We report the preparation of loadable ultrathin, multilayered polyelectrolyte/dendrimer films by the sequential electrostatic deposition of negatively charged poly(styrenesulfonate) (PSS) and a positively charged fourth generation poly(amidoamine) dendrimer (4G PAMAM). Multilayers were first constructed on planar supports to examine their layer-by-layer growth. Quartz crystal microbalance (QCM) measurements showed regular growth for each layer deposited, while UV−vis spectrophotometry revealed an adsorption−desorption trend to film formation, with partial PSS removal upon deposition of 4G PAMAM. PSS/4G PAMAM films were subsequently constructed on spherical latex colloids. Fluorescence spectroscopy showed that the films, when exposed to dye-containing solutions, acted as nanoreservoirs, sequestering the charged molecules from solution due to the presence of the oppositely charged dendrimer. Release of the entrapped dye molecules was subsequently achieved by concentration-dependent diffusion in isotonic saline solutions, illustrating the potential of the dendrimer-based films as systems for the uptake and release of various compounds.
Hollow microcapsules comprised of poly(styrenesulfonate) (PSS) and a fourth generation poly(amidoamine) dendrimer (4G PAMAM) were prepared by depositing PSS/4G PAMAM multilayers on melamine formaldehyde (MF) colloid particles by the layer-by-layer self-assembly technique and subsequently dissolving the templated cores. The PSS/4G PAMAM layers were unstable toward the core removal procedure (pH approximately 1), resulting in a low yield of intact hollow capsules (<10% for 3.5 microm diameter MF templates). Stretching of the multilayer film due to core swelling during MF core dissolution leads to partial or complete destruction of capsules, giving discrete PSS-4G PAMAM complexes. Yields were increased by increasing inter- and intramolecular attractive forces between the PSS chains in the capsules through electrostatic, hydrophobic, and a combination of these interactions. The yields, however, were practically unaffected by enhancing such effects between dendrimer molecules. Transmission electron microscopy and scanning force microscopy measurements show no deformation for 3.5 microm capsules stabilized through the various interactions stated above. Further, capsules were filled with low molecular weight dextran sulfate and subsequently loaded with a model, therapeutically active molecule, doxorubicin hydrochloride (DOX). Release of DOX from the capsules was also studied to highlight the drug delivery potential of the dendrimer-based microcapsules.
This work includes investigation on solubility enhancement of indomethacin (IND) in the presence of poly(amidoamine) (PAMAM) dendrimers and passive targeting of the PAMAM/IND complex so formed to the inflamed regions in an animal model. The complex formation was confirmed by infrared and (1)H nuclear magnetic resonance spectroscopy methods. Solubility of IND in aqueous G4-PAMAM followed Higuchi's A(N) curve depending on pH of the solubilizing medium. The solubility was decreased upon addition of dendrimer to the IND saturated solution at various pH, indicating aggregation behavior of the PAMAM/IND complex and conforming to the Higuchi's A(N) solubility profile. The in vitro release of IND from the PAMAM/IND complex through a cellophane membrane, from a Franz diffusion cell, showed 79 +/- 3.2% drug release in 24 h. The drug release was further retarded in the presence of human serum albumin (HSA) suggesting the significance of complex HSA binding in altering in vivo behavior of the complex. Intravenous administration of the PAMAM/IND complex formulation in rats showed a two-compartment pharmacokinetic profile. Enhanced effective IND concentrations in the inflamed regions were obtained for the prolonged time period with the PAMAM/IND complex compared to the free drug in arthritic rats indicating preferred accumulation of IND to the inflamed region. The targeting efficiency of PAMAM/IND complex was 2.29 times higher compared to free drug. In contrast to the previous investigations, two interesting findings reported here are: (a) solubility behavior of IND in G4-PAMAM dendrimer deviates from linearity with increasing concentrations of dendrimer at acidic to neutral pH values and (b) inspite of lymphatic drainage, retention of PAMAM/IND complexes occurs at the inflammatory site.
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