Large Scale Production of Polyhydroxyalkanoates (PHAs) from Wastewater: A Study of Techno-Economics, Energy Use and Greenhouse Gas Emissions
The biodegradable family of polymers
polyhydroxyalkanoates is an interesting substitute for convectional
fossil-based plastics. However, the manufacturing and environmental
impacts associated with their production via intracellular bacterial
fermentation are strongly dependent on the raw material used and on
energy consumption during the extraction process, limiting their
potential for commercialization. Industrial wastewater is studied in
this paper as a promising alternative feedstock for waste valorization.
Based on results from laboratory and pilot-scale experiments, a
conceptual process design, techno-economic analysis and life cycle
assessment are developed for the large-scale production of the most
common type of polyhydroxyalkanoate, polyhydroxbutyrate.
Intracellular polyhydroxybutyrate is obtained via fermentation of
microbial community present in industrial wastewater and the
downstream processing is based on chemical digestion with
surfactant and hypochlorite. The economic potential and
environmental performance results help identifying bottlenecks and
best opportunities to scale-up the process prior to industrial
implementation. The outcome of this research indicates that the
fermentation of wastewater towards PHB presents advantages
compared to traditional PHAs production from sugars because the
null environmental burdens and financial costs of the raw material in
the bioplastic production process. Nevertheless, process optimization
is still required to compete with the petrochemicals counterparts.
[1] M. Carus, “Production capacities for bio-based polymers in Europe -
status quo and trends towards 2020,” Nova-Institute for Ecology and
Innovation. Press release. July 2013.
[2] R. J. Van Wegen, Y. Ling, and A. P. J Middelberg, “Industrial
production of polyhydroxyalkanoates using Escherichia coli: An
economic analysis,” Chemical Engineering Research and Design, vol.
76, pp. 417-426, March 1998.
[3] C. S. K., Reddy, R. Ghai, Rashmi, and V. C. Kalia,
“Polyhydroxyalkanoates: an overview,” Bioresource Technology, vol.
87, pp. 137-146, April 2003.
[4] R. A. J Verlinden, D. J. Hill, M. A. Kenward, C. D. Williams, and I.
Radecka, “Bacterial synthesis of biodegradable polyhydroxyalkanoates,”
Journal of Applied Microbiology, vol. 102, pp. 1437–1449, June 2007.
[5] L. L. Madison, and G.W. Huisman, “Metabolic engineering of poly(3-
hydroxyalkanoates): from DNA to plastic,” Microbiology and Molecular
Biology Reviews, vol. 63, pp. 21-53, March 1999.
[6] H. Salehizadeh, and M. C. M. Van Loosdrecht, “Production of
polyhydroxyalkanoates by mixed culture: recent trends and
biotechnological importance,” Biotechnology Advances, vol. 22, pp.
261-279, January 2004.
[7] Y. Jiang, L. Marang, J. Tamis, M. C. M. van Loosdrecht, H. Dijkman,
and R. Kleerebezem, “Waste to resource: Converting paper mill
wastewater to bioplastic,” Water Research, vol. 46, pp. 5517-5530,
November 2012.
[8] J. Tamis, L. Katlin, Y. Jiang, M. C. M. van Loosdrecht, and R.
Kleerebezem, “Enrichment of Plasticicumulans acidivorans at pilot-scale
for PHA production on industrial wastewater,” Journal of
Biotechnology, to be published.
[9] N. Jacquel, C.-W. Lo, Y.-H. Wei, H.-S. Wu, and S. S. Wang, “Isolation
and purification of bacterial poly(3-hydroxyalkanoates),” Biochemical
Engineering Journal, vol. 39, pp. 15–27, April 2008.
[10] L. A. Smith, K. J. Roberts, D. Machin, and G. McLeod, “An
examination of the solution phase and nucleation properties of sodium,
potassium and rubidium dodecyl sulphates,” Journal of Crystal Growth,
vol. 226, pp. 158–167, June 2001.
[11] R. Smith, Chemical process design and integration, pp. 17-31,
Chichester: John Wiley & Sons, 2005.
[12] R. K. Sinnott, Coulson & Richardson's chemical engineering. Volume 6:
chemical engineering design, fourth ed., pp. 246-279, Oxford: Elsevier,
2005.
