Et ve Et Ürünlerinde Soğuk Plazma Uygulamaları

Year 2015, Volume: 8 Issue: 2, 79 - 86, 01.12.2015

Simge Aktop Veli Gök Mehmet Özkan Recep Kara

Abstract

Et ve et ürünlerinin dayanıklılığının arttırılması için birçok yöntem kullanılmaktadır. Et endüstrisinde yaygın olarak kullanılan pişirme, haşlama ve soğutma gibi ısıl işlemler, ette bazı değişikliklere neden olabilmektedir. Bu ısıl işlemlere alternatif olarak ısıl olmayan teknolojiler ortaya çıkmıştır. Bu teknolojiler arasında, tat, koku ve yapıda önemli değişikliklere neden olmayan, çevre dostu olan ve proseste toksik maddelerin kullanılmadığı soğuk plazma teknolojisi ön plana çıkmaktadır. Radyo frekansı ve dielektrik (yalıtkan) bariyer boşaltıcı gibi plazma sistemlerinden elde edilen soğuk plazma, et ve et ürünlerinde mikrobiyolojik bozulmaya neden olan mikroorganizmaların inaktivasyonunda kullanılabilmektedir. Bu derlemenin amacı, birçok gıda ürününde denemeleri yapılan soğuk plazma teknolojisinin et ve et ürünlerindeki uygulamalarını inceleyerek, et endüstrisindeki uygulanabilirliği hakkında bilgi vermektir.

Keywords

Et ve et ürünleri, Dekontaminasyon, İnaktivasyon, Novel (yeni nesil) teknolojiler, Soğuk plazma

Applications of Cold Plasma in Meat and Meat Products

Abstract

Many methods are used to increase durability of meat and meat products. Thermal treatments such as cooking, scalding and cooling which are used in meat industry widespreadly, can cause to some changes in meat. Non-thermal technologies emerged as alternative to this thermal treatments. Cold plasma which do not cause to changes in flavor, odor and texture, is environvent friendly and do not be used toxic substances in process, attract attention among this technologies. Cold plasma which can be obtained from systems of plasma such as radio frequency and dielectric barier discharge (DBD), is used in inactivation of microorganisms which cause to microbiyological spoilage in meat and meat products. The aim of this review is to investigate that the applications of cold plasma technologies in meat and meat products and also to inform about its feasibility in meat industry.

Keywords

Meat and meat products, Decontamination, Inactivation, Novel Technologies, Cold plasma

