Since the Tohoku earthquake, there

Since the Tohoku earthquake, there is much interest in processed foods, which can be stored for long periods at
room temperature. Retort heating is one of the main technologies employed for producing it. We developed the
innovative food processing technology, which supersede retort, using ohmic heating and aseptic packaging.
Electrical heating involves the application of alternating voltage to food. Compared with retort heating, which
uses a heat transfer medium, ohmic heating allows for high heating efficiency and rapid heating. In this paper
we ohmically heated chicken breast samples and conducted various tests on the heated samples. The
measurement results of water content, IMP, and glutamic acid suggest that the quality of the ohmically heated
samples was similar or superior to that of the retort-heated samples. Furthermore, based on the monitoring of
these samples, it was observed that sample quality did not deteriorate during storage.

introdution
1. Introduction
Currently, retort heating is one of the main technologies employed
for producing processed foods, which can be stored for long periods at
room temperature. There is a strong demand for retort food from
consumers as emergency food because of their long shelf life and ease
of consumption; furthermore, such foods are popular as everyday
food. However, retort sterilization relies on external heating, using hot
water or steam as a heat transfer medium; this results in poor heat
transfer efficiency and, consequently, considerable energy loss.
Ohmic heating is an emerging thermal process technology and
describes the process when an electrical current is passed directly
through a food and the resistance imposed by the food leads to the
generation of heat within the product. The basic principles as well as
the main factors influencing ohmic cooking have been explained by
Sastry (1992) and Ye, Ruan, Chen, and Doona (2004). Sastry and
Palaniappan (1992) reported that ohmic heating can be used in a
continuous flow mode to cook and sterilize liquid food and solid–liquid
mixtures. Huixian et al. (2007) reported that the microbial counts and
the calculated decimal reduction time resulting from ohmic heating
were superior to those resulting from conventional heating, and there
was no difference in the degree of protein denaturation between the
two methods. Nowadays ohmic heating is viewed as an alternative
heating system for pumpable foods and there are currently a number
of commercial scale processing plants in various countries (UK, Italy,
Mexico) producing fruit and/or vegetables in sauces and also
pasteurized orange juice and liquid egg. Sarkis, Jaeschke, Tessaro, and
Marczak (2013), Mercali, Jaeschke, Tessaro, and Marczak (2013), and
Mercali, Jaeschke, Tessaro, and Marczak (2012), reported on the
denaturation of anthocyanins and vitamin C in acerola and blueberry
during ohmic heating compared to the denaturation of these during
conventional heating. Moreno, Pizzaro, Parada, Pinilla, and Reyes
(2012) reported that ohmic heating is the best dehydrating method.
And the color and the hardness of osmotically dehydrated strawberry
with ohmic heating and vacuum impregnation was superior to the
conventional method. The effect of ohmic heating and vacuum
impregnation changed the shelf-life from 12 days to 25 days. While a
number of the early patents in ohmic heating were in the area of meat
processing the amount of in depth research conducted to date has
been quite limited in spite of the fact that ohmic heating has the
potential to cook meat in a much shorter time than the conventional
cooking procedures. Shirsat, Brunton, Lyng, and Mckenna (2004) and
Piette et al. (2004) showed that it is possible to cook comminuted
meat emulsions ohmically to a comparable quality of the conventional
cooked samples. Dai et al. (2013) evaluated the color and sarcoplasmic
protein of pork following water bath and ohmic cooking at 10 °C to
80 °C. Ohmic heating of fluids, which may also contain solid foods, has
been thoroughly studied and reported in the literature. Bertlini and
Romagnoli (2012) showed that the process-target-cost of vegetable
soup was reduced with ohmic treatment and aseptic packagingHowever, these products represent a relatively small proportion of total
cooked meats and no results have yet been presented on the quality of
ohmically cooked noncomminuted meats. The direct application of
ohmic heating to solid food is limited (De Alwis & Fryer, 1992). There
are no studies on the production technology for solid food with
commercial-level sterility attained by heating at 100 °C or higher or by
ohmic heating without the use of conductive liquids.
The ohmic method requires uniform conductivity values within the
meat which means that a perfectly even distribution of injected salt or
brine solutions must be achieved in the case of non-comminuted
meats. A lot of research was done on electrical conductivity of foods
(Palaniappan & Sastry, 1991) and on the changes in electrical
conductivity of foods during ohmic heating (Halden, De Alwis, &
Fryer, 1990). Sanjay, Sudhir, and Lynn (2008) published a paper
about the change of electrical conductivity values over a special
temperature range in a very small unit. This research team looked
mainly into the electrical conductivity changes of fruits and also a
few details about the behavior of different meat pieces were
published but there is still a lack of research in the ohmic heating
of full meat products.
