Your search keyword '"Bellare, Jayesh R"' showing total 204 results

201. Chitosan reinforced apatite-wollastonite coating by electrophoretic deposition on titanium implants.

Author

Sharma S, Soni VP, and Bellare JR

Subjects

Electrophoresis methods, Materials Testing, Porosity, Apatites chemistry, Calcium Compounds chemistry, Chitosan chemistry, Coated Materials, Biocompatible chemistry, Electroplating methods, Prostheses and Implants, Silicates chemistry, Titanium chemistry

Abstract

A novel bioactive porous apatite-wollastonite/chitosan composite coating was prepared by electrophoretic deposition. The influence of synthesis parameters like pH of suspension and current density was studied and optimized. X-ray diffraction confirmed crystalline phase of apatite-wollastonite in powder as well as composite coating with coat crystallinity of 65%. Scanning electron microscope showed that the porosity had interconnections with good homogeneity between the phases. The addition of chitosan increased the adhesive strength of the composite coating. Young's modulus of the coating was found to be 9.23 GPa. One of our key findings was sheet-like apatite growth unlike ball-like growth found in bioceramics. Role of chitosan was studied in apatite growth mechanism in simulated body fluid. In presence of chitosan, dense negatively charged surface with homogenous nucleation was the primary factor for sheet-like evolution of apatite layer. The results suggest that incorporation of chitosan with apatite-wollastonite in composite coating could provide excellent in vitro bioactivity with enhanced mechanical properties.

Published

2009

202. A small-angle X-ray scattering study of the structure of lysozyme-sodium dodecyl sulfate complexes.

Author

Narayanan J, Abdul Rasheed AS, and Bellare JR

Subjects

Animals, Chickens, Micelles, Surface-Active Agents chemistry, Muramidase chemistry, Scattering, Small Angle, Sodium Dodecyl Sulfate chemistry, X-Ray Diffraction

Abstract

The structure of lysozyme-sodium dodecyl sulfate (SDS) complexes in solution is studied using small-angle X-ray scattering (SAXS). The SAXS data cannot be explained by the necklace and bead model for unfolded polypeptide chain interspersed with surfactant micelles. For the protein and surfactant concentrations used in the study, there is only marginal growth of SDS micelles as they complex with the protein. Being a small and rather rigid protein, lysozyme can penetrate the micellar core which is occupied by flexible and disordered paraffin chains and also the shell occupied by the hydrated head groups. A partially embedded swollen micellar model seems appropriate and describes well the scattering data. The SAXS intensity profiles are analyzed by considering the change in the electron scattering length density of the micellar core and shell due to complexation with protein and treating the intermicellar interaction using rescaled mean spherical approximation (RMSA) for charged spheres.

Published

2008

203. Self-assembled surfactant nano-structures important in drug delivery: a review.

Author

Giddi HS, Arunagirinathan MA, and Bellare JR

Subjects

Animals, Humans, Hydrogen-Ion Concentration, Liposomes chemistry, Micelles, Phospholipids chemistry, Drug Delivery Systems, Nanostructures chemistry, Surface-Active Agents chemistry

Abstract

Role of self assembled structures as a vehicle is significant over the years. Their applications have been found for all routes of drug delivery. These micro and nano structures are containers loaded with drugs, ideal for targeted and sustained release of the drug. Drug efficacy depends on the drug loaded into the vehicle, temperature, drug solubility, pH, release characteristics, additives and most significantly, the vehicle morphology. This in turn suggests that the same vehicle cannot be used with high efficiency for all types of drugs and locations where the drug delivery has to take place. The status of various self assembled structures and their applications in drug delivery is reviewed in this communication.

Published

2007

204. Extended time range modeling of myelin growth.

Author

Taribagil R, Arunagirinathan MA, Manohar C, and Bellare JR

Abstract

When some poorly water-soluble solid surfactants are contacted with water, several microstructures are observed as part of the dissolution process of the surfactants in water. One such microstructure called "myelin," which is observed when a surfactant like phosphatidylcholine is contacted with water, is the subject of this paper. In this study we have used video microscopy to investigate myelin growth over a wide time range, namely 0.25-700 s, and found that existing models do not correctly express myelin growth over extended time ranges. When studied over a wide time range, the myelin growth was found to evolve over three distinct regimes, namely ballistic, diffusional, and subdiffusional regimes. The underlying growth models are physically explained and mathematically expressed. A relationship is derived between the width of myelin and the growth rate at long times. The estimated width of myelin is consistent with experiments.

Published

2005