51 research outputs found
Characterisation and Skin Distribution of Lecithin-Based Coenzyme Q10-Loaded Lipid Nanocapsules
The purpose of this study was to investigate the influence of the inner lipid ratio on the physicochemical properties and skin targeting of surfactant-free lecithin-based coenzyme Q10-loaded lipid nanocapsules (CoQ10-LNCs). The smaller particle size of CoQ10-LNCs was achieved by high pressure and a lower ratio of CoQ10/GTCC (Caprylic/capric triglyceride); however, the zeta potential of CoQ10-LNCs was above /â 60 mV/ with no distinct difference among them at different ratios of CoQ10/GTCC. Both the crystallisation point and the index decreased with the decreasing ratio of CoQ10/GTCC and smaller particle size; interestingly, the supercooled state of CoQ10-LNCs was observed at particle size below about 200 nm, as verified by differential scanning calorimetry (DSC) in one heatingâcooling cycle. The lecithin monolayer sphere structure of CoQ10-LNCs was investigated by cryogenic transmission electron microscopy (Cryo-TEM). The skin penetration results revealed that the distribution of Nile red-loaded CoQ10-LNCs depended on the ratio of inner CoQ10/GTCC; moreover, epidermal targeting and superficial dermal targeting were achieved by the CoQ10-LNCs application. The highest fluorescence response was observed at a ratio of inner CoQ10/GTCC of 1:1. These observations suggest that lecithin-based LNCs could be used as a promising topical delivery vehicle for lipophilic compounds
A quantitative systems pharmacology consortium approach to managing immunogenicity of therapeutic proteins
Immunogenicity is a major challenge in drug development and patient care. Currently, most efforts are dedicated to the elimination of the unwanted immune responses through Tâcell epitope prediction and protein engineering. However, because it is unlikely that this approach will lead to complete eradication of immunogenicity, we propose that quantitative systems pharmacology models should be developed to predict and manage immunogenicity. The potential impact of such a mechanistic modelâbased approach is precedented by applications of physiologicallyâbased pharmacokinetics
Oligo(ethylene glycol)-Based Thermosensitive Dendrimers and Their Tumor Accumulation and Penetration
Surface functionalisation regulates polyamidoamine dendrimer toxicity on bloodâbrain barrier cells and the modulation of key inflammatory receptors on microglia
AbstractDendrimers are branched polymers with spherical morphology. Their tuneable chemistry and surface modification make them valuable nanomaterials for biomedical applications. In view of possible dendrimer uses as brain-aimed nanocarriers, the authors studied amine- and lipid-functionalised (G4) polyamidoamine (PAMAM) biocompatibility with cell population forming the bloodâbrain barrier (BBB). Both amine-PAMAM and lipid-PAMAM dendrimers were able to enter endothelial and primary neural cells. However, only amine-PAMAM damaged cell membranes in a dose-dependent manner. Transmission electron microscopy evidenced the ability of dendrimers to precipitate salts and serum components present in culture medium that slightly increased toxicity of the amine-PAMAM. Amine- and lipid-PAMAM were both able to cross the BBB and differently induced CD11b and CCR2 overexpression on primary CX3CR1-GFP murine microglia in vitro. These data emphasise the role of dendrimer surface functionalisation in toxicity and neural immune cell activation, raising concerns about possible neuroinflammatory reactions
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