Fractionation of squalene from amaranth seed oil

Amaranth seed oil was fractionated in a bench‐scale short‐path distillation unit to obtain fractions rich in squalene. Fractionations were conducted with degummed amaranth oil, alkali‐refined amaranth oil, and simulated amaranth oil. Squalene concentration was increased about sevenfold with a squale...

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Bibliographic Details
Published in:Journal of the American Oil Chemists' Society 1997-04, Vol.74 (4), p.413-418
Main Authors: Sun, H. (North Dakota State University, Fargo, ND.), Wiesenborn, D, Tostenson, K, Gillespie, J, Rayas-Duarte, P
Format: Article
Language:English
Subjects:
Alkali‐refining
Amaranth
amaranth oil
AMARANTHUS
Analytical, structural and metabolic biochemistry
Biological and medical sciences
Distillates
Distillation
Fatty acids
Fractionation
Fundamental and applied biological sciences. Psychology
Oilseeds
Other biological molecules
Recovery
Room temperature
Seeds
Semisolids
short‐path distillation
Simulation
Soybean oil
Soybeans
Squalene
squalene content
squalene recovery
Terpenes, steroids. Hormones
Vacuum
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Summary:Amaranth seed oil was fractionated in a bench‐scale short‐path distillation unit to obtain fractions rich in squalene. Fractionations were conducted with degummed amaranth oil, alkali‐refined amaranth oil, and simulated amaranth oil. Squalene concentration was increased about sevenfold with a squalene recovery of 76.0% in the distillate when degummed amaranth oil was fractionated at 180°C and 3 mtorr vacuum. Free fatty acids codistilled with squalene, lowering the squalene content of the distillate, and resulted in a semisolid distillate at room temperature. Alkali‐refining was subsequently used to reduce the free fatty acid content before fractionation. A simulated oil (7% squalene/93% soybean oil) and alkali‐refined amaranth oil were fractionated at three temperatures (160, 170, and 180°C) and five vacuum settings (10, 100, 200, 400, and 600 mtorr). The highest squalene recoveries from simulated oil and alkali‐refined amaranth oil were 73.4 and 67.8%, respectively, both at 180°C and 100 mtorr, which translates to 12.1‐and 9.2‐fold increases in squalene concentration, respectively. The squalene recovery of the alkali‐refined amaranth oil at 180°C was not significantly different at 10 mtorr vs. 100 mtorr. The results of this study can be used as a component to assess the economic feasibility of fractionating amaranth seed for starch, oil, meal, and squalene.
ISSN:0003-021X
1558-9331
DOI:10.1007/s11746-997-0099-8