Polyurethanes preparation using proteins obtained from microalgae

It is widely believed that the biofuels can be sustainably produced using microalgae that are known to convert CO 2 from the atmosphere to lipids, in the presence of nutrient and accumulate them as their body mass. However, when algal biofuels are produced using thermochemical route, ~30–65 % of pro...

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Published inJournal of materials science Vol. 49; no. 22; pp. 7824 - 7833
Main Authors Kumar, Sandeep, Hablot, Elodie, Moscoso, Jose Luis Garcia, Obeid, Wassim, Hatcher, Patrick G., DuQuette, Brandon Michael, Graiver, Daniel, Narayan, Ramani, Balan, Venkatesh
Format Journal Article
LanguageEnglish
Published Boston Springer US 15.11.2014
Springer
Springer Nature B.V
Subjects
Algae
Amines
Amino acids
Biodiesel fuels
Biomass
Biomass energy
Carbonates
Catalysis
Characterization and Evaluation of Materials
Chemical tests and reagents
Chemistry and Materials Science
Classical Mechanics
Crystallography and Scattering Methods
Cyclotron resonance
Flammability
Fourier transforms
Freeze drying
Fuels
Hydrolysis
Hydroxides
Ions
Lipids
Mass spectrometry
Materials Science
Peptides
Plastic foam
Polymer Sciences
Polyols
Polyurethane foam
Proteins
Slurries
Solid Mechanics
Biocrude
Microalgae
Polyol
Foam
Polyurethane Foam
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Summary:It is widely believed that the biofuels can be sustainably produced using microalgae that are known to convert CO 2 from the atmosphere to lipids, in the presence of nutrient and accumulate them as their body mass. However, when algal biofuels are produced using thermochemical route, ~30–65 % of proteins present in algae are lost due to decomposition and some of the nitrogen from amino acids is incorporated into the biofuels. The algal protein is a valuable resource that can bring additional revenue to the biorefinery by converting this co-product to high-value polyurethanes. In this work, we have demonstrated a one-step removal of proteins from algae through hydrolysis of the proteins to smaller peptides and amino acids using environment friendly flash hydrolysis (FH) process. Subcritical water was used as a reactant and as a reaction media for hydrolyzing the algae proteins via FH. Scenedesmus spp., slurry in water (3.8 %), was used as the algal feed stock during the FH process which was run at 280 °C for a residence time of 10 s. The soluble amino acids and peptides were separated from the other insoluble algal biomass components (cell wall and lipids) by filtration followed by freeze-drying. The product was then characterized by ion chromatography and Fourier transform ion cyclotron resonance mass spectrometry to determine its composition. The freeze-dried peptide and amino acids were then reacted with diamine and ethylene carbonate to produce polyols that were further processed to produce polyurethane. The relatively high hydroxyl value of these amino acid-based polyols and their compatibility with other commercially available polyols made them particularly suitable for producing rigid polyurethane foams. Due to the presence of amines and secondary amines in these polyols, the polymerization process was self-catalytic and the resulting foams are less flammable than conventional rigid polyurethane foams. The conversion of algal proteins to high-value industrial products by a relatively simple process greatly improves the value of proteins extracted from algae.
ISSN:0022-2461
1573-4803
DOI:10.1007/s10853-014-8493-8