Study on the drug release property of cholesteryl end-functionalized poly(epsilon-caprolactone) microspheres

End-functionalized poly/oligo(epsilon-caprolactone)s were synthesized through the ring-opening polymerization of epsilon-caprolactone initiated by cholesterol with a hydroxyl group. Using the end-functionalized poly/oligo(epsilon-caprolactone)s with different molecular weights, the microsphere drug delivery systems were fabricated using a convenient melting-emulsion method. The drug release properties of microspheres were investigated with the presence of an enzyme, Pseudomonas cepacia lipase, as well as in the absence of the enzyme. The release profiles can be fitted nicely by the classical empirical exponential expression. Under the hydrolytic condition, the drug release is mainly controlled by Fickian diffusion, and the high molecular weight of the matrix results in a slower drug release rate. Under the enzymatic condition, the drug release is dominated by combined degradation and diffusion mechanism, and the high molecular weight sample exhibits a faster release rate that is mainly caused by the higher degradation rate of the sample with lower cholesteryl moiety content.     

Semi-interpenetrating network of poly(ethylene glycol) and poly(D,L-lactide) for the controlled delivery of protein drugs

We have prepared a semi-interpenetrating network (IPN) of poly(ethylene glycol) dimethacrylate (PEGDMA) with entrapped poly(D,L-lactide) (PLA) using photochemical techniques. These IPNs were developed for the controlled delivery of protein drugs such as growth factors. The PEG component draws water into the network, forming a hydrogel within the PLA matrix, controlling and facilitating release of the protein drug, while the PLA component both strengthens the PEG hydrogel and enhances the degradation and elimination of the network after the protein drug is released. The rate and extent of swelling and the resultant protein release kinetics could be controlled by varying the PEG/PLA ratio and total PLA content. These IPNs were prepared using a biocompatible benzyl benzoate/benzyl alcohol solvent system that yields a uniform, fine dispersion of the protein throughout the PEG/PLA IPN matrix. IPNs composed of high molecular mass PLA and lower PEG/PLA ratios exhibited lower equilibrium swelling ratios. The release of bovine serum albumin (BSA), a model protein, from these IPNs was characterized by a large initial burst, regardless of the PEG/PLA ratio, due to the entrapment of residual solvent within the network. Microparticles of the PEG/PLA IPNs were also prepared using a modified Prolease strategy. Residual solvent removal was significantly enhanced using this process. The microparticles also exhibited a significant reduction in the initial burst release of protein. Mixtures of different compositions of PEG/PLA microparticles should be useful for the delivery of a variety of protein drugs with different release kinetics from any tissue-engineering matrix.     

Injectable, in situ forming poly(propylene fumarate)-based ocular drug delivery systems

This study sought to develop an injectable formulation for long-term ocular delivery of fluocinolone acetonide (FA) by dissolving the anti-inflammatory drug and the biodegradable polymer poly(propylene fumarate) (PPF) in the biocompatible, water-miscible, organic solvent N-methyl-2-pyrrolidone (NMP). Upon injection of the solution into an aqueous environment, a FA-loaded PPF matrix is precipitated in situ through the diffusion/extraction of NMP into surrounding aqueous fluids. Fabrication of the matrices and in vitro release studies were performed in phosphate buffered saline at 37 degrees C. Drug loadings up to 5% were achieved. High performance liquid chromatography was employed to determine the released amount of FA. The effects of drug loading, PPF content of the injectable formulation, and additional photo-crosslinking of the matrix surface were investigated. Overall, FA release was sustained in vitro over up to 400 days. After an initial burst release of 22 to 68% of initial FA loading, controlled drug release driven by diffusion and bulk erosion was observed. Drug release rates in a therapeutic range were demonstrated. Release kinetics were found to be dependent on drug loading, formulation PPF content, and extent of surface crosslinking. The results suggest that injectable, in situ formed PPF matrices are promising candidates for the formulation of long-term, controlled delivery devices for intraocular drug delivery.     

Subcutaneous polymeric matrix system p(HEMA-BGA) for controlled release of an anticancer drug (5-fluorouracil). II: Release kinetics

A subcutaneous polymeric drug delivery system, which consists of a polymeric matrix of poly(hydroxyethyl methacrylate-bisglycol acrylate), was developed. 5-fluorouracil was used as the model anticancer drug. Polymer-drug beads with a diameter of 3 mm were prepared by low-temperature radiation polymerization. In order to modify the release rate, polymeric beads with different composition, drug loading and crosslinking density were obtained. The kinetics of drug release were described by the expression Mt/M infinity = ktn. The diffusional release exponent 'n', which was calculated from the release curves, indicated that the mechanism of drug release from the polymeric matrix is due to the anomalous (non-Fickian) type of diffusion.     

