A Radiolabeling Method for Precise Quantification of Polymers.

Radiolabeling a protein, molecule, or polymer can provide accurate and precise quantification in biochemistry, biomaterials, pharmacology, and drug delivery research. Herein, we describe a method to 125I label two different polymers for precise quantification in different applications. The surfaces of model contact lenses were modified with phenylboronic acid to bind and release the natural polymer, hyaluronic acid (HA); HA uptake and release were quantified by radiolabeling. In the second example, the in vivo distribution of a mucoadhesive micelle composed of the block copolymer of poly(lactide)-b-poly(methacrylic acid-co-acrylamidophenylboronic acid) was investigated. The presence of phenyl boronic acid groups (PBA), which bind to mucosal surfaces, was proposed to improve the retention of the micelle. 125I labeling of polymers was examined for quantification of microgram amounts of HA present on a contact lens or to evaluate the enhanced retention of PBA micelles on mucosal surfaces in vivo. The introduction of phenol groups onto the polymers allowed for the labeling. HA was modified with phenol groups through a coupling reaction of its carboxylic acid with hydroxybenzylamine. Phenol functional block copolymer micelles with and without PBA were synthesized by including N-(4-hydroxyphenethyl)acrylamide during polymerization. The phenol groups of HA and the block copolymers were labeled with 125I using a modified ICl labeling method. 125I labeling enabled quantification of HA loading and release including the effect of varying amounts of PBA on the contact lens surfaces. Micelles made from 125I-labeled block copolymers with and without PBA were administered intranasally to Brown Norway rats. The animals were sacrificed either immediately after or 4 h after their last nasal instillation, and the nasopharyngeal tissues were removed and quantified. Radioactivity measurements demonstrated that the presence of the PBA mucosal binding groups led to approximately four times higher retention. The HA and block copolymer 125I labeling presented in this article demonstrates the utility of the method for quantification and tracking of microgram quantities of polymers in diverse applications.

PEG-containing siloxane materials by metal-free click-chemistry for ocular drug delivery applications.

Metal-free click-chemistry can be used to create silicone hydrogels for ocular drug delivery applications, imparting the benefits of silicones without catalyst contamination. Previous work has demonstrated the capacity for these materials to significantly reduce protein adsorption. Building upon this success, the current work examines and optimizes different materials in terms of their protein adsorption and drug release capabilities. Specifically, incorporating lower molecular weight poly-ethylene glycol (PEG) is better able to reduce protein adsorption. However, with higher molecular weight PEG, the materials exhibit excellent water content and better drug release profiles. The lower molecular weight PEG is also able to deliver the drug over a period in excess of four months, with the amount of crosslinking having the greatest impact on the amount of drug release. Overall, these materials show great promise for ocular applications.

Atropine and Roscovitine Release from Model Silicone Hydrogels.

PURPOSE: Drug delivery to the anterior eye has a low compliance and results in significant drug losses. In pediatric patients, eye diseases such as myopia and retinoblastoma can potentially be treated pharmacologically, but the risk associated with high drug concentrations coupled with the need for regular dosing limits their effectiveness. The current study examined the feasibility of atropine and roscovitine delivery from model silicone hydrogel materials which could potentially be used to treat myopia and retinoblastoma, respectively. METHODS: Model silicone hydrogel materials that comprised TRIS and DMA were prepared with the drug incorporated during synthesis. Various materials properties, with and without incorporated drug, were investigated including water uptake, water contact angle, and light transmission. Drug release was evaluated under sink conditions into phosphate buffered saline. RESULTS: The results demonstrate that up to 2 wt% of the drugs can be incorporated into model silicone hydrogel materials without adversely affecting critical materials properties such as water uptake, light transmission, and surface hydrophilicity. Equilibrium water content ranged from 15 to 32% and transmission exceeded 89% for materials with at least 70% DMA. Extended release exceeding 14 days was possible with both drugs, with the total amount of drug released from the materials ranging from 16% to over 76%. Although a burst effect was noted, this was thought to be due to surface-bound drug, and therefore storage in an appropriate packaging solution could be used to overcome this if desired. CONCLUSIONS: Silicone hydrogel materials have the potential to deliver drugs for over 2 weeks without compromising lens properties. This could potentially overcome the need for regular drop instillation and allow for the maintenance of drug concentration in the tear film over the period of wear. This represents a potential option for treating a host of ophthalmic disorders in children including myopia and retinoblastoma.

PNIPAAm-grafted-collagen as an injectable, in situ gelling, bioactive cell delivery scaffold.

We synthesized two thermoresponsive, bioactive cell scaffolds by decorating the backbone of type I bovine collagen with linear chains of poly(N-isopropylacrylamide) (PNIPAAm), with the ultimate aim of providing facile delivery via injection and support of retinal pigment epithelial (RPE) cells into the back of the eye for the treatment of retinal degenerative diseases. Both scaffolds displayed rapid, subphysiological phase transition temperatures and were capable of noninvasively delivering a liquid suspension of cells that gels in situ forming a cell-loaded scaffold, theoretically isolating treatment to the injection site. RPE cells demonstrated excellent viability when cultured with the scaffolds, and expulsion of cells arising from temperature-induced PNIPAAm chain collapse was overcome by incorporating a room-temperature incubation period prior to scaffold phase transition. These results indicate the potential of using PNIPAAm-grafted-collagen as a vehicle for the delivery of therapeutic cells to the subretinal space.

Responding to change: thermo- and photo-responsive polymers as unique biomaterials.

Responsive polymer systems that react to thermal and light stimuli have been a focus in the biomaterials literature because they have the potential to be less invasive than currently available materials and may perform well in the in vivo environment. Natural and synthetic polymer systems created to exhibit a temperature-sensitive phase transition lead to in situ forming hydrogels that can be degradable or non-degradable. These systems typically yield physical gels whose properties can be manipulated to accommodate specific applications while requiring no additional solvents or cross-linkers. Photo-responsive isomerization, dimerization, degradation, and triggered processes that are reversible and irreversible may be used to create unique gel, micelle, liposome, and surface-modified polymer systems. Unique wavelengths induce photo-chemical reactions of polymer-bound chromophores to alter the bulk properties of polymer systems. The properties of both thermo- and photo-responsive polymer systems may be taken advantage of to control drug delivery, protein binding, and tissue scaffold architectures. Systems that respond to both thermo- and photo-stimuli will also be discussed because their multi-responsive properties hold the potential to create unique biomaterials.