Literature alerts

Literature alerts

• A hydrophobic nanocapsule controls the photophysics of aromatic molecules by suppressing their favored solution pathways. Kaanumalle IS, Gibb CLD, Gibb BC, Ramamurthy V. 2005. Journal of the American Chemical Society 127:3674–3675.
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• A novel mechanism of endothelial protein C receptor release, in microparticulate form, by activated protein C. Casa MP, Fukudome K, Toh CH. 2004. Blood, 104:531A.
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• A novel method to enhance the stability of alginate-poly-L-lysine-alginate microcapsules. Wang MS, Childs RF, Chang PL. 2005. Journal of Biomaterials Science—Polymer Edition 16:91–113.
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• Accumulation and fate of microorganisms and microspheres in biofihns formed in a pilot-scale water distribution system. Langmark J, Storey MV, Ashbolt NJ, Stenstrom TA. 2005. Applied and Environmental Microbiology 71:706–712.
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• Activated leukocytes and endothelial cells enhance retention of ultrasound contrast microspheres containing perfluoropropane in inflamed venules. Yasu T, Greener Y, Jablonski E, Killam AL, Fukuda S, Suematsu M, Tojo SJ, Schmid-Schonbein GW. 2005. International Journal of Cardiology 98:245–252.
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• Activated protein C induces the release of microparticle- associated endothelial protein C receptor. Perez-Casal M, Downey C, Fukudome K, Marx G, Toh CH. 2005. Blood 105:1515–1522.
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• Adsorption of a cationic dye molecule on polystyrene microspheres in colloids: Effect of surface charge and composition probed by second harmonic generation. Eckenrode HM, Jen SH, Han J, Yeh AG, Dai HL. 2005. Journal of Physical Chemistry B 109:4646–4653.
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• Adsorption/release behaviour of oligonucleotides on polymeric core-shell micro-spheres. Tondelli L, Ballestri M, Cazzato A, Federici F, Magnani L, Spamacci K, Laus M. 2005. Journal of Controlled Release 101:355–356.
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• Alginate microcapsules prepared with xyloglucan as a synthetic extracellular matrix for hepatocyte attachment. Seo SJ, Akaike T, Choi YJ, Shirakawa M, Kang IK, Cho CS. 2005. Biomaterials 26:3607–3615.
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• All-trans-retinoic acid microspheres: Preparation and in vitro characterization. Cirpanli Y, Unlu N, Calis S, Hincal AA. 2004. European Journal of Pharmaceutical Sciences S53.
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• Antisense peptide nucleic acid delivered by core-shell microspheres. Chiarantini L, Cerasi A, Millo E, Benatti U, Laus M, Spamacci K, Magnani L, Tondelli L. 2005. Journal of Controlled Release 101:397–398.
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• Artificial cell microcapsule for oral delivery of live bacterial cells for therapy: Design, preparation, and in-vitro characterization. Wei OY, Chen HM, Jones ML, Metz T, Hague T, Martoni C, Prakash S. 2004. Journal of Pharmacy and Pharmaceutical Sciences 7:315–324.
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• Baclofen-loaded microspheres: Preparation and efficacy testing in a new rabbit model. Lagarce F, Renaud P, Faisant N, Nicolas G, Cailleux A, Richard J, Menei P, Benoit JP. 2005. European Journal of Pharmaceutics and Biopharmaceutics 59:449–459.
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• Biocompatibility evaluation of different alginates and alginate-based micro-capsules. Orive G, Carcaboso AM, Hernandez RM, Gascon AR, Pedraz JL. 2005. Biomacromolecules 6:927–931.
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• Biodisposition of PEG-coated lipid microspheres of indomethacin in arthritic rats. Palakurthi S, Vyas SP, Diwan PV. 2005. International Journal of Pharmaceutics 290:55–62.
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• Biofunctional polyelectrolyte multilayers and microcapsules: control of non-specific and bio-specific protein adsorption. Heuberger R, Sukhorukov G, Voros J, Textor M, Mohwald H. 2005. Advanced Functional Materials 15:357–366.
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• Bloadhesive interaction and hypoglycemic effect of insulin-loaded lectin-microparticle conjugates in oral insulin delivery system. Kim BY, Jeong JH, Park K, Kim JD. 2005. Journal of Controlled Release 102:525–538.
