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References
Burja A.M., Banaigs B., AbouMansour E., Burgees J.G., and Write P.C., 2001, Marine cyanobacteria a prolific source of natural products. Tetrahedron. 57:
9347-9377.
Chen K.J., Tseng C.K., Chang F.R., Yang J.I., Yeh C.C., Chen W.C., Wu S.F, Chang H.W., Lee J.C., 2013, Aqueous extract of the edible Gracilariatenuistipitata
inhibits hepatitis C viral replication via cyclooxygenase-2 suppression andreduces virus-induced inflammation, PLoS One 8(2):e57704.
Cornish M.L., Garbary D.J., 2010. Antioxidants from macroalgae: Potential applications in human health and nutrition, Algae 25, 155–171.
De Almeida C.L., FalcaoHde S., Lima G.R., Montenegro Cde A., Lira N.S., de Athayde-Filho P.F., Rodrigues L.C., de Souza M.F., Barbosa-Filho J.M., Batista
L.M.,2011. Bioactivities from marine algae of the genus gracilaria. Int J MolSci, 12(7):4550–4573.
Elsie H. B., and DhanaRajan M.S., 2010, Evaluation of antibacterial activity and phytochemical screening of
Gelidiumacerosa.
, J PharamSci Res., 2(11):
704-707.
Etahiri S., Bultel-PoncéV., Elkouri A .E., Assobhei O., Zaoui D.,and Guyot M.,2003, Antibacterial activities of marine algae from the Atlantic coast of
Morocco, Mar Life 13:3-9.
Gupta S., and Abu – Ghannam N., 2011, Bioactive Potential and Possible Health Effectsof Edible Brown Seaweeds, Trends in Food Science & Technology,
22 ,315 – 326.
Kajiwara T., Matsui K., Akakabe Y., Murakawa T., and Arai C., 2007. Antimicrobial Browning Inhibitory Effect of Flavor Compounds in Seaweeds,
Developments in Applied Phycology , 1 , 187 – 196.
Kidgell J.T., de Nys R., Hu Y., Paul N.A., Roberts D.A., 2014, Bioremediation of acomplex industrial effluent by bio sorbents derived from freshwater
microalgae, PLOS ONE 9: (6) 94706.
Kim K.N., Heo S.J., Kang S.M., Ahn, G., Jeon Y.J., 2010. Fucoxanthin induces apoptosis in human leukemia HL-60 cells through a ROS-mediated Bcl-xL
pathway,
Toxicol. in Vitro
,
24
, 1648–1654.
Kohen R., and Nyska A.2002, Oxidation of biological systems: Oxidative stress phenomena,antioxidants, redox reactions, and method for their quantification,
Toxicol. Pathol. 30(6):620 650.
Lazarus J.V., Sperle I., Maticic M., and Wiessing L., 2014 “A systematic review of Hepatitis C virus treatment uptake among people who inject drugs in the
European Region,
BMC Infectious Diseases
. 14: 6.
Lee D.S., Park W.S., Heo S.J., Cha S.H., Kim D., Jeon Y.J., Park S.G., Seo S.K., Choi J.S., Park S.J., 2011, Polyopesaffinis alleviates airway inflammation in a
murinemodel of allergic asthma. J Biosci 36 (5):869 – 877.
Lima-Filho J.V. M., Caravalho A. F. F. U., Freitas S. M., 2002. Antibacterial activity of extracts of six macroalgae from the northeastern Brasilian Coast. Bras J
Microbiol. 33:211-14.
Roberts D.A., Paul N.A., Dworjanyn S.A., Hu Y., Bird M., de Nys R., 2014. Gracilaria waste biomass (sampahrum putlaut) as a bio resource for selenium bio
sorption, J. Appl. Phycol., 1-10.
Sibeni F., Calderini F., 2012, A Tool for Fishery Statistics Analysis. Food and Agriculture Organisation of the United Nations, Fish Stat J 101, 2549- 2553.
Souza B.W., Cerqueira M.A., Martins J.T., Quintas M.A., Ferreira A.C., Teixeira J.A., Vicente A.A.,2011, Antioxidant potential of two red seaweeds from the
Brazilian coasts, J Agric Food Chem 59(10):5589–5594.
Tabarsa M., Rezaei M., Ramezanpour Z., and Waaland J.R., 2012, Chemical compositions of the marine algae Gracilariasalicornia (Rhodophyta) and
Ulvalactuca(Chlorophyta) as a potential food source, J Sci Food Agric 92: 2500-2506.
Thomas N.V., Kim S.K., 20011. Potential pharmacological applications of polyphenolicderivates from marine brown algae, Environ. Toxicol. Pharmacol. 32,
325–335.
Yanti F., Heryanto K., Andre S., Jae-Kwan H., 2015, Antioxidant Potentials of Marine Red and Green Algae Extracts
In-vitro
, Sch. Acad. J. Pharm., 4(3):
177-180.
Yasuhara-B.J., and Lu Y., 2010, “Marine compounds and their antiviral activities,
Antiviral Research
86: (3) 231–240.
