左旋多巴甲酯在PLGA微球的稳定性研究

目的：考察左旋多巴甲酯在PLGA微球中的稳定性并探讨其稳定方法。方法：利用HPLC的方法考察了左旋多巴甲酯在不同pH值和光照的环境中和微球里的稳定性。结果：左旋多巴甲酯在pH3中稳定,在微球中也可以稳定一周。结论：包封左旋多巴甲酯在PLGA微球中,是一种有效地保护了左旋多巴甲酯在微球中的活性,可以实现长效缓释,是一种可行的方案。     

Light microscope identification of murine B and T cells by means of functional polymeric microspheres.

Covalent bonding of purified antibodies to polymeric microspheres of 0.4 to 0.8 μm diameter yields conjugates which can be used to label lymphocytes in the light microscope. Nonadherent microspheres can be separated by means of a discontinuous density gradient and quantitative measurements of adherent microsphere distributions can be made through examination of Wright's stained dry mounts or through fluorescent microscopic examination of cells in suspension.In general the distributions of adherent microspheres on mouse splenic and thymic lymphocytes in direct or indirect labelling assays show good agreement with results obtained from fluorescent antibody techniques. In comparison to fluorescent antibody the use of these antibody-microsphere conjugates has the advantage of allowing direct correlations between the surface antigens of cells and their histologie morphology.     

Conjugation of (E)-5-[2-(Methoxycarbonyl)ethenyl]cytidine to hydrophilic microspheres: development of a mobile microscale UV light actinometer

( E)-5-[2-(Methoxycarbonyl)ethenyl]cytidine was biotinylated through a diisopropylsilylacetal linkage and attached to the surface of hydrophilic streptavidin-coated microspheres through the high-affinity noncovalent interaction between biotin and streptavidin. The functionalized microspheres form a stable suspension in water. Upon UV irradiation, the nonfluorescent ( E)-5-[2-(methoxycarbonyl)ethenyl]cytidine on the microspheres undergoes photocyclization to produce highly fluorescent 3-beta-D-ribofuranosyl-2,7-dioxopyrido[2,3-d]pyrimidine. The fluorescence intensity of the microspheres can be correlated to the particle-specific UV doses applied at different suspension concentrations. The microspheres allow one to measure the UV dose (fluence) distribution in high-throughput water disinfection systems.     

Efficient on-chip proteolysis system based on functionalized magnetic silica microspheres

An easily replaceable enzymatic microreactor has been fabricated based on the glass microchip with trypsin-immobilized magnetic silica microspheres (MS microspheres). Magnetic microspheres with small size (approximately 300 nm in diameter) and high magnetic responsivity to magnetic field (68.2 emu/g) were synthesized and modified with tetraethyl orthosilicate (TEOS). Aminopropyltriethoxysilane (APTES) and glutaraldehyde (GA) were then introduced to functionalize the MS microspheres for enzyme immobilization. Trypsin was stably immobilized onto the MS microspheres through the reaction of primary amines of the proteins with aldehyde groups on the MS microspheres. The trypsin-immobilized MS microspheres were then locally packed into the microchannel by the application of a strong field magnet to form an on-chip enzymatic microreactor. The digestion efficiency and reproducibility of the microreactor were demonstrated by using cytochrome c (Cyt-C) as a model protein. When compared with an incubation time of 12 h by free trypsin in the conventional digestion approach, proteins can be digested by the on-chip microreactor in several minutes. This microreactor was also successfully applied to the analysis of an RPLC fraction of the rat liver extract. This opens a route for its further application in top-down proteomic analysis.     

Distribution of embryos and 500-microM microspheres in the rabbit oviduct: controls for acute motion analysis during transport

Distributions of embryos and 500-micron diameter microspheres were measured in the cleared oviducts of 32 rabbits at 8 intervals post coitus (pc) and normalized to percentage of isthmic length. By 18 h pc, 46% of the embryos had entered the isthmus and were denuded of the cumulus, while 55% of the microspheres had entered the isthmus. By 24 h pc, all embryos and microspheres were in the isthmus. At 72, 78, and 84 h pc, 6.5, 37, and 93% of embryos and 21, 73, and 95% of microspheres were in the cornu, respectively. The mean positions of embryos and microspheres progressed at approximately 1% of isthmic length per hour between 24 and 72 h pc. Throughout isthmic transport, embryos and microspheres in individual oviducts were tightly grouped and had similar statistical distributions. Although microspheres began to transfer into the uterine horns earlier than embryos, the data suggest that 500-micron microspheres can be used in studies to quantify discrete movements within the oviduct prior to 72 h pc. The data further suggest that opposing forces may be generated by contractile events that keep embryos grouped and possibly control their rate of progress through the oviduct.     

