The aerobic nitrogen-fixing cyanobacterium, Cyanothece sp. BH68K produces non-mucoid variants defective in exopolysaccharide (EPS) production at a high frequency. The EPS-producing wild-type colonies (EPS(+)) have a characteristic smooth and shiny appearance which allows them to be easily distinguished from the EPS(-) variants. When grown on agar plates lacking a source of combined nitrogen, the EPS(-) variants exhibited a yellow phenotype typical of nitrogen starvation. These EPS(-) variants showed varying degrees of reversion back to the EPS(+) phenotype. After reversion, they exhibited normal diazotrophic growth on agar plates. Alcian blue and ruthenium red staining indicated that the EPS is an acidic polysaccharide, which is present as a loose network around the cell, and which can be completely removed by low speed centrifugation. The accumulation of EPS takes place mainly during the stationary phase. All EPS(-) variants failed to produce any EPS. Analysis of growth of wild-type and EPS(-) variants revealed that EPS production is beneficial for diazotrophic growth on solid medium, but not in liquid medium. In addition, EPS phenotypic alteration may have some advantage in the dispersal of cells from one place to another in the natural environment.
High drug resistance, poor water solubility, short half-life, and low local drug concentration are obstacles for successful delivery of chemotherapeutic drugs for lung cancer. A new method involving the use of nanoparticles (NPs) for pulmonary delivery is proposed. However, use of NPs is limited by the particle size range for pulmonary drug delivery considering that NPs cannot be deposited directly into the lungs. NPs polymerized into microspheres (polymeric microspheres, PMs) will result in suitable particle sizes and retain the advantages of nanodrugs after redispersion when applied in pulmonary delivery. We report the development of novel NPs in the form of PMs loaded with paclitaxel (PTX) and quercetin (QUE) double drugs based on the synthesis of oleic acid-conjugated chitosan (OA-CTS) for pulmonary delivery. This approach is aimed toward prolonging PTX retention time in the presence of QUE and bypassing P-glycoprotein drug efflux pumps. NPs loaded with PTX or QUE were prepared with 11% substitution degree using OA-CTS as the carrier by ionic cross-linking method, which NPs loaded with PTX or QUE were used in the preparation of PMs by spray-drying. The diameters of the PMs ranged from 1 to 5 μm which had uniform size range. Scanning electron microscopy showed that PMs were polymers formed by a large number of NPs and readily redispersed (after redispersion, size of NPs ranged between 250 and 350 nm) in water within 1 h. PMs displayed slow-release characteristics at pH 4.5 and 7.4. The in vivo pharmacokinetic and biodistribution studies suggested that PMs exhibit prolonged circulation time and a markedly high accumulation in the lung. The obtained results indicate that PMs can serve as a promising pulmonary delivery system for combined pharmacotherapy using hydrophobic anticancer drugs.
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