Effect of loading on swelling-controlled drug release from hydrophobic polyelectrolyte gel beads

Phosphates-Containing Interpenetrating Polymer Networks (IPNs) Acting as Slow Release Fertilizer Hydrogels (SRFHs) Suitable for Agricultural Applications

Novel, phosphorus-containing slow release fertilizer hydrogels (SRFHs) composed of interpenetrating polymer networks (IPNs) with very good swelling and mechanical properties have been obtained and characterized. It was found that introducing organophosphorus polymer based on a commercially available monomer, 2-methacryloyloxyethyl phosphate (MEP), as the IPN’s first component network results in much better swelling properties than for a terpolymer with acrylic acid (AAc), 2-methacryloyloxyethyl phosphate (MEP) and bis[2-(methacryloyloxy)ethyl] phosphate (BMEP) when the same weight ratios of monomers are employed. The procedure described in this paper enables the introduction of much larger amounts of phosphorus into polymer structures without significant loss of water regain ability, which is crucial in the application of such materials in the agricultural field.

Contact lenses for antifungal ocular drug delivery: a review

INTRODUCTION

Fungal keratitis, a potentially blinding disease, has been difficult to treat due to the limited number of approved antifungal drugs and the taxing dosing regimen. Thus, the development of a contact lens (CL) as an antifungal drug delivery platform has the potential to improve the treatment of fungal keratitis. A CL can serve as a drug reservoir to continuously release drugs to the cornea, while limiting drug loss through tears, blinking, drainage and non-specific absorption.

AREAS COVERED

This review will provide a summary of currently available methods for delivering antifungal drugs from commercial and model CLs, including vitamin E coating, impregnated drug films, cyclodextrin-functionalized hydrogels, polyelectrolyte hydrogels and molecular imprinting. This review will also highlight some of the main factors that influence antifungal drug delivery with CLs.

EXPERT OPINION

Several novel CL materials have been developed, capable of extended drug release profiles with a wide range of antifungal drugs lasting from 8 h to as long as 21 days. However, there are factors, such as first-order release kinetics, effectiveness of continuous drug release, microbial resistance, ocular toxicity and potential complications from inserting a CL in an infected eye, that still need to be addressed before commercial applications can be realized.

pH Sensitive graft copolymers for zero order drug release: a mechanistic analysis

Aliphatic polyesters containing pendent unsaturation were synthesized by the polycondensation of a diol, dicarboxylic acid and glycidyl methacrylate. Grafting methacrylic acid (MAA) resulted in graft copolymers containing polyester backbone and MAA grafts. Depending on composition, the polymers swelled extensively and eroded or dissolved at near neutral pH but remained in collapsed state at acidic pH. Three representative drugs differing in solubility, viz., Diltiazem hydrochloride (DH), Indomethacin (IM) and Verapamil hydrochloride (VH) were released at constant rate from tablets made by compressing spray-dried microparticles. The release of DH at constant rate has been attributed to increase in diffusion coefficient of the drug from the swollen layer of matrix. The release of IM and VH at constant rate was governed by erosion and was enhanced in matrices which undergo dissolution. The release rate was enhanced with increasing MAA content and the frequency of grafts along the polyester backbone. Once a day dosage forms for drugs differing in solubility have been developed using a single polymer matrix which is easy to manufacture.

Noncross-Linked Copolymers of Dimethylaminoethyl Methacrylate and Methacrylic Acid as Oral Drug Carriers

The purpose of this study was to synthesize new water-soluble ampholytic copolymers consisting of tertiary amine and carboxylic acid pendent groups for oral drug carriers. The polymers were prepared with a 1:1 molar ratio of dimethylaminoethyl methacrylate and methacrylic acid by free radical polymerization. After polymerization, polymer rods were recovered, dissolved (or swollen) in de-ionized water, and freeze-dried before obtaining fine powders. Drug release experiments with various drugs, representing a variety of drug solubility and types of amine, were carried out with compressed tablets (total weight of 600 mg) containing a variety of basic drugs in pH's of 1.5 and 7. Surprisingly, zero-order release kinetics even from a tablet geometry has been obtained with drug loading ranging from 20-50%. Drug release in pH 7 maintains a zero-order rate up to 80-85% release after a slight initial burst, whereas in pH 1.5 one may not find the initial burst and zero-order kinetics is extended up to 90-95% release. Drug release becomes faster in pH 1.5 than pH 7 due to the faster rate of protonation of the tertiary amine in acidic conditions. The release of basic drugs in pH 1.5 is not significantly different even with varying solubility and types of amine (primary, secondary, and tertiary). However, different drug release profiles in pH 7 are observed with different types of amine and solubility.