Mathematical modeling of functionalized-microsphere based assays for rapid DNA detection: From sample preparation to results

Functionalized microspheres are frequently used in the detection of biomolecules. A fundamental understanding of the mechanisms involved in enzymatic assays is required to estimate a method's utility. The mathematical methodology is illustrated through a theoretical analysis to assess the performance of a diagnostic method based on the horseradish peroxidase catalyzed reaction to detect pathogens in clinical specimens. The first part of the analysis focuses on the collection of target DNA molecules onto a functionalized fiber in a lysis micro-reactor (LMR). Expressions are derived for hybridization rates that include convective transport. In the next step the fiber is contacted with functionalized chitosan microspheres containing horse radish peroxidase. Chitosan microspheres are conjugated to the fiber with the target DNA acting as a unique tether. The final step is the release of chitosan microspheres in a chromogenic substrate and monitoring absorption changes. The analysis provides estimates of the method sensitivity and processing time and we show that DNA with a concentration as low as 10⁻⁴ copies per milliliter can be detected in less than 30 min. The modeling methodology presented can readily be extended to similar enzymatic, microsphere-based assays for quantitative purposes and feasibility studies.     

pH-sensitive genipin-cross-linked chitosan microspheres for heparin removal

Chitosan hydrogel microspheres were obtained by cross-linking chitosan in its inverse emulsion using genipin as cross-linker. The genipin-cross-linked chitosan microspheres (ChGp) swell significantly in water at pH values below 6.5 and shrink to a smaller extent at pH values above 6.5. ChGp microspheres bind heparin in water. The kinetics of heparin binding was found to be pH dependent and was faster and more efficient at a lower pH. That can be also controlled by the weight of ChGp microspheres used. Rate and efficiency of heparin adsorption at pH 7.4, which is typical of blood, could be increased by quaternization of ChGp microspheres using glycidyltrimethylammonium chloride (GTMAC). The polymeric material obtained thus can be potentially useful for heparin removal in biomedical applications.     

Application of bead-based assays for flow cytometry analysis

To date microsphere-based assays in flow cytometry have focused on the detection of antibody or antigen. Most studies have been research based to evaluate the performance of the technique relative to conventional techniques. However, there have not been any carefully controlled studies of the sensitivity and specificity, as well as analytic sensitivity of the FMIA technique. As such, it is difficult to document advantages of this tecnique clearly. The data suggest that FMIA is considerably more sensitive than conventional techniques, and the ability to analyze for multiple analytes in one sample dilution is attractive. This ability to simultaneously analyze for multiple samples is primarily dependent upon the size difference as sensed by FALS of the microspheres. However, it is also possible to use microspheres of the same size but that differ in either fluorescence or RALS signal. If microspheres of the same size are used but one fluoresces red and the signal in the assay uses a green fluorochrome, then the two microspheres can be separated by their red fluorescence. Using this technique, one can increase the number of microspheres that can be used in an assay. It is also possible to use microspheres of the same size but with different abilities to scatter the incident light at right angles. The use of these microspheres is then similar to the nonfluorescent versus red microspheres. By the judicious combination of microsphere size, it is possible to easily differentiate eight different microspheres. With the addition of a fluorescebt dye and/or differences in right-angle light-scatter capabilities, the number of different microspheres that can be used simultaneously becomes quite large. In practice, the number of microspheres that can be differentiated is no doubt greater than the number of analytes that need to be assayed in one assay.Although the apparent increase in sensitivity and the ability to simultaneously detect and quantitate numerous analytes are important attributes of FMIA, there are drawbacks to this method. Although the FMIA lends itself well to one-step no-wash procedures, when wash steps are necessary they are time-consuming and ineffecient. Most wash steps in FMIA use centrifugation of the microspheres to remove them from the reagent. There is a significant loss of microspheres in these wash steps, which are time-consuming. There are studies ussing vacuum filtration of the suspension to separate the microspheres from the reagents. A number of different groups are pursuing an automated or semiautomated method for the efficient washing and reagent delivery system for FMIA. Commercial systems are being developed that may allow for the easier handling of these reagents.Numerous groups are investigating the use of microspheres and flow cytometry primarily in immunoassay development. The procedure has the advantages of the simultaneous yet discrete analysis of multiple analytes and the inherent increase in sensitivity using fluorescence over other signals. There will no doubt be wider applications     

