posted on 2008-07-14, 11:35authored byMieke Vleugels, Gilbert Shama, Xu-Tao Deng, Elizabeth Greenacre, Tim Brocklehurst, Michael G. Kong
The ability of atmospheric pressure glow discharges
(APGD) to inactivate microorganisms has been demonstrated in a
number of previous studies. However, most of this work has been
performed using microorganisms that do not form biofilms and
with the microorganisms supported on abiotic surfaces that discourage
cell growth. When microorganisms attach to the surface
of a food, they can extract nutrients from the food and proliferate
at the surface. Often this growth takes the form of biofilms which
comprise three-dimensional (3-D) networks of polysaccharides
that attach microorganisms to surfaces and serve to protect them
from external stresses; fresh foods, such as salad crops, frequently
harbor biofilms. We believe that the use of APGD offers a potential
for inactivating microorganisms on the surface of fresh
foods that cannot be readily treated by other methods without
inducing unacceptable changes to these foods. As a first step
toward a full evaluation of the viability of the APGD technology
for food safety control, we consider in this paper two key issues,
namely: 1) whether atmospheric glow discharges can inactivate
biofilm-forming microorganisms and 2) whether plasma treatment
causes significant discoloration to food surfaces. Using the
biofilm-forming bacterium Pantoea agglomerans and bell peppers
(Capsicum annuum) as a typical example of plant tissue, we show
that atmospheric He-O2 plasmas can be effective inactivation
agents without causing unacceptable levels of discoloration to the
peppers, and that furthermore they are superior to the use of
low-pressure ultraviolet sources.
History
School
Mechanical, Electrical and Manufacturing Engineering
Citation
VLEUGELA, M. ... et al, 2005. Atmospheric plasma inactivation of biofilm-forming bacteria for food safety control. IEEE Transactions on Plasma Science, 33(2), pp. 824-828