Browsing by Author "Raj, DK"
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Item Evaluation of Polypropylene Hollow-Fiber Prototype Bioreactor for Bioartificial Liver(TISSUE ENGINEERING PART A, 2013) Palakkan, AA; Raj, DK; Rojan, J; Raj, RGS; Kumar, PRA; Muraleedharan, CV; Kumary, TVHepatocytes in high density are a requisite for the functional performance of complex devices such as bioartificial liver (BAL). In addition to high cell number, efficient mass transfer is also a key parameter in such devices. High-density culture of cells and efficient mass transfer can be achieved in BAL with hollow-fiber-based bioreactors. Even though different types of hollow fibers have been tried in a BAL, prospects of using polypropylene hollow fibers are not well evaluated. In this study, a prototype of bioreactor with polypropylene hollow fibers was fabricated and evaluated for cytotoxicity and hepatocyte function. High density of HepG2/adult hepatocyte cultures was used to evaluate polypropylene hollow fiber to support the biochemical activities (albumin and urea production), ammonia detoxification, and gene expression and to provide effective oxygenation. The results confirmed that a polypropylene hollow-fiber prototype bioreactor is able to provide efficient oxygenation and supported hepatocyte functions in a high-density culture.Item Galactosylated alginate-curcumin micelles for enhanced delivery of curcumin to hepatocytes(INTERNATIONAL JOURNAL OF BIOLOGICAL MACROMOLECULES, 2016) Sarika, PR; James, NR; Kumar, PRA; Raj, DKGalactosylated alginate-curcumin conjugate (LANH(2)-Alg Ald-Cur) is synthesized for targeted delivery of curcumin to hepatocytes exploiting asialoglycoprotein receptor (ASGPR) on hepatocytes. The synthetic procedure includes oxidation of alginate (Alg), modification of lactobionic acid (LA), grafting of targeting group (modified lactobinic acid, LANH(2)) and conjugation of curcumin to alginate. Alginate-curcumin conjugate (Alg-Cur) without targeting group is also prepared for the comparison of properties. LANH(2)-Alg Ald-Cur self assembles to micelle with diameter of 235 +/- 5 nm and zeta potential of -29 mV in water. Cytotoxicity analysis demonstrates enhanced toxicity of LANH(2)-Alg Ald-Cur over Alg-Cur on HepG2 cells. Cellular uptake studies confirm that LANH(2)-Alg Ald-Cur can selectively recognize HepG2 cells and shows higher internalization than Alg-Cur conjugate. Results indicate that LANH(2)-Alg Ald-Cur conjugate micelles are suitable candidates for targeted delivery of curcumin to HepG2 cells. (C) 2016 Elsevier B.V. All rights reserved.Item Galactosylated pullulan-curcumin conjugate micelles for site specific anticancer activity to hepatocarcinoma cells(COLLOIDS AND SURFACES B-BIOINTERFACES, 2015) Sarika, PR; James, NR; Nishna, N; Kumar, PRA; Raj, DKGalactosylated pullulan curcumin conjugate (LANH(2)-Pu Aid-Cur SA) is developed for target specific delivery of curcumin to hepatocarcinoma cells by five step synthetic strategy, which includes oxidation of pullulan (Pu Ald), introduction of amino group to the targeting ligand (LANH(2)), grafting of the LANH(2) to Pu Aid, modification of curcumin (Cur SA) and conjugation of Cur SA to pullulan. Nongalactosylated pullulan curcumin conjugate (Pu-Cur SA) is also prepared to compare the enhancement in cytotoxicity offered by the targeting group. Both LANH(2)-Pu Aid-Cur SA and Pu-Cur SA conjugates could self assemble to micelle in water with hydrodynamic diameters of 355 +/- 9 nm and 363 +/- 10 nm, respectively. Both conjugates show spherical morphology and enhance stability of curcumin in physiological pH. Compared to Pu-Cur SA, LANH(2)-Pu Aid-Cur SA exhibits higher toxicity and internalization towards HepG2 cells. This indicates the enhanced uptake of LANH(2)-Pu Ald-Cur SA conjugate via ASGPR (asialoglycoprotein receptor) mediated endocytosis into HepG2 cells. (C) 2015 Elsevier B.V. All rights reserved.Item Gum arabic-curcumin conjugate micelles with enhanced loading for curcumin delivery to hepatocarcinoma cells(CARBOHYDRATE POLYMERS, 2015) Sarika, PR; James, NR; Kumar, PRA; Raj, DK; Kumary, TVCurcumin is conjugated to gum arabic, a highly water soluble polysaccharide to enhance the solubility and stability of curcumin. Conjugation of curcumin to gum arabic is confirmed by H-1 NMR, fluorescence and UV spectroscopy studies. The conjugate self assembles to spherical nano-micelles (270 +/- 5 nm) spontaneously, when dispersed in aqueous medium. Spherical morphology of the self assembled conjugate is evidenced by field emission scanning electron microscopy and transmission electron microscopy. The self assembly of the amphiphilic conjugate into micelle in aqueous