Chitosomes as drug delivery systems for C-phycocyanin: preparation and characterization.

The aim of this work was to investigate chitosomes, i.e. liposomes coated by a polyelectrolyte complex between chitosan (CH) and xantan gum (XG), as potential delivery system for oral administration of the protein C-phycocyanin. To this purpose several CH-XG-microcomplexes were prepared in aqueous lactic acid at different chitosan-xanthan gum percent ratios and rheological properties of the microcomplexes were studied to analyse the contribution of chitosan and xanthan gum in the reaction of microcomplexation. After establishing the best microcomplexes, chitosomes were prepared by coating C-phycocyanin loaded liposomes with the CH-XG hydrogels using spray-drying or freeze-drying. The chitosomes were characterized in terms of morphology, size distribution, zeta potential, swelling properties, drug release, and mucoadhesive properties. Rheological studies showed the influence of xanthan gum in the microcomplex properties. Moreover, obtained results demonstrated the effects of formulation and process variables on particle size, drug content, swelling, drug release, and especially on the mucoadhesiveness of C-PC chitosomes of CH-XG. In particular, chitosomes prepared by spray-drying technique using CH-XG in 0.5/8.0 (w/w) ratio showed a regular surface and a drug release characteristic for a Fickian diffusion of the active ingredient. The in vitro mucoadhesive study revealed that the spray-drying method is advantageous to prepare C-phycocyanin loaded chitosomes with excellent mucoadhesive properties for colonic drug delivery.

Phycocyanin liposomes for topical anti-inflammatory activity: in-vitro in-vivo studies.

OBJECTIVES: The aim of this work was to investigate the anti-inflammatory activity of C-phycocyanin (C-PC) on skin inflammation after topical administration and the influence of liposomal delivery on its pharmacokinetic properties. METHODS: Liposomes of different size and structure were prepared with different techniques using soy phosphatidylcholine and cholesterol. Vesicular dispersions were characterised by transmission electron microscopy, optical and fluorescence microscopy for vesicle formation and morphology, dynamic laser light scattering for size distribution, and Zetasizer for zeta-potential. C-PC skin penetration and permeation experiments were performed in vitro using vertical diffusion Franz cells and human skin treated with either free or liposomal drug dispersed in a Carbopol gel. KEY FINDINGS: The protein was mainly localised in the stratum corneum, while no permeation of C-PC through the whole skin thickness was detected. Two percent C-PC-encapsulating liposomes showed the best drug accumulation in the stratum corneum and the whole skin, higher than that of the corresponding free 2% C-PC gel. Moreover, skin deposition of liposomal C-PC was dose dependent since skin accumulation values increased as the C-PC concentration in liposomes increased. The topical anti-inflammatory activity of samples was evaluated in vivo as inhibition of croton oil-induced or arachidonic acid-induced ear oedema in rats. CONCLUSIONS: The results showed that C-PC can be successfully used as an anti-inflammatory drug and that liposomal encapsulation is effective in improving its anti-inflammatory activity.

Nuclear import of DNA in digitonin-permeabilized cells.

DNA can enter intact mammalian nuclei with varying degrees of efficiency in both transfected and microinjected cells, yet very little is known about the mechanism by which it crosses the nuclear membrane. Nucleocytoplasmic transport of fluorescently labeled DNA was studied using a digitonin-permeabilized cell system. DNA accumulated in the nucleus with a punctate staining pattern in over 80% of the permeabilized HeLa cells. Nuclear localization of the labeled DNA was energy dependent and occurred through the nuclear pore, but did not require the addition of soluble cytoplasmic protein factors necessary for protein import.

Phycocyanin: laser activation, cytotoxic effects, and uptake in human atherosclerotic plaque.

Phycocyanin is a phycobiliprotein with peak absorption at 620 nm. The laser activation, cytotoxic effects, and uptake into atherosclerotic plaque of phycocyanin was studied. Optimal activation was produced by argon dye laser at 0.5 W and a total energy dose of 300 J/cm2 at 620 nm and 650 nm, irradiated through blood with a hematocrit of 8%. Activation was evidenced by reduction of optical density by 0.3 units at 340 nm caused by oxidation of the reduced nicotinamide adenine dinucleotide phosphate (NADPH) in a buffered reaction solution containing 0.1 mg/ml of phycocyanin. Cytotoxicity was evaluated by measuring viability of mouse myeloma cells in culture after incubation with phycocyanin (0.25 mg/ml) and irradiated by 300 J/cm2 at 514 nm. After 72 hours post-treatment the cells showed 15% viability compared to 69% and 71% for control cells exposed to laser only or phycocyanin only, respectively. Atherosclerotic artery segments obtained within 5 hours postmortem were perfused with 0.1 mg/ml phycocyanin in oxygenated Krebs Ringer solution at 30 mm Hg for 5 minutes followed by washout with phycocyanin-free Krebs for 10 minutes. Artery sections examined histologically by light and fluorescence microscopy showed specific fluorescence localization within the plaque particularly at the elastic laminae and to a larger extent at the internal elastic lamina but not in the medial muscle layer. In conclusion, phycocyanin is a cytotoxic photosensitizer that exhibits specific binding to plaque and is activated at a wavelength minimally absorbed by blood. These properties suggest potential therapeutic use for plaque localization and regression.