Antymikrobiologiczne opakowania żywności

• Autorzy: Agnieszka Martyn , Zdzisław Targoński

Warianty tytułu

Antimicrobial Food Packagings

• Języki publikacji: PL

Abstrakty

Wzrastające wymagania konsumentów dotyczące bezpiecznej, minimalnie przetworzonej żywności oraz wydłużonego czasu jej przechowywania mobilizują przemysł spożywczy do wprowadzania m.in. aktywnych, w tym antymikrobiologicznych opakowań żywności. Głównymi antymikrobiologicznymi składnikami tych opakowań są: kwas benzoesowy, kwas sorbowy oraz ich sole, nizyna, lizozym, olejki eteryczne i inne. Składniki te, odpowiednio wkomponowane w matryce opakowania, zapobiegają lub ograniczają rozwój wielu drobnoustrojów, np.: Listeria monocytogenes, Salmonella typhimurium, Staphylococcus aureus oraz pleśni: Penicillium, Aspergillus niger. Skuteczność opakowania antymikrobiologicznego zależy od doboru składników antymikrobiologicznych do matrycy opakowania oraz rodzaju produktu spożywczego przeznaczonego do zapakowania. Problematyka ta jest przedmiotem niniejszego artykułu. (abstrakt oryginalny)

EN

The increasing consumer demand for safety, healthy, minimally processed food and for its longer shelf- life forces the food industry to introduce, among other things, active packagings including antimicrobial food packagings. The major components of such packagings comprise: benzoic acid, sorbic acid, their salts, nisin, lysozyme, essential oils, and others. Those components, adequately incorporated into the matrices of packagings, protect against or reduce the development of many micro-organisms, such as: Listeria monocytogenes, Salmonella typhimurium, Staphylococcus aureus, or moulds: Penicillium and Aspergillus niger. The effectiveness of antimicrobial packagings depend on what antimicrobial components are selected for the packaging matrix, as well as on the kind of food product to be packed. Those issues constitute the subject of this paper. (original abstract)

Słowa kluczowe

PL

Opakowania produktów spożywczych; Bezpieczeństwo zdrowotne żywności; Bezpieczeństwo mikrobiologiczne; Innowacje w opakowalnictwie

EN

Food packaging; Food health safety; Microbiological safety; Innovations in packaging

• Czasopismo: Żywność: nauka - technologia - jakość
• Rocznik: 17 (2010)
• Numer: nr 5 (72)
• Strony: 33--44