Easy method to determine refractive indices of microspheres and in micro-regions of inhomogeneous media

We describe an innovative method which can accurately determine the refractive index (RI) of individual microspheres by immersing the microspheres in a medium and analyzing their phase-contrast microscopic images. Compared with the current techniques for microsphere RI measurement, the method has several advantages: it is simple and easy and it cannot only measure the RI of each individual microsphere but also perform measurement simultaneously on all the microspheres in the same field of view. In measurement, microspheres are not required to be suspended in a specific liquid but in any medium with known RI which is appropriate for the microspheres or even just in atmosphere. By using microspheres with known RI as sensors, the method can also be used for rapid in situ measurement of the local RI of inhomogeneous media. In this paper, we describe the principle of the method and the experiments of using the method to measure the RI of individual microspheres. Its applications for sensing instantaneous RI/concentration/temperature variation in critical situations such as anywhere in mixing flows or living biological specimens are also presented.     

Spray-dried mucoadhesive microspheres: Preparation and transport through nasal cell monolayer

The purpose of this research was to prepare spray-dried mucoadhesive microspheres for nasal delivery. Microspheres composed of hydroxypropyl methylcellulose (H), chitosan (CS), carbopol 934P (CP) and various combinations of these mucoadhesive polymers, and maltodextrin (M), colloidal silicon dioxide (A), and propylene glycol (P) as filler and shaper, were prepared by spray-drying technique. Using propranolol HCl as a model drug, microspheres were prepared at loadings exceedings 80% and yields between 24% and 74%. Bulky, free flowing microspheres that had median particle size between 15 and 23 μm were obtained. Their zeta potential was according to the charge of polymer. Adhesion time of mucoadhesive microspheres on isolated pig intestine was ranked, CS>CP: H>CP>H, while the rank order of swelling was CP>CS>H. Increasing the amount of CP in CP∶H formulations increased the percentage of swelling. Infrared (IR) spectra showed no interaction between excipients used except CS with acetic acid. The release of drug from CP and CP∶H microspheres was slower than the release from H and CS microspheres, correlated to their viscosity and swelling. Long lag time from the CP microspheres could be shortened when combined with H. The permeation of drug through nasal cell monolayer corresponded to their release profiles. These microspheres affected the integrity of tight junctions, relative to their swelling and charge of polymer. Cell viability was not affected except from CS microspheres, but recovery could be obtained. In conclusion, spray-dried microspheres of H, CS, CP, and CP∶H could be prepared to deliver drug through nasal cell monolayer via the opening of tight junction without cell damaging. Published: February 10, 2006     

Synthesis and Characterization of Dual-Functionalized Core-Shell Fluorescent Microspheres for Bioconjugation and Cellular Delivery

The efficient transport of micron-sized beads into cells, via a non-endocytosis mediated mechanism, has only recently been described. As such there is considerable scope for optimization and exploitation of this procedure to enable imaging and sensing applications to be realized. Herein, we report the design, synthesis and characterization of fluorescent microsphere-based cellular delivery agents that can also carry biological cargoes. These core-shell polymer microspheres possess two distinct chemical environments; the core is hydrophobic and can be labeled with fluorescent dye, to permit visual tracking of the microsphere during and after cellular delivery, whilst the outer shell renders the external surfaces of the microspheres hydrophilic, thus facilitating both bioconjugation and cellular compatibility. Cross-linked core particles were prepared in a dispersion polymerization reaction employing styrene, divinylbenzene and a thiol-functionalized co-monomer. These core particles were then shelled in a seeded emulsion polymerization reaction, employing styrene, divinylbenzene and methacrylic acid, to generate orthogonally functionalized core-shell microspheres which were internally labeled via the core thiol moieties through reaction with a thiol reactive dye (DY630-maleimide). Following internal labeling, bioconjugation of green fluorescent protein (GFP) to their carboxyl-functionalized surfaces was successfully accomplished using standard coupling protocols. The resultant dual-labeled microspheres were visualized by both of the fully resolvable fluorescence emissions of their cores (DY630) and shells (GFP). In vitro cellular uptake of these microspheres by HeLa cells was demonstrated conventionally by fluorescence-based flow cytometry, whilst MTT assays demonstrated that 92% of HeLa cells remained viable after uptake. Due to their size and surface functionalities, these far-red-labeled microspheres are ideal candidates for in vitro, cellular delivery of proteins.     