[13] G. D. Ulrich, and P. T. Vasudevan, “How to estimate utility costs,”
Chemical Engineering, vol. 4, pp. 66-69, April 2006.
[14] International Standards Organization (ISO), ISO 14040:2006,
“Environmental management. Life cycle assessment. Principles and
framework,” 2006a.
[15] International Standards Organization (ISO), ISO 14044:2006,
“Environmental management. Life cycle assessment. Requirements and
guidelines,” 2006b.
[16] U.S. Environmental Protection Agency, “Accounting framework for
biogenic CO2 emissions from stationary sources,” Office of
Atmospheric Programs, Climate Change Division, Washington, DC,
2011.
[17] P. Pawelzik, M. Carus, J. Hotchkiss, R. Narayan, S. Selke, M. Wellisch,
M. Weiss, B. Wicke, and M. K. Patel, “Critical aspects in the life cycle
assessment (LCA) of bio-based materials–Reviewing methodologies and
deriving recommendations,” Resources, Conservation and Recycling,
vol. 73, pp. 211–228, April 2013.
[18] Y. Jiang, G. Mikova, R. Kleerebezem, L. A. M. van der Wielen, and
M.C. Cuellar, “Feasibility study of an alkaline-based chemical treatment
for polyhydroxyalkanoates purification from mixed enriched culture,”
unpublished.
[19] D. Michael, “Biodegradable polymer supply chains: implications and
opportunities for agriculture,” Wondu Holdings, Sydney, 2004.
[20] J. Choi, and S. Y. Lee, “Process analysis and economic evaluation for
Poly(3-hydroxybutyrate) production by fermentation,” Bioprocess
Engineering, vol. 17, pp. 335-342, November 1997.
[21] M. Akiyama, T. Tsugea, and Y. Doia, “Environmental life cycle
comparison of polyhydroxyalkanoates produced from renewable carbon
resources by bacterial fermentation,” Polymer Degradation and Stability,
vol. 80, pp. 183–194, February 2003.
[22] S. Y. Lee, and J. Choi, “Effect of fermentation performance on the
economics of poly(3-hydroxybutyrate) production by Alcaligenes latus,”
Polymer Degradation and Stability, vol. 59, pp. 387-393, January 1998.
[23] J. A. Posada, J. M. Naranjo, J. A. López, J. C. Higuita, and C. A.
Cardona, “Design and analysis of poly-3-hydroxybutyrate production
processes from crude glycerol,” Process Biochemistry, vol. 46, pp. 310–
317, January 2011.
[24] N. Gurieff, and P. Lant, “Comparative life cycle assessment and
financial analysis of mixed culture polyhydroxyalkanoate production,”
Bioresource Technology, vol. 98, pp. 3393–3403, July 2007.
[25] J. M. Naranjo, J. A. Posada, J. C. Higuita, and C. A Cardona,
“Valorization of glycerol through the production of biopolymers: The
PHB case using Bacillus megaterium,” Bioresource Technology, vol.
133, pp.38–44, April 2013.
[26] T. Mumtaz, N. A. Yahaya, S.Abd-Aziz, N. A. Rahman, P. L. Yee, Y.
Shirai, and M. A. Hassan, “Turning waste to wealth-biodegradable
plastics polyhydroxyalkanoates from palm oil mill effluent - a Malaysian
perspective,” Journal of Cleaner Production, vol. 18, pp. 393-1402, June
2010.
[27] ICIS Pricing. http://www.icis.com/
[28] M. Patel, C. Bastioli, L. Marini, and E. Würdinger, “Life cycle
assessment of bio-based polymers and natural fibres composites,”
Biopolymers online, vol.10, January 2005.
[29] R. Briones, L. Tai, E. Daoud, and J. Hart, “Life Cycle Assessment.
Identifying process improvement opportunities and assessing
alternatives,” California environmental protection agency department of
toxic substances control, DTSC, Plastics Hazards Reduction Unit, June
2011.
[30] A. Liebich, and J. Giegrich, “Eco-profiles of the European plastics
industry. Polyethylene terephthalate (PET). Bottle grade,” Plastics
Europe, Heidelberg, April 2010.
[1] M. Carus, “Production capacities for bio-based polymers in Europe -
status quo and trends towards 2020,” Nova-Institute for Ecology and
Innovation. Press release. July 2013.