Swelling and aspirin release study: cross-linked pH-sensitive vinyl acetate-co-acrylic acid (VAC-co-AA) hydrogels

The objective of this work was to develop new pH-sensitive hydrogels to deliver gastric mucosal irritating drugs to the lower part of the gastrointestinal tract. For this purpose, cross-linked vinyl acetate-co-acrylic acid (VAC-co-AA) hydrogels were synthesized by using N, N, methylene bisacrylamide (MBAAm) as a cross-linking agent. Different ratios of 90:10, 70:30, 50:50, 30:70, and 10:90 of VAC-co-AA were synthesized. All of the compositions were cross-linked using 0.15, 0.30, 0.45, and 0.60 mol percent MBAAm. Swelling and aspirin release were studied for 8 hour period. The drug release data were fitted into various kinetic models like the zero-order, first-order, Higuchi, and Peppas. Hydrogels were characterized by Fourier transform infrared spectroscopy and scanning electron microscopy. In addition to the above, these hydrogels were loaded with 2%, 8% and 14% w/v aspirin solutions, keeping the monomeric composition and degree of cross-linking constant. In conclusion, it can be said that aspirin can be successfully incorporated into cross-linked VAC/AA hydrogels and its swelling and drug release can be modulated by changing the mole fraction of the acid component in the gels.

Dependence of copolymer composition, swelling history, and drug concentration on the loading of diltiazem hydrochloride (DIL.HCl) into poly[(N-isopropylacrylamide)-co-(methacrylic acid)] hydrogels and its release behaviour from hydrogel slabs

The loading of an antihypertensive cationic drug, diltiazem hydrochloride (DIL.HCl), into poly(N-isopropylacrylamide) [P(N-iPAAm)], poly(methacrylic acid) [P(MAA)], and their poly[(N-isopropylacrylamide)-co-(methacrylic acid)] P[(N-iPAAm)-co-(MAA)] hydrogels as well as their release behaviour have been investigated. For this purpose, two series of hydrogels have been tested, one previously soaked under acidic pH (treated hydrogels) and the other from the synthesis and washed in deionized water (untreated hydrogels). For the drug loading, these two series of hydrogels have been soaked in drug solutions with different concentrations. DIL.HCl amounts loaded by the gels as well as swelling degrees as a function of both hydrogel composition and DL.HCl concentration in the loading solution have been analyzed. Due to the interactions among DIL.HCl and the MAA group, "untreated" enriched MAA copolymer hydrogels present the highest drug load and loading efficiency. A DIL.HCl concentration of 320 microm/mL has been employed to load copolymers for release experiments, because for this concentration, hydrogels reach relative high drug load with a still high efficiency of loading. Release has been tested in three media, namely, fresh water (Milli-Q grade, pH 7.0), 0.1 N hydrogen chloride (pH 1.2), and a phosphate buffer (pH 7.0). In general, release is lower in fresh water and acidic media than in phosphate buffer. To explain these results, the effect of temperature, medium, and composition on the pH and thermo sensitivity of the hydrogels as well as the diltiazem-polymer interactions have been taken into account.

Synthesis and characterization of surface-hydrophobic ion-exchange microspheres and the effect of coating on drug release rate

Biodegradable, dextran-based ion-exchange microspheres (IE-MS) have been used for localized delivery of anticancer drugs and chemosensitizers. Because of their hydrophilic nature, the IE-MS release their payload quickly. The purpose of this work was to develop an IE-MS system that could provide a broad range of release rates for in vitro and in vivo applications. Sulfopropylated dextran microspheres (SP C25 MS) were surface-modified by acylation. These hydrophobically modified sulfopropylated dextran microspheres (HM-MS) were further coated with the cationic acrylic polymer Eudragit RL100 (EU-MS). The changes in chemical composition after the surface modification and coating were characterized by X-ray photoelectron spectroscopy. The effects of the modification and coating on the surface hydrophobicity, equilibrium swelling, surface morphology, and drug loading capacity were investigated. The HM-MS showed little change in swelling and functionality, despite significantly increased affinity to oil and carbon content on the surface. The coated microspheres (EU-MS) exhibited a profoundly decreased swelling ratio, an even higher affinity to oil, a higher loading capacity, and a lower drug release rate. Through further coating of the EU-MS with different amounts of corn oil, the rate of drug release could be tailored to cover a relatively wide range. These results suggest that a versatile delivery system with various release profiles can be prepared by a combination of hydrophobic modification, polymer coating, and oil coating.

