 concentration in the vitreous humor was 0.7±0.2 μg/mL, followed by 1.5±1.0 and 1.1±0.8 μg/mL after 3 and 7 days, respectively. 39.9%±6.0% of BQ123 was still present in the polymer depot at t=7 days.

Conclusions:

The results show that an intravitreal injection of this drug delivery system leads to a prolonged vasodilative response and a BQ123 release over 7 days, suggesting its therapeutic potential in the management of retinal ischemic conditions.

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Development of an Intravitreal Peptide (BQ123) Sustained Release System Based on Poly(2-Hydroxyoctanoic Acid) Aiming at a Retinal Vasodilator Response

Abstract

Abstract

Purpose:

Methods:

Results:

Conclusions:

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References

Supplementary Material