[2] R. J. Van Wegen, Y. Ling, and A. P. J Middelberg, “Industrial
production of polyhydroxyalkanoates using Escherichia coli: An
economic analysis,” Chemical Engineering Research and Design, vol.
76, pp. 417-426, March 1998.
[3] C. S. K., Reddy, R. Ghai, Rashmi, and V. C. Kalia,
“Polyhydroxyalkanoates: an overview,” Bioresource Technology, vol.
87, pp. 137-146, April 2003.
[4] R. A. J Verlinden, D. J. Hill, M. A. Kenward, C. D. Williams, and I.
Radecka, “Bacterial synthesis of biodegradable polyhydroxyalkanoates,”
Journal of Applied Microbiology, vol. 102, pp. 1437–1449, June 2007.
[5] L. L. Madison, and G.W. Huisman, “Metabolic engineering of poly(3-
hydroxyalkanoates): from DNA to plastic,” Microbiology and Molecular
Biology Reviews, vol. 63, pp. 21-53, March 1999.
[6] H. Salehizadeh, and M. C. M. Van Loosdrecht, “Production of
polyhydroxyalkanoates by mixed culture: recent trends and
biotechnological importance,” Biotechnology Advances, vol. 22, pp.
261-279, January 2004.
[7] Y. Jiang, L. Marang, J. Tamis, M. C. M. van Loosdrecht, H. Dijkman,
and R. Kleerebezem, “Waste to resource: Converting paper mill
wastewater to bioplastic,” Water Research, vol. 46, pp. 5517-5530,
November 2012.
[8] J. Tamis, L. Katlin, Y. Jiang, M. C. M. van Loosdrecht, and R.
Kleerebezem, “Enrichment of Plasticicumulans acidivorans at pilot-scale
for PHA production on industrial wastewater,” Journal of
Biotechnology, to be published.
[9] N. Jacquel, C.-W. Lo, Y.-H. Wei, H.-S. Wu, and S. S. Wang, “Isolation
and purification of bacterial poly(3-hydroxyalkanoates),” Biochemical
Engineering Journal, vol. 39, pp. 15–27, April 2008.
[10] L. A. Smith, K. J. Roberts, D. Machin, and G. McLeod, “An
examination of the solution phase and nucleation properties of sodium,
potassium and rubidium dodecyl sulphates,” Journal of Crystal Growth,
vol. 226, pp. 158–167, June 2001.
[11] R. Smith, Chemical process design and integration, pp. 17-31,
Chichester: John Wiley & Sons, 2005.
[12] R. K. Sinnott, Coulson & Richardson's chemical engineering. Volume 6:
chemical engineering design, fourth ed., pp. 246-279, Oxford: Elsevier,
2005.
[13] G. D. Ulrich, and P. T. Vasudevan, “How to estimate utility costs,”
Chemical Engineering, vol. 4, pp. 66-69, April 2006.
[14] International Standards Organization (ISO), ISO 14040:2006,
“Environmental management. Life cycle assessment. Principles and
framework,” 2006a.
[15] International Standards Organization (ISO), ISO 14044:2006,
“Environmental management. Life cycle assessment. Requirements and
guidelines,” 2006b.
[16] U.S. Environmental Protection Agency, “Accounting framework for
biogenic CO2 emissions from stationary sources,” Office of
Atmospheric Programs, Climate Change Division, Washington, DC,
2011.
[17] P. Pawelzik, M. Carus, J. Hotchkiss, R. Narayan, S. Selke, M. Wellisch,
M. Weiss, B. Wicke, and M. K. Patel, “Critical aspects in the life cycle
assessment (LCA) of bio-based materials–Reviewing methodologies and
deriving recommendations,” Resources, Conservation and Recycling,
vol. 73, pp. 211–228, April 2013.
[18] Y. Jiang, G. Mikova, R. Kleerebezem, L. A. M. van der Wielen, and
M.C. Cuellar, “Feasibility study of an alkaline-based chemical treatment
for polyhydroxyalkanoates purification from mixed enriched culture,”
unpublished.
[19] D. Michael, “Biodegradable polymer supply chains: implications and
opportunities for agriculture,” Wondu Holdings, Sydney, 2004.