References

• Aktan T. Atmosferik Basınç Soğuk Plazma ile Yüzey Sterilizasyonu. Süleyman Demirel Üniversitesi, Fen Bilimleri Enstitüsü, Fizik Anabilim Dalı, Yüksek Lisans Tezi, 2011.
• Alexe P, Stoica M, Mihalcea L and Borda D. Non-thermal novel food processing technologies. Journal of Agroalimentary Process and Technologies 2013, 19(2), 212-217.
• Banu MS, Sasakila P, Dhanapal A, Kavitha V, Yazhini G and Rajamani L. Cold Plasma As A Novel Food Processing Technology. International Journal of Emerging trends in Engineering and Development. Issue 2, Vol.4, May, 2012, 803-818.
• Bozkurt D. Soğuk Plazma Uygulamasının Vitaminler Ve Polifenol Oksidaz (PFO) Enzimi Aktivitesi Üzerine Etkisi. Hacettepe Üniversitesi, Fen Bilimleri Enstitüsü, Gıda Mühendisliği Anabilim Dalı, Yüksek Lisans Tezi, 2014.
• Chen J, Yang L, Gao J and Guo Y. Plasma Sterilization Using The RF Glow Discharge. Applied Surface Science, 255 (2009), 8960-8964.
• Cullen PJ, Misra NN, Sullivan C, Pankaj SK, Alvarez-Jubete L, Cama R, Jacoby F. Applications of cold technology in food packaging. Elsevier, Trends in Food Science & Technology, 35 (2014), 5-17.
• Dirks BP. The Effect of Nonthermal Dielectric Barrier Discharge Plasma on Salmonella enterica and Campylobacter jejuni on Raw Poultry. A Thesis Submitted to the Faculty of Drexel University. Master of Science in Biology, March 2010.
• Efe E ve Akan T. Nano-Saniye Puls Elektrik Alanların ve Puls Plazmaların Biyolojik Hücreler Üzerine Etkisi. www.ursi.org.tr/2006-Kongre/pdf/66.pdf. (Erişim tarihi: 24.04.2015).
• Güleç HA. Gıda Endüstrisinde Isıl Olmayan Plazma Teknolojileri. Gıda, (2012), 37 (5): 295-302.
• Ha SD, Jahid IK, Han N and Zhang CY. Mixed culture biofilms of Salmonella Typhimurium and cultivable indigenous microorganisms on lettuce show enhanced resistance of their sessile cells to cold oxygen plasma. Elsevier, Food Microbiology, 46 (2015), 383-394.
• Jo C, Jayasena DD, Kim HJ, Yong HI, Park S, Kim K and Choe W. Flexible thin-layer dielectric barrier discharge plasma treatment of pork butt and beef loin: Effects on pathogen inactivation and meat-quality attributes. Elsevier, Food Microbiology, 46 (2015), 51-57.
• Jo C, Kim B, Yun H, Jung S, Jung Y, Jung H and Choe W. Effect of atmospheric pressure plasma on inactivation of pathogens inoculated onto bacon using two different gas compositions. Elsevier, Food Microbiology, 28 (2011), 9-13.
• Kayar G ve Yıldız H. Gıda sanayinde soğuk plazma tekniği uygulamaları. 7. Gıda Mühendisliği Kongresi, 24-26 Kasım 2011, Ankara Türkiye, 44 s.
• Kim Y, Kim J, Lee E and Cho E. Inactivation of Campylobacter jejuni using Radio-frequency Atmospheric Pressure Plasma on Agar Plates and Chicken Hams. Korean J. Food Sci. An., 2013, Vol.33, No.3, pp. 327-324.
• Korachi M, Aslan N. Low temperature atmospheric plasma for microbial decontamination. Microbial pathogens and strategies for combating them: science, technology and education (A. Méndez-Vilas, Ed.), Formatex, 2013, 453-459.
• Laroussi M, Leipold F. Evaluation of the roles of reactive species, heat, and UV radiation in the inactivation of bacterial cells by air plasmas at atmospheric pressure. Science Direct, International Journal of Mass Spectrometry, 233 (2004), 81-86.
• Lee KT. Quality and safety aspects of meat products as affected by various physical manipulations of packaging materials. Elsevier, Meat Science, 86 (2010), 138-150.
• Leipold F, Schultz-Jensen N, Kusano Y, Bindslev H, Jacobsen T. Decontamination of objects in a sealed container by means of atmospheric pressure plasmas. Elseveir, Food Control, 22 (2011), 1296-1301.
• Lerouge S, Wertheimer MR and Yahia L’H. Plasma Sterilization: A Review of Parameters, Mechanisms, and Limitations. Plasmas and Polymers, Vol.6, No.3, September, 2001.
