Microbiological Investigation on Some Biodegradable Plastics used as Packaging Materials

Authors

  • Rosemary M. Gutierrez Department of Biology College of Science University of the Philippines Baguio
  • Socorro Martha Meg-ay V. Daupan
  • Ann Ville Fabian
  • Cindy Cristel Miclat

Keywords:

Biodegradation, Low Density Polyethylene (LDPE), Oxo-biodegradable Plastic (OBD), Scanning Electron Microscopy (SEM)

Abstract

In the past several years, many biodegradable plastics have been introduced in the commercial market because ordinary, non-biodegradable plastics are known to be recalcitrant to microbial attack. When these types of plastics accumulate  in our environment, it is the primary source of  water and land pollution and other environmental problems like spread of diseases and flooding.   The degrading abilities of two bacterial species, Cellulomonas flavigena and Arthrobacter luteus and the white rot fungus Phanerochaete chrysosporium were investigated in the laboratory by incubating strips of biodegradable plastics with pure bacterial cultures in  petri dishes and determining their  weight loss through time. Soil burial tests were also undertaken for three types of biodegradable plastics to investigate on the degrading abilities of the natural soil microflora for  up to 90 days.  Interestingly, the  white fungus Phanerochaete chrysosporium, was  able to degrade the ordinary non-biodegradable low density polyethylene (LDPE) plastic at a greater rate, as indicated by  a higher percent weight loss as compared to the weight loss of  the oxo-biodegradable plastic (OBD). Scanning Electron Microscope (SEM) analyses of the two types  of plastics incubated with pure cultures of P. chrysosporium  showed signs of degradation like holes, cracks, striations and flakes on the surfaces of LDPE and OBD.  Pure cultures of microorganisms used in this study are known to possess enzymes like amylases, cellulases,  peroxidases, laccases and other ligninolytic enzymes that support a wide range  of degradation of several aromatic compounds which might be responsible for the degradation of plastics observed in this study.

Author Biography

  • Rosemary M. Gutierrez, Department of Biology College of Science University of the Philippines Baguio
    Department of Biology/Associate Professor of Biology

References

Shah A.A., Hasan F., Hameed S., Ahmed S. 2008. Biodegradation of Plastics: A Comprehensive Review. Biotechnology Advances 26, 246-265.

Ren X. 2003. Biodegradable plastics: a solution or a challenge? Journal of Cleaner Production 11, 27-40.

Abd-El-haleem D., Amara A., Zaki S. Abulhamd A. Abulreesh G. 2007. Biosynthesis of biodegradable polyhydroxyalkanotes biopolymers in genetically modified yeasts; Int. J. Environ. Sci. Tech., 4 (4): 513-520.

Shah A.A. 2007, Role of Microorganisms in Biodegradation of Plastics. Department of Microbiology. Quaid-iAzam University, Islamabad.

Salmoral EM, Gonzalez MC, and Mariscal MP. 2000. Biodegradable plastic made from bean products. Industrial Crops and Products (Issues1-2) 217-225.

Ohtaki A. Nakasaki K. 2000. Comparison of the weight-loss degradability of various biodegradable plastics under laboratory composting conditions, J. Mater Cycles Waste Manag. 2:118-124.

Gilmore D.F. Antoun S., Lenz R.W. Goodwin S., Austin R., Fuller R.C., 1992. The fate of biodegradable plastics in municipal leaf compost. J.Ind Microbiol 10:199-206.

Johnson K.E., Pometto III A.L., Nikolov Z.L. 1993. Degradation of degradable starch-polyethylene plastics in a compost environment. Appl Environ Microbiol 59:1155-1161.

Labuzek S., Nowak B., and Pajak J. The susceptibility of polyethylene modified with bionelle to biodegradation of filamentous fungi. Polish Journal of Environmental Studies. 2004 13:59-68.

Rudeekit Y., Thanawasee L. Nukul E, Kongkiat K. 2010. Comparative degradation of biodegradable plastics by aerobic microorganisms using ASTM D and ASTM D as standard methods. National Metal and Materials Technology Center. Phathumthani 12-120.

