473 resultados para ZNSE MICROSPHERES


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Organosilica microspheres synthesised via a novel surfactant-free emulsion-based method show applicability towards optical encoding, solid-phase synthesis and high-throughput screening of bound oligonucleotide and peptide sequences.

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The purpose of this study was to evaluate the effect of cyclosporine (CyA)-cyclodextrin (CD) complex incorporated within PLGA inicrospheres on microsphere characteristics, with particular emphasis on drug release kinetics. For this purpose, microspheres encapsulated with CyA and those loaded by CyA-CD complex were prepared by solvent evaporation and multiple emulsification solvent evaporation methods, respectively. Morphology, size, encapsulation efficiency and drug release pattern from microspheres were evaluated. Also, physicochemical properties of drug inside microspheres were characterized by differential scanning calorimetry (DSC) and infrared spectroscopy (IR) studies. Scanning electron microscopy (SEM) studies showed that microspheres encapsulated with CyA had islands on the microsphere surface but the islands were not seen on the surface of microspheres loaded by complex. Size range varied from 1 to 25 mu m for CyA encapsulated microspheres and 1 to 50 mu m for complex loaded microspheres. The release of CyA was biphasic with an initial more rapid release phase followed by a slower phase but drug release was twice as fast for complex loaded microspheres. IR studies did not indicate any chemical interaction between the components of microspheres and DSC thermograms revealed that CyA was present either in its amorphous state in microspheres or the presence of CyA as an inclusion complex within microspheres loaded by complex. In conclusion, using CyA as an inclusion complex with CD within microspheres can affect microsphere characteristics and drug release and it is possible to modify microsphere properties like drug release by incorporating CDs as complexing agents.

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The ability to grow microscopic spherical birefringent crystals of vaterite, a calcium carbonate mineral, has allowed the development of an optical microrheometer based on optical tweezers. However, since these crystals are birefringent, and worse, are expected to have non-uniform birefringence, computational modeling of the microrheometer is a highly challenging task. Modeling the microrheometer - and optical tweezers in general - typically requires large numbers of repeated calculations for the same trapped particle. This places strong demands on the efficiency of computational methods used. While our usual method of choice for computational modelling of optical tweezers - the T-matrix method - meets this requirement of efficiency, it is restricted to homogeneous isotropic particles. General methods that can model complex structures such as the vaterite particles, such as finite-difference time-domain (FDTD) or finite-difference frequency-domain (FDFD) methods, are inefficient. Therefore, we have developed a hybrid FDFD/T-matrix method that combines the generality of volume-discretisation methods such as FDFD with the efficiency of the T-matrix method. We have used this hybrid method to calculate optical forces and torques on model vaterite spheres in optical traps. We present and compare the results of computational modelling and experimental measurements.

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Biodegradable poly(dl-lactide-co-glycolide) microspheres were prepared using a modified double emulsion solvent evaporation method for the delivery of the subunit tuberculosis vaccine (Ag85B-ESAT-6), a fusion protein of the immunodominant antigens 6-kDa early secretory antigenic target (ESAT-6) and antigen 85B (Ag85B). Addition of the cationic lipid dimethyl dioctadecylammonium bromide (DDA) and the immunostimulatory trehalose 6,6'-dibehenate (TDB), either separately or in combination, was investigated for the effect on particle size and distribution, antigen entrapment efficiency, in vitro release profiles and in vivo performance. Optimised formulation parameters yielded microspheres within the desired sub-10 mu m range (1.50 +/- 0.13 mu m), whilst exhibiting a high antigen entrapment efficiency (95 +/- 1.2%) and prolonged release profiles. Although the microsphere formulations induced a cell-mediated immune response and raised specific antibodies after immunisation, this was inferior to the levels achieved with liposomes composed of the same adjuvants (DDA-TDB), demonstrating that liposomes are more effective vaccine delivery systems compared with microspheres.

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The ability of liposomes and microspheres to enhance the efficacy of a sub-unit antigen was investigated. Microspheres were optimised by testing a range of surfactants employed in the external aqueous phase of a water-in-oil-in-water (w/o/w) double emulsion solvent evaporation process for the preparation of microspherescomposed of poly(d,l-lactide-co-glycolide) and the immunological adjuvant dimethyl dioctadecyl ammonium bromide (DDA)and then investigated with regard to the physico-chemical and immunological characteristics of the particles produced. The results demonstrate that this parameter can affect the physico-chemical characteristics of these systems and subsequently, has a substantial bearing on the level of immune response achieved, both humoural and cell mediated, when employed for the delivery of the sub-unit tuberculosis vaccine antigen Ag85B-ESAT-6. Moreover, the microsphere preparations investigated failed to initiate immune responses at the levels achieved with an adjuvant DDA-based liposome formulation (DDA-TDB), further substantiating the superior ability of liposomes as vaccine delivery systems.