Development of rationally designed affinity-based drug delivery systems

Many drug delivery systems have been developed to provide sustained release of proteins in vivo. However, the ability to predict and control the rate of release from delivery systems is still a challenge. Toward this goal, we screened a random drug-binding peptide library (12 amino acids) to identify peptides of varying (i.e. low, moderate, and high) affinity for a model polysaccharide drug (heparin). Peptide domains of varying affinity for heparin identified from the library were synthesized using standard solid phase chemistry. A mathematical model of drug release from a biomaterial scaffold containing drug-binding peptide domains identified from the library was developed. This model describes the binding kinetics of drugs to the peptides, the diffusion of free drug, and the kinetics of enzymatic matrix degradation. The effect of the ratio of binding sites to drug, the effect of varying the binding kinetics and the rate of enzymatic matrix degradation on the rate of drug release was examined. The in vitro release of the model drug from scaffold containing the peptide drug-binding domains was measured. The ability of this system to deliver and modulate the biological activity of protein drugs was also assessed using nerve growth factor (NGF) in a chick dorsal root ganglia (DRG) neurite extension model. These studies demonstrate that our rational approach to drug delivery system design can be used to control drug release from tissue-engineered scaffolds and may be useful for promoting tissue regeneration in vivo.     

A theoretical model to characterize the drug release behavior of drug-eluting stents with durable polymer matrix coating

The time-dependent local drug delivery from drug-eluting stents (DES) plays a critical role in reducing restenosis in intravascular stenting. To better understand the basic mechanism of drug release for certain polymer-drug-coated DES platforms, a cylindrical diffusion model was applied successfully to quantitatively describe the experimental drug release data of Dynalink-E in vitro and in vivo. The results showed that the profiles of Dynalink-E everolimus release could be controlled by such characteristic parameters as coating thickness and diffusion coefficient. The model could be used to quantitatively characterize the drug release profiles and IVIV correlations.     

存储混合型缓释体系动力学模型

本文针对目前存储混合型缓释体系的释放动力学模型假设多、预测精度低等问题 ,探讨该体系的释放机理 ,并建立动力学模型以期为实际剂型研制提供理论依据。通过将化学工程的传递原理应用于药物控制释放领域 ,分析了药物在膜内的扩散过程 ,建立了非稳态条件下当药物初始装填量大于其在聚合物膜内饱和溶解度时的存储混合型缓释体系的释放动力学模型 ,并采用巯嘌呤和乙烯 /乙烯醇共聚物 (摩尔比为 :乙烯 /乙烯醇 =44 / 5 6 )组成的存储混合型缓释体系对模型进行实验验证。实验结果表明 ,模型的预测值与实验值吻合较好 (相对偏差 <5 % )。同时讨论了药物初始装填量、空白膜厚等因素对释放速率的影响。     

Experimental Studies and Modeling of Drug Release from a Tunable Affinity-Based Drug Delivery Platform

An affinity-based drug delivery platform for controlling drug release is analyzed by a combination of experimental studies and mathematical modeling. This platform has the ability to form selective interactions between a therapeutic agent and host matrix that yields advantages over systems that employ nonselective methods. The incorporation of molecular interactions in drug delivery can increase the therapeutic lifetime of drug delivery implants and limit the need for multiple implants in treatment of chronic illnesses. To analyze this complex system for rational design of drug delivery implants, we developed a mechanistic mathematical model to quantify the molecular events and processes. With a β-cyclodextrin hydrogel host matrix, defined release rates were obtained using a fluorescent model drug. The key processes were the complexation between the drug and cyclodextrin and diffusion of the drug in the hydrogel. Optimal estimates of the model parameters were obtained by minimizing the difference between model simulation and experimentally measured drug release kinetics. Model simulations could predict the drug release dynamics under a wide range of experimental conditions.     

