Mucoadhesive thermogel platform for treating anterior ocular conditions.

A platform mucoadhesive and thermogelling eyedrop was developed for application to the inferior fornix for the treatment of various anterior segment ocular conditions. The poly(n-isopropylacrylamide) polymers (pNIPAAm), containing a disulfide bridging monomer, were crosslinked with chitosan to yield a modifiable, mucoadhesive, and natively degradable thermogelling system. Three different conjugates were studied including a small molecule for treating dry eye, an adhesion peptide for modeling delivery of peptides/proteins to the anterior eye, and a material property modifier to create gels with different rheologic characteristics. Based on the conjugate used, different material properties such as solution viscosity and lower critical solution temperature (LCST) were produced. In addition to releasing the conjugates through disulfide bridging with ocular mucin, the thermogels were shown to deliver atropine, with 70%-90% being released over 24-h, depending on the formulation studied. The results illustrate that these materials can deliver multiple therapeutic payloads at one time and release them through various mechanisms. Finally, the safety and tolerability of the thermogels was demonstrated both in vitro and in vivo. The gels were instilled into the inferior fornix of rabbits and were shown to not produce any adverse effects over 4 days. These materials were demonstrated to be highly tunable, creating a platform that could be easily modified to deliver various therapeutic agents to treat a multitude of ocular diseases and have the potential to be an alternative to conventional eyedrops.

Thermo-responsive and mucoadhesive gels for the treatment of cystinosis.

Mucoadhesive thermogels were developed by crosslinking poly(n-isopropylacrylamide) based polymers with chitosan and incorporating disulfide bridges, capable of releasing cysteamine upon interaction with mucin, for the treatment of cystinosis. Through crosslinking with chitosan and incorporating varying concentrations of the disulfide monomer into the polymer backbone, the extent of how mucoadhesive the developed thermogels were could be controlled. Through disulfide bridging with mucin, the thermogels released 6 to 10 µg of the conjugate model 2-mercaptopyridine over five days. Utilizing chitosan as the crosslinker, the developed thermogels were shown to degrade to a statistically higher extent following incubation with lysozyme, the highest concentration tear enzyme, by gravimetric and rheologic analysis. The developed thermogels were extensively tested in vivo utilizing a rat model in which materials were applied directly to the corneal surface and a rabbit model in which thermogels were applied to the inferior fornix. With the developed models, there was no adverse reactions or visual discomfort incurred following application of the thermogels. It has been demonstrated that the thermogels produced can be applied to the inferior fornix and release the stable conjugated payload over several days. The developed thermogel was designed to improve upon the current clinical treatment options for ocular cystinosis which are acidic topical formulations that require reapplication multiple times a day.

Tunable release of ophthalmic therapeutics from injectable, resorbable, thermoresponsive copolymer scaffolds.

The sustained release of ophthalmic therapeutics to the posterior segment of the eye is a challenge. Injectable polymer materials have the potential to reduce injection frequency by providing long term therapeutic delivery. Copolymers with varying N-isopropylacrylamide, acrylamide (AAm), acrylic acid N-hydroxysuccinimide, and (r)-α-acryloyloxy-ß,ß-dimethyl-γ-butyrolactone (DBA) were synthesized by RAFT polymerization to develop injectable, resorbable, and thermoresponsive copolymer scaffolds. Upon injection into physiological conditions, these copolymers undergo a temperature induced gelation to form a drug releasing scaffold. Modification of the copolymer's AAm/DBA ratio and molecular weight afforded significant and precise control over the scaffold's physical properties and subsequent drug release profile. Hydrolytic DBA ring-opening enables redissolution of the copolymers for clearance from the body. Precise control over the drug release profile from these copolymer scaffolds by simple alteration of composition and molecular weight provides an efficient method to customize the minimally invasive delivery of therapeutics to the posterior segment of the eye. © 2015 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 105B: 53-62, 2017.

Phenylboronic-Acid-Based Polymeric Micelles for Mucoadhesive Anterior Segment Ocular Drug Delivery.

Topical drug delivery to the front of the eye is extremely inefficient due to effective natural protection mechanisms such as precorneal tear turnover and the relative impermeability of the cornea and sclera tissues. This causes low ocular drug bioavailability, requiring large frequent doses that result in high systemic exposure and side effects. Mucoadhesive drug delivery systems have the potential to improve topical drug delivery by increasing pharmaceutical bioavailability on the anterior eye surface. We report the synthesis and characterization of a series of poly(L-lactide)-b-poly(methacrylic acid-co-3-acrylamidophenylboronic acid) block copolymer micelles for use as mucoadhesive drug delivery vehicles. Micelle properties, drug release rates, and mucoadhesion were shown to depend on phenylboronic acid content. The micelles showed low in vitro cytotoxicity against human corneal epithelial cells and undetectable acute in vivo ocular irritation in Sprague-Dawley rats, suggesting good biocompatibility with the corneal surface. The micelles show the potential to significantly improve the bioavailability of topically applied ophthalmic drugs, which could reduce dosage, frequency of administration, and unintentional systemic exposure. This would greatly improve the delivery of the ocular drugs such as the potent immunosuppressive cyclosporine A used in the treatment of severe dry eye disease.

Development of injectable, resorbable drug-releasing copolymer scaffolds for minimally invasive sustained ophthalmic therapeutics.

Copolymers based on N-isopropylacrylamide (NIPAAm), acrylic acid N-hydroxysuccinimide (NAS) and varying concentrations of acrylic acid (AA) and acryloyloxy dimethyl-γ-butyrolactone (DBA) were synthesized to create thermoresponsive, resorbable copolymers for minimally invasive drug and/or cell delivery to the posterior segment of the eye to combat retinal degenerative diseases. Increasing DBA content was found to decrease both copolymer water content and lower critical solution temperature. The incorporation of NAS provided an amine-reactive site, which can be exploited for facile conjugation of bioactive agents. Proton nuclear magnetic resonance analysis revealed the onset of hydrolysis-dependent opening of the DBA lactone ring, which successfully eradicated copolymer phase transition properties and should allow the gelled polymer to re-hydrate, enter systemic circulation and be cleared from the body without the production of degradation byproducts. Hydrolytic ring opening occurs slowly, with over 85% copolymer mass remaining after 130 days of incubation in 37°C phosphate buffered saline. These slow-degrading copolymers are hypothesized to be ideal delivery vehicles to provide minimally invasive, sustained, localized release of pharmaceuticals within the posterior segment of the eye to combat retinal degenerative diseases.