Regional blood flow measurements with 15 micron and 50 micron microspheres in pregnant guinea-pigs

Two sizes of microsphere were used to determine regional blood flow in pregnant guinea-pigs. Tissue perfusion measured with 50 micron microspheres was significantly greater than that measured with 15 micron microspheres in the small intestine, uterus, vagina, and placenta. A significantly larger proportion of the smaller microspheres passed through the systemic vasculature and could be detected in the lungs.     

Generation and differentiation of microtissues from multipotent precursor cells for use in tissue engineering

This protocol describes an effective method for the production of spherical microtissues (microspheres), which can be used for a variety of tissue-engineering purposes. The obtained microtissues are well suited for the study of osteogenesis in vitro when multipotent stem cells are used. The dimensions of the microspheres can easily be adjusted according to the cell numbers applied in an individual experiment. Thus, microspheres allow for the precise administration of defined cell numbers at well-defined sites. Here we describe a detailed workflow for the production of microspheres using unrestricted somatic stem cells from human umbilical cord blood and adapted protocols for the use of these microspheres in histological analysis. RNA extraction methods for mineralized microtissues are specifically modified for optimum yields. The duration of running the complete protocol without preparatory cell culture but including 2 weeks of microsphere incubation, histological staining and RNA isolation is about 3 weeks.     

Collagen adsorption on quercetin loaded polycaprolactone microspheres: approach for "stealth" implant

We recently experimented with collagen coating on the surface of quercetin loaded polycaprolactone microspheres by simple adsorption technique to mimic extra cellular matrix and reduce immune or inflammatory responses at the site of implants. The collagen immobilization on polymeric scaffold surfaces through various surface modification techniques was the current scenario to improve bio-integration of the polymers with the in vivo system. Nevertheless, it requires other chemicals or processing methods to modify the surface of polymers to immobilize the collagen covalently. Here protein adsorption principle is used for the coating of collagen onto the surface of solid microspheres and characterized. Optical, ATR-FTIR, SEM analysis confirm collagen coating. The reduction in burst release of the quercetin from the PCL microspheres further confirms its presence and role in the controlled release. The results indicate that the adsorption technique can be the simple strategy to coat collagen on the surface of polyester implants to develop stealth implant in shorter time with low cost technology.     

Use of receptors immobilized on microspheres to identify ligand binding sites in tissue sections: detection of lymph node ligands for L-Selectin

 Particulate microspheres bearing immobilized probes can be used to identify ligands expressed by cells and require only brightfield microscopy for detection. There are distinct advantages to using microspheres to detect low affinity interactions; microspheres require no secondary amplification or detection procedures subsequent to the binding interaction, reducing opportunities for detachment of bound probe, and concentrating probes on microspheres may greatly increase binding avidity. Selectin leukocyte-endothelial adhesion molecules undergo low affinity binding to ligands, and these interactions may be difficult to detect with standard techniques. The aim of this study was to determine if immobilizing recombinant L-Selectin on microspheres would facilitate detection of specific tissue ligands. Microspheres were incubated with sections of rabbit peripheral lymph node in a modified Stamper-Woodruff assay, and binding was assessed by brightfield microscopy. L-Selectin-IgG microspheres bound to high endothelial venules, known to be sites of expression for L-Selectin ligands. Specificity was indicated by the lack of binding of microspheres coated with control protein, and inhibition of binding by antibody to L-Selectin and by competitive antagonists of L-Selectin ligand interactions. Accepted: 10 September 1996     

Smart latexes for bioseparation

Monodisperse, thermosensitive microspheres with sub-micron diameters are used for separation and collection of proteins and other biomolecules. The thermosensitivity gives the microspheres two valuable features. One is the controllability of affinity between microsphere and protein with temperature. The quality and quantity of proteins to be adsorbed on the microspheres can be controlled with temperature. The other feature is reversible control of dispersion stability. Microspheres which have adsorbed target proteins in the dispersion can be easily recovered by changing temperature. This revised version was published online in July 2006 with corrections to the Cover Date.     