Solid drug particles encapsulated bead-on-string nanofibers: the control of bead number and its corresponding release profile

Abstract

Bead-on-string nanofibers are explored as potential carriers of micro-level solid drug particles in recent years in drug release and tissue engineering. The special alternating distribution of nanoscale fiber and micro beads satisfied the fully encapsulation of particle drugs and the corresponding sustained release. Antibiotic drug tetracycline hydrochloride (TCH) was used as solid model drug particles. The present study fabricated poly (lactic-co-glycolic acid) (PLG A) bead-on-string nanofibers with different TCH loading rates for the controlled drug delivery. Bead number (BN), as one of the crucial factors that determine the encapsulation capability, was successfully controlled by tailoring the electrospinning parameters: voltage, flow rate and distance. The in vitro release experiment analyze by UV-Visible light spectrophotometer indicated that the bead-on-string nanofiber with more BN would increase the total release quantity of TCH. The drug released from bead-on-string nanofibers was mainly driven by classical Fickian diffusion. PLGA bead-on-string nanofibers suggest the potential as promising substrate for solid drug particles delivery applications.     

Biodegradable fumarate-based drug-delivery systems for ophthalmic applications

The function of a photocrosslinked poly(propylene fumarate) (PPF)/poly(N-vinyl pyrrolidone) (PVP) matrix for the sustained release of three ophthalmic model drugs, acetazolamide (AZ), dichlorphenamide (DP), and timolol maleate (TM), was investigated. The drugs differ in molecular weight and degree of dissociation in aqueous environments; both are parameters that significantly influence drug diffusivity. AZ, DP, and TM-loaded cylindrical rods (10 mm length, 0.6 mm diameter) were fabricated by photoinduced cross-copolymerization of PPF and N-vinyl pyrrolidone (NVP) in molds. The released amounts of AZ, DP, TM, and NVP were determined by high-performance liquid chromatography (HPLC). The effects of drug properties and loading on the release kinetics were investigated. The in vitro release of AZ, DP, and TM was well sustained from the polymer matrices over a period of approximately 210, 270, and 250 days, respectively. The release kinetics correlated with the HPLC retention profiles of the different drugs. Following a small initial burst release (<10%), a dual modality release controlled by diffusion and bulk erosion was found for all drugs. Drug release rates of up to 4 microg/day were reached. Matrix drug loading generally affected the extent of the burst release, release kinetics, as well as the matrix water content and matrix degradation that were determined gravimetrically. Microcomputed tomography was used to image structural and dimensional changes of the devices. A preliminary rabbit implantation study revealed promising ocular biocompatibility of drug-free PPF/PVP matrices. All results indicate the potential of photocrosslinked PPF-based matrices as polymeric carriers for long-term ophthalmic drug delivery.     

Sustained-release delivery systems of triclosan for treatment of Streptococcus mutans biofilm

Dental diseases are chronic infections caused by oral bacteria harboring the dental biofilm. Local sustained-release delivery systems prolong the duration of a drug in the oral cavity, thus enhancing its therapeutic potential, while reducing its side effects. Triclosan is an agent that was found to have an antibacterial effect against oral bacteria. However, its substantivity in the oral cavity is low, resulting in reduced antibacterial efficiency. The purpose of this study was to develop a local sustained release device containing triclosan and to test its antibacterial efficacy on Streptococcus mutans biofilm. Our results show that we can formulate an ethylcellulose-based, nondegradable, sustained-release device in which 80% of the loaded triclosan is released over a 10-day period. The release rate of triclosan corresponded to the Higuchi's planar homogenous diffusion release model (r2 = 0.998). A degradable local sustained-release delivery based on a methacrylate ester matrix was also developed for a faster release rate of triclosan. The release kinetics in those types of sustained-release delivery systems was erosion control. The local sustained-release delivery system significantly affected the viability of S. mutans in biofilm compared to placebo as was tested by confocal laser scanning microscopy. Our in vitro results show that triclosan can be incorporated into degradable or nondegradable sustained-release drug delivery systems. The release of triclosan from the local sustained-release delivery system can be controlled, thus extending its antibacterial properties.     

A vanadium/aspirin complex controlled release using a poly(beta-propiolactone) film. Effects on osteosarcoma cells.

