449 research outputs found
Solvatochromic absorption and fluorescence studies of adenine, thymine and uracil thio-derived acyclonucleosides
Adenine, thymine and uracil thio-derived acyclonucleosides were synthesized and characterized by UV-Vis, FT-IR, 1H and 13C NMR spectroscopic techniques. The photophysical properties of the derivatives were evaluated in solvents with diverse polarities and at various pH values. The solvent dependent absorbance and emission spectral shifts were analysed using physical parameters of the selected solvents. The regression and correlation coefficients were calculated using multiple regression techniques. The fitting coefficients gave an estimate of the contribution of each interaction to the total spectral shift in various solutions. Multiple linear regression studies, Kamlet-Taft equation and stokes shift correlation with orientation polarizability provide valuable information concerning spectroscopic characteristics of the studied molecules
Sustained and controlled release of daunomycin from cross-linked poly(aldehyde guluronate) hydrogels
We have incorporated daunomycin, an antineoplastic agent, into a biodegradable hydrogel through a labile covalent bond. In brief, sodium alginate was chemically broken down to low molecular weight and followed by oxidation to prepare poly(aldehyde guluronate). Adipic dihydrazide was used to incorporate the drug into the polymer backbone and cross-link the polymer to form hydrogels. Daunomycin can be released from the hydrogel after the hydrolysis of the covalent linkage between the drug and the polymer. A wide range of release profiles of daunomycin (e.g., from 2 days to 6 weeks) has been achieved using these materials, and the biological activity of the released daunomycin was maintained. Β© 2000 Wiley-Liss, Inc. and the American Pharmaceutical Association J Pharm Sci 89: 910β919, 2000Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/34502/1/8_ftp.pd
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Oxidized alginate hydrogels as niche environments for corneal epithelial cells
Chemical and biochemical modification of hydrogels is one strategy to create physiological constructs that maintain cell function. The aim of this study was to apply oxidised alginate hydrogels as a basis for development of a biomimetic niche for limbal epithelial stem cells that may be applied to treating corneal dysfunction. The stem phenotype of bovine limbal epithelial cells (LEC) and the viability of corneal epithelial cells (CEC) were examined in oxidised alginate gels containing collagen IV over a 3-day culture period. Oxidation increased cell viability (P </= 0.05) and this improved further with addition of collagen IV (P </= 0.01). Oxidised gels presented larger internal pores (diameter: 0.2 - 0.8 microm) than unmodified gels (pore diameter: 0.05 - 0.1 microm) and were significantly less stiff (P </= 0.001), indicating that an increase in pore size and a decrease in stiffness contributed to improved cell viability. The diffusion of collagen IV from oxidised alginate gels was similar to that of unmodified gels suggesting that oxidation may not affect the retention of extracellular matrix proteins in alginate gels. These data demonstrate that oxidised alginate gels containing corneal extracellular matrix proteins can influence corneal epithelial cell function in a manner that may impact beneficially on corneal wound healing therapy
A Fluorescent Thermometer Based on a Pyrene-Labeled Thermoresponsive Polymer
Thermoresponsive polymers that undergo a solubility transition by variation of the temperature are important materials for the development of βsmartβ materials. In this contribution we exploit the solubility phase transition of poly(methoxy diethylene glycol methacrylate), which is accompanied by a transition from hydrophilic to hydrophobic, for the development of a fluorescent thermometer. To translate the polymer phase transition into a fluorescent response, the polymer was functionalized with pyrene resulting in a change of the emission based on the microenvironment. This approach led to a soluble polymeric fluorescent thermometer with a temperature range from 11 Β°C to 21 Β°C. The polymer phase transition that occurs during sensing is studied in detail by dynamic light scattering
Chondrogenic phenotype of different cells encapsulated in ΞΊ-carrageenan hydrogels for cartilage regeneration strategies
Engineering articular cartilage substitutes using hydrogels
with encapsulated cells is an approach that has received
increasing attention in recent years. Hydrogels based on
ΞΊ-carrageenan (ΞΊC), a thermoreversible natural-origin polymer,
have been recently proposed as new cell/growth factor
delivery vehicles for regenerative medicine. In this work, we
report the potential of such hydrogels encapsulating either
human-adipose-derived stem cells (hASCs), human nasal
chondrocytes (hNCs), or a chondrocytic cell line (ATDC5) for
cartilage regeneration strategies. The in vitro cellular behavior
of the encapsulated cells within ΞΊC hydrogel was analyzed
after different culturing periods using biochemical assays and
histological and real-time reverse-transcription PCR analysis. The three types of cells encapsulated in ΞΊC hydrogels showed
good cellular viability and proliferation up to 21 days of
culture, and the cell-laden hydrogels were positive for specific
cartilage markers. In summary, the results demonstrate that
