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28 Bioconversion of Food Waste to Wealth – Circular Bioeconomy Approach
and from 10.14% to 18.10% for cellulose. Solid–liquid fat extraction pretreatment
technique provided high sugar yield and high degradation of starch and cellulose
by enzymatic hydrolysis.
Utilizing food waste as animal feed is a successful alternative technique to landfill.
Food waste was given as pig feed many decades, but sometimes the presence of meat
in food waste and non-heat-treated food waste could end up with foot-and-mouth
disease and African swine fever. In 2001, the outbreak of foot-and-mouth disease
caused a crisis in British agriculture and farm, by slaughtering more than 6 million
animals, costing 8 billion pounds to the public and private sector. Enzymatic diges-
tion helps in digesting the food waste into pasteurized feed with more digestible
nutrients like free sugars, amino acids, and fatty acids. Pandey et al. [53] converted
food waste into organic soil amendments (OSAs) by three stages starting from (i)
enzymatic digestion, (ii) pasteurization, and (iii) acidification. The developed OSA
can be used as an effective fertilizer (chemical and pathogen-free), and authors
revealed 25% increase in growth rate for the strawberry plant. Further, the byprod-
uct of this process can be potentially used as feed for pork or chicken. Authors
succeeded in converting food waste to OSA with a non-detectable level of pathogens
(Escherichia coli O157: H7, Salmonella LT2, and Listeria monocytogenes). Later,
Jinno et al. [47] took a step further by feeding the enzymatic digested food waste to
the growing pigs and compared with the control diet (based on corn and soybean
meal). There was no significant difference in body weights between the control
and enzymatic digested food waste. For instance, a pig weighed between 32 and
–33.6 kg on day 1 was grown to 108.15 kg (control diet) and 98.77 kg (for enzymatic
digested food waste). One can observe that animal feed from enzyme-treated food
waste should be able to provide necessary nutrients and can be effectively used as a
substitute for corn or soy compositions in their diet.
28.4.3.1
Enzyme Immobilization Technology
The application of enzymes in valorizing food waste has numerous advantageous
over the conventional chemical process. However, it is important to note the major
issues in maintaining the stability and activity of enzymes due to the non-favorable
environment for enzymes like non-neural pH and higher temperature. Enzyme
immobilization technology is tailored to improve the enzyme catalytic features like
activity, selectivity, and resistance to inhibitors [54]. Immobilizing enzymes on a
solid support or cross-linking via enzyme–enzyme will improve the performance
and stability and also enable the reuse of enzymes. This enzyme immobilization
technique is in use from 1960s, and the past six decades of research and industrial
practice has abandoned the tedious trial-and-error approach and brought the
rational approach for designing immobilized enzymes [55]. Several immobilization
strategies can be used like entrapment, adsorption, covalent binding, ionic binding
or metal-linked immobilization, and the selection of immobilization technique is
depending on the physicochemical characteristics of enzyme, support material,
and substrate matrix. Further, the selection of support material should possess
high physical stability (mechanical strength), chemical stability, and biological
stability during processing, inert on immobilized enzyme and the target analyte,
and adequate functional groups for effective binding of enzymes and achieve high
loading capacity and biodegradability.