A delivery system for vanadium was developed using poly(beta-propiolactone) (PbetaPL) films. The release kinetics of a complex of vanadium (IV) with aspirin (VOAspi) was evaluated with films prepared from polymers of different molecular weights, as well as with variable drug load. A sustained release of vanadium over 7 days was achieved. The drug release kinetics depends on contributions from two factors: (a) diffusion of the drug; and (b) erosion of the PbetaPL film. The experimental data at an early stage of release were fitted with a diffusion model, which allowed determination of the diffusion coefficient of the drug. VOAspi does not show strong interaction with the polymer, as demonstrated by the low apparent partition coefficient (approximately 10(-2)). UMR106 osteosarcoma cells were used as a model to evaluate the anticarcinogenic effects of the VOAspi released from the PbetaPPL film. VOAspi-PbetaPL film inhibited cell proliferation in a dose-response manner and induced formation of approximately half of the thiobarbituric acid reactive substances (TBARS), an index of lipid peroxidation. compared to that with free VOAspi in solution. The unloaded PbetaPL film did not generate cytotoxicity, as evaluated by cell growth and TBARS. Thus, the polymer-embedded VOAspi retained the antiproliferative effects showing lower cytotoxicity than the free drug. Results with VOAspi-PbetaPL films suggest that this delivery system may have promising biomedical and therapeutic applications.     

Biodegradable poly(vinyl alcohol)/polyoxalate electrospun nanofibers for hydrogen peroxide-triggered drug release

Release of drugs in a controlled and sustainable manner is of great interest for treating some inflammatory diseases, drug delivery, and cosmetics. In this work, we demonstrated the control release of a drug from composite nanofibers mediated by hydrogen peroxide. Composite nanofibers of polyvinyl alcohol (PVA)/polyoxalate (PVA/POX NFs) blended at various weight ratios were successfully prepared by electrospinning. Rhodamine B (RB) was used as a model of drug and was initially loaded into the POX portion. The morphology of NFs was characterized using scanning electron microscopy (SEM). The functional groups presented in the NFs were characterized using IR spectroscopy. In vitro release behavior and cell toxicity of nanofibers were also investigated using the MTT assay. The results indicated that POX content had a significant effect on the size and release profiles of nanofibers. Microstructure analysis revealed that sizes of PVA/POX NFs increased with increasing POX content, ranging from 214 to 422 nm. Release profiles of RB at 37 °C were non-linear and showed different release mechanisms. The mechanism of drug release depended on the chemical composition of the NFs. RB release from the NFs with highest POX content was caused by the degradation of the nanofiber matrix, whereas the RB release in lower POX content NFs was caused by diffusion. The NFs with POX showed a loss of structural integrity in the presence of hydrogen peroxide as seen using SEM. The MTT assay showed that composite nanofibers had minimal cytotoxicity. We anticipate that nanofibrous PVA/POX can potentially be used to target numerous inflammatory diseases that overproduce hydrogen peroxide and may become a potential candidate for use as a local drug delivery vehicle.     

Polyurethane elastomer with PEO-PTMO-PEO soft segment for sustained release of drugs

Blood-compatible segmented polyurethanes and polyurethaneureas were evaluated as drug delivery matrices using crystal violet and benzethonium chloride as model drugs. These polymers were synthesized from ABA-type triblock copolyether as a prepolymer, where A stands for poly(ethylene oxide) and B for poly(tetramethylene oxide). Microphase separation was observed in segmented polyurethaneureas, including drug-doped films. Crystal violet dissolved more in the hard segment domain than in the soft segment matrix, whereas benzethonium chloride was easily dissolved in the soft segment matrix. The drug release behaviours from these films were analysed by the exponent relation Mt/M infinity = ktn, where k and n are constants and Mt/M infinity is the fraction of drug released until time, t. The constant k grew with increasing poly(ethylene oxide) content in the prepolymer, i.e. increased swelling. The constant n was found to be close to 0.5 in many samples, which suggests the release of drug from these polymers is explained by the Fickian diffusion model. However, the mechanism became non-Fickian with increased swelling of the devices.     

Chitosan coated alginate beads containing poly(N-isopropylacrylamide) for dual-stimuli-responsive drug release

Chitosan coated alginate beads containing poly(N-isopropylacrylamide) (PNIPAAM), were prepared to be used as a controlled pH/temperature sensitive drug delivery system with improved encapsulation efficiency and delayed release rate. The studied beads were characterized by differential scanning calorimetry, scanning electron microscopy, and Fourier transform infrared spectroscopy. Water uptake and release studies using indomethacin as a model drug were also performed. The drug loading efficiency of the beads with the polyelectrolyte complex coating is significantly higher (84%) than that of the uncoated ones (74%). The equilibrium swelling of the developed materials was found to be pH- and thermo- responsive. For all the conditions it was found that the release profile was slower for the coated beads, indicating that the polyelectrolyte complex coating could slow down the release rate effectively. These results suggest that the studied smart system has potential to be used as an effective pH/temperature sustainable delivery system for biomedical applications.     