• Maisch T, Shimizu T, Mitra A, Heinlin J, Karrer S, Li YF, Morfill G and Zimmermann JL. Contact-free cold atmospheric plasma treatment of Deinococcus radiodurans. J Ind Microbiol Biotechnol, (2012), 39: 1367–1375, DOI 10.1007/s10295-012-1137-6.
• Matthes R, Assadian O and Kramer A. Repeated applications of cold atmospheric pressure plasma does not induce resistance in Staphylococcus aureus embedded in biofilms. GMS, Hygiene and Infection Control, 2014, Vol. 9(3), ISSN 2196-5226.
• Miao H, Yun G. The sterilization of Escherichia coli by dielectric-barrier discharge plasma at atmospheric pressure. Applied Surface Science, 257 (2011), 7065–7070.
• Midgley J and Small A. Review of new and emerging technologies for red meat safety. Finalreport Food Safety, Meat & Livestock Australia, Locked Bag 991, North Sydney, NSW 2059, June 2006.
• Mihalcea L, Alexe P and Stoica M. Atmospheric Cold Plasma As New Strategy For Foods processing - An Overview. Innovative Romanian Food Biotechnology, Vol.15, 2014.
• Misra NN, Tiwari BK, Rahavarao KSMS and Cullen P. Nonthermal Plasma Inactivation of Food-Borne Pathogens. Food Engineering Reviews, Volume 3, Numbers 3-4 (2011), 159-170.
• Moreau M, Orange N and Feuilloley MGJ. Non-thermal plasma technologies: New tools for bio-decontamination. Elsevier, Biotechnology Advances, 26 (2008), 610-617.
• Noriega E, Shama G, Laca A, Díaz M and Kong MG. Cold atmospheric gas plasma disinfection of chicken meat and chicken skin contaminated with Listeria innocua. Food Microbiology, 28 (7), pp. 1293-1300, (2011).
• Özkendir OM ve Ufuktepe Y. Lazer-Plazma Etkileşme Mekanizmalarının İncelenmesi. Çukurova Üniversitesi, Fen ve Mühendislik Bilimleri Dergisi 11, No.1,102-112, (2000).
• Pankaj SK, Bueno-Ferrer C, Misra NN, Milosavljević V and O’Donnell CP, Pankai SK, Bourke, P, Keener K, Cullen PJ. Applications of cold plasma technology in food packaging, Trends in Food Science & Technology, 35 (2014), 5-17.
• Rød SK, Hansen F, Leipold and Knøchel S. Cold atmospheric pressure plasma treatment of ready-to-eat meat: Inactivation of Listeria innocua and changes in product quality. Elsevier, Food Microbiology, 30 (2012), 233-238.
• Schlüter O, Fröhling A, Durek J, Schnabel U, Ehlbeck J and Bolling J. Indirect plasma treatment of fresh pork: Decontamination efficiency and effects on quality attributes. Elsevier, Innovative Food Science and Emerging Technologies, 16 (2012), 381-390.
• Takai O. Solution plasma processing (SPP). Pure Appl. Chem., Vol. 80, No. 9, pp. 2003–2011, 2008. DOI: 10.1351/pac200880092003.
• Ulbin-Figlewicz N, Brychcy E and Jarmoluk A. Effect of low-pressure cold plasma on surface microflora of meat and quality attributes. J Food Sci Technol (February 2015), 52(2): 1228–1232, DOI 10.1007/s13197-013-1108-6.
• Ulbin-Figlewicz N, Jarmoluk A and Marycz K. Antimicrobial activity of low-pressure plasma treatment against selected foodborne bacteria and meat microbiota. Ann Mikrobiol, DOI 10.1007/s13213-014-0992-y, (2013).
• Wan J, Coventry J, Swiergon P, Sanguansri P and Versteeg C. Advances in innovative processing technologies for microbial inactivation and enhancement of food safety-pulsed electric field and low-temperature plasma. Elsevier, Trends in Food Science & Technology, 20 (2009) 414-424.
• Yangılar F ve Oğuzhan P. Plazma Teknolojilerinin Gıda Endüstrisinde Kullanımı. Gıda, (2013), 38 (3): 183-189.
• Ziuzina D, Patil S, Cullen PJ, Keener K, Bourke P. Atmospheric Cold Plasma inactivation of Escherichia coli, Salmonella enterica serovar Typhimurium and Listeria monocytogenes inoculated on fresh produce. Food Microbiology , (Accepted February 2014).