BLBS102-c40 BLBS102-Simpson March 21, 2012 14:23 Trim: 276mm X 219mm Printer Name: Yet to Come
780 Part 7: Food Processing
processes have gained wide applications for products such as
those derived from refined vegetable oils, e.g., deodorizer dis-
tillate of vegetable oils, palm oil for obtaining tocotrienols and
tocopherols, rice oil for oryzanol recovery, monoglyceride con-
centration, carotenoid recovery from palm oil, heavy petroleum
characterization, and herbicides (Barnicki et al. 1996, Sakiyama
et al. 2001, Batistella et al. 2002a,b, Fregolente et al. 2005, Ito
et al. 2006, Shi et al. 2007c). Recently, a new process of molec-
ular distillation was developed for recovery of tocotrienols and
tocopherols from rapeseed by a combination of acid-catalyzed
methyl esterification and crystallization followed by fractional
distillation of derived products and for the recovery of orange
peel oil and essence products rich in aldehydes, esters, and other
special volatile compounds (Lutisan et al. 2002, Jiang et al.
2006). An industrial production of a typical industrial fractional
vacuum distillation plant is shown in Figure 40.10. In order to
increase the yield and quality of the final products, the distiller
is operated continuously.
Figure 40.10.The vacuum fractional molecular distillation column.
SUMMARY
One of the most important trends in the food industry today is
the demand for “natural” foods and ingredients that are free from
toxic chemical additives. The growing interest in natural foods
has raised the demand for natural health-promoting products of
nonsynthetic origin. High-value functional substances can be
obtained from biological materials by various purification and
separation methods from plant materials or by-products. Among
the separation processes being used or developed are physical
and chemical processes such as centrifugation, filtration, mem-
brane separation, precipitation, chromatography, solvent extrac-
tion, supercritical fluid extraction, crystallization, evaporation,
and distillation.
The separation problems presented by the production of sol-
uble material have a number of aspects that influence the nature
of the extraction technique chosen. An important factor is the
stability of the extracted product. In the case of unstable prod-
ucts, a rapid separation process is necessary in order to avoid
significant loss of products. Extraction with organic solvents
by traditional methods is a well-established method for the se-
lective separation of specific constituents from raw materials.
The conventional procedures for preparing concentrated extracts
are steam distillation or solvent extraction with an organic sol-
vent. Extractants with a low boiling point, such as ethyl acetate,
methanol, dichloromethane, etc., are traditionally used for iso-
lating valuable constituents from such products as hops, spices,
and oil seeds and also for removing or reducing the level of less-
desirable accompanying substances (such as nicotine, caffeine).
But a very important step in the process is the complete re-
moval of the solvents from extracts and its residue as they are
in part toxicologically objectionable. In addition, organic sol-
vents have a low selectivity. Extraction must be followed by
removal of the solvent from the extract, for example by distil-
lation. The challenges in the separation processes are to both
meet food regulations and to conduct the separation effectively
and economically. Many compounds in the concentrated ex-
tract will be thermally labile and prone to degradation if heated
too vigorously. The removal of the solvent can pose serious
problems since the residual level of the solvent must be min-
imized, but not at the expense of the degradation of the final
extract. Public health, environment, and safety issues are the
major concerns in the use of organic solvents in food processing.
The possibility of solvent residues remaining in the final prod-
uct has been a growing concern to consumers, thus warranting
stringent environmental regulations. The extent of residual sol-
vent levels and also the composition of the extraction solvents
used in the food industry are well regulated within the existing
laws and regulations. The solvents used for this purpose must
meet the requirements of foodstuffs legislation, which can vary
from country to country. In recent years, national and interna-
tional bodies (such as the Food and Drug Administration, USA;
the EC Codex Committee; and the FAO/WHO, Geneva) have
increasingly emphasized the importance of complying with such
criteria.
The demand for ultra-pure and high value-added products is
redirecting the focus of the food and pharmaceutical industries