Polymeric materials formed via layer-by-layer (LbL) assembly have promise for use as drug delivery vehicles. These multilayered materials, both as capsules and thin fi lms, can encapsulate a high payload of toxic or sensitive drugs, and can be readily engineered and functionalized with specific properties. This review highlights important and recent studies that advance the use of LbL-assembled materials as therapeutic devices. It also seeks to identify areas that require additional investigation for future development of the field. A variety of drug-loading methods and delivery routes are discussed. The biological barriers to successful delivery are identified, and possible solutions to these problems are discussed. Finally, state-of-the-art degradation and cargo release mechanisms are also presented.
We report a general and facile method for the encapsulation of DNA in nanoengineered, degradable polymer microcapsules. Single-stranded (ss), linear double-stranded (ds), and plasmid DNA were encapsulated into disulfide-cross-linked poly(methacrylic acid) (PMA) capsules. The encapsulation procedure involves four steps: adsorption of DNA onto amine-functionalized silica (SiO(2)(+)) particles; sequential deposition of thiolated PMA (PMA (SH)) and poly(vinylpyrrolidone) to form multilayers; cross-linking of the thiol groups of the PMA (SH) in the multilayers into disulfide linkages; and removal of the sacrificial SiO(2)(+) particles. Multilayer growth was dependent on the surface coverage of DNA on the SiO(2)(+) particles, with stable capsules formed from particles with up to 50% DNA surface coverage. The encapsulation strategy applies to nucleic acids with varied size and conformation and allows DNA to be concentrated over 100-fold from dilute solutions into monodisperse, uniformly loaded polymer capsules. The capsule loading can be controlled by the DNA:SiO(2)(+)particle ratio, and for 1 microm diameter capsules, loadings of approximately 1000 chains of 800 bp dsDNA and more than 10,000 chains of 20-mer ssDNA can be achieved. The encapsulated DNA was released and successfully used in polymerase chain reactions as both templates (linear dsDNA and plasmid DNA) and primer sequences (ssDNA), confirming the functionality and structural integrity of the encapsulated DNA. These DNA-loaded polymer microcapsules hold promise as delivery vehicles for gene therapy and diagnostic applications.
We present a thermodynamic study of the adsorption of lysozyme on a negatively charged core-shell microgel at pH 7.2. The carrier particles consist of a polystyrene core onto which a charged poly (N-isopropylacrylamide-co-acrylic acid) network is attached. Isothermal titration calorimetry (ITC) is used to investigate the temperature and salt dependence of lysozyme binding. Our ITC analysis unequivocally shows that the adsorption of lysozyme onto the charged gel is driven by entropy. The addition of salt strongly decreases the binding affinity, indicating significant electrostatic contributions to the adsorption process. However, at high salt concentrations, substantial protein binding with unaltered entropies is still observed pointing to large contributions from hydrophobic interactions. Furthermore, the calorimetric analysis suggests that protonation of lysozyme takes place upon binding. This is directly shown by analysis of the enzymatic activity of adsorbed lysozyme. It was found that the activity is enhanced about $3.5 times, indicating that lysozyme has taken up approximately one proton when entering the gel. The entire set of data demonstrates that core-shell microgels present ''smart'' colloidal carriers for lysozyme that enhance its activity.
Engineered polymer capsules are finding widespread importance in the delivery of encapsulated toxic or fragile drugs. The effectiveness of polymer capsules as therapeutic delivery vehicles is often dependent on the degradation behavior of the capsules because it is often necessary to release the encapsulated drugs at specific times and in certain locations. Herein we investigate the parameters that govern the formation and degradation of a recently introduced new class of polymer hydrogel capsules based on disulfide cross-linked poly(methacrylic acid). We report a new and efficient method for the synthesis of thiol-functionalized poly(methacrylic acid) (PMA(SH)), the main component of the capsules. Polymeric capsules were synthesized by the layer-by-layer deposition of PMA(SH) and poly(vinylpyrrolidone) (PVPON) on silica particle templates, followed by cross-linking the PMA(SH) layers and removing PVPON and the template particles. The disulfide cross-links provided a redox-active trigger for degradation that was initiated by a cellular concentration of glutathione. We demonstrate that increasing the degree of PMA(SH) thiol modification affords direct control over the thickness of the polymer film and the degradation rate of the polymer capsules. Furthermore, the degradation rate of the PMA(SH) capsules was independent of film thickness, suggesting a bulk erosion process.
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