BLBS102-c39 BLBS102-Simpson March 21, 2012 14:20 Trim: 276mm X 219mm Printer Name: Yet to Come
39 Minimally Processed Foods 747
food safety systems in the world, outbreaks of illness that are
linked to consumption of fresh fruits and vegetables have been
reported. The Public Health Agency of Canada, Health Canada,
and the Canadian Food Inspection Agency have been coordinat-
ing to identify gaps, develop and enforce solutions to improve the
Government’s response to outbreaks, and to ensure Canadians
are provided with the highest levels of food safety protection.
Food quality and safety are not necessarily complementary. In
fact, they are opposing in some cases. The balance and optimiza-
tion of the two parameters has been a major challenge in food
processing. The use of intense and broad-spectrum technologies
such as thermal treatment for microbial inactivation and shelf
life extension are known to be effective but unfortunately result
in accelerated degradation of sensory, nutritive, and functional
quality of food products. There is also the aspect of excessive
energy use with some of the food processing technologies. More
recent technological advancements have allowed the application
of mild processing of food with the promise of safe products
without the downside of quality degradation. These technolo-
gies are termed as minimal processing technologies, and food
products obtained by their applications are referred to as min-
imally processed foods. Thus, minimally processed products
have not undergone very extensive transformation, particularly
thermal processing as compared to conventional foods. The aim
of each minimal processing technique is to minimize the rate of
deterioration within the food matrix.
OVERVIEW OF THERMAL PROCESSING
TECHNIQUES
Thermal processing involves the application of adequate heat
to inactivate undesired spoilage microorganisms, degrading en-
zymes, and antinutrients, and prepare the food product to be
consumed. It is robust and widely used in processing and pre-
serving foods. Sufficient heat destroys microorganisms and food
enzymes but also impacts both desirable (textural changes, pro-
tein coagulation, and release of aroma) and undesirable changes
(nutrient loss, loss of freshness) in the food. Thus, in practice,
designing appropriate thermal process typically involves consid-
eration of time–temperature combinations that are required to
inactivate the most heat-resistant pathogens and spoilage organ-
isms in a given food matrix. There is often the need to evaluate
heat penetration characteristics in a given food product, includ-
ing can or container in order to evaluate temperature distribu-
tions. The choice of process depends on the minimum possible
heat treatment that should guarantee freedom from pathogens
and toxins and give the desired quality and storage life.
High Temperature Short Time Process
The mechanism of heat destruction of microorganisms has been
attributed to thermally induced changes in the chemical structure
of proteins in the cells. The phenomenon can be described by a
first-order reaction equation.
dN
dt
=−koNe(−
RTE)
(1)
whereNis concentration,tis process time,kois the activation
factor,Eis activation energy, andTis absolute temperature.
Along with the microbial inactivation, other chemical reactions
that occur during thermal processing lead to degradation of vari-
ous quality attributes (sensory, vitamin C, thiamine, flavor, etc.).
These degradation reactions can also be described using kinetic
equations similar to Equation 1 with their relevant activation
factors and activation energies. Several studies have confirmed
that at high temperatures, the destruction rate of pathogenic
bacteria accelerated more rapidly than the degradation rate of
nutrients (Holdsworth 1985). Thez-value (defined as change
in the death or degradation rate based on temperature, i.e., the
change in temperature required for tenfold change in microbial
or chemical resistance) is typically around 10◦C for microbial
death, whereas the value for chemical degradation is around
30 ◦C. Thus, the interaction between safety and quality can be
examined by considering microbial death kinetics and chemical
degradation kinetics.
High temperature short time (HTST) process takes ad-
vantage of the differences in the microbial inactivation and
quality degradation kinetics to improve retention of nutrients
(higher quality) while ensuring adequate microbial inactivation.
Temperature–time combinations used for HTST may range from
about 72◦C for 15 seconds for pasteurization of milk to much
higher temperatures for shorter times. It is typically applied
at about 132–143◦C for different times depending on the re-
quiredFovalues (the amount of time a food is maintained at the
reference temperature of 121.11◦C; used as a benchmark and
indicating the severity of a process) to sterilize low-acid foods
and beverages. The use of temperatures beyond 138◦C is usually
referred to as ultra high temperature (UHT) processing. A major
limitation associated with HTST lies in its application to prod-
ucts that are highly viscous, solid, or that contain solid particles.
Safety considerations require that sufficient heat is applied to
sterilize the fastest moving (which is really the slowest heating)
particle in the system. This implies that other slower moving
particles are overprocessed, since they receive the high temper-
ature but not the short time, resulting in degraded quality of the
product. There are also limitations of heat transfer rate in solids,
which may lead to surface heating and reduced quality. These
limitations create a need for other technologies for effective de-
livery of energy to the product to enhance both safety and quality.
Aseptic Processing
Aseptic processing is an answer to the limitations of HTST. In
this technique, processed food products and package are brought
together aseptically (i.e., in a sterile environment). Liquid food
product is initially sterilized by HTST or UHT and then heat
is transferred to the solid particulate components as they are
transported by the liquid and filled into presterilized containers.
This revolutionary packaging system first appeared in US super-
markets in the 1970s (Fellows 1988, Holdsworth 1992, Welch
and Mitchell 2000). In 1989, the Institute of Food Technologist
selected aseptic packaging as “the most significant food sci-
ence innovation in the past fifty years.” An aseptic process for a
low-acid product containing particulates (potato soup) was filed