Biodegradable PLGA microcarriers for injectable delivery of chondrocytes: effect of surface modification on cell attachment and function

Poly(D,L-lactic-co-glycolic acid) (PLGA) microspheres were prepared by an oil/water emulsion solvent evaporation method to use as an injectable microcarrier for cell delivery. Three different kinds of PLGA microspheres having hydrophobic, negatively charged, and positively charged surfaces were prepared. Hydrophobic and negatively charged PLGA microspheres were prepared by using terminally capped and uncapped PLGA polymer, respectively. Positively charged PLGA microspheres were prepared by blending PLGA with PLGA-g-poly(L-lysine) graft copolymer as a surface modifying agent. Bovine chondrocytes were cultured on the three PLGA microspheres under serum conditions to comparatively evaluate cell attachment, cell proliferation, and cell function with respect to surface properties. Positively charged PLGA microspheres showed the highest cell attachment, growth, and function compared to hydrophobic and negatively charged microspheres. Surface-modified PLGA microspheres can potentially be used as an injectable delivery system for cells into a tissue defect site.     

Designed synthesis of fluorous‐functionalized magnetic mesoporous microspheres for specific enrichment of phosphopeptides with fluorous derivatization

In this work, for the first time, perfluorinated magnetic mesoporous microspheres were designed and synthesized for the highly specific enrichment of fluorous‐derivatized phosphopeptides through the unique fluorine–fluorine interactions. The perfluorinated magnetic mesoporous microspheres were prepared through a surfactant‐mediated one‐pot approach and successfully applied to the selective extraction of fluorous‐derivatized phosphopeptides from β‐casein tryptic digest, protein mixtures, and human serum. Thanks to the hydrophilic silanol groups exposed on the surface, perfluorinated groups modified in the pore channels and the magnetic cores, the flourous‐functionalized magnetic microspheres exhibited excellent dispersibility, specificity toward fluorous‐derivatized phosphopeptides while facilitated separation procedures. The novel composites achieved a high selectivity of 1:1000 toward nonphosphorylated peptides and proved to be practicable in the enrichment of endogenous phosphopeptides in the human serum sample.     

Morphological analysis of transportation pathways of microspheres after their introduction into the uterine horn cavity in cyclic pigs

Countercurrent transfer is thought to be one of the most important mechanisms involved in the transfer of substances between the uterus and oviduct. The present study was aimed at recognizing other putative transportation pathways from the uterine cavity through the oviduct onto the surface of and into internal ovarian structures. Microspheres (latex beads, 0.8 m in diameter) were introduced into the uterine horn cavity of pigs, for 30 min, at various days of the estrous cycle. The transportation pathways of the beads were then analyzed by light and electron microscopy. The transport of microspheres through the oviduct canal into ovarian tissues took place on each day of the estrous cycle. The largest numbers of microspheres passed through the tunica albuginea to the corpora lutea. Some of microspheres also reached the surface of the uterine ligament through the oviduct canal, where they attained the lumen of blood and lymphatic vessels, mainly of the vascular subovarian (VSP) and paraovarian lymphatic plexus (PLP), via the lymphatic stomata pathway. Transport of microspheres also took place simultaneously through the uterine and oviduct walls and from particular organs through blood and lymphatic vessels. Although the present results do not exclude the participation of countercurrent transfer between venous, lymphatic, and arterial vessels, they provide morphological evidence for the presence of direct transportation pathways of substances, released into the uterine lumen, into ovarian tissues through the oviduct canal.     

利用生物可降解海藻酸钙微球保护苏云金杆菌晶体与芽胞免受紫外线降解

采用基于注射挤压器的液滴形成技术制备包裹了苏云金杆菌晶体和芽胞的海藻酸钙凝胶微球.通过调节该装置的活塞重量和空气压力,获得了平均直径为20μm的微球.SDS-PAGE分析与平板菌落涂布实验表明,凝胶微球可有效减少紫外线对苏云金杆菌晶体和芽胞的损伤作用.利用小菜蛾进行的毒力生测发现,凝胶微球可有效防止紫外线引起的晶体和芽胞杀虫毒力的下降.本研究的液滴形成技术也可适用于其它微球包裹过程.