Your search keyword '"Soni VP"' showing total 4 results

1. Bioconductive 3D nano-composite constructs with tunable elasticity to initiate stem cell growth and induce bone mineralization.

Author

Sagar N, Khanna K, Sardesai VS, Singh AK, Temgire M, Kalita MP, Kadam SS, Soni VP, Bhartiya D, and Bellare JR

Subjects

Alkaline Phosphatase metabolism, Animals, Calcium analysis, Cell Adhesion drug effects, Cell Proliferation drug effects, Cell Shape drug effects, Durapatite chemistry, Durapatite pharmacology, Humans, Magnetic Resonance Spectroscopy, Male, Microscopy, Atomic Force, Muramidase metabolism, Nanocomposites ultrastructure, Particle Size, Phosphorus analysis, Porosity, Rabbits, Spectrometry, X-Ray Emission, Spectrophotometry, Atomic, Spectroscopy, Fourier Transform Infrared, Stem Cells drug effects, Sus scrofa, Viscosity, X-Ray Diffraction, Biocompatible Materials pharmacology, Calcification, Physiologic drug effects, Elasticity, Nanocomposites chemistry, Stem Cells cytology, Tissue Scaffolds chemistry

Abstract

Bioactive 3D composites play an important role in advanced biomaterial design to provide molecular coupling and improve integrity with the cellular environment of the native bone. In the present study, a hybrid lyophilized polymer composite blend of anionic charged sodium salt of carboxymethyl chitin and gelatin (CMChNa-GEL) reinforced with nano-rod agglomerated hydroxyapatite (nHA) has been developed with enhanced biocompatibility and tunable elasticity. The scaffolds have an open, uniform and interconnected porous structure with an average pore diameter of 157±30μm and 89.47+0.03% with four dimensional X-ray. The aspect ratio of ellipsoidal pores decrease from 4.4 to 1.2 with increase in gelatin concentration; and from 2.14 to 1.93 with decrease in gelling temperature. The samples were resilient with elastic stain at 1.2MPa of stress also decreased from 0.33 to 0.23 with increase in gelatin concentration. The crosslinker HMDI (hexamethylene diisocyanate) yielded more resilient samples at 1.2MPa in comparison to glutaraldehyde. Increased crosslinking time from 2 to 4h in continuous compression cycle show no improvement in maximum elastic stain of 1.2MPa stress. This surface elasticity of the scaffold enables the capacity of these materials for adherent self renewal and cultivation of the NTERA-2 cL.D1 (NT2/D1), pluripotent embryonal carcinoma cell with biomechanical surface, as is shown here. Proliferation with MG-63, ALP activity and Alizarin red mineralization assay on optimized scaffold demonstrated ***p<0.001 between different time points thus showing its potential for bone healing. In pre-clinical study histological bone response of the scaffold construct displayed improved activity of bone regeneration in comparison to self healing of control groups (sham) up to week 07 after implantation in rabbit tibia critical-size defect. Therefore, this nHA-CMChNa-GEL scaffold composite exhibits inherent and efficient physicochemical, mechanical and biological characteristics based on gel concentrations, gelatin mixing and gelling temperature thus points to creating bioactive 3D scaffolds with tunable elasticity for orthopedic applications., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published

2016

2. Bone healing evaluation of nanofibrous composite scaffolds in rat calvarial defects: a comparative study.

Author

Jaiswal AK, Dhumal RV, Ghosh S, Chaudhari P, Nemani H, Soni VP, Vanage GR, and Bellare JR

Subjects

Absorptiometry, Photon, Animals, Bone Density physiology, Bone Regeneration physiology, Fractures, Bone diagnostic imaging, Male, Nanocomposites chemistry, Nanocomposites therapeutic use, Nanofibers chemistry, Osteogenesis physiology, Rats, Rats, Sprague-Dawley, Skull diagnostic imaging, Tissue Engineering instrumentation, Tissue Engineering methods, X-Ray Microtomography, Fracture Healing physiology, Fractures, Bone physiopathology, Skull injuries, Tissue Scaffolds chemistry

Abstract

We studied the in vivo performance of scaffolds consisting of nanofibrous poly(L-lactic acid) (P) and blend of poly(L-lactic acid/gelatin) (PG) prepared by electrospinning and further composited them with hydroxyapatite (HA) via alternate soaking method, to get poly(L-lactic acid)/hydroxyapatite (PH) and poly(L-lactic acid)/gelatin/hydroxyapatite (PGH) scaffolds respectively. The purpose of this study was to assess and compare bone regeneration potential of electrospun P, PG and electrospun-alternate soaked PH and PGH scaffolds using rat as an animal model by creating two 5 mm circular defects in calvaria. The respective scaffolds were implanted into the defects as one side implantation and both side implantation. Defects left empty served as a negative control for one side implantation and as sham control for both side implantations. The outcomes of the scaffold implantation were determined after 6 and 10 weeks by digital radiography, micro-CT, dual-energy X-ray absorptiometry (DEXA) and histological analysis. PGH scaffold regenerated maximum amount of new bone with high bone mineral density (BMD) into the defects and complete closure occurred in just 6 weeks while other scaffolds failed to close the defects completely. PGH group exhibited highest BMD value after 10 weeks. Histological findings showed abundant osteoblasts and initiation of matrix mineralization in HA containing scaffolds. Masson's trichrome staining showed collagen deposition in all scaffold groups except sham control group. Biochemical and haematological parameters were well with in normal range, indicating no infection due to scaffold implantation. These results prove PGH scaffold as a potential biomaterial for bone regenerative medicine.