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• Carbidopa/levodopa-loaded biodegradable microspheres: In vivo evaluation on experimental Parldnsonism in rats. Arica B, Kas HS, Moghdam A, Akalan N, Hincal AA. 2005. Journal of Controlled Release 102:689–697.
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• CdS-nanoparticle/polymer composite shells grown on silica nanospheres by atom transfer radical polymerization. Cui T, Zhang JH, Wang JY, Cui F, Chen W, Xu FB, Wang Z, Zhang K, Yang B. 2005. Advanced Functional Materials 15:481–486.
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• Cellulose acetate butyrate microcapsules containing dextran ion-exchange resins as self-propelled drug release system. Fundueanu G, Constantin M, Esposito E, Cortesi R, Nastruzzi C, Menegatti E. 2005. Biomaterials 26:4337–4347.
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• Chameleon water: Assemblies confined in nanocapsules. Henry M, Bogge H, Diemann E, Muller A. 2005. Journal of Molecular Liquids 118:155–162.
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• Characterization of porous PLGA/PLA microparticles as a scaffold for three dimensional growth of breast cancer cells. Sahoo SK, Panda AK, Labhasetwar V. 2005. Biomacromolecules 6:1132–1139.
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• Characterization of the adsorption of PDADMAC on Si02 microspheres. Zhu YH, Da H, Yang XL, Hu Y. 2004. Chinese Journal of Chemical Physics 17:775–778.
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• Characterization of trophoblast microparticles generated during in vitro perfusion of human placental tissue. Di Santo S, Malek A, Sager R, Andres AC, Schneider H. 2004. Placenta 25:A37.
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• Chitosan microspheres for pulmonary delivery of insulin: In vivo evaluation in rats. Carrion-Recio D, Remunan-Lopez C. 2004. European Journal of Pharmaceutical Sciences S63.
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• Circulating cell-derived microparticles in Crohn's disease. Chamouard P, Desprez D, Hugel B, Kunzelmann C, Gidon-Jeangirard C, Lessard M, Baumann R, Freyssinet JM, Grunebaum L. 2005. Digestive Diseases and Sciences 50:574–580.
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• Circulating microparticles are increased in patients with atrial fibrillation and reduced left atrial appendage velocity. Ederhy S, Di Angelantonio E, Hugel B, Mallat Z, Boccara F, Cohen A. 2004. European Heart Journal 25:530.
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• Comparison of hyperbranched and linear polyglycidol unimolecular reverse micelles as nanoreactors and nanocapsules. Kumar KR, Brooks DE. 2005. Macromolecular Rapid Communications 26:155–159.
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• Composite tectocapsules containing porous polymer microspheres as release gates. Croll LM, Stover HDH, Hitchcock AP. 2005. Macromolecules 38:2903–2910.
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• Cross-priming of T cell responses by synthetic microspheres carrying a CD8(+ ) T cell epitope requires an adjuvant signal. Boisgerault F, Rueda P, Sun CM, Hervas-Stubbs S, Rojas M, Leclerc C. 2005. Journal of Immunology 174:3432–3439.
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• Cumulative irritation potentials of combination therapies: A comparison of adapalene gel 0.1%, tazarotene cream O.05%, and tretinoin microsphere 0.04% when applied in combination with topical antibacterial gels. Dosik J, Arsonnaud S. 2005. Journal of the American Academy of Dermatology 52:P22.
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• Damage of integrated circuits by high-velocity microparticles penetrating thick-wall obstacles. Roman OV, Dybov OA, Romanov GS, Usherenko SM. 2005. Technical Physics Letters 31:46–47.
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• Development and bioadhesive properties of chitosan-ethylcellulose microspheres for nasal delivery. Martinac A, Filipovic-Grcic J, Voinovich D, Perissutti B, Franceschinis E. 2005. International Journal of Pharmaceutics 291:69–77.
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• Development and characterization of PLGA nanospheres and nanocapsules containing xanthone and 3-methoxyxanthone. Teixeira M, Alonso MJ, Pinto MMM, Barbosa CM. 2005. European Journal of Pharmaceutics and Biopharmaceutics 59:491–500.
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• Development of new reverse micellar microencapsulation technique to load water-soluble drug into PLGA microspheres. Kim H, Cho MH, Sah H. 2005. Archives of Pharmacal Research 28:370–375.
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• Effect of basic fibroblast growth factor incorporating gelatin microspheres on erectile function in the diabetic rat. Suetomi T, Hisasue S, Sato Y, Tabata Y, Akaza H, Tsukamoto T. 2005. Journal of Urology 173:1423–1428.
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• Effect of poly-L-lysine coating on macrophage activation by alginate-based microcapsules: Assessment using a new in vitro method. Juste S, Lessard M, Henley N, Menard M, Halle JP. 2005. Journal of Biomedical Materials Research Part A 72A:389–398.
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• Effect of relative humidity on the oxidative stability of microencapsulated sea buckthorn seed oil. Partanen R, Hakala M, Sjovall O, Kallio H, Forssell P. 2005. Journal of Food Science 70:E37.
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• Effects of formulation variables and characterization of guaifenesin wax micro-spheres for controlled release. Mani N, Park MO, Jun HW. 2005. Pharmaceutical Development and Technology 10:71–83.
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• Effects of gamma-irradiation on trehalose-hydroxyethylcellulose microspheres loaded with vancomycin. Bartolotta A, D'Oca MC, Campisi M, De Caro V, Giandalia G, Giannola LI, Brai M, Calderaro E. 2005. European Journal of Pharmaceutics and Biopharmaceutics 59:139–146.
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• Effects of rain and sunlight on oriental fruit moth (Lepidoptera: Tortricidae) pheromone microcapsules applied to apple foliage. Waldstein DE, Gut U. 2004. Journal of Agricultural and Urban Entomology 21:117–128.
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• Fabrication of a highly transpartent conductive thin film from polypyrrole/ poly(methyl methacrylate) core/shell nanospheres. Jang J, Oh JH. 2005. Advanced Functional Materials 15:494–502.
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• Fabrication of mixed Zn/Cu-bound polyimine microspheres with fine-tuned diameter and internal gradation of metal composition. Houjou H, Sasaki T, Shimizu Y, Koshizaki N, Kanesato M. 2005. Advanced Materials 17:606.
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• Fabrication of multicolor-encoded microspheres by tagging semiconductor nanocrystals to hydrogel spheres. Kuang M, Wang DY, Bao HB, Gao MY, Mohwald H, Jiang M. 2005. Advanced Materials 17:267.
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• Fabrication of polyaniline/ethylcellulose composite microspheres by microencap-sulation. Yang FY, Chu Y, Huo L, Yang Y, Liu Y. 2005. Chemistry Letters 34:388–389.
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• Facilitated production of secretory IgA against Shiga toxin B subunits by intranasal application of antigen-coated polystyrene microspheres. Kurohane K, Kobayashi C, Imai Y. 2005. Microbiology and Immunology 49:149–154.
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• Fast-dissolving mucoadhesive microparticulate delivery system containing pirmdcam. Cilurzo F, Selmin F, Minghetti P, Rimoldi I, Damartin F, Montanan L. 2005. European Journal of Pharmaceutical Sciences 24:355–361.
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• Fine-tuning the degree of organic functionalization of mesoporous silica nanosphere materials via an interfacially designed co-condensation method. Radu DR, Lai CY, Huang JG, Shu X, Lin VSY. 2005. Chemical Communications 10:1264–1266.
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• First experience with transcoronary ablation of septum hypertrophy with microspheres in patients with hypertrophic obstructive cardiomypoathy. Konorza T, Haude M, Katz M, Bose D, Neudorf U, Erbel R. 2004. American Journal of Cardiology 30:178E.
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• Flame retarded polyurea with microencapsulated ammonium phosphate for textile coating. Giraud S, Bourbigot S, Rochery M, Vroman I, Tighzert L, Delobel R, Poutch F. 2005. Polymer Degradation and Stability 88:106–113.
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• Formation of L-poly(lactic acid) microspheres by rapid expansion of CO2 saturated polymer suspensions. Matsuyama K, Zhang DH, Urabea T, Mishima K. 2005. Journal of Supercritical Fluids 33:277–283.
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• Formation of nanoparticle-loaded microcapsules based on hydrogen-bonded multilayers. Lee D, Rubner MF, Cohen RE. 2005. Chemistry of Materials 17:1099–1105.
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• Growth of well-defined ZnO microparticles with additives from aqueous solution. Li P. Wei Y, Liu H, Wang XK. 2005. Journal of Solid State Chemistry 178:855–860.
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• Hepatic arterial yttrium 90 microspheres: Another treatment option for hepatocellular carcinoma. Dawson LA. 2005. Journal of Vascular and Interventional Radiology 16:161–164.
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• High-frequency ultrasound scattering from microspheres and single cells. Baddour RE, Sherar MD, Hunt JW, Czamota GJ, Kolios MC. 2005. Journal of the Acoustical Society of America 117:934–943.
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• High-performance liquid chromatography separation characteristics of molecular-imprinted poly(methacrylic acid) microparticles prepared by suspension polymerization. Kim K, Kim D. 2005. Journal of Applied Polymer Science 96:200–212.
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• Hollow porous carbon nanospheres with large surface area and stability, assembled from oxidized fullerenes. Wang YL, Nepal D, Geckeler KE. 2005. Journal of Materials Chemistry 15:1049–1054.
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• Imaging fiber microarray fluorescent ion sensors based on bulk optode microspheres. Wygladacz K, Bakker E. 2005. Analytica Chimica Acta 532:61–69.
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• In vitro study of anticancer drug doxorubicin in PLGA-based microparticles. Lin RY, Ng LS, Wang CH. 2005. Biomaterials 26:4476–4485.
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• In vivo efficacy and toxicity of intratumorally delivered mitomycin C and its combination with doxorubicin using microsphere formulations. Cheung RY, Rauth AW, Wu XY. 2005. Anti-Cancer Drugs 16:423–433.
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• In vivo monitoring of fluorescent nanosphere delivery in anesthetized rats using an implantable fiber-optic microprobe. Lo LW, Tsai PJ, Huang SHY, Chen WY, Wang YT, Chang CH, Yang CS. 2005. Analytical Chemistry 77:1125–1131.
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• Induction of dendritic cell-mediated immune responses against HIV-1 by antigen-capturing nanospheres in mice. Kawamura M, Wang X, Uto T, Sato K, Ueno M, Akagi T, Hiraishi K, Matsuyama T, Akashi M, Baba M. 2005. Journal of Medical Virology 76:7–15.
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• Inflammatory response to peritoneal implantation of alginate-poly-L-lysine microcapsules. Robitaille R, Dusseault J, Henley N, Desbiens K, Labrecque N, Halle JP. 2005. Biomaterials 26:4119–4127.
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• Influence of lipid nanocapsules composition on their aptness to freeze-drying. Dulieu C, Bazile D. 2005. Pharmaceutical Research 22:285–292.
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• Influence of the combinations of polymethacrylate which have different perme-ability on swelling and dissolution characteristics of microspheres formulated by solvent evaporation method. Baykara T, Kylycarslan M. 2004. European Journal of Pharmaceutical Sciences S50.
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• Investigation of polymer magnetic microspheres. Ali-Zade RA. 2005. Colloids and Surfaces A-Physicochemical and Engineering Aspects 255:111–117.
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• Investigations on the modified release ibuprofen microspheres. Canefe K, Devrim B. 2004. European Journal of Pharmaceutical Sciences S40.
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• Investigations on the stability of diphenhydramine HC1 microspheres. Canefe K, Ozturk N, Devrim B. 2004. European Journal of Pharmaceutical Sciences S41.
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• Lack of efficacy of a reduced microparticle diet in a multi-centred trial of patients with active Crohn's disease. Lomer MCE, Grainger SL, Ede R, Catterall AP, Greenfield SM, Cowan RE, Vicary FR, Jenkins AR, Fidler H, Harvey RS, Ellis R, McNair A, Ainley CC, Thompson RPH, Powell JJ. 2005. European Journal of Gastroenterology & Hepatology 17:377–384.
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• Low hematocrit and serum albumin concentrations underlie the overestimation of tacrolimus concentrations by microparticle enzyme immunoassay versus liquid chromatography-tandem mass spectrometry. Brown NW, Gonde CE, Adams JE, Tredger JM. 2005. Clinical Chemistry 51:586–592.
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