medium significantly enhances the solubility (900 fold of that of free curcumin) and stability of curcumin in physiological pH. The anticancer activity of the conjugate micelles is found to be higher in human hepatocellular carcinoma (HepG2) cells than in human breast carcinoma (MCF-7) cells. The conjugate exhibits enhanced accumulation and toxicity in HepG2 cells due to the targeting efficiency of the galactose groups present in gum arabic. (C) 2015 Elsevier Ltd. All rights reserved.Item Microgravity as a means to incorporate HepG2 aggregates in polysaccharide-protein hybrid scaffold(JOURNAL OF MATERIALS SCIENCE-MATERIALS IN MEDICINE, 2016) Sarika, PR; James, NR; Anilkumar, PR; Raj, DK; Kumary, TVTissue culture under microgravity provides a venue which promotes cell-cell association while avoiding the detrimental effects of high shear stress. Hepatocytes cultured on carriers or entrapped within matrices under simulated microgravity conditions showed improved cell function and proliferation. In the present study, a new approach was adopted where a non-cell adherent scaffold was incorporated with hepatospheroids (HepG2) under microgravity. Gum arabic (GA) was cross-linked with gelatin (GA-Gel) and collagen (GA-Col) to prepare non-cell adherent scaffolds. Microgravity experiments with GA-Gel and GA-Col indicated that GA-Col is a better substrate compared to GA-Gel. Microgravity experiments of GA-Col scaffolds with HepG2 cells confirmed that the non-adherent surface with porous architecture can incorporate hepatocyte spheroids and maintain liver specific functions. Albumin and urea synthesis of hepatocytes was sustained up to 6 days under microgravity conditions in the presence of GA-Col scaffold. This new approach of using non-cell adherent matrix and microgravity environment for developing biological substitutes will be beneficial in tissue engineering, bioartificial liver devices and in vitro safety assessment of drugs.Item Nanogels based on alginic aldehyde and gelatin by inverse miniemulsion technique: synthesis and characterization(CARBOHYDRATE POLYMERS, 2015) Sarika, PR; Kumar, PRA; Raj, DK; James, NRNanogels were developed from alginic aldehyde and gelatin by an inverse miniemulsion technique. Stable inverse miniemulsions were prepared by sonication of noncontinuous aqueous phase (mixture of alginic aldehyde and gelatin) in a continuous organic phase (Span 20 dissolved in cyclohexane). Cross-linking occurred between alginic aldehyde (M) and gelatin (gel) in the presence of borax by Schiff's base reaction during the formation of inverse miniemulsion. The effects of surfactant (Span 20) concentration, volume of the aqueous phase and AA/gel weight ratio on the size of the alginic aldehyde-gelatin (AA-gel) nanoparticles were studied. Nanogels were characterized by DLS, FT-IR spectroscopy, TGA, SEM and TEM. DLS, TEM and SEM studies demonstrated nanosize and spherical morphology of the nanogels. Hemocompatibility and in vitro cytocompatibility analyses of the nanogels proved their nontoxicity. The results indicated the potential of the present nanogel system as a candidate for drug- and gene-delivery applications. (C) 2014 Elsevier Ltd. All rights reserved.Item Preparation, characterization and biological evaluation of curcumin loaded alginate aldehyde-gelatin nanogels(MATERIALS SCIENCE & ENGINEERING C-MATERIALS FOR BIOLOGICAL APPLICATIONS, 2016) Sarika, PR; James, NR; Kumar, PRA; Raj, DKCurcumin, a natural polyphenol exhibits chemopreventive and chemotherapeutic activities towards cancer. In order to improve the bioavailability and therapeutic efficacy, curcumin is encapsulated in alginate aldehyde-gelatin (Alg Ald-Gel) nanogels. Alginate aldehyde-gelatin nanogels are prepared by inverse miniemulsion technique. Physicochemical properties of the curcumin loaded nanogels are evaluated by, Dynamic light scattering (DLS), NMR spectroscopy and Scanning electron microscopy (SEM). Curcumin loaded nanogels show hydrodynamic diameter of 431 +/- 8 nm and a zeta potential of 36 +/- 4 my. The prepared nanogels exhibit an encapsulation efficiency of 72 +/- 2%. In vitro drug release studies show a controlled release of curcumin from nanogels over a period of 48 h. Hemocompatibility and cytocompatibility of the nanogels are evaluated. Bare nanogels are cytocompatible and curcumin loaded nanogels induce anticancer activity towards MCF-7 cells. In vitro cellular uptake of the curcumin loaded nanogels using confocal laser scanning microscopy (CLSM) confirms the uptake of nanogels in MCF-7 cells. Hence, the developed nanogel system can be a suitable candidate for curcumin delivery to cancer cells. (C) 2016 Elsevier B.V. All rights reserved.