Twórcy

autor

Agnieszka Martyn

• Uniwersytet Przyrodniczy w Lublinie

autor

Zdzisław Targoński

• Uniwersytet Przyrodniczy w Lublinie

Bibliografia

• [1] An D.S., Kim Y.M., Lee S.B., Paik H.D. Lee D.S.: Antimicrobial low density polyethylene film coated with bacteriocins in binder medium. Food Sci. Biotechnol., 2000, 9, 14-20.
• [2] Ahvenainen R.: Active and intelligent packaging; in Novel food packaging techniques. Ed. by R. Ahvenainen. Woodhead Publishing Limited, Cambridge, England, 2003.
• [3] Appendini P. Hotchkiss J.H.: Immobilization of lysozyme on food contact polymers as potential food an microbial film. Pack. Technol. Sci., 1997, 10, 271-279.
• [4] Appendini P., Hotchkiss J.H.: Review of antimicrobial food packaging. Int. Food Sci. Emer. Technol., 2002, 3, 113-123.
• [5] Baron J.K., Sumner S.S.: Antimicrobial containing edible films as inhibitory systems to control microbial growth on meat product. J. Food Prot., 1993, 56, 916.
• [6] Boziaris I.S., Adams M.R.: Effect of chelator and nizin produced in situ on inhibition and inactivation of Gram negatives. Int. J. Food Microbiol., 1999, 53, 105-113.
• [7] Branem J.K., Davidson P.M.: Enhacement of nisin, lysozyme and monolaurin antimicrobial activities by ethylenediaminetetraacetic acid and lactoferrin. Int. J. Food Microbiol., 2004, 90, 63-74.
• [8] Brul S., Coote P.: Preservative agents in food. Mode of action and microbial resistance in microorganisms. Int. J. Food Microbiol., 1999, 50, 1-17.
• [9] Cagri A., Ustunol Z., Osburn W., Ryser E.T.: Inhibition of Listeria monocytogenes on hot dogs using antimicrobial whey protein - based edible casings. J Food Sci., 2003, 68 (1), 291-299.
• [10] Cagri A., Ustunol Z., Ryser E.T.: Antimicrobial, mechanical and moisture barrier properties of low pH whey protein- based edible films containing p-aminobenzoic or sorbic acid. J. Food Sci., 2001, 66 (6), 865-870.
• [11] Cagri A., Ustunol Z., Ryser E.T.: Inhibition of three pathogens on bologna and summer sausage using antimicrobials edible films. J. Food Sci., 2002, 67 (6), 2317-2324.
• [12] Cha D.S., Chen J., Park H.J., Chinnan M.S.: Inhibition of Listeria monocytogenes in tofu by use of polyethylene film coated with a cellulosic solution containing nisin; Int. J. Food Sci. Technol., 2003, 38, 499-503.
• [13] Chen M.C., Yeh G.H.C., Chiang B.H.: Antimicrobial and physicochemical properties of methylocellulose and chitosan films containing a preservative. J. Food Proc. Pres., 1996, 20, 379-390.
• [14] Coma V., Sebti I., Pardon P., Deschamps A., Pichavant F.H.: Antimicrobial edible packaging based on cellulosic ethers fatty acids and nisin incorporation to inhibit Listeria innocua and Staphylococcus aureus. J. Food Prot. 2001, 64 (4), 470-475.
• [15] Conte A., Buonocore G.G., Sinigaglia M., Del Nobile M.A.: Development of immobilized lysozyme based active film. J. Food Eng., 2007, (78), 741-745.
• [16] Cutter C.N., Siragusa G.R.: Population reduction of gram negative pathogens following treatments with and chelators under various conditions. J. Food Prot.,1995, 58 (9), 977-983.
• [17] Cutter C.N., Willet J.N., Siragusa G.R.: Improved antimicrobial activity of nisin-incorporated polymers films by formulation change and addition of grade chelator. Let. Appl. Microbiol., 2001, 33, 325-328.
• [18] Devlieghere F., Vermein L., Bockstal A., Debevere J.: Study on antimicrobial activity of a food packaging material containing potassium sorbate. Act. Alimen. 2000, 29, 137-146.
• [19] Dobias J., Chudackova K., Voldrich M., Marek M.: Properties of polyethylene films with incorporated benzoic anhydride and/or ethyl or propyl esters of 4-hydroxybenzoic acid and their suitability for food packaging. Food Add. Contamin, 2000, 17 (12),1047-1053.
• [20] Fink J.K.: Reactive Polymers Fundamentals and Applications. Williams Andrew Publishing, Norwich, N.Y., USA, 2005.
• [21] Floros J.D., Dock L.L., Han J.H.: Active packaging technologies and applications. Food Cosmet. Drug Packag, 1997, 20 (1), 10-17.