hASCs embedded in ΞΊC hydrogels proliferate faster and exhibit
higher expression levels of typical cartilage markers as
compared with hNCs or ATDC5 cells. Based on these data, it is
possible to conclude that ΞΊC hydrogel provides a good support
for culture and differentiation of encapsulated cells and that
hASCs may provide an advantageous alternative to primary
chondrocytes, currently used in clinical treatments of cartilage
defects/diseases.Elena G. Popa would like to acknowledge Cristina Correia for help in the isolation of hNCs for this work. The authors would like to acknowledge the Portuguese Foundation for Science and Technology (PhD grant, SFRH/BD/64070/2009)
A two-component pre-seeded dermal-epidermal scaffold
We have developed a bilayered dermal-epidermal scaffold for application in the treatment of full-thickness skin defects. The dermal component gels in situ and adapts to the lesion shape, delivering human dermal fibroblasts in a matrix of fibrin and cross-linked hyaluronic acid modified with a cell adhesion-promoting peptide. Fibroblasts were able to form a tridimensional matrix due to material features such as tailored mechanical properties, presence of protease-degradable elements and cell-binding ligands. The epidermal component is a robust membrane containing cross-linked hyaluronic acid and poly-l-lysine, on which keratinocytes were able to attach and to form a monolayer. Amine-aldehyde bonding at the interface between the two components allows the formation of a tightly bound composite scaffold. Both parts of the scaffold were designed to provide cell-type-specific cues to allow for cell proliferation and form a construct that mimics the skin environment.D.S.K. acknowledges funding from the Biotechnology Research Endowment from the Department of Anesthesiology at Boston Children's Hospital. I.P.M. acknowledges the Portuguese Foundation for Science and Technology for the grant BD/39396/2007 and the MIT-Portugal Program. D.G. acknowledges the Swiss National Science Foundation for a post-doctoral fellowship (PBGEP3-129111). B.P.T. acknowledges an NIR Ruth L. Kirschstein National Research Service Award (F32GM096546)
Cell-Based Bone Tissue Engineering
The authors review the available data on bone tissue engineering and discuss possible new research areas that could help to make bone tissue engineering a clinical success
Delivery systems made of natural-origin polymers for tissue engineering and regenerative medicine applications
There is an emergent need in the development of more specific and effective therapeutic agent carriers to help on the regeneration of a plethora of tissues. The ultimate aim of bioactive factors delivery systems development is to improve the human health with the fewest possible adverse reactions. While there have been many polymeric scaffolds and matrices with different forms and compositions developed to load and deliver bioactive factors, the delivery strategy should be established based on the type of molecules to deliver and mechanisms to control their release. As most bioactive factors such as proteins and genes are water-soluble, natural polymers are more favored than synthetic ones for this purpose. A core-shell structuring of biomaterials (in the cases of particles or fibers) where water-based polymers being placed in the inner core part may be the most common design principal to secure bioactive factors during the processing of synthetic drug delivery scaffolds.(undefined)info:eu-repo/semantics/submittedVersio
An Implantable Vascularized Protein Gel Construct That Supports Human Fetal Hepatoblast Survival and Infection by Hepatitis C Virus in Mice
Widely accessible small animal models suitable for the study of hepatitis C virus (HCV) in vivo are lacking, primarily because rodent hepatocytes cannot be productively infected and because human hepatocytes are not easily engrafted in immunodeficient mice.We report here on a novel approach for human hepatocyte engraftment that involves subcutaneous implantation of primary human fetal hepatoblasts (HFH) within a vascularized rat collagen type I/human fibronectin (rCI/hFN) gel containing Bcl-2-transduced human umbilical vein endothelial cells (Bcl-2-HUVEC) in severe combined immunodeficient X beige (SCID/bg) mice. Maturing hepatic epithelial cells in HFH/Bcl-2-HUVEC co-implants displayed endocytotic activity at the basolateral surface, canalicular microvilli and apical tight junctions between adjacent cells assessed by transmission electron microscopy. Some primary HFH, but not Huh-7.5 hepatoma cells, appeared to differentiate towards a cholangiocyte lineage within the gels, based on histological appearance and cytokeratin 7 (CK7) mRNA and protein expression. Levels of human albumin and hepatic nuclear factor 4alpha (HNF4alpha) mRNA expression in gel implants and plasma human albumin levels in mice engrafted with HFH and Bcl-2-HUVEC were somewhat enhanced by including murine liver-like basement membrane (mLBM) components and/or hepatocyte growth factor (HGF)-HUVEC within the gel matrix. Following ex vivo viral adsorption, both HFH/Bcl-2-HUVEC and Huh-7.5/Bcl-2-HUVEC co-implants sustained HCV Jc1 infection for at least 2 weeks in vivo, based on qRT-PCR and immunoelectron microscopic (IEM) analyses of gel tissue.The system described here thus provides the basis for a simple and robust small animal model of HFH engraftment that is applicable to the study of HCV infections in vivo
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