Release of propranolol and diclofenac from low Mw DL-poly(lactic acid)

The controlled release of two drugs, i.e. the sodium salt of diclofenac and propranolol was studied, by using low molecular weight D,L-Poly(lactic acid) as a matrix. Tablets of the above polymer containing those drugs were immersed into buffers with various pH values and delivery was recorded as a function of time, via UV-spectroscopy. The results showed that the polymer is appropriate for such biomedical applications, as generally, it ensures complete drug delivery within 45-60 days, which is acceptable for most cases. On the other hand, the release rate depends on many parameters including the interactions among drug, matrix and the surrounding liquid, which adds complexity to the process and requires careful investigation for proper design of a controlled release system.     

Controlled release of rhodium (II) carboxylates and their association complexes with cyclodextrins from hydroxyapatite matrix

Preparation and characterization of a controlled release system of rhodium (II) citrate, acetate. propionate, butyrate and their inclusion or association compounds with cyclodextrin (CD) are described. The porous hydroxyapatite (HA) was characterized by X-ray powder pattern diffraction, FTIR and solid state 31P NMR. Scanning electron microscopy and gas adsorption analysis (BET) were also performed. Release profiles of rhodium (II) carboxylates and their inclusion or association compounds from HA matrix were obtained at different drug loadings (5% and 10%). These were reasonably consistent with a diffusion model. This analysis, mainly using rhodium (II) citrate and butyrate, showed that the strategy of using CDs with a HA matrix may offer a useful new method for the controlled release of these compounds, and hence an alternative strategy for the controlled release of chemotherapeutic agents containing toxic metals. This may be a valuable new technique for localized anti-tumour chemotherapy that minimizes the side effects of such agents.     

Modeling vancomycin release kinetics from microporous calcium phosphate ceramics comparing static and dynamic immersion conditions

The release kinetics of vancomycin from calcium phosphate dihydrate (brushite) matrices and polymer/brushite composites were compared using different fluid replacement regimes, a regular replacement (static conditions) and a continuous flow technique (dynamic conditions). The use of a constantly refreshed flowing resulted in a faster drug release due to a constantly high diffusion gradient between drug loaded matrix and the eluting medium. Drug release was modeled using the Weibull, Peppas and Higuchi equations. The results showed that drug liberation was diffusion controlled for the ceramics matrices, whereas ceramics/polymer composites led to a mixed diffusion and degradation controlled release mechanism. The continuous flow technique was for these materials responsible for a faster release due to an accelerated polymer degradation rate compared with the regular fluid replacement technique.     

Functionalized bridged silsesquioxane-based nanostructured microspheres: performance as novel drug-delivery devices in bone tissue-related applications

Two kinds of functionalized nanostructured hybrid microspheres, based on the bridged silsesquioxane family, were synthesized by employing the sol-gel method via self-assembly of two different organic-inorganic bridged monomers. The architecture reached at molecular level allowed the incorporation of acetylsalicylic acid (ASA) as an anti-inflammatory model drug. The ASA-functionalized microspheres were characterized as delivery devices in simulated body fluid (SBF). The release behaviors of the synthesized microspheres (Fickian or anomalous diffusion mechanisms) were shown to be dependent on the chemical nature of the bridged monomers employed to synthesize the hybrid materials. The functionalized microspheres were proposed as delivery systems into calcium phosphate cements (CPCs), in order to slow down the characteristic drug-delivery kinetics of this kind of bone tissue-related materials. The incorporation of the new functionalized microparticles into the CPCs represented a viable methodology to modify the ASA-release kinetics in comparison to a conventional CPC containing the drug dispersed into the solid phase. The ASA-delivery profiles obtained from the microsphere-loaded CPCs showed that 40-60% of drug can be released after 2 weeks of testing in SBF. The inclusion of the microspheres into the CPC matrices allowed modification of the release profiles through a mechanism that involved two stages: (1) the diffusion of the drug through the organic-inorganic matrix of the microspheres (according to a Fickian or anomalous diffusion, depending on the nanostructuring) and (2) the subsequent diffusion of the drug through the ceramic matrix of the hardened cements. The release behavior of the composite cements was shown to be dependent on the nanostructuring of the hybrid microspheres, which can be selectively tailored by choosing the desired chemical structure of the bridged precursors employed in the sol-gel synthesis. The obtained results demonstrated the ability of this new class of functionalized hybrid microdevices as delivery systems into calcium phosphate materials with potential bone tissue-related drug-delivery applications.