• [22] Franklin N.B., Cooksey K.D., Getty K.J.K.: Inhibition of Listeria monocytogenes on the surface of individually packaged hot dogs with a packaging film coating containing nisin. J. Food Prot., 2004, 67 (3), 480-485.
• [23] Gontard N. : Panorama des emballages alimentaire actif, in Les emballages actifs, coordonnatrice Gontard N., Editions TEC & DOC, Londres 2000.
• [24] Gosh K.G., Sriatsava A.N., Shmara T.R.: Development and application of fungastic wrappers in food preservation. J. Food Sci. Technol., 1977, 14, 261-264.
• [25] Guerra N.P., Macias C.L., Agrasar A.T., Castro L.P.: Development of a bioactive packaging cellophane using Nisaplin® as biopreservative agent. Lett. Appl. Microbiol, 2005, 40, 106-110.
• [26] Han J.H., Rooney M.L.: Active Food Packaging Woorkshop, Annunal Conference of the Canadian Institute of Food Science and Technology (CIFSTA), May 26, 2002.
• [27] Han J.H.: Antimicrobial food packaging, in Novel ford packaging techniques edited by R. Ahvenainen, Woodhead Publishing Limited, Cambridge, England, 2003.
• [28] Han J.H.: Antimicrobial food packaging. Food Technology, 2000, 54 (3), 56-65.
• [29] Hansen R., Rippl C., Midkiff D., Neuwirth J.: Antimicrobial absorbent pads. Us Patent, 1989, 4 865 855.
• [30] Holzapfel W.H., Geisen R., Schillinger U.: Review paper. Biological preservation of foods with references to protective cultures, bacteriocins and food- grade enzymes. Int. J. Food Microbiol.,1995, 24, 343-362.
• [31] Hotchkiss J.H.: Recent research in MAP and active packaging system in Abstract, 27th Annual Convection Australian Institute of Food Science and Technology, Canberra 1995, p 104.
• [32] Kandemir N., Yemenicioglu, Mecitoglu C., Elmaci Z.S., Arslanglu, Göksungur Y., Baysal T.: Production of antimicrobial films by incorporation of partially purified lysozyme into biodegradable films of crude exopolysaccharides obtained from Aureobasidium pullulans fermentation. Food Technol Biotechnol, 2005, 43 (4), 343-350.
• [33] Krejcova O., Svirkova E., Dobias J., Plockova M.: Inhibition of lactic amid bacteria and Bacillus sp growth in cheese and meat product due to effect of polymer packaging film with incorporated nisin. Czech J. Food Sci., 2004, 22 (special issue), 303-305.
• [34] Lee C.H, Park H.J., Lee D.S.: Influence of antimicrobial packaging on kinetics of spoilage microbial growth in milk and orange juice. J. Food Eng., 2004, 65, 527-531.
• [35] Lee C.H., An D.S., Lee S.C., Park H.J., Lee D.S.: A coating for use as an antimicrobial and antioxydative packaging material incorporating nisin and a tocopherol. J. Food Eng., 2004, 62, 323-329.
• [36] Limjaroen P., Ryser E., Lockhart H., Harte B.: inactivation of Listeria monocytogenes on beef bologna and cheddar cheese using polyvinylidene chloride films containing sorbic acid. J. Food Sci., 2005, 70 (5), M267-M271.
• [37] López-Rubio A., Almenar E., Hernandez- Muñoz P., Lagarón J.M., Catalá Gavara R.: Overview of active polymer-based packaging technologies for food application. Food Rev. Int., 2004, 20 (4), 357-387.
• [38] Matche R.S., Kulkarmi G., Raj B.: Modification of ethylene acrylic acid film for antimicrobial activity. J. Appl. Polym. Sci., 2006, 10 (4), 3063-3068.
• [39] Mecitoğlu C., Yemenicioğlu A., Arslanoğlu, Elmac Z.S., Korel F., Çetin A.E.: Incorporation of partially purified hen egg white lysozyme into zein films for antimicrobial food packaging. Food Res. Int., 2006, 39, 12-21.
• [40] Miltz X., Passy N., Mannheim C.H.: Trends and applications of active packaging systems. in Food and packaging materials: chemical interactions. Ed. Ackerman P., Jägerstad M., Ohlsson T., Cambridge: Royal Society of Chemistry, 1997, pp. 201-220.
• [41] Ming X., Weber G.H., Ayres J. W., Sandine W.E.: Bacteriocins applied to food packaging materials to inhibit Listeria monocytogenes on meat. J. Food Sci., 1997, 62 (2), 413-415.
• [42] Monte A., Sinigaglia M., Del Nobile M.A.: Antimicrobial effectiveness of lysozyme immobilized on polyvinylalcohol - based film against Alicyclobacillus acidoterrestis. J. Food Prot., 2006, 69 (4), 861-865.
