Antitumor Efficacy of Silver Nanoparticles Biosynthe-sized from Marine Red Seaweed Halymenia porphyroides Boergesen on Dalton’s Lymphoma Ascites in Mice

DOI:

https://doi.org/10.37285/ijpsn.2021.14.6.5

Authors

  • Vishnu Kiran Manam Unit of Algal Biotechnology and Bionanotechnology, PG and Research Department of Plant Biology and Biotechnology, Pachaiyappa’s College, University of Madra
  • Subbaiah Murugesan Unit of Algal Biotechnology and Bionanotechnology, PG and Research Department of Plant Biology and Biotechnology, Pachaiyappa’s College,

Abstract

The biosynthesized silver nanoparticles from marine red seaweed Halymenia porphyroides against Dalton’s lymphoma ascites (DLA)-induced tumor inoculation was studied for antitumor activity. The biosynthesized silver nanoparticles from marine red seaweed Halymenia porphyroides were given orally to Swiss albino mice (50 mg/kg/day) for 14 days showed a significant reduction in body weight, packed cell volume, andviable tumor cell count when compared to the mice of the DLA control group.The haematological parameters of the treatment group with biosynthesized silver nanoparticles also exhibited increased haemoglobin, RBCs, Platelets, and decreased WBCs compared to the DLA control group of mice. Similarly, the biochemical parameters like total cholesterol, aspartate amino-transferase (AST), alanine aminotransferase (ALT), triglycerides (TL), and alkaline phosphatase (ALP) of the treatment control group with biosynthesized silver nanoparticles reversed the parameters to normal levels compared to the DLA control group of mice. The antitumor efficacy of the biosynthesized silver nanoparticles from Halymenia porphyroides was confirmed based on the haematological, biochemical, life span, packed cell volume, cell count, and histopathological analysis. 

Downloads

Download data is not yet available.

Metrics

Metrics Loading ...

Keywords:

Antitumor, Halymenia porphyroides, Silver nanoparticles, Dalton’s lymphoma ascites (DLA)

Downloads

Published

2021-12-01

How to Cite

1.
Manam VK, Murugesan S. Antitumor Efficacy of Silver Nanoparticles Biosynthe-sized from Marine Red Seaweed Halymenia porphyroides Boergesen on Dalton’s Lymphoma Ascites in Mice . Scopus Indexed [Internet]. 2021 Dec. 1 [cited 2024 Dec. 22];14(6):5683-90. Available from: https://ijpsnonline.com/index.php/ijpsn/article/view/2342

Issue

Section

Research Articles

References

Agarwal RC, Rachana J, Wasim R, and Ovais M (2009). Anti-Carcinogenic effects of Solanumlycopersicum fruit extract on Swiss albino and C57B1 Mice. Asian Pacific J Cancer Prev 10: 379-382.

Al-Sheddi ES, Farshori NN, Al-Oqail MM, Al-Massarani SM, Saquib Q, Wahab R, Musarrat J, Al-Khedhairy AA, and Siddiqui MA (2018). Anticancer Potential of Green Synthesized Silver Nanoparticles Using Extract of Nepeta deflersiana against Human Cervical Cancer Cells (HeLA). Bioinorganic Chemistry and Applications 12.

Appleman D, Edwin R, Skavinski, Abraham M, and Stein (1950).Catalase studies on normal and cancerous rats. Cancer Research10:498-505.

Arun GI and Chaudhari AN. (2013). Biogenic synthesis of nano particles and potential applications: An eco-friendly approach. J Nanomed Nanotech 4(2): 1-7.

Baskar R, Dai J, Wenlong N, Yeo R, and Yeoh KW (2014). Biological response of cancer cells to radiation treatment. Front Mol Biosci 1: 24.

Bhuvaneswari S and Murugesan S (2012). Antitumour activity of Chondrococcus hornemannii and Spyridia fusiformis on Dalton’s lymphoma ascites in mice. Bangladesh J Pharmacol. 7: 173–177.

Buttacavoli M, Albanese NN, Di Cara G, Alduina R, Faleri C, Gallo M, Pizzolanti G, Gallo G, Feo S, Baldi F, and Cancemi P (2017). Anticancer activity of biogenerated silver nanoparticles: an integrated proteomic investigation. Oncotarget 9(11): 9685–9705.

Carpena M, Caleja C, Pereira E, Pereira C, Ćirić A, Soković M, and Prieto MA (2021). Red Seaweeds as a Source of Nutrients and Bioactive Compounds: Optimization of the Extraction. Chemosensors 9(6): 132.

Chabner BA and Collins JM (1990). Cancer chemotherapy: Principles an practice. Lippincott JB, Philadelphia. p 1-15.

Chandini SK, Ganesan PV, Suresh N and Bhaskar (2008). Seaweeds as a source of nutritionally beneficial compounds – A review. J Food Sci Technol 45: 1–13.

Chikara S, Nagaprashantha LD, Singhal J, Horne D, Awasthi S, and Singhal SS (2018). Oxidative stress and dietary phytochemicals: Role in cancer chemoprevention and treatment. Cancer Lett 413: 122–134.

Chitra V., Shrinivas S, and Nandu K (2009). Evaluation of Anticancer activity of Vitexnegundo study. Intl J Pharm Tech Res 1(4): 1485-1489.

