High pressure extractionProbably, t

High pressure extraction
Probably, the extraction of compounds from natural sources is the area most studied and widely applied in the field of high pressure technologies. Certainly, there are thousands of scientific papers published on the topic in the past two to three decades with hundreds of patents filed 8 and 9.

SC-CO2 extraction has clear advantages over traditional extraction techniques and is a promising alternative as it allows to achieve comparable extract yields with respect to the conventional organic solvent extraction and with quality better or similar to that of mechanical extraction [10•]. There are several review papers available in the literature 8, 11, 12•• and 13•• which compiled the recent advances in the field. A recent survey by King [14•] indicates that, currently in the world, there are more than 150 SC-CO2 extraction plants with an extraction volume equal to or greater than 500 L, and many of these production plants are dedicated to the extraction of natural products, leading to the recovery of high-added value compounds. De Melo et al. [13••] reported that in a span of 13 years (i.e. between 2000 and 2013), more than 300 botanical materials have been extracted using SC-CO2, of which 28% seeds, 17% leaves, 10% fruits, 7% roots, 5% flowers, 2% barks, the remaining being processed parts, mixtures, etc. Table 1 schematizes recent papers addressing high pressure extraction of bioactives from food processing residues, indicating the residue, the target compound, the kind of solvent (possibly added with co-solvent), the extraction mode (batch/continuous), the operating pressure and temperature, the mass of residue extracted, the solvent flow rate, the duration of the extraction, the method used for the analysis of the bioactives, and it also reports some important features addressed in the work. An extensive analysis of the effect of process parameters (pressure, temperature, solvent flow rate, particle diameter, bed porosity, extractor diameter to length ratio and extractor free volume) on the kinetics of SC-CO2 extraction has been recently presented by Duba and Fiori [15]. But, as a rule of thumb in solvent choice, ‘like dissolves like’ indicates the use of polar solvents for polar solute and likewise the use of nonpolar solvents for nonpolar solute [16]. CO2, being a nonpolar solvent, is not suitable for most polar solutes like phenolic compounds unless augmented with co-solvents, as it is evidenced in Table 1.