Published

2013

3. Enhanced mechanical strength and biocompatibility of electrospun polycaprolactone-gelatin scaffold with surface deposited nano-hydroxyapatite.

Author

Jaiswal AK, Chhabra H, Soni VP, and Bellare JR

Subjects

Adsorption, Alkaline Phosphatase metabolism, Biocompatible Materials pharmacology, Cell Adhesion drug effects, Cell Proliferation drug effects, Elastic Modulus drug effects, Humans, Microscopy, Atomic Force, Nanofibers ultrastructure, Nanostructures ultrastructure, Osteoblasts cytology, Osteoblasts drug effects, Osteoblasts enzymology, Osteoblasts ultrastructure, Thermogravimetry, X-Ray Diffraction, Durapatite pharmacology, Gelatin pharmacology, Materials Testing methods, Mechanical Phenomena drug effects, Nanostructures chemistry, Polyesters pharmacology, Tissue Scaffolds chemistry

Abstract

In this study for the first time, we compared physico-chemical and biological properties of polycaprolactone-gelatin-hydroxyapatite scaffolds of two types: one in which the nano-hydroxyapatite (n-HA) was deposited on the surface of electrospun polycaprolactone-gelatin (PCG) fibers via alternate soaking process (PCG-HAAS) and other in which hydroxyapatite (HA) powders were blended in electrospinning solution of PCG (PCG-HAB). The microstructure of fibers was examined by scanning electron microscopy (SEM) and transmission electron microscopy (TEM) which showed n-HA particles on the surface of the PCG-HAAS scaffold and embedded HA particles in the interior of the PCG-HAB fibers. PCG-HAAS fibers exhibited the better Young's moduli and tensile strength as compared to PCG-HAB fibers. Biological properties such as cell proliferation, cell attachment and alkaline phosphatase activity (ALP) were determined by growing human osteosarcoma cells (MG-63) over the scaffolds. Cell proliferation and confocal results clearly indicated that the presence of hydroxyapatite on the surface of the PCG-HAAS scaffold promoted better cellular adhesion and proliferation as compared to PCG-HAB scaffold. ALP activity was also observed better in alternate soaked PCG scaffold as compared to PCG-HAB scaffold. Mechanical strength and biological properties clearly demonstrate that surface deposited HA scaffold prepared by alternate soaking method may find application in bone tissue engineering., (Copyright © 2013 Elsevier B.V. All rights reserved.)

Published

2013

4. Influence of carboxymethyl chitin on stability and biocompatibility of 3D nanohydroxyapatite/gelatin/carboxymethyl chitin composite for bone tissue engineering.

Author

Sagar N, Soni VP, and Bellare JR

Subjects

Blood Platelets cytology, Blood Platelets metabolism, Cell Line, Humans, Platelet Adhesiveness, Tissue Engineering methods, Bone Substitutes chemistry, Chitin chemistry, Durapatite chemistry, Gelatin chemistry, Materials Testing, Nanocomposites chemistry, Tissue Scaffolds chemistry

Abstract

A novel three-dimensional (3D) scaffold has been developed from the unique combination of nanohydroxyapatite/gelatin/carboxymethyl chitin (n-HA/gel/CMC) for bone tissue engineering by using the solvent-casting method combined with vapor-phase crosslinking and freeze-drying. The surface morphology and physiochemical properties of the scaffold were investigated by dissolvability test, infrared absorption spectra (IR), X-ray diffraction (XRD), transmission electron microscope (TEM), scanning electron microscope (SEM), mechanical testing, and soaking in simulated body fluid (SBF). An optimized (composition and processing parameters) ratio of n-HA:gel:CMC (1:2:1), exhibited ideal porous structure with regular interconnected pores (75-250 μm) and higher mechanical strength. Result suggested that the divalent (Ca(++)), carboxyl (COO(-)), amino (NH4(+)), and phosphate (PO4(3-)) groups created favorable ionic interactions which facilitated structural stability and integrity of the composite scaffold. The SBF soaking experiment confirmed the apatite nucleation ability, induced by CMC incorporation. Furthermore, hemocompatibility (hemolysis, platelet adhesion, and protein adsorption) and biocompatibility with MG63 osteoblast cells (MTT assay, cell morphology, and confocal studies from within the 3D scaffold) indicated that the structural and dimensional stability of composite scaffold provided an optimal mechanosensory environment for enhancement of cell adhesion, proliferation, and network formation. The n-HA/gel/CMC composite, therefore, may serve as a promising composite scaffold for guided bone regeneration., (Copyright © 2012 Wiley Periodicals, Inc.)

Published

2012