Bimodal release of theophylline from "seed-matrix" beads made of acrylic polymers

The purpose of this research was to design a "seed-matrix" structure for an in vitro bimodal theophylline release profile and to investigate the mechanism and kinetics of drug release as well as the influence of various factors on the properties of the theophylline-containing microspheres. "Seed" microspheres with high theophylline content were prepared from Eudragit L100 and Eudragit S100, copolymers of methyl methacrylate and methacrylic acid, by the solvent removal process. The seed-matrix beads were subsequently prepared by incorporation of the seed microspheres into Eudragit RL100, a copolymer of acrylic and methacrylic acid esters with a low content of quaternary ammonium group. Increasing the size of encapsulated drug particles and the rate of agitation during the preparation, or decreasing the amount of surfactants led to an increase in the size of the microspheres produced. Scanning electron microscopy revealed porous morphology of the microspheres. The release rate of theophylline was enhanced as the content of methacrylic acid in the copolymer increased and the size of the microspheres decreased. The kinetics of drug release from the microspheres was controlled by swelling at the early stage and by diffusion in the later stage. The drug was released from the matrix of the seed-matrix beads at pH 1.2 and from both the matrix and the seeds at pH 6.8. A bimodal release profile of theophylline was obtained from the seed-matrix beads made of acrylic polymers.

In vitro investigation of ionic polysaccharide microspheres for simultaneous delivery of chemosensitizer and antineoplastic agent to multidrug-resistant cells

Insufficient intratumoral concentration of therapeutic agents and multidrug resistance are major factors responsible for failure of treatment of solid tumors. Simultaneous delivery of chemosensitizing and antineoplastic agents by microspheres could lead to enhanced chemotherapy of multidrug-resistant (MDR) tumors. Ionic polysaccharide microspheres derived from dextran were used to load chemosensitizers (e.g., verapamil) and anticancer drugs such as vinblastine. High drug loading was achieved for both a single agent and dual agents. The equilibrium drug loading was dependent on the ratio of the microspheres (MS) to the drug, as well as the relative affinity of the agents to the MS in the case of dual agents. The drug release from drug-MS involved hydration and swelling of the MS in addition to ion exchange. The effectiveness of MS-delivered chemosensitizers in the reversal of drug resistance was evaluated by measuring the uptake of [3H]vinblastine by MDR cells (CHRC5). The concomitant delivery of verapamil with vinblastine by the MS led to a 6-7-fold increase in the uptake of vinblastine, a level similar to the uptake obtained with free drug solutions. The results suggest that the antineoplastic and chemosensitizing agents were released effectively from the MS and the bioactivity of the chemosensitizer was preserved during the process.

Water-soluble polycations as oral drug carriers (tablets)

New bioerodible materials that are noncross-linked and water-soluble copolymers of trimethylaminoethyl methacrylate chloride (TMAEMC) and methyl methacrylate (MMA) were synthesized and then bound to anionic drugs (diclofenac Na and Na sulfathiazote) to form water-insoluble complexes. These drug-polymer complexes release the bound drugs only in ionic media. Compressed tablets were prepared from these anion-exchange resins, and their release profiles follow zero-order kinetics (n > 0.89, where n is the release exponent). The effects of various excipients (dextrose, lactose, and microcrystalline cellulose) were studied, and the polymer composition was found to influence the duration of drug release. It was also found that the release of anionic drugs from drug-PTMAEM/MMA is linear and that it is possible to "tailor-make" their release kinetics by suitably altering the copolymer composition. When a high content of a water-insoluble excipient (i.e., microcrystalline cellulose) was used to fabricate the tablets, the release kinetics deviated from linearity (n = 0.73). In general, release kinetics were well described by a dissociation/erosion mechanism. Drug loading could be increased by increasing the exchange capacity of the polymer (i.e., by increasing the content of the quaternary amine monomer).

Constant-rate drug release from novel anionic gel beads with transient composite structure

A new anionic composite bead system with a transient membrane-matrix structure, capable of prolonged constant-rate drug release, has been developed from suspension-polymerized poly(methyl methacrylate-co-methacrylic acid) (PMMA/MAA). These composite beads have a thin PMMA/MAA surface layer and a core consisting of the sodium salt form of the polymer (PMMA/MANa). The high loading (> 20%) of a model drug (oxprenolol HCl) that is achievable in this system from a loading solution concentration as low as 0.5% suggests the formation of a drug-polymer complex in the form of an ionic salt in the core. The release of oxprenolol from such composite beads shows an initial burst effect followed by an extended constant-rate region before leveling off. Apparently, the surface PMMA/MAA layer functions as a transient rate-controlling membrane before it is completely ionized. Because the ionization process is slow, the rate-controlling characteristics of the surface layer and the resulting constant rate of drug release are both sustained for an extended period. The unique feature of the present system is not only its high drug loading capability, but also the transient nature of the rate-controlling surface layer, which is completely ionized towards the latter part of the drug release, thus avoiding prolonged tailing of drug release that is normally associated with permanent membrane-matrix systems.