Gould J.M., Gordon S.H., Dexter L.B. and Swanson C.L. 1990. Biodegradation of starch containing plastics. American Chemical Society. Canadian Harvest USA. Cambridge, MN.

Steinbuchel A. (ed) 2003. Biopolymers, Vol 9, Wiley-VCH, Weinheim

Glass J.E., and Swift G. 2003. Agricultural and polysynthetic Polymers, Biodegradation and Utilization. ACS Symposium Series 433, American Chemical Society, Washington DC, 9-64.

Griffin G. 1994. Chemistry and technology of biodegradable polymers. Blackie Academic Professional

Artham T. and Doble M. 2008. Biodegradation of Aliphatic and Aromatic Polycarbonates. Macromol Biosci 8(1):14–24 January.

Gu J.D., Ford T.E., Mitton D.B., Mitchell R. 2000. Microbial degradation and deterioration of polymeric materials. In: Revie W, editor. The Uhlig Corrosion Handbook. 2nd Edition. New York: Wiley; p. 439–460.

Chanda M and Roy S.K. 1998. Plastics Technology Handbook, 3rd Edition, New York : Marcel Dekker.

Zheng Y., Yanful E.K., and Bassi A.S. 2005. A review of plastic waste biodegradation. Critical Reviews in Biotechnology. 25: 243-250.

Milstein O., R Gersonde, A Huttermann, M J Chen and J J Meister. 1992. Fungal biodegradation of lignopolystyrene graft copolymers. Appl. Environ. Microbiol., 58(10):3225.

Barratt S.R., Ennos A.R., Greenhalgh M., Robson G.D., Handley PS. 2003. Fungi are the predominant micro-organisms responsible for degradation of soil-buried polyester polyurethane over a range of soil water holding capacities. J. Appl. Microbiol. 95:78 – 85.

Russell J.R., Huang J., Anand P., Kucera K., Sandoval A.G., Dantzler K.W., Hickman D., Jee J., Kimovec F.M., Koppstein D., Marks D.H., Mittermiller P.A., Núñez,S.J. Santiago M., Townes M.A., Vishnevetsky M., Williams N.E., Vargas M.P.N., Boulanger L., Slack C.B. and Strobel S.A. 2011. Biodegradation of polyester polyurethrane by endophytic fungi. Appl. Environ. Microbiol. 2011, 77(17): 6076.

Reddy CA. and Souza TMD. 1994. Physiology and molecular biology of the lignin peroxidases of Phanerochaete chrysosporium. FEMS Microbiol. Rev. 13: 137-152.

Dey S., Maiti T.K., Saha N., Banerjee R., Bhattacharyya, B.C., 1991. Extracellular protease and amylase activities in ligninase producing liquid culture of Phanerochaete chrysosporium. Process Biochem. 26, 325–329.

Sethuraman, A., Akin, D.E., Erikson, K.E.L., 1998. Plant-cell-wall degrading enzymes produced by the white-rot fungus Ceriporiopsis subvermispora. Biotechnol. Appl. Biochem. 27, 37–47.

Carillo R.T, Vasques R.R., Cervantes D.D., Torres H.V. Guzman A.M. and Dominquez A.T. 2003. Starch- based plastic polymer degradation by the white rot fungus Phanerocharete chrysoporium grown on sugarcane bagasse pith: enzyme production. Bioresource Technology (86), 1-5.

Urooja Z., Houlden A., and Robson G.D., 2013. Fungal communities associated with the biodegradation of polyester polyurethane buried under compost at different temperatures. Appl. Environ. Microbiol., 79(23):7313.

Downloads

Published

2015-02-15

How to Cite

Microbiological Investigation on Some Biodegradable Plastics used as Packaging Materials. (2015). Asian Journal of Applied Sciences, 3(1). https://ajouronline.com/index.php/AJAS/article/view/2153

Similar Articles

11-20 of 243

You may also start an advanced similarity search for this article.