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1.
Polymers (Basel) ; 15(5)2023 Mar 03.
Article in English | MEDLINE | ID: mdl-36904532

ABSTRACT

Fibrous structures, in general, have splendid advantages in different forms of micro- and nanomembranes in various fields, including tissue engineering, filtration, clothing, energy storage, etc. In the present work, we develop a fibrous mat by blending the bioactive extract of Cassia auriculata (CA) with polycaprolactone (PCL) using the centrifugal spinning (c-spinning) technique for tissue-engineered implantable material and wound dressing applications. The fibrous mats were developed at a centrifugal speed of 3500 rpm. The PCL concentration for centrifugal spinning with CA extract was optimized at 15% w/v of PCL to achieve better fiber formation. Increasing the extract concentration by more than 2% resulted in crimping of fibers with irregular morphology. The development of fibrous mats using a dual solvent combination resulted in fine pores on the fiber structure. Scanning electron microscope (SEM) images showed that the surface morphology of the fibers in the produced fiber mats (PCL and PCL-CA) was highly porous. Gas chromatography-mass spectrometry (GC-MS) analysis revealed that the CA extract contained 3-methyl mannoside as the predominant component. The in vitro cell line studies using NIH3T3 fibroblasts demonstrated that the CA-PCL nanofiber mat was highly biocompatible, supporting cell proliferation. Hence, we conclude that the c-spun, CA-incorporating nanofiber mat can be employed as a tissue-engineered construct for wound healing applications.

2.
Int J Biol Macromol ; 106: 712-718, 2018 Jan.
Article in English | MEDLINE | ID: mdl-28823513

ABSTRACT

Starch is an emerging polymer in biomedical research area due to its ease of availability, low- cost and biological values. Starch polymer has been used as powder and film in applications such as tissue engineering and hemostatic application. Starch in fibrous form is very difficult to produce due to the branched amylopectin structure. With the advent of electrospinning fibrous form of starch is attempted by various researchers. The present paper reports comprehensive review of attempts made on electrospinning of starch and its potential applications in biomedical and tissue engineering.


Subject(s)
Amylopectin/chemistry , Polymers/chemistry , Starch/chemistry , Tissue Engineering , Biomedical Technology , Hemostatics/chemistry , Humans
3.
Cell Biol Int ; 35(1): 73-80, 2011 Jan.
Article in English | MEDLINE | ID: mdl-20923413

ABSTRACT

Several studies are currently ongoing to construct synthetic bone-like materials with composites of natural and polymeric materials with HA (hydroxyapatite). The present study aims to fabricate composite nanofibrous substrate of Chit/HA (chitosan/HA - 80:25) prepared by dissolving in TFA/DCM (trifluoroacetic acid/dichloromethane) (70:30, w/w) for 5 days and electrospun to fabricate a scaffold for bone tissue engineering. HA (25 wt %) was sonicated for 30 min to obtain a homogenous dispersion of nanoparticles within the Chit (80 wt %) matrix for fabricating composite nanofibrous scaffold (Chit/HA). The nanofibres of Chit and Chit/HA were obtained with fibre diameters of 274 ± 75 and 510 ± 198 nm, respectively, and characterized by FESEM (field emission scanning electron microscopy) and FTIR (Fourier transform infrared). The interaction of hFOBs (human fetal osteoblasts) and nanofibrous substrates were analysed for cell morphology (FESEM), mineralization [ARS (Alizarin Red-S) staining], quantification of minerals and finally identified the elements present in Chit/HA/osteoblasts by EDX (energy-dispersive X-ray) analysis. EDX analysis confirmed that the spherulites contain calcium and phosphorus, the major constituents in calcium phosphate apatite, the mineral phase of the bone. Mineralization was increased significantly (P<0.001) up to 108% in Chit/HA compared with Chit nanofibres. These results confirmed that the electrospun composite Chit/HA nanofibrous substrate is a potential biocomposite material for the proliferation and mineralization of hFOBs required for enhanced bone tissue regeneration.


Subject(s)
Bone Regeneration , Nanofibers/chemistry , Osteoblasts/chemistry , Tissue Scaffolds/chemistry , Biocompatible Materials/chemistry , Calcification, Physiologic , Cells, Cultured , Chitosan/chemistry , Humans , Hydroxyapatites/chemistry , Materials Testing , Osteoblasts/physiology , Tissue Engineering
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