Abstract
On account of the rigid structure of alginate chains, the oxidation-reductive amination reaction was performed to synthesize the reductive amination of oxidized alginate derivative (RAOA) that was systematically characterized for the development of pharmaceutical formulations. The molecular structure and self-assembly behavior of the resultant RAOA was evaluated by an FT-IR spectrometer, a 1H NMR spectrometer, X-ray diffraction (XRD), thermal gravimetric analysis (TGA), a fluorescence spectrophotometer, rheology, a transmission electron microscope (TEM) and dynamic light scattering (DLS). In addition, the loading and in vitro release of ibuprofen for the RAOA microcapsules prepared by the high-speed shearing method, and the cytotoxicity of the RAOA microcapsules against the murine macrophage RAW264.7 cell were also studied. The experimental results indicated that the hydrophobic octylamine was successfully grafted onto the alginate backbone through the oxidation-reductive amination reaction, which destroyed the intramolecular hydrogen bond of the raw sodium alginate (SA), thereby enhancing its molecular flexibility to achieve the self-assembly performance of RAOA. Consequently, the synthesized RAOA displayed good amphiphilic properties with a critical aggregation concentration (CAC) of 0.43 g/L in NaCl solution, which was significantly lower than that of SA, and formed regular self-assembled micelles with an average hydrodynamic diameter of 277 nm (PDI = 0.19) and a zeta potential of about −69.8 mV. Meanwhile, the drug-loaded RAOA microcapsules had a relatively high encapsulation efficiency (EE) of 87.6 % and good sustained-release properties in comparison to the drug-loaded SA aggregates, indicating the good affinity of RAOA to hydrophobic ibuprofen. The swelling and degradation of RAOA microcapsules and the diffusion of the loaded drug jointly controlled the release rate of ibuprofen. Moreover, it also displayed low cytotoxicity against the RAW264.7 cell, similar to the SA aggregates. In view of the excellent advantages of RAOA, it is expected to become the ideal candidate for hydrophobic drug delivery in the biomedical field.
Highlights
Alginate, mainly originated from seaweeds, is a kind of natural anionic heteropolysaccharide
The resultant alginate derivative grafted with hydrophobic side groups seems to be an amphipathic polymeric surfactant which is able to realize the loading of hydrophobic drugs through its self-assembly behavior [19]
The research goal of the present study was to systematically characterize the alginate derivative that is synthesized via the oxidation-reductive amination reaction with the aim of developing the pharmaceutical formulations
Summary
Mainly originated from seaweeds, is a kind of natural anionic heteropolysaccharide. As a result of their excellent advantages, such as non-toxicity, immunogenicity, low cost, good biodegradation and biocompatibility, alginate and its derivatives can be used in food, cosmetics, drug delivery vehicles, tissue engineering scaffolds, and wound dressings [4,5,6,7]. Raw alginate is very hydrophilic due to the presence of abundant carboxyl and hydroxyl groups on its molecular chain [10], which leads to poor compatibility with hydrophobic drug molecules including ibuprofen, tanshinone IIA, ciprofloxacin, triclosan, etc. The hydrophilic alginate has unpredictable and uncontrollable degradation kinetics and extensive water uptake properties, resulting in its poor stability in biological buffers, which significantly limits its practical application as a hydrophobic pharmaceutical carrier [15,16,17]. The resultant alginate derivative grafted with hydrophobic side groups seems to be an amphipathic polymeric surfactant which is able to realize the loading of hydrophobic drugs through its self-assembly behavior [19]
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