Production de vins mousseux a partir de "Vinhos Verdes" blancs monovarietaux

On a fait l'étude comparative de vins mousseux élaborés à partir de vins de base issus de cinq cépages recommandés pour la Région: Loureiro, Trajadura, Avesso, Pedernã et Azal blanc, en ce qui concerne les propriétés organoleptiques. Les vins de base ont été produits selon le processus utilisé dans la Région -égrappage, pressurage, débourbage et fermentation alcoolique-, ayant été soumis aussi à une fermentation malolactique. La prise de mousse a été effectuée en bouteille, avec des levures immobilisées en billes d'alginate, pendant cinq mois à 14 °C. Les propriétés sensorielles des vins ont été évaluées en utilisant des fiches classificatrices et descriptives, par une chambre de neuf dégustateurs expérimentés. Le traitement statistique des résultats, effectué par le logiciel SPSS, a été fait en recourrant à l'analyse de variance. On a trouvé quelques différences parmi les cinq vins mousseux surtout en ce qui concerne l'aspect du cordon et l'arôme. Cependant, tous ces vins ont obtenu des classifications globales au-dessus de l'acceptable, atteignant parfois l'excellent. Ces résultats préliminaires ainsi obtenus, basés sur les caractéristiques organoleptiques, suggèrent la possibilité d'obtenir des vins mousseux de qualité à partir des cépages de "Vinho Verde"

De novo bone formation on macro/microporous silk and silk/nano-sized calcium phosphate scaffolds

Macro/micro porous silk/nano-sized calcium phosphate scaffolds (SC16) with bioactive and superior physicochemical properties have been recently developed. In this study, we aim at evaluating the new bone formation ability of the SC 16 scaffolds in vivo, using silk fibroin scaffolds (S16) as control. The CaP distribution profile in the scaffolds was characterized by Micro-Computed Tomography. The in vitro mineralization behavior was examined by immersion in Simulated Body Fluid solution from 1 to 14 days. The long-term hydration degree and weight loss ratio of the scaffolds were evaluated by immersion in an Isotonic Saline Solution from 1 month to 1 year. In vivo osteogenesis properties of the scaffolds were screened by implantation into the rat femur defects for 3 weeks. The results showed that the CaP phase distributed homogeneously in the SC16 scaffolds. Mineralization was only observed in SC16 scaffolds, and both scaffolds gradually degraded with time. The staining of the explants showed that new bone formation with higher density was observed in the SC16 scaffolds as compared to S16 scaffolds, guiding the growth of new bone directly onto its surface. These results demonstrated that the SC16 hybrid scaffolds are osteoconductive and can be good candidates for bone tissue engineering as promoted superior de novo bone formation.This study was supported by the Portuguese Foundation for Science and Technology (FCT) projects OsteoCart (PTDC/CTM-BPC/115977/2009) and Tissue2Tissue (PTDC/CTM/105703/2008). Research leading to these results has received funding from the European Union's Seventh Framework Programme (FP7/2007-2013) under grant agreement no REGPOT-CT2012-316331-POLARIS. Le-Ping Yan is an FCT PhD scholarship holder (SFRH/BD/64717/2009)

Association of radio polar cap brightening with bright patches and coronal holes

Radio-bright regions near the solar poles are frequently observed in Nobeyama Radioheliograph (NoRH) maps at 17 GHz, and often in association with coronal holes. However, the origin of these polar brightening has not been established yet. We propose that small magnetic loops are the source of these bright patches, and present modeling results that reproduce the main observational characteristics of the polar brightening within coronal holes at 17 GHz. The simulations were carried out by calculating the radio emission of the small loops, with several temperature and density profiles, within a 2D coronal hole atmospheric model. If located at high latitudes, the size of the simulated bright patches are much smaller than the beam size and they present the instrument beam size when observed. The larger bright patches can be generated by a great number of small magnetic loops unresolved by the NoRH beam. Loop models that reproduce bright patches contain denser and hotter plasma near the upper chromosphere and lower corona. On the other hand, loops with increased plasma density and temperature only in the corona do not contribute to the emission at 17 GHz. This could explain the absence of a one-to-one association between the 17 GHz bright patches and those observed in extreme ultraviolet. Moreover, the emission arising from small magnetic loops located close to the limb may merge with the usual limb brightening profile, increasing its brightness temperature and width.Comment: 8 pages, 6 figures, 1 table. Accepted for publication in The Astrophysical Journa

