Synthesis of metal nanoparticles using Heliconia rostrata leaf extract and their antiproliferative and apoptotic property

Mallesha, L.; Vinay, G.; Rekha, N.

Growing Science » Current Chemistry Letters » Synthesis of metal nanoparticles using Heliconia rostrata leaf extract and their antiproliferative and apoptotic property

Journals

CCL Volumes

Volume 1 (23)
- Issue 1 (7)
- Issue 2 (5)
- Issue 3 (6)
- Issue 4 (5)

Volume 2 (26)
- Issue 1 (7)
- Issue 2 (6)
- Issue 3 (6)
- Issue 4 (7)

Volume 3 (30)
- Issue 1 (7)
- Issue 2 (10)
- Issue 3 (8)
- Issue 4 (5)

Volume 4 (21)
- Issue 1 (5)
- Issue 2 (5)
- Issue 3 (6)
- Issue 4 (5)

Volume 5 (20)
- Issue 1 (5)
- Issue 2 (5)
- Issue 3 (5)
- Issue 4 (5)

Volume 6 (20)
- Issue 1 (5)
- Issue 2 (5)
- Issue 3 (5)
- Issue 4 (5)

Volume 7 (15)
- Issue 1 (4)
- Issue 2 (4)
- Issue 3 (4)
- Issue 4 (3)

Volume 8 (20)
- Issue 1 (5)
- Issue 2 (5)
- Issue 3 (5)
- Issue 4 (5)

Volume 9 (20)
- Issue 1 (5)
- Issue 2 (5)
- Issue 3 (5)
- Issue 4 (5)

Volume 10 (43)
- Issue 1 (5)
- Issue 2 (7)
- Issue 3 (17)
- Issue 4 (14)

Volume 11 (43)
- Issue 1 (14)
- Issue 2 (11)
- Issue 3 (10)
- Issue 4 (8)

Volume 12 (78)
- Issue 1 (21)
- Issue 2 (22)
- Issue 3 (20)
- Issue 4 (15)

Volume 13 (68)
- Issue 1 (23)
- Issue 2 (17)
- Issue 3 (16)
- Issue 4 (12)

Countries

Current Chemistry Letters

ISSN 1927-730x (Online) - ISSN 1927-7296 (Print) Quarterly Publication Volume 7 Issue 2 pp. 65-72 , 2018

Synthesis of metal nanoparticles using Heliconia rostrata leaf extract and their antiproliferative and apoptotic property Pages 65-72 Download PDF

Authors: Lingappa Mallesha, Guruswamy Vinay, Nanjappagowda Dharmappa Rekha

DOI: 10.5267/j.ccl.2018.4.001

Keywords: Heliconia rostrate, Nanoparticles, Anti-proliferative activity

Abstract: An ecofriendly methods for the synthesis of medicinally important class of heterocyclic scaffold, pyrazole 4-carbonitrile derivatives by one pot three component reaction of malononitrile, phenyl hydrazine and aromatic aldehyde has been achieved at room temperature. Greener protocols of reaction are followed by using sodium chloride to accelerate the reaction in aqueous media. Present methodology is a condition based divergence on synthesis of pyrazole by using simple salts, which offers several advantages like use of aqueous media and high yield of product along with short reaction time, simple work up procedure, no waste or by products, avoid the use of heavy metals or nanoparticles are the fascinating characteristics of reaction.

How to cite this paper

 Mallesha, L., Vinay, G & Rekha, N. (2018). Synthesis of metal nanoparticles using Heliconia rostrata leaf extract and their antiproliferative and apoptotic property.Current Chemistry Letters, 7(2), 65-72.