[20] J. Choi, and S. Y. Lee, “Process analysis and economic evaluation for
Poly(3-hydroxybutyrate) production by fermentation,” Bioprocess
Engineering, vol. 17, pp. 335-342, November 1997.
[21] M. Akiyama, T. Tsugea, and Y. Doia, “Environmental life cycle
comparison of polyhydroxyalkanoates produced from renewable carbon
resources by bacterial fermentation,” Polymer Degradation and Stability,
vol. 80, pp. 183–194, February 2003.
[22] S. Y. Lee, and J. Choi, “Effect of fermentation performance on the
economics of poly(3-hydroxybutyrate) production by Alcaligenes latus,”
Polymer Degradation and Stability, vol. 59, pp. 387-393, January 1998.
[23] J. A. Posada, J. M. Naranjo, J. A. López, J. C. Higuita, and C. A.
Cardona, “Design and analysis of poly-3-hydroxybutyrate production
processes from crude glycerol,” Process Biochemistry, vol. 46, pp. 310–
317, January 2011.
[24] N. Gurieff, and P. Lant, “Comparative life cycle assessment and
financial analysis of mixed culture polyhydroxyalkanoate production,”
Bioresource Technology, vol. 98, pp. 3393–3403, July 2007.
[25] J. M. Naranjo, J. A. Posada, J. C. Higuita, and C. A Cardona,
“Valorization of glycerol through the production of biopolymers: The
PHB case using Bacillus megaterium,” Bioresource Technology, vol.
133, pp.38–44, April 2013.
[26] T. Mumtaz, N. A. Yahaya, S.Abd-Aziz, N. A. Rahman, P. L. Yee, Y.
Shirai, and M. A. Hassan, “Turning waste to wealth-biodegradable
plastics polyhydroxyalkanoates from palm oil mill effluent - a Malaysian
perspective,” Journal of Cleaner Production, vol. 18, pp. 393-1402, June
2010.
[27] ICIS Pricing. http://www.icis.com/
[28] M. Patel, C. Bastioli, L. Marini, and E. Würdinger, “Life cycle
assessment of bio-based polymers and natural fibres composites,”
Biopolymers online, vol.10, January 2005.
[29] R. Briones, L. Tai, E. Daoud, and J. Hart, “Life Cycle Assessment.
Identifying process improvement opportunities and assessing
alternatives,” California environmental protection agency department of
toxic substances control, DTSC, Plastics Hazards Reduction Unit, June
2011.
[30] A. Liebich, and J. Giegrich, “Eco-profiles of the European plastics
industry. Polyethylene terephthalate (PET). Bottle grade,” Plastics
Europe, Heidelberg, April 2010.
@article{"International Journal of Earth, Energy and Environmental Sciences:69703", author = "Cora Fernandez Dacosta and John A. Posada and Andrea Ramirez", title = "Large Scale Production of Polyhydroxyalkanoates (PHAs) from Wastewater: A Study of Techno-Economics, Energy Use and Greenhouse Gas Emissions", abstract = "The biodegradable family of polymers
polyhydroxyalkanoates is an interesting substitute for convectional
fossil-based plastics. However, the manufacturing and environmental
impacts associated with their production via intracellular bacterial
fermentation are strongly dependent on the raw material used and on
energy consumption during the extraction process, limiting their
potential for commercialization. Industrial wastewater is studied in
this paper as a promising alternative feedstock for waste valorization.
Based on results from laboratory and pilot-scale experiments, a
conceptual process design, techno-economic analysis and life cycle
assessment are developed for the large-scale production of the most
common type of polyhydroxyalkanoate, polyhydroxbutyrate.
Intracellular polyhydroxybutyrate is obtained via fermentation of
microbial community present in industrial wastewater and the
downstream processing is based on chemical digestion with
surfactant and hypochlorite. The economic potential and
environmental performance results help identifying bottlenecks and
best opportunities to scale-up the process prior to industrial
implementation. The outcome of this research indicates that the
fermentation of wastewater towards PHB presents advantages
compared to traditional PHAs production from sugars because the
null environmental burdens and financial costs of the raw material in
the bioplastic production process. Nevertheless, process optimization
is still required to compete with the petrochemicals counterparts.
", keywords = "Circular economy, life cycle assessment,
polyhydroxyalkanoates, waste valorization.", volume = "9", number = "5", pages = "442-6", }