Physicochemical characterization of novel chitosan-soy protein/TEOS porous hybrids for tissue engineereing applications

In this paper we report a new type of cross-linked porous structure based on a chitosansoy protein blend system developed by means of combining a sol-gel process with the freeze-drying technique. The final structure was investigated by Fourier transform infrared spectroscopy with attenuated total reflectance (FTIR-ATR), contact angle measurements and the morphology by scanning electron microscopy (SEM). The water uptake capability and the weight loss were measured up to 14 days and their mechanical properties were assessed with compression tests. Results showed that the addition of tetraethyl orthosilicate (TEOS) to the chitosan-soy protein blend system provide specific interactions at the interface between the two polymers allowing to tailor the size and distribution as well as the degradation rate of the hybrids. Finally, TEOS incorporation induces an increase of the surface energy that influences the final physicochemical properties of the materials.(undefined

Dendrimers and derivatives as a potential therapeutic tool in regenerative medicine strategies : a review

Since the pioneering work dealing with the synthesis and physicochemical aspects of dendrimers, a predictable and tunable set of compositions for therapeutic, scaffolding and imaging systems has been reported. These are well documented, butmanyhot issues should be examined and reviewed. Herein, a review is given on dendritic nanopolymers and their applications that show promise in the field of regenerative medicine. This review begins with a brief overview on research merging nanotechnology and regenerative medicine. Fundamentals of the synthesis and macromolecular structure of dendritic polymers are provided. Dendrimers fulfill the requirements as carriers for gene, nucleic acids, bioactive molecules and peptide/protein delivery aimed at modulate the cells functions, in vitro and in vivo. However, to make use of this potential, toxicological, drug-loading capacity, surface engineering and host–guest chemistries in dendrimers must be addressed and thus are also discussed. We focus on recent work involving dendrimers with applications in tissue engineering and the central nervous system. Due to their innovative character, applications beyond drug delivery systems became possible, namely as scaffolding and chemoattractants for tissue regeneration, and implantable biodegradable nanomaterialbased medical devices integrated with drug delivery functions (theranostics). Finally, we highlight promising areas for further research and comment on how and why dendrimer and dendron technology should be viewed as the next generation of biomaterials for the 21st century.The authors wish to acknowledge the funding provided by the Portuguese Foundation for Science and Technology (FCT) through the POCTI and FEDER programs, and FCT project (SMARTCARBO). This work was carried out under the scope of the European NoE EXPERTISSUES (NMP3-CT-2004-500283) and European Union HIPPOCRATES STREP Project (NMP3-CT-2003-505758). Canon Foundation in Europe is also gratefully acknowledged

Gellan gum-based hydrogels for intervertebral disc tissue engineering applications

Intervertebral disc (IVD) degeneration is a challenging clinical problem that urgently demands viable nucleus pulposus (NP) implant materials. The best suited biomaterial for NP regeneration has yet to be identified, but it is believed that biodegradable hydrogel-based materials are promising candidates. In this work, we have developed ionic- and photo-crosslinked methacrylated gellan gum (GG–MA) hydrogels to be used in acellular and cellular tissue-engineering strategies for the regeneration of IVDs. The physicochemical properties of the developed hydrogels were investigated by Fourier-transform infrared spectroscopy, 1H nuclear magnetic resonance and differential scanning calorimetry. The swelling ability and degradation rate of hydrogels were also analysed in phosphate-buffered saline solution at physiological pH for a period of 30 days. Additionally, the morphology and mechanical properties of the hydrogels were assessed under a scanning electron microscope and dynamic compression, respectively. An in vitro study was carried out to screen possible cytotoxicity of the gellan gum-based hydrogels by culturing rat lung fibroblasts (L929 cells) with hydrogel leachables up to 7 days. The results demonstrated that gellan gum was successfully methacrylated. We observed that the produced GG–MA hydrogels possess improved mechanical properties and lower water uptake ability and degradation rate as compared to gellan gum. This work also revealed that GG–MA hydrogels are non-cytotoxic in vitro, thus being promising biomaterials to be used in IVD tissue-engineering strategies.The authors are grateful for funds provided by the Portuguese Foundation for Science and Technology (FCT) through the POCTI and FEDER programmes, including Project ProteoLight (Grant No. PTDC/FIS/68517/2006). This work was also carried outwith the support of the European Union-funded Collaborative Project Disc Regeneration (Grant No. NMP3-LA-2008-213904)