A novel cooking method such as ohmic heating may offer a number
of advantages, such as quicker cooking and less power consumption and
safer product, however, the important considerations for a food product
are its taste, quality, and customer satisfaction.
There have been no studies on ohmic heating combined with
aseptic packaging for meat nor on meat measured for one year
as shelf-stable food of meat. In this study, we developed novel
food processing technology, which supersedes retort processing,
using ohmic heating and aseptic packaging. Chicken cooked by
combined ohmic heating and aseptic packaging was tested and
compared with chicken heated by retort heating. We examined
the temperature history, electrical conductivity data and lethal
rate during current application. Additionally, we assess quality and
sensory tests on the sterilized packaged food heated by those two
methods.
2. Materials and methods
2.1. Material
Chicken meat was purchased from Miyagawa Shokucho Keiran and
stored in a freezer at −80°C until experimentation.
2.2. Equipment
We used a high-frequency power unit (HJU3000-HF-30, Hano
Manufacturing). The output voltage was 10–100 V, output frequency
was 20kHz, and maximumpower outputwas 3kW. A polyphenylsulfone
(PPSU) container with an internal diameter of 3cm and a length of 10cm
(Sunny) was used as the heating cell. Titanium foils (30-μm thick) were
used as electrodes.
2.3. Preparation of samples
The stored meat was removed from the freezer and thawed in a
refrigerator at 5 °C. Then, the meat was shaped into a cylindrical form
(approximately 30mm×100mm, 70 g±0.5 g) so that it could fit into
the heating cell, and was wrapped with polyvinylidene chloride film.
Wrapping the sample with the film made it easier to clean the cell and
prepare it for the next test.
Themeatwas inserted into the heating cell. Thereafter, silicone rings
and stainless caps, in that order, were attached to the cell, and the cell
was fixed using a stainless steel retainer. A type T thermocouple covered
with an insulator was inserted into the cell through a hole in one of the
stainless steel caps and fixed in place. Given that the pressure inside the
cell increases during heating, the cell was retained securely to prevent
steam leakage during heating. The electrodes of the high-frequency
power unit were connected to the stainless steel caps and an electric
current was then applied to the heating cell. The voltage was set at
the maximum, 100V. The current was set to 5 A because the maximum
effective current is around 1.5 A for chicken breast when the measured
temperature is between 10°C and 140°C.
The current application was stopped when the temperature of the
cold point exceeded 121 °C for four continuous minutes. When the
temperature decreased to below 100 °C, the sample was placed
aseptically in a sterilized retort pouch andwas sealed using a heat sealer
(Ishizaki Electric MFG). Following cooling for 20 min under flowing
water, the sterilization-test sample was stored in an incubator at 35 °C
for 14 days; the quality-test sample, at 25 °C for 2, 14, 28, 56, 84, 112,
168, 224, 280, or 365 days; and the sensory-test sample, at 25 °C for
14days.
In this study, the ohmically heated sample was compared with a
retort-heated sample in the quality and sensory tests. The retortheating
sample was shaped into a cylindrical form with the same size
and weight as the ohmic-heating sample, frozen at −80 °C, and sent to
Nihon Senshoku, Fukuoka Prefecture (shipping temperature −20 °C),
where it was retort heated. The retort-heated sample was stored for 2,
14, 28, 56, 84, 112, 168, 224, 280, or 365days. Furthermore, prior to retort
heating,we ensured that the samplewas stored at the same temperature
as the ohmically heated sample.
2.4. Temperature measurement at different locations
Every point was measured three times. The heating cell and the
locations of thermocouples placed on the cell for temperature
measurement are shown in Fig. 1. The thermocouples were placed at
five locations (A–E) (see Fig. 1) and temperature changes until 121 °C
were recorded.
2.5. Electrical conductivity calculation
Measurement was made five times. The distance between the
electrodes d [m], electrode contact area A [m2], applied voltage V [V],
and measured current I [A] were substituted in Eq. (1) below. This
equation was derived from Ohm's law, the relational expression
between electrical resistance and electrical resistivity, and the relational
expression between electric