Behavior of concentrated emulsions prepared by acid-hydrolyzed insoluble microalgae proteins from Chlorella protothecoides.

BACKGROUND: Microalgae are a promising alternative source to meet the increasing global demand for protein. The insoluble microalgae protein fraction that makes up over half of the protein composition of the biomass has shown potential to serve as a functional emulsifier after acidic hydrolysis. However, creaming was observed due to the flocculation of emulsion droplets, suggesting a preferable use in concentrated emulsions. RESULTS: In this study, we examined the emulsifying behavior of the untreated insoluble microalgae protein fraction and two of its hydrolysates obtained in 0.5 mol L-1 HCl for 4 h at 65 °C (Hydrolysates 65) or 85 °C (Hydrolysates 85), at a concentration of 3% (w/w), and elevated levels of oil (50-70%). The results showed an increase in droplet size and apparent viscosity with increasing oil content in the emulsions. The emulsions made with Hydrolysates 85 had the smallest droplet size and the highest apparent viscosity. The gravitational separation was hindered when oil content was increased. The Hydrolysates 85 stabilized emulsions had a gel-like structure and were stable against coalescence or creaming during a 7 day storage test. CONCLUSION: The results suggest that the thermal acid-treated fraction Hydrolysates 85 may, in particular, be a good emulsifier to formulate concentrated emulsion-based foods with oil content over 50%, such as mayonnaise, salad dressings, or dips. © 2020 The Authors. Journal of The Science of Food and Agriculture published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.

Ionic strength and pH stability of oil-in-water emulsions prepared with acid-hydrolyzed insoluble proteins from Chlorella protothecoides.

BACKGROUND: Chlorella protothecoides is one of the most widely commercialized and studied microalgae species. Recent research reported improved emulsifying properties of the insoluble protein fraction from C. protothecoides after thermal-acid treatment. RESULTS: In this research, we studied the influence of ionic strength (sodium chloride 50-500 mmol L-1 or calcium chloride 5-50 m mol L-1 ) and pH (2-9) on the stability of oil-in-water emulsions prepared by 3% (w/w) of the untreated insoluble microalgae protein fraction or hydrolysates obtained after treatment with hydrochloric acid at 65 °C (Hydrolysates 65) or 85 °C (Hydrolysates 85) for 4 h. The emulsions were prepared by mixing 10% (w/w) oil and homogenized at 68.9 MPa. The ionic strength and pH were, subsequently, adjusted. The mean particle diameter of emulsions remained constant despite extensive variations in ionic strength or pH. Emulsion droplets stabilized by Hydrolysates 85 were stable against coalescence at all ionic strengths or pH values tested. CONCLUSION: The results indicate a high potential to use acid-hydrolyzed insoluble microalgae protein fractions for the formulation of various emulsion-based food systems. © 2020 The Authors. Journal of The Science of Food and Agriculture published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.

An erosion-type hydrolysis behavior of insoluble protein fraction from Chlorella protothecoides.

BACKGROUND: Acid-induced hydrolysis of proteins has been used to improve the solubility and functional properties of various proteins, and could be a promising tool to facilitate the use of currently underutilized insoluble microalgae protein-rich fractions in food applications. However, the results of a prior study showed an unusual resistance of an insoluble microalgae protein-rich fraction to acid hydrolysis at room temperature. RESULTS: In the present study, the insoluble protein-rich fraction extracted from microalgae Chlorella prothothecoides was treated with 0.5 mol L-1 hydrochloric acid at 25, 45, 65 or 85 °C for 0-4 h. The results showed that hydrolysis of the fraction at 85 °C for 4 h led to decreases in the amount of insoluble protein-rich aggregates and the formation of fragments with a lower molecular weight, as well as an increase in protein solubility by approximately 40%. Nevertheless, some aggregated insoluble protein-rich particles remained, even after hydrolysis at 85 °C for 4 h. CONCLUSION: The higher temperature improved the efficiency of the acid hydrolysis of the insoluble protein fraction from microalgae Chlorella prothothecoides, which is highly acid-resistant. Overall, an erosion-based mechanism was suggested for the acid hydrolysis of insoluble microalgae protein fraction. © 2019 The Authors. Journal of The Science of Food and Agriculture published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.

Shear rheological properties of acid hydrolyzed insoluble proteins from Chlorella protothecoides at the oil-water interface.

Microalgae are promising protein sources due to their overall high protein content. The low aqueous-solubility of microalgae proteins, however, limits their application in food, pharmaceutical or personal care systems, unless solubility is enhanced by e.g. hydrolysis. In this study, we examined the interfacial rheological properties at the oil-water interface of insoluble microalgae protein-rich fraction from Chlorella protothecoides and their hydrolysates prepared by hydrolysis in hydrochloric acid at 65 °C (Hydrolysates 65) and 85 °C (Hydrolysates 85). Results showed increased interfacial activity of the insoluble microalgae protein-rich fraction after hydrolysis: Hydrolysates 65 and Hydrolysates85 had higher interfacial storage Gi' and loss moduli Gi″ compared to the untreated insoluble microalgae protein-rich fraction. Increasing amounts of soluble protein fragments mixed with insoluble protein particles in hydrolysates stabilized interfacial layers. The influence of pH on the interfacial behavior of samples was also determined and revealed that Gi' and Gi″ values of treated and untreated protein fractions decreased as pH increased beyond their isoelectric points due to increasing electrostatic repulsions between adsorbed protein fragments and aggregates. The high viscoelasticity of the acid-hydrolyzed insoluble microalgae protein-rich fraction at the oil-water interface indicates a high potential for them to be useful in stabilizing emulsion-based products.