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Post-operative infections resulting from total hip arthroplasty are caused by bacteria such as Staphylococcus aureus and Pseudomonas aeruginosa entering the wound perioperatively or by haemetogenous spread from distant loci of infection. They can endanger patient health and require expensive surgical revision procedures. Gentamicin impregnated poly (methyl methacrylate) bone cement is traditionally used for treatment but is often removed due to harbouring bacterial growth, while bacterial resistance to gentamicin is increasing. The aim of this work was to encapsulate the antibiotics vancomycin, ciprofloxacin and rifampicin within sustained release microspheres composed of the biodegradable polymer poly (dl-lactide-co-glycolide) [PLCG] 75:25. Topical administration to the wound in hydroxypropylmethylcellulose gel should achieve high local antibiotic concentrations while the two week in vivo half life of PLCG 75:25 removes the need for expensive surgical retrieval operations. Unloaded and 20% w/w antibiotic loaded PLCG 75:25 microspheres were fabricated using a Water in Oil emulsification with solvent evaporation technique. Microspheres were spherical in shape with a honeycomb-like internal matrix and showed reproducible physical properties. The kinetics of in vitro antibiotic release into newborn calf serum (NCS) and Hank's balanced salt solution (HBSS) at 37°C were measured using a radial diffusion assay. Generally, the day to day concentration of each antibiotic released into NCS over a 30 day period was in excess of that required to kill St. aureus and Ps. auruginosa. Only limited microsphere biodegradation had occurred after 30 days of in vitro incubation in NCS and HBSS at 37°C. The moderate in vitro cytotoxicity of 20% w/w antibiotic loaded microspheres to cultured 3T3-L1 cells was antibiotic induced. In conclusion, generated data indicate the potential for 20% w/w antibiotic loaded microspheres to improve the present treatment regimens for infections occurring after total hip arthroplasty such that future work should focus on gaining industrial collaboration for commercial exploitation.

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Antisense technology is a novel drug discovery method, which provides an essential tool for directly using gene sequence information to rationally design specific inhibitions of mRNA, to treat a wide range of diseases. The efficacy of naked oligodeoxynucleotides (ODNs) is relatively short lived due to rapid degradation in vivo. The entrapment of ODNs within biodegradable sustained-release delivery systems may improve ODN stability and reduce dose required for efficacy. Biodegradable polymer microspheres were evaluated as delivery devices for ODNs and ribozymes. Poly(lactide-co-glycolide) polymers were used due to their biocompatibility and non toxic degradation products. Microspheres were prepared using a double emulsion-deposition method and the formulations characterised. In vitro release profiles were characterised by an initial burst effect during the first 48 hours of release followed by a more sustained release. The release profiles were influenced by microsphere size, copolymer molecular weight, copolymer ratio, ODN loading, ODN length, and ODN chemistry. The serum stability of ODNs was significantly improved when entrapped within polymer microspheres. The cellular association of ODNs entrapped within small spheres (1-2μm) was improved by approximately 20-fold in A431 carcinoma cells compared with free ODNs. Fluorescence microscopy studies showed a more diffuse subcellular distribution when delivered as a microsphere formulation compared with free ODNs, which exhibited the characteristic punctate periplasmic distribution. For in vivo evaluation, polymer microspheres containing fluorescently-labelled ODNs were stereo-taxically administered to the neostriatum of the rat brain. Free ODN resulted in a punctate cellular distribution after 24 hours. In comparison ODN delivered using polymer microspheres were intensely visible in cells 48 hours post administration, and fluorescence appeared to be diffuse covering both cytosolic and nuclear regions. Whole-body autoradiography was also used to evaluate the biodistribution of free tritium labelled ODN and ODN entrapped microspheres, following subcutaneous administration to Balb-C mice. Polymer entrapped ODN gave a similar biodistribution to free ODN. Free ODN was distributed within 24 hours, whereas polymer released ODN was observed still presented in organs and at the site of administration seven days post administration.

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Antisense oligodeoxynucleotides can selectively inhibit gene expression provided they are delivered to their target site successfully for a sufficient duration. Biodegradable microspheres have previously been developed for the potential systemic delivery of antisense oligodeoxynucleotides and offer an excellent strategy for central administration of antisense oligodeoxynucleotides, providing a sustained-release delivery system. Biodegradable microspheres were formulated to entrap antisense oligodeoxynucleotides for stereotaxic implantation into site-specific regions of the rat brain.Release profiles of antisense oligodeoxynucleotides from biodegradable microspheres over 56 days that were triphasic were observed with high molecular weight polymers. Antisense oligodeoxynucleotides loaded into microspheres (1-10μm) had a five-fold increase in cellular association with glial and neuronal cells compared to the naked molecule, which was partially due to a greater cellular accumulation as observed by a slower efflux profile. In vivo distribution studies of antisense oligodeoxynucleotides demonstrated that the use of microspheres provided a sustained-release over more than 2 days compared to 12 hours of the naked molecule. Efficacy of antisense oligodeoxynucleotides was demonstrated during locomotor activity investigations, which significantly reduced cocaine-induced locomotor activity, where no efficacy was demonstrated with microspheres, possibly attributed to antisense loading and measurements being taken during a lag phase of antisense oligodeoxynucleotide release. Biodegradable microspheres can be delivered site-specifically into the brain and provide sustained-release of antisense oligodeoxynucleotides, offering the potential of in vivo efficacy in these reagents in the brain.

