Sea cucumber is a kind of precious

Sea cucumber is a kind of precious seafood, known as “sea ginseng”. It contains more than 50 kinds of nutrients including amino acids, essential or polyunsaturated fatty acids, vitamins and trace elements, etc., and active substances, such as collagen proteins, polysaccharides, saponins and brain glycosides (Jiang et al., 2004). These substances have many roles of antitumor (Jin et al., 2009 and Sugawara et al., 2006), anticoagulant (Li and Lian, 1988), lowering blood-fat (Liu et al., 2012), antifungal activity (Chludil et al., 2002 and Kumar et al., 2007), inhibition of angiogenesis (Zhao et al., 2011), immunomodulatory (Wang et al., 2010), inducing neurite outgrowth (Kaneko et al., 2007). Therefore, sea cucumber has a wide range of applications in fields of medicine, health care, food, etc. Due to easy autolysis of sea cucumber out of the sea water and the need for preservation, more than 90% of the fresh sea cucumbers are usually processed into instant, semi- or dried products. As the first step of the process, heating and cooking are normally used to deactivate the autolyzed enzymes in sea cucumbers. After then a large amount of the processing liquor is produced as waste byproduct to discharge into sea. The chemical compositions in the waste liquor are almost the same as sea cucumber itself, such as polysaccharides, proteins, oils, saponins and so on. If the active components were separated effectively from the waste liquor, pollution of the environment would be reduced and considerable economic benefits could be obtained. The methods for extracting active ingredients from waste liquor of processing sea cucumber include precipitation of protein at their isoelectric point, alcohol precipitation, desalination and distillation (Zhao et al., 2010, Yuan et al., 2009, Jiang, 2012 and Cong et al., 2006). Usually only one or two kinds of active substances were extracted or separated from the waste liquor. However, other effective components were not considered synchronously. As these mentioned methods indicated, multi-step separation technologies were applied to separate multi-active substances from the processing sea cumber, which led to the loss of active substances and high cost of recovery.

Multiphase salting-out extraction can achieve the recovery of the multi-active substances synchronously with simple and effective step. The multiphase salting-out extraction system is composed of hydrophobic/hydrophilic organic solvent, salt and water. The ingredients in a complex sample will distribute into the different phases of multiphase salting-out extraction system according to their quality in polarity and solubility, e.g. water-soluble, alcohol-soluble and fat-soluble. Multiphase salting-out extraction systems have many advantages, such as short time to form phase due to low viscosity of system, easy recovery of solvent by evaporation, low cost, simple scale-up and high product yield (Xu and Wang, 2009). The system is also known as aqueous two-phase system in this multiphase salting-out extraction system when the hydrophilic solvent is only used. If the solvents are composed of hydrophilic and hydrophobic solvents, the system is also called three-liquid-phase system. The aqueous two-phase system have been successfully used in separation of bio-based chemicals, e.g. 1,3-propanediol, 2,3-butanediol, biobutanol, lactic acid and succinic acid (Liu et al., 2009, Jiang et al., 2009, Sun et al., 2009, Sun et al., 2014, Li et al., 2009, Li et al., 2010, Li et al., 2011 and Dai et al., 2011), natural products, e.g. α-galactosidase, oil and alginates and recombinant human albumin (Dhananjay and Mulimani, 2009, Sharma et al., 2002 and Sharma and Gupta, 2002; Dong et al., 2012). The three-liquid-phase salting-out extraction has been applied in the isolation of complex natural products e.g. diosgenin and steroidal saponins (Liu et al., 2010 and Wei et al., 2012). In our previous report, aqueous two-phase salting-out extraction system can successfully achieve extraction of polysaccharides and proteins from waste liquor (Chen et al., 2013). The results indicated that t-butanol/ammonium sulphate and ethanol/sodium carbonate systems performed better in extracting protein and polysaccharide directly from the waste liquor. The recovery yield of protein for two different aqueous two-phase systems can reach 99.6% and 96.9%, and the recovery yield of polysaccharide were 96.3% and 90.6%, respectively. In previous study, both saponins and oils mainly existed in the solvent phase when a single hydrophobic or hydrophilic solvent used in salting-out extraction system. Other separation technology was still need to further separate saponins and oils from the solvent phase. Therefore, in this study a three-liquid-phase salting-out extraction system containing ethanol, sodium carbonate and hexane was applied to extract proteins, polysaccharides, saponins, oils simultaneously from waste liquor. The effects of different n-hexane concentration and extraction time on the partition of the proteins, polysaccharides, saponins, oils were investigated to determine the optimal extraction conditions for three-liquid-phase salting-out extraction system. In addition, amplification of this three-liquid-phase system and the recycle of solvents and salt were also investigated.