Impact of food model (micro)structure on the microbial inactivation efficacy of cold atmospheric plasma

The large potential of cold atmospheric plasma (CAP) for food decontamination has recently been recognized. Room-temperature gas plasmas can decontaminate foods without causing undesired changes. This innovative technology is a promising alternative for treating fresh produce. However, more fundamen...

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Veröffentlicht in:	International journal of food microbiology 2017-01, Vol.240, p.47-56
Hauptverfasser:	Smet, C., Noriega, E., Rosier, F., Walsh, J.L., Valdramidis, V.P., Van Impe, J.F.
Format:	Artikel
Sprache:	eng
Schlagworte:	Anti-Bacterial Agents - pharmacology Cell culture Cold atmospheric gas plasma Cold Temperature Colonies Colony Count, Microbial Culture media Deactivation Decontamination Decontamination - methods Dielectric barrier discharge Effectiveness Food Food contamination & poisoning Food Contamination - analysis Food Contamination - prevention & control Food industry Food Microbiology - methods Food model (micro)structure Food processing industry Gas plasmas Growth conditions Growth morphology Helium Immobilization Inactivation Inactivation support system Listeria Listeria monocytogenes Listeria monocytogenes - growth & development Microbial Sensitivity Tests Microbial Viability - drug effects Microorganisms Oxygen plasma Plasma Plasma Gases - pharmacology Salmonella Salmonella typhimurium - growth & development Shoulder Stationary phase Stressing Studies Sublethal injury Support systems
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container_title	International journal of food microbiology
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creator	Smet, C. Noriega, E. Rosier, F. Walsh, J.L. Valdramidis, V.P. Van Impe, J.F.
description	The large potential of cold atmospheric plasma (CAP) for food decontamination has recently been recognized. Room-temperature gas plasmas can decontaminate foods without causing undesired changes. This innovative technology is a promising alternative for treating fresh produce. However, more fundamental studies are needed before its application in the food industry. The impact of the food structure on CAP decontamination efficacy of Salmonella Typhimurium and Listeria monocytogenes was studied. Cells were grown planktonically or as surface colonies in/on model systems. Both microorganisms were grown in lab culture media in petri dishes at 20°C until cells reached the stationary phase. Before CAP treatment, cells were deposited in a liquid carrier, on a solid(like) surface or on a filter. A dielectric barrier discharge reactor generated helium-oxygen plasma, which was used to treat samples up to 10min. Although L. monocytogenes is more resistant to CAP treatment, similar trends in inactivation behavior as for S. Typhimurium are observed, with log reductions in the range [1.0–2.9] for S. Typhimurium and [0.2–2.2] for L. monocytogenes. For both microorganisms, cells grown planktonically are easily inactivated, as compared to surface colonies. More stressing growth conditions, due to cell immobilization, result in more resistant cells during CAP treatment. The main difference between the inactivation support systems is the absence or presence of a shoulder phase. For experiments in the liquid carrier, which exhibit a long shoulder, the plasma components need to diffuse and penetrate through the medium. This explains the higher efficacies of CAP treatment on cells deposited on a solid(like) surface or on a filter. This research demonstrates that the food structure influences the cell inactivation behavior and efficacy of CAP, and indicates that food intrinsic factors need to be accounted when designing plasma treatment.