Refrences

1. Raveendran P., Fu J., and Wallen S. L. (2006). A simple and green method for the synthesis of Au, Ag and Au-Ag alloy nanoparticles. Green Chem., 8 (1) 34-38.
2. Huang J., Li Q., Sun D., Lu Y., Su Y., Yang X., Wang H., Shao W., He N., Hong J., and
Chen C. (2007). Biosynthesis of silver and gold nanoparticles by novel sundried Cinnamomum camphora leaf. Nanotechnol., 18 (10) 105104-105115.
3. Hashmi S. K., and Hutchings G. J. (2006). Gold catalysis. Angew. Chem. Int. Ed., 45 (47) 7896-7936.
4. Magudapathy P., Gangopadhyay P., Panigrahi B. K., Nair K. G. M., and Dhara S. (2001). Electrical transport studies of Ag nanoclusters embedded in glass matrix. Physica B, 299 (1-2) 142-146.
5. Bruno A O., and David J. F. (2004). Sparse coding of sensory inputs. Curr. Opin. Neurol., 14 (4) 481-487.
6. Rao C. N. R., and Cheetham A. K. (2001). Science and technology of nanomaterials: current status and future prospects. J. Mater. Chem. 11 (12) 2887-2894.
7. Zhang S. X., Wang N., Yu H. J., Niu, Y. M., and Sun C. Q. (2005). Covalent attachment of glucose oxidase to an Au electrode modified with gold nanoparticles for use as glucose biosensor. Bioelectrochem., 67 (1) 15-22.
8. Sun Y., and Xia Y. (2002). Shape-controlled synthesis of gold and silver nanoparticles. Science, 298 (5601) 2176-2179.
9. EI-Sayed H., Huang X., and EI-Sayed M. A. (2006). Selective laser photo-thermal therapy of epithelial carcinoma using anti-EGFR antibody conjugated gold nanoparticles. Cancer Lett., 239 (1) 129-135.
10. Brako L., and Zarucchi J. L. (2016). Catalogue of the flowering plants and gymnosperms of peru. Monogr. Syst. Bot. Mo. Bot. Gard., 45 (i-xl) 1286-1287.
11. Mathina and Rajalakshmi R. (2016). Heliconia rostrata flower extract–A new eco-friendly inhibitor for mild steel acid corrosion. Chem. Sci. Rev. Lett., 5 (17) 72-82.
12. Geetha R., Ashokkumar T., Tamilselvan S., Govindaraju, Sadiq M., and Singaravelu G. (2013). Green synthesis of gold nanoparticles and their anticancer activity. Cancer Nano., 4 (4-5) 91-98.
13. Sasikala, Linga Rao M., Savithramma N., and Prasad T. N. V. K. V. (2015). Synthesis of silver nanoparticles from stem bark of Cochlospermum religiosum (L.) Alston: an important medicinal plant and evaluation of their antimicrobial efficacy. Appl. Nanosci., 5 (7) 827-835.
14. Ravichandran V., Tiah Z. X., Subashini G., Terence F. W. X., Eddy F. C. Y., Nelson J., and Sokkalingam A. D. (2011). Biosynthesis of silver nanoparticles using mangosteen leaf extract and evaluation of their antimicrobial activities. J. Saudi. Chem. Soc., 15 (2) 113-120.
15. Rosarin F. S., Arulmozhi V., Nagarajan S., and Mirunalini S. (2013) Antiproliferative effect of silver nanoparticles synthesized using amla on Hep2 cell line. Asian Pac. J. Trop. Med., 6 (1) 1-10.
16. Rekha N. D., Aradhya S. M., and Jayashree K. (2015). The antiangiogenic, antioxidant and proapototic chemopreventive properties of tannins from memecylon malabaricum. Int. J. Pharm. Sci. Res., 6 (1) 259-266.
17. Belakavadi M., and Salimath B. P. (2005). Mechanism of inhibition of ascites tumor growth in mice by curcumin is mediated by NF-kB and caspase activated dnase. Mol. Cell Biochem., 273 (1-2) 57-67.
18. Danladi J., Mariga A. A., Yaro J. D., Ahmed S. A., and Akpulu S. P. (2013). Comparative studies of dry and wet cervical smear in human. Asian J. Med. Chem., 5 (2) 41-43.