Injectable gellan gum-based hydrogels for intervertebral disc regeneration

Intervertebral disc (IVD) degeneration is a challenging pathology that, due to the inefficiency of the current treatments, urgently demands for the development of new regenerative approaches[1]. The best viable implant material for nucleus pulposus (NP) regeneration has yet to be identified, but it is believed that biodegradable hydrogelbased materials are promising candidates[2]. In this work, we are proposing the use of ionic- and photocrosslinked methacrylated gellan gum (GG-MA) hydrogels as potential acellular and cellular injectable scaffolds for IVD regeneration

Macro/microporous silk fibroin scaffolds with potential for articular cartilage and meniscus tissue engineering applications

This study describes the developmental physicochemical properties of silk fibroin scaffolds derived from high concentration aqueous silk fibroin solutions. The silk fibroin scaffolds were prepared with different initial concentrations (8%, 10%, 12% and 16% (wt%)) and obtained by combining the salt-leaching and freeze-drying methodologies. The results indicated that the antiparallel β-pleated sheet (silk-II) conformation was present in the silk fibroin scaffolds. All the scaffolds possessed macro/micro porous structure. Homogeneous porosity distribution was achieved in all the groups of samples. As the silk fibroin concentration increased from 8% to 16%, the mean porosity decreased from 90.8±0.9% to 79.8±0.3%, and the mean interconnectivity decreased from 97.4±0.5% to 92.3±1.3%. The mechanical properties of the scaffolds exhibited a concentration dependence. The dry state compressive modulus increased from 0.81±0.29 MPa to 15.14±1.70 MPa, and the wet state dynamic storage modulus increased around 20-30 folds at each testing frequencies when the silk fibroin concentration increased from 8% to 16%. The water-uptake ratio decreased by means of increasing silk fibroin concentration. The scaffolds present favorable stability as their structure integrity, morphology and mechanical properties were maintained after in vitro degradation for 30 days. Based on these results, the scaffolds developed in this study are herein proposed to be used in meniscus and cartilage tissue engineering scaffolding.Tissue2Tissue project (PTDC/CTM/105703/2008

Calcium-phosphate derived from mineralized algae for bone tissue engineering applications

In this work, several routes are described towards obtaining pure inorganic phases derived from Coralline officinallis red algae. The scanning electron microscopy studies have shown that it becomes possible not only to eliminate the undesired organic phase, but also to preserve or tailor the red algae typical microporosity. X-ray diffraction analysis was used to investigate the phase content of the red algae before and after performing the different treatment routes. Hydroxyapatite nanocrystallites were obtained after converting the coralline calcium carbonate skeleton by means of combining thermal and chemical routes. These results were confirmed by Fourier transform infra-red spectroscopic analysis. The processing routes herein described are very promising in order to design bioceramics of algae origin that might find useful applications as bone fillers and tissue engineering scaffolds

Rheological and mechanical properties of acellular and cellladen methacrylated gellan gum hydrogels

Tissue engineered hydrogels hold great potential as nucleus pulposus substitutes (NP), as they promote intervertebral disc (IVD) regeneration and re-establish its original function. But, the key to their success in future clinical applications greatly depends on its ability to replicate the native 3D micro-environment and circumvent their limitation in terms of mechanical performance. In the present study, we investigated the rheological/mechanical properties of both ionic- (iGG-MA) and photo-crosslinked methacrylated gellan gum (phGG-MA) hydrogels. Steady shear analysis, injectability and confined compression stress-relaxation tests were carried out. The injectability of the reactive solutions employed for the preparation of iGG-MA and phGG-MA hydrogels was firstly studied, then the zero-strain compressive modulus and permeability of the acellular hydrogels were evaluated.In addition, human intervertebral disc (hIVD) cells encapsulated in both iGG-MA and phGG-MA hydrogels were cultured in vitro, and its mechanical properties also investigated under dynamic mechanical analysis at 37ºC and pH 7.4. After 21 d of culturing, hIVD cells were alive (Calcein AM) and the E’ of ionic-crosslinked hydrogels and photo-crosslinked was higher than that observed for acellular hydrogels. Our study suggests that methacrylated gellan gum hydrogels present promising mechanical and biological performance as hIVD cells were producing extracellular matrix