doi_str_mv	10.1016/j.ijfoodmicro.2016.07.024
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Typhimurium and [0.2–2.2] for L. monocytogenes. For both microorganisms, cells grown planktonically are easily inactivated, as compared to surface colonies. More stressing growth conditions, due to cell immobilization, result in more resistant cells during CAP treatment. The main difference between the inactivation support systems is the absence or presence of a shoulder phase. For experiments in the liquid carrier, which exhibit a long shoulder, the plasma components need to diffuse and penetrate through the medium. This explains the higher efficacies of CAP treatment on cells deposited on a solid(like) surface or on a filter. 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Room-temperature gas plasmas can decontaminate foods without causing undesired changes. This innovative technology is a promising alternative for treating fresh produce. However, more fundamental studies are needed before its application in the food industry. The impact of the food structure on CAP decontamination efficacy of Salmonella Typhimurium and Listeria monocytogenes was studied. Cells were grown planktonically or as surface colonies in/on model systems. Both microorganisms were grown in lab culture media in petri dishes at 20°C until cells reached the stationary phase. Before CAP treatment, cells were deposited in a liquid carrier, on a solid(like) surface or on a filter. A dielectric barrier discharge reactor generated helium-oxygen plasma, which was used to treat samples up to 10min. Although L. monocytogenes is more resistant to CAP treatment, similar trends in inactivation behavior as for S. Typhimurium are observed, with log reductions in the range [1.0–2.9] for S. Typhimurium and [0.2–2.2] for L. monocytogenes. For both microorganisms, cells grown planktonically are easily inactivated, as compared to surface colonies. More stressing growth conditions, due to cell immobilization, result in more resistant cells during CAP treatment. The main difference between the inactivation support systems is the absence or presence of a shoulder phase. For experiments in the liquid carrier, which exhibit a long shoulder, the plasma components need to diffuse and penetrate through the medium. This explains the higher efficacies of CAP treatment on cells deposited on a solid(like) surface or on a filter. This research demonstrates that the food structure influences the cell inactivation behavior and efficacy of CAP, and indicates that food intrinsic factors need to be accounted when designing plasma treatment.</description><subject>Anti-Bacterial Agents - pharmacology</subject><subject>Cell culture</subject><subject>Cold atmospheric gas plasma</subject><subject>Cold Temperature</subject><subject>Colonies</subject><subject>Colony Count, Microbial</subject><subject>Culture media</subject><subject>Deactivation</subject><subject>Decontamination</subject><subject>Decontamination - methods</subject><subject>Dielectric barrier discharge</subject><subject>Effectiveness</subject><subject>Food</subject><subject>Food contamination & poisoning</subject><subject>Food Contamination - analysis</subject><subject>Food Contamination - prevention & control</subject><subject>Food industry</subject><subject>Food Microbiology - methods</subject><subject>Food model (micro)structure</subject><subject>Food processing industry</subject><subject>Gas plasmas</subject><subject>Growth conditions</subject><subject>Growth morphology</subject><subject>Helium</subject><subject>Immobilization</subject><subject>Inactivation</subject><subject>Inactivation support system</subject><subject>Listeria</subject><subject>Listeria monocytogenes</subject><subject>Listeria monocytogenes - growth & development</subject><subject>Microbial Sensitivity Tests</subject><subject>Microbial Viability - drug effects</subject><subject>Microorganisms</subject><subject>Oxygen plasma</subject><subject>Plasma</subject><subject>Plasma Gases - pharmacology</subject><subject>Salmonella</subject><subject>Salmonella typhimurium - growth & development</subject><subject>Shoulder</subject><subject>Stationary phase</subject><subject>Stressing</subject><subject>Studies</subject><subject>Sublethal injury</subject><subject>Support systems</subject><issn>0168-1605</issn><issn>1879-3460</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2017</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNqNUU1v1TAQtBCIPgp_ARlxKYeEtZ3YyRE98VGpEhc4W46zpo6SONhOpf57_PoKQpw4WdqdmfXMEPKGQc2AyfdT7ScXwrh4G0PNy6gGVQNvnpAD61RfiUbCU3Ioi65iEtoL8iKlCQBaIeA5ueCqBcVEdyA_rpfN2EyDoydFuoQRZ3r1oPwu5bjbvEekYaX5FunDePBmpn4tLH9nsi8rdM5bY-9PKjbMIzV5CWm7xegt3WaTFvOSPHNmTvjq8b0k3z99_Hb8Ut18_Xx9_HBT2ZbzXLVGCdm1HGQrlGNq7NVQ_BmQBjtkfdN20g5OysHZHhq0xQhioxg0EoXtxSW5OutuMfzcMWW9-GRxns2KYU-adSUaLljTFejbf6BT2ONafqdZLyTnQjayoPozqjhPKaLTW_SLifeagT61oSf9Vxv61IYGpUsbhfv68cI-LDj-Yf6OvwCOZwCWSO48Rp2sx9Xi6CParMfg_-PML9gMoSY</recordid><startdate>20170102</startdate><enddate>20170102</enddate><creator>Smet, C.