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There is a growing body of experimental evidence suggesting that the gastrointestinal tract (GIT) may be penetrated by sub-micron sized polymeric particles which have the capacity to deliver therapeutic compounds. We investigated this, initially with Fluoresbrite™ carboxylate latex microspheres (0.87 m diameter) which were administered orally to rats. Microsphere numbers within blood samples were then quantified using fluorescence microscopy or FACS technology. These studies were prone to quantitative error, but indicated that increased microsphere translocation occurred if particles were administered in conjunction with large volumes of hypotonic liquid, and that uptake was very rapid. Test particles were detected in blood, only a few minutes after dosing. To improve quantification, GPC technology was adopted. 0.22 m latex particles were found to accumulate in greatest numbers within the Mononuclear phagocyte system tissues after gavage. Again translocation was rapid. The ability of test particles to leave the intestinal lumen and access systemic compartments was found to be highly dependent on their size and hydrophobicity, determined by hydrophobic interaction chromatography. Considerably lower numbers of 0.97 m diameter latex microspheres were detectable within extra-intestinal tissue locations after gavage. Histological studies showed that Fluoresbrite™ microspheres accumulate within the liver, spleen, Mesenteric lymph node and vasculature of rats after oral administration. Fluorescent particles were observed in both the Peyer's patches (PPs), and non lymphoid regions of rat intestinal mucosa after gavage, conductive to the acceptance that more than one mechanism of particle absorption may operate.

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In this project, antigen-containing microspheres were produced using a range of biodegradable polymers by single and double emulsion solvent evaporation and spray drying techniques. The proteins used in this study were mainly BSA, tetanus toxoid, F1 and V, Y. pestis subunit vaccines and the cytokine, interferon-gamma. The polymer chosen for use in the vaccine preparation will directly determine the characteristics of the formulation. Full in vitro analysis of the preparations was carried out, including surface hydrophobicity and drug release profiles. The influence of the surfactants employed on microsphere surface hydrophobicity was demonstrated. Preparations produced with polyhydroxybutyrate and poly(DTH carbonate) polymers were also shown to be more hydrophobic than PLA microspheres, which may enhance particle uptake by antigen presenting cells and Peyer's patches. Systematic immunisation with microspheres with a range of properties showed differences in the time course and extent of the immune response generated, which would allow optimisation of the dosing schedule to provide maximal response in a single dose preparation. Both systematic and mucosal responses were induced following oral delivery of microencapsulated tetanus toxoid indicating that the encapsulation of the antigen into a microsphere preparation provides protection in the gut and allows targeting of the mucosal-associated lymphoid tissue. Co-encapsulation of adjuvants for further enhancement of immune response was also carried out and the effect on loading and release pattern assessed. Co-encapsulated F1 and interferon-gamma was administered i.p. and the immune responses compared with singly encapsulated and free subunit antigen.

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Antisense oligonucleotides (AODNs) can selectively inhibit individual gene expression by binding specifically to rnRNA. The over-expression of the epidermal growth factor receptor (EGFR) has been observed in human breast and glioblastoma tumours and therefore AODNs designed to target the EGFR would be a logical approach to treat such tumours. However, poor pharmacokinetic/pharmacodynamic and cellular uptake properties of AODNs have limited their potential to become successful therapeutic agents. Biodegradable polymeric poly (lactide-co-glycolide) (P(LA-GA)) and dendrimer delivery systems may allow us to overcome these problems. The use of combination therapy of AODNs and cytotoxic agents such as 5-fluorouracil (5-FU) in biodegradable polymeric formulations may further improve therapeutic efficacy. AODN and 5-FU were either co-entrapped in a single microsphere formulation or individually entrapped in two separate microsphere formulations (double emulsion method) and release profiles determined in vitro. The release rates (biphasic) of the two agents were significantly slower when co-entrapped as a single microsphere formulation compared to those obtained with the separate formulations. Sustained release over 35 days was observed in both types of formulation. Naked and microsphere-loaded AODN and 5-FU (in separate formulations) were tested on an A431 vulval carcinoma cell line. Combining naked or encapsulated drugs produced a greater reduction in viable cell number as compared with either agent alone. However, controls and Western blotting indicated that non-sequence specific cytotoxic effects were responsible for the differences in viable cell number. The uptake properties of an anionic dendrimer based on a pentaerythritol structure covalently linked to AODNs (targeting the EGFR) have been characterised. The cellular uptake of AODN linked to the dendrimer was up to 3.5-fold higher in A431 cells as compared to naked AODN. Mechanistic studies suggested that receptor-mediated and adsorptive (binding protein-mediated) endocytosis were the predominant uptake mechanisms for the dendrimer-AODN. RNase H cleavage assay suggested that the dendrimer-AODN was able to bind and cleave the target site. A reduction of 20%, 28% and 45% in EGFR expression was observed with 0.05μM, 0.1μM and 0.5μM dendrimer-AODN treatments respectively with a reduction in viable cell number. These results indicated that the dendrimer delivery system may reduce viable cell number by an antisense specific mechanism.