Clarkson BD and Burchenal JH (1965). Progress in leukemias. Prog Clin Cancer 10: 625–633.

Dagnelie PC (1997). Some algae are potentially adequate sources of vitamin B-12 for vegans/comments on the paper by Rauma et al., (1995). Journal of Nutrition 127(2): 379.

Heinemann MG, Rosa CH, Rosa GR, and Dias D (2021). Biogenic synthesis of gold and silver nanoparticles used in environmental applications: A review. Trends in Environmental Analytical Chemistry 30: e00129.

Hogland HC (1982). Haematological complication of cancer chemotherapy. Semin Oncol 9: 95–102.

Holdt SL and Kraan S (2011). Bioactive compounds in seaweed: functional food applications and legislation. J Appl Phycol 23: 543–597.

Krishnamurthy V (2005b). Edible seaweeds. Souvenir, National Symposium on Marine Plants, Their Chemistry and Utilization. SRUA & SDMRI. p 4.

Kumari P, Kumar M, Gupta V, Reddy CRK, and Jha B (2010). Tropical marine macroalgae as potential sources of nutritionally important PUFAs. Food Chem 120: 749–757.

Mary KT, Kuttan G, and Kuttan K (1994). Partial purification of Tumuor reducing principle from Helicanthiselasticus. Cancer Letter 81:53-57.

Muthu IS, Selvaraj BMK, Kalimuthu K, and Sangiliyandi G (2010). Antitumor activity of silver nanoparticles in Dalton’s lymphoma ascites tumour model. Intl J Nanomed 5: 753–762.

Nisizawa K (1988). In: Production and utilization of products from commercial seaweeds, (ed Mchaugh D. J.). FAO, 299: 147.

Pucci C, Martinelli C, and Ciofani G (2019). Innovative approaches for cancer treatment: Current perspectives and new challenges. Ecancermedicalscience 13: 961.

Rajesh KS, Malrakodi C, and Venkat KS (2017). Synthesis and characterization of silver nanoparticles from marine brown seaweed and its antifungal efficiency against clinical fungal pathogens. Asian J Pharm Clin Res 10(2): 190-193.

Reitman S and Frankel S (1957). A colorimetric method for the determination of serum glutamic oxaloacetate and glutamic pyrutrasnaminases. American J clin path 28: 56-63.

Rutberg FG, Dubina MV, and Kolikov VA (2008). Effect of silver oxide nanoparticles on tumour growth in vivo. Dokl Biochem Biophys 421:191–193.

Sak K (2012). Chemotherapy and Dietary Phytochemical Agents. Chemother Res Pract 1–11.

Sangiliyandi G, Jung HP, Jae WH, and Jin-Hoi K (2015). Comparative assessment of the apoptotic potential of silver nanoparticles synthesized by Bacillus tequilensis and Calocybe indica in MDA-MB-231 human breast cancer cells: targeting p53 for anticancer therapy. Intl J Nanomed 10: 4203–4223.

Santhosh KH, Senthil KN, and Reghu CH (2007). Anti tumuor activity of Methanolic extract of Hypericum hookerianum on EAC Cell line in Swiss albino mice. J Pharmacological Sci 103: 354-359.

Sathiyanarayanan L, Shinnathambi, Arulmozi, and Chidham-barnathan N (2006). Anti-carcinogenic activity of Leptadeniareti-culataI against Dalton’s ascitic lymphoma. Iranian J Pharm Toxicol 6: 133–136.

Siegel RL, Miller KD, and Jemal (2020). A Cancer statistics. CA Cancer J Clin 70: 7–30.

Singh S, Sharma B, Kanwar SS, and Kumar A (2016). Lead Phytochemicals for Anticancer Drug Development. Front Plant Sci 7: 8973.

Unnikrishnan MC and Kuttan R (1990). Tumuor reducing and anti-carcinogenic activity of selected species. Cancer letter 51: 85-89.

Vasanthi H, Charles DR, Vidyalakshmi KS, and Rajamanickam GV (2006). Free radical scavenging and antioxidant activity of a red alga Acanthophoraspicifera – Relation to its chemical composition. Seaweed Res Utiln 28(1): 119–125.

Vishnu Kiran Mand Murugesan S (2014). In vitro cytotoxic activity of silver nano particle biosynthesized from Colpomeniasinuosa and Halymenia poryphyroides using DLA and EAC cell lines. World J Pharm Sci 2(9): 926.

Vishnu Kiran Mand Murugesan S (2020). Biosynthesis and characterization of silver nanoparticles from marine macroscopic brown seaweed Colpomeniasinuosa (Mertens ex Roth) Derbes and Solier. J Adv Chem Sci 6(1): 663–666.

Vishnu Kiran Mand Murugesan S (2020). Biosynthesis and characterization of silver nanoparticles from marine macroscopic red seaweed Halymenia porphyroides Boergesen (crypton). J Nanosci Tech 6(2): 886–890.

Wypij M, Jędrzejewski T, Trzcińska-Wencel J, Ostrowski M, Rai M, and Golińska P (2021). Green Synthesized Silver Nanoparticles: Antibacterial and Anticancer Activities, Biocompatibility, and Analyses of Surface-Attached Proteins. Frontiers in Microbiology 12: 888.

Zlatkis A, Zak B, and Boyle AJ (1953). A new method for the direct determination of serum cholesterol. J Lab Clin Med 41: 486 – 492.