Browsing by Author "Tanmay Bera"

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Characterization of antiplatelet properties of silver nanoparticles
(2009) Siddhartha Shrivastava; Tanmay Bera; Sunil K. Singh; Gajendra Singh; P. Ramachandrarao; Debabrata Dash
Thrombotic disorders have emerged as serious threat to society. As anticoagulant and thrombolytic therapies are usually associated with serious bleeding complications, the focus has now shifted to regulating and maintaining platelets in an inactive state. In the present study we show that nanosilver has an innate antiplatelet property and effectively prevents integrin-mediated platelet responses, both in vivo and in vitro, in a concentration-dependent manner. Ultrastructural studies show that nanosilver accumulates within platelet granules and reduces interplatelet proximity. Our findings further suggest that these nanoparticles do not confer any lytic effect on platelets and thus hold potential to be promoted as antiplatelet/antithrombotic agents after careful evaluation of toxic effects. © 2009 American Chemical Society.
Characterization of biomimetically synthesized Hap-Gel nanocomposites as bone substitute
(2008) Tanmay Bera; A.N. Vivek; S.K. Saraf; P. Ramachandrarao
There is an increasing demand for an affordable and easy-to-fabricate material to help patients having a long bone gap. In this paper, we describe the biomimetic synthesis of Hap-Gel in situ nanocomposite powders with varied proportions. Their biocompatibility and bone regeneration abilities were assessed on a rabbit model. The use of Hap crystals and Gel molecule, the soluble form of bone protein, makes the nanocomposites comparable to natural bone in constituents. The application of biomimetic principles improves crystal morphology and the interaction of Hap crystals with the Gel molecules as seen through in vitro characterizations. Out of the various compositions studied, one with 80:20 proportions of Hap to Gel proved to be closest to the characteristics of natural bone. The immunological response to this composite, assessed through intradermal inoculation, did not reveal any reaction. The in vivo implantation studies in the femoral condyle of the animals, as assessed by serial post-operative follow-up radiography and the histological evaluation, revealed a good biocompatibility and bone-regeneration ability of the material. Thus, nanocomposites of Hap-Gel have a great potential for serving as an effective and affordable biomaterial for bone grafting applications. © 2008 IOP Publishing Ltd.
Characterization of enhanced antibacterial effects of novel silver nanoparticles
(Institute of Physics Publishing, 2007) Siddhartha Shrivastava; Tanmay Bera; Arnab Roy; Gajendra Singh; P. Ramachandrarao; Debabrata Dash
In the present study, we report the preparation of silver nanoparticles in the range of 10-15 nm with increased stability and enhanced anti-bacterial potency. The morphology of the nanoparticles was characterized by transmission electron microscopy. The antibacterial effect of silver nanoparticles used in this study was found to be far more potent than that described in the earlier reports. This effect was dose dependent and was more pronounced against gram-negative bacteria than gram-positive organisms. Although bacterial cell lysis could be one of the reasons for the observed antibacterial property, nanoparticles also modulated the phosphotyrosine profile of putative bacterial peptides, which could thus affect bacterial signal transduction and inhibit the growth of the organisms. © IOP Publishing Ltd.
MWCNTs as reinforcing agent to the Hap-Gel nanocomposite for artificial bone grafting
(2010) Santosh K. Yadav; Tanmay Bera; Preeti S. Saxena; Ashok K. Maurya; Rajendra S. Garbyal; Robert Vajtai; P. Ramachandrarao; Anchal Srivastava
The essence of this investigation is to explore MWCNTs as reinforcing agents to strengthen Hap-Gel nanocomposites for artificial bone grafting applications without significantly compromising their biocompatibility. Hap-Gelatin composites, reinforced with various proportions of MWCNTs, were synthesized to optimize the MWCNT content in the composites which yield commendable improvement in the strength. The morphological studies reveal that the MWCNTs act as templates for nucleation of Hap crystals. The biocompatibility of MWCNT reinforced Hap-Gelatin composites were evaluated in animal model through the histopathological investigation of tissues from skin, kidney, and liver. On histopathological examination, no noticeable alteration due to toxicity was found for lower concentration of MWCNTs. Mild reversible changes in the liver and tubular damage in kidney have been observed for higher concentration (4 wt % of MWCNTs). It can be inferred from the findings that MWCNTs, in proportions less than 4%, can successfully be used to reinforce the Hap-Gel nanocomposite to improve its mechanical properties. However, how safe would these CNT reinforced bone implants would be when used for prolonged period in actual physiological conditions needs to be investigated further. © 2009 Wiley Periodicals, Inc.
Study of mechanism of enhanced antibacterial activity by green synthesis of silver nanoparticles
(2011) Upendra Kumar Parashar; Vinod Kumar; Tanmay Bera; Preeti S Saxena; Gopal Nath; Sunil K Srivastava; Rajiv Giri; Anchal Srivastava
The extensive use of silver nanoparticles needs a synthesis process that is greener without compromising their properties. The present study describes a novel green synthesis of silver nanoparticles using Guava (Psidium guajava) leaf extract. In order to compare with the conventionally synthesized ones, we also prepared Ag-NPs by chemical reduction. Their optical and morphological characteristics were thoroughly investigated and tested for their antibacterial properties on Escherichia coli. The green synthesized silver nanoparticles showed better antibacterial properties than their chemical counterparts even though there was not much difference between their morphologies. Fourier transform infrared (FTIR) spectroscopic analysis of the used extract and as-synthesized silver nanoparticles suggests the possible reduction of Ag + by the water-soluble ingredients of the guava leaf liketannins, eugenol and flavonoids. The possible reaction mechanism for the reduction of Ag+ has been proposed and discussed. The time-dependent electron micrographs and the simulation studies indicated that a physical interaction between the silver nanoparticles and the bacterial cell membrane may be responsible for this effect. Based on the findings, it seems very reasonable to believe that this greener way of synthesizing silver nanoparticles is not just an environmentally viable technique but it also opens up scope to improve their antibacterial properties. © IOP Publishing Ltd.