</creator><creator>Noriega, E.</creator><creator>Rosier, F.</creator><creator>Walsh, J.L.</creator><creator>Valdramidis, V.P.</creator><creator>Van Impe, J.F.</creator><general>Elsevier B.V</general><general>Elsevier BV</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7QL</scope><scope>7QO</scope><scope>7QR</scope><scope>7T7</scope><scope>7U9</scope><scope>8FD</scope><scope>C1K</scope><scope>FR3</scope><scope>H94</scope><scope>M7N</scope><scope>P64</scope><scope>RC3</scope><scope>7X8</scope></search><sort><creationdate>20170102</creationdate><title>Impact of food model (micro)structure on the microbial inactivation efficacy of cold atmospheric plasma</title><author>Smet, C. ; 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Room-temperature gas plasmas can decontaminate foods without causing undesired changes. This innovative technology is a promising alternative for treating fresh produce. However, more fundamental studies are needed before its application in the food industry. The impact of the food structure on CAP decontamination efficacy of Salmonella Typhimurium and Listeria monocytogenes was studied. Cells were grown planktonically or as surface colonies in/on model systems. Both microorganisms were grown in lab culture media in petri dishes at 20°C until cells reached the stationary phase. Before CAP treatment, cells were deposited in a liquid carrier, on a solid(like) surface or on a filter. A dielectric barrier discharge reactor generated helium-oxygen plasma, which was used to treat samples up to 10min. Although L. monocytogenes is more resistant to CAP treatment, similar trends in inactivation behavior as for S. Typhimurium are observed, with log reductions in the range [1.0–2.9] for S. Typhimurium and [0.2–2.2] for L. monocytogenes. For both microorganisms, cells grown planktonically are easily inactivated, as compared to surface colonies. More stressing growth conditions, due to cell immobilization, result in more resistant cells during CAP treatment. The main difference between the inactivation support systems is the absence or presence of a shoulder phase. For experiments in the liquid carrier, which exhibit a long shoulder, the plasma components need to diffuse and penetrate through the medium. This explains the higher efficacies of CAP treatment on cells deposited on a solid(like) surface or on a filter. This research demonstrates that the food structure influences the cell inactivation behavior and efficacy of CAP, and indicates that food intrinsic factors need to be accounted when designing plasma treatment.</abstract><cop>Netherlands</cop><pub>Elsevier B.V</pub><pmid>27507138</pmid><doi>10.1016/j.ijfoodmicro.2016.07.024</doi><tpages>10</tpages><oa>free_for_read</oa></addata></record>
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subjects	Anti-Bacterial Agents - pharmacology Cell culture Cold atmospheric gas plasma Cold Temperature Colonies Colony Count, Microbial Culture media Deactivation Decontamination Decontamination - methods Dielectric barrier discharge Effectiveness Food Food contamination & poisoning Food Contamination - analysis Food Contamination - prevention & control Food industry Food Microbiology - methods Food model (micro)structure Food processing industry Gas plasmas Growth conditions Growth morphology Helium Immobilization Inactivation Inactivation support system Listeria Listeria monocytogenes Listeria monocytogenes - growth & development Microbial Sensitivity Tests Microbial Viability - drug effects Microorganisms Oxygen plasma Plasma Plasma Gases - pharmacology Salmonella Salmonella typhimurium - growth & development Shoulder Stationary phase Stressing Studies Sublethal injury Support systems
title	Impact of food model (micro)structure on the microbial inactivation efficacy of cold atmospheric plasma
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