PACKAGING SPECTRUM: Determination of the critical substances migration from cellulosic food packaging materials containing the protective sorption layer by chromatographic methods; Karol BAL, Monika KACZMARCZYK, Alicja KASZUBA; ABSTRACT: Development of a sorption layer between cellulose packaging and food product was the goal of the SoLaPack research project realized in the framework of the CORNET. Barrier coatings are made of various substances approved for contact with food such as starch granules, cyclodextrines, latex, bentonites etc. As a critical substances for testing were selected benzophenone, bisphenol A, phthalates and mineral oils, which may be present in packaging from recycled cellulose. Barrier properties were tested using migration chamber with a Tenax® as a food simulant. Determination of benzophenone and phthalates migration was carried out using gas chromatography and mass spectrometry (GC/MS). Mineral oils were determined by gas chromatography with FID detector and bisphenol A was determined by liquid chromatography with fluorescence detection. Selected materials with sorption layers are stopping migration of critical substances while are not a barrier where condensation in the packaging can occur. IN POLISH: OZNACZANIE METODAMI CHROMATOGRAFICZNYMI MIGRACJI SUBSTANCJI KRYTYCZNYCH Z CELULOZOWYCH OPAKOWAŃ DO ŻYWNOŚCI ZAWIERAJĄCYCH SORPCYJNĄ WARSTWĘ OCHRONNĄ; STRESZCZENIE: Celem projektu badawczego SoLaPack realizowanego w ramach CORNET było opracowanie sorpcyjnej warstwy ochronnej dla celulozowych opakowań produktów spożywczych. Powłoki barierowe zostały wykonane z różnych substancji, dopuszczonych do kontaktu z żywnością, takich jak skrobia, cyklodekstryny, lateks, bentonity itp. Jako substancje krytyczne do badania wybrano benzofenon, bisfenol A, oleje mineralne i ftalany, które mogą być obecne w opakowaniach celulozowych pochodzących z recyklingu. Właściwości barierowe badano w komorze migracyjnej stosując Tenax jako substancję modelową żywności. Oznaