7 resultados para Bioencapsulation
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The use of stem cells is a promising therapeutic approach for the substantial challenge to regenerate cartilage. Considering the two prerequisites, namely the use of a 3D system to enable the chondrogenic differentiation and growth factors to avoid dedifferentiation, the diffusion efficiency of essential biomolecules is an intrinsic issue. We already proposed a liquified bioencapsulation system containing solid microparticles as cell adhesion sites1. Here, we intend to use the optimized system towards chondrogenic differentiation by encapsulating stem cells and collagenII-TGF-β3 PLLA microparticles. As a proof-of-concept, magnetite-nanoparticles were incorporated into the multilayered membrane. This can be a great advantage after implantation procedures to fixate the capsules in situ with the held of an external magnetic patch and for the follow-up through imaging. Results showed that the production of glycosaminoglycans and the expression of cartilage-relevant markers (collagen II, Sox9, aggrecan, and COMP) increased up to 28 days, while hypertrophic (collagen X) and fibrotic (collagen I) markers were downregulated. The presence of nanofibers in the newly deposited ECM was visualized by SEM, which resembles the collagen fibrils of native cartilage. The presence of the major constituent of cartilage, collagen II, was detected by immunocytochemistry and afranin-O and alcian blue stainings revealed a basophilic ECM deposition, which is characteristic of neocartilage. These findings suggest that the proposed system may provide a suitable environment for chondrogenic differentiation.
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Inspired by the native co-existence of multiple cell types and from the concept of deconstructing the stem cell niche, we propose a co-encapsulation strategy within liquified capsules. The present team has already proven the application of liquified capsules as bioencapsulation systems1. Here, we intend to use the optimized system towards osteogenic differentiation. Capsules encapsulating adipose stem cells alone (MONO-capsules) or in co-culture with endothelial cells (CO-capsules) were maintained in endothelial medium with or without osteogenic differentiation factors. The suitability of the capsules for living stem and endothelial cells encapsulation was demonstrated by MTS and DNA assays. The osteogenic differentiation was assessed by quantifying the deposition of calcium and the activity of ALP up to 21 days. CO capsules had an enhanced osteogenic differentiation, even when cultured in the absence of osteogenic factors. Furthermore, osteopontin and CD31 could be detected, which respectively indicate that osteogenic differentiation had occurred and endothelial cells maintained their phenotype. An enhanced osteogenic differentiation by co-encapsulation was also confirmed by the upregulation of osteogenic markers (BMP-2, RUNX2, BSP) while the expression of angiogenic markers (VEGF, vWF, CD31) revealed the presence of endothelial cells. The proposed capsules can also act as a growth factor release system upon implantation, as showed by VEGF and BMP-2 quantification. These findings demonstrate that the co-encapsulation of stem and endothelial cells within liquified injectable capsules provides a promising strategy for bone tissue engineering.
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Nanomaterials make up an emerging area in Chemistry and in the science of materials. This area constitutes the development of methods for synthesizing nanoscopic particles of a given material used for scientific investigation. Nanomaterials have a wide range of commercial possibilities and technological applications, including their use in analytical chemistry, as well as in electronics, optics, engineering, medicine, devices for liberation of drugs, bioencapsulation, among others. This paper presents a summary about nanoelectrodes, devices built from nanoparticles, which show great potential as electrochemical tools in many different types of analysis. The purpose of this paper is to review the construction methodologies of nanoelectrodes, and to point out their successful applicability in the various fields of immune assays and other analytical procedures with quantitative purposes.
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Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)
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[EN] Brine shrimp nauplii (Artemia sp.) are used in aquaculture as the major food source for many cultured marine larvae, and also used in the adult phase for many juvenile and adult fish. One artemia species, Artemia franciscana is most commonly preferred, due to the availability of its cysts and to its ease in hatching and biomass production. The problem with A. franciscana is that its nutritional quality is relatively poor in essential fatty acids, so that it is common practice to enrich it with emulsions like SELCO and ORIGO. This “bioencapsulation”, enrichment method permits the incorporation of different kinds of products into the artemia. This brine-shrimp’s non-selective particle-feeding habits, makes it particularly suitable for this enrichment process. The bioencapsulation is done just prior to feeding the artemia to a predator organism. This allows the delivery of different substances, not only for nutrient enrichment, but also for changing pigmentation and administering medicine. This is especially useful in culturing ornamental seahorses and tropical fish in marine aquaria In this study the objectives were to determine, the relative nutrient value of ORIGO and SELCO as well as the optimal exposure to these supplements prior to their use as food-organisms.
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Die Bioverkapselung ist eine faszinierende Methode, um biologische Materialien einschließlich Zellen in Siliziumdioxid, Metalloxiden oder hybriden Sol-Gel-Polymeren zu immobilisieren. Bisher wurde nur die Sol-Gel-Vorläufertechnologie genutzt, um Bakterien- oder Hefezellen in Siliziumdioxid zu immobilisieren. Hierfür wurden verschiedene Reagenzien als wässrige Vorläufer getestet, um poly(Silicate) auf Biomolekülen (Bhatia et al., 2000) oder Zellen (Liu und Chen 1999; Coradin und Livage, 2007) zu bilden. Einer der erfolgreichsten bisherigen Methoden verwendet eine Mischung aus Silicaten und kolloidalem Silica. Diese initialen Vorläufer werden durch die Zugabe von Salzsäure neutralisiert, was die Gelbildung fortschreiten lässt und die Verkapselung von Bakterien in einem Silica-Netzwerk zur Folge hat (Nassif et al., 2003). Mit der Entdeckung von Silicatein, einem Enzym, das aus Demospongien isoliert wurde und die Bildung von poly(Silicat) katalysiert, wurde es möglich, poly(Silicat) unter physiologischen Bedingungen zu synthetisieren. Silicatein wurde rekombinant in E. coli hergestellt und ist in der Lage, bei Raumtemperatur, neutralem pH-Wert und in wässrigen Puffersystemen aus Siliziumalkoxiden poly(Silicat) zu bilden (Krasko et al., 2000; Müller et al., 2007b; Zhou et al., 1999). In vivo katalysiert Silicatein die Synthese der Silicathülle der Schwamm-Spiculae (Skelettelemente; Müller et al., 2005b; Müller et al., 2007a; Müller et al., 2007b; Schröder et al., 2007a). Dieses Biosilica wurde in Form von Silica-Nanospheren mit Durchmessern zwischen 100 nm und 250 nm organisiert vorgefunden (Pisera 2003; Tahir et al., 2005). Mit dieser Arbeit konnte gezeigt werden, dass Escherichia coli erfolgreich mit dem Silicatein-Gen transformiert werden kann. Das Level der Proteinexpression kann in Anwesenheit von Isopropyl-β-D-thiogalaktopyranosid (IPTG) effizient erhöht werden, indem man die Bakterienzellen gleichzeitig mit Kieselsäure inkubiert. Dieser Effekt konnte sowohl auf Ebene der Synthese des rekombinanten Proteins durch Western Blot als auch durch Immunfluoreszenzmikroskopie nachgewiesen werden. Das heterolog produzierte Silicatein besitzt enzymatische Aktivität und kann die Polymerisation von Kieselsäure katalysieren. Dies konnte sowohl durch Färbung mit Rhodamin123, als auch durch Reaktion der nicht polymerisierten, freien Kieselsäure mit dem ß-Silicomolybdato-Farbsystem (Silicomolybdänblau) nachgewiesen werden. Elektronenmikroskopische Untersuchungen zeigten, dass nur die silicateinexprimierenden Bakterien während des Wachstums in Anwesenheit von Kieselsäure eine viskose Hülle um Zelle herum bilden. Ebenfalls konnte gezeigt werden, dass Silicatein-α aus Suberites domuncula nach Transformation in E. coli an die Zelloberfläche dieser Zellen transportiert wurde und dort seine enzymatische Funktion beibehielt. Die Silicathülle wurde mittels Raster-Elektronenmikroskopie (REM) analysiert. Die Bakterien, die Silicatein exprimierten und poly(Silicat) an ihrer Oberfläche synthetisierten, zeigten die gleichen Wachstumsraten wie die Bakterien, die das Gen nicht enthielten. Schlussfolgernd lässt sich sagen, dass die silicateinvermittelte Verkapselung von Bakterien mit poly(Silicat) die Bandbreite der Anwendung von Bakterien für die Produktion von rekombinanten Proteinen verbessern, erweitern und optimieren könnte.
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The use of antibiotics in aquaculture has been limited. Scientifics seeking for natural substitutes to prevent of aquatic animals diseases. Considering seaweeds are rich of nutritions and bioactive compounds, the purpose of this study is: investigation the potential and use possibility of native seaweeds from Persian Gulf in shrimp aquculture industry to improve growth, survival of postlarvae and to resistance against pathogens such as vibriosis. For this propose 7 macroalgae species from Bushehr province coast, inclouding: green algae (C. iyengarii), brown algae (S. angutifolium and S. ilicifolium) and red algae (L. snyderiae, K. alvarezii and G. corticata) were collected and identified. Then seaweed extracts abtained by Water, Ethanol, Methanol and Chloroform solvents by soaking method. In vitro antibacterial activity of extracts against Gr+ bacteria (S. aureus and B. subtilis) and Gr- bacteria (V. harveyi, V. alginolyticus and E. coli) was conducted by Agar diffusion, MIC and MBC methods. Antioxidant activity also by DPPH and EC50 methods was investigated. According to results of these two tests four seaweeds species (S. angutifolium, L. snyderiae, K. alvarezii and G. corticata) were selected for use in shrimp postlarvae (PL22) diets by Bio-Encapsulation (Artemia enrichment). Before of enrichment, toxicity effect of extracts to Artemia nauplii were evaluated by determination of LC50 24 h method. From results of this section Ethanol extracts were selected to bioencapsulation. After encapsulation shrimp postlarvae divided to 12 groups in triplicate, namely: C-, C+, S (200), S (400), S (600), L(200), L(400), L(600), G(300), G(600), K(300) and K(600). During 30 days of reared period C- and C+ use of basal diet and unenriched Artemia, but the other groups use of basal diet and enriched Artemia. Except C-, the shrimps in first day of culture put in 107 cfu/ml v. harveyi suspension for 30 minutes, and after water exchange 10 ml of this dose was added to reared aquaria. After 30 days survival percentage, obtained weight and SGR% were investigated. To evaluate vibrio loading, every 10 days 5 postlarvae were sampled randomly for vibrio count. Results showed that vibrio count in C- was less than the others and in C+ was more than the others. In treatments vibrio count in L(200) was the most and L(600) was the less. Survival rate in C- was the most and after that G(600) with 79.4±6.6% and then S(300) and K(600) were 73.3±7.3% and 70.6±6.6% respectively that were significantly compare the other (P < 0.01). Also the C+ was the less with 33.3±6.6% that difference was significant (P< 0.01). In this study growth parameters of all groups that fed by enriched Artemia were better than C+ (P<0.05). After cultre period 10 shrimp of every aquarium disinfected and reared for 10 days like before treatment. After 10 days the shrimps were challenged by 3×108 cfu/ml V. harveyi and mortality was recorded for 7 days. The all of animals in C- were survive but more than 90% of C+ were dead. And survival in all of treatments were better the C+ (P<0.05). The study showed the ethanol extracts of selected seaweed from Persian Gulf is a good source for growth, Survival and disease control in shrimp larviculture.