• [43] Muriello G., Ercolini D., La Storia A., Casaburi A., Villlani F.: Development of polythene films for food packaging activated with an antisterial bacteriocin from Lactobacillus curvatus 32Y. J. Apl. Microbiol., 2004, 97, 314-322.
• [44] Muriello P., De Luca E., La Storia A., Viliani F., Ecrolini D.: Antimicrobial activity of a nisinactived plastic film for food packaging. Lett. Appl. Microbiol., 2005, 41, 464-469.
• [45] Nielsen P.V., Rios R.: Inhibition of fungal growth on bread by volatile components from spices and herbs and the possible application in active packaging with special emphasis on mustard essential oil. Int J. Food Microbiol., 2000, 60, 219-229.
• [46] Özdemir M., Floros J.D.: Active food packaging technologies. Crit. Rev. Food Sc. Nutr., 2004, 44, 185-193.
• [47] Quintavalla S., Vincini L.: Antimicrobial food packaging in meat industry. Meat Sci., 2002, 62, 373-380.
• [48] Padgett T., Han I.Y., Dawson P.L.: Incorporation of food grade antimicrobial compounds into biodegradable packaging films. J. Food Prot., 1998, 61 (10), 1330-1335.
• [49] Park S.I., Deaschel M.A., Zhao Y.: Functional properties of antimicrobial lysozyme-chitosan composite film. J. Food Sci., 2004, 69 (8), M215-M221.
• [50] Pronato Y., Rakshit S.K., Salokhe V.M.: Enhancing antimicrobial activity of chitosan films by incorporating garlic oils, potassium sorbate and nisin: Lebensm- Wiss u.-Technol., 2005, 38, 859-865.
• [51] Rooney M.: Active Food Packaging. Blackie Academic and Professional London, England, 1995.
• [52] Rudra J.A., Dave K., Haynie D.T. : Antimicrobial polypeptide multilayer nanocoating. J. Biomater. Sci. Polymer End, 2006, 17 (11), 1301-1315.
• [53] Scannell A.G.M., Hill C., Ross R.P., Marx S., Hartmieren W., Arendt E.K.: Development of bioactive food packaging materials using immobilized bacteriocins Lactacin 3147 and Nisaplin®. Int. J. Food Microbiol., 2000, 60, 241-249.
• [54] Schillinger U., Geisen R., Holzapfel W.H.: Potential of antagonistic microorganisms and bacteriocins for the biological preservation of foods. Trends Food Sci. Technol. 1996, 7, 158-164.
• [55] Sebti I., Coma V.: Active edible polysaccharide coating and intereactions between solution coating compounds. Carbohydr. Polym. 2002, 49, 139-144.
• [56] Seydim A.C., Sarikus G.: Antimicrobial of activity of whey proteins based edible films incorporated with oregano rosemary and garlic essential oils. Food Res. Int. 2006, 39, 639-644.
• [57] Soares N.F.F., Rutishauser D.M., Melo N., Cruz R.S., Andrade N.J.: Inhibition of microbial growth in bread through active packaging. Packag. Technol. Sci., 2002, 15, 129-132.
• [58] Solomakos N, Govaris A.: Nisin and its food application. Deltion tes Ellenikes- Kteniatrikes- Etaireias, J. Vet. Med. Soc., 2005, 56 (2), 122-129.
• [59] Sonneveld K.: What driver (food) packaging innovation?. Pack. Technol. Sci ., 2000, 13 (1), 29-35.
• [60] Vartiainen J., Skytta E., Enqvist J., Ahvenainen R.: Properties of antimicrobial plastics, containing traditional food preservatives. Packag. Technol. Sci., 2003, 16 (6), 223-229.
• [61] Vermeirein L., Devlieghere F., Dabereve J.: Effectiveness of some recent antimicrobial packaging concept. Food Add. Contamin. 2002, 19 Suppl.,163-171.
• [62] Vermeirein L., Devlieghere F., Dabereve J.: New preservation technologies: possibilities and limitation; Int. Dairy J., 2004, 14, 273-285.
• [63] Vermeiren L., Devilghere F., van Beest M., de Kruijf N., Debevere J.: Development in active packaging of foods. Trends Food Sci. Technol, 1999, 10, 77-86.
• [64] Weng Y.M., Chen M.J, Chem W.M.: Benzoyl chloride modified ionomer films as antimicrobial food packaging materials. Int. Food Sci. Technol., 1997, 32, 229-234.
• [65] Weng Y.M., Chen M.J, Chem W.M.: Antimicrobial food packaging materials from poly ethylenco-methaacrylic acid. Lebensm- Wiss u.-Technol., 1998, 32 (4), 191-195.
• [66] Weng Y.M., Chen M.J.: Sorbic anhidryde as anitmycotic additive in polyethylene food packaging films. J. Plastic Films Sh,1997, 13, 287-298.
• [67] Zivanivic S., Chi S., Draughon A.F.: Antimicrobial activity of chitosan films enriched with essential oils. J. Food Sci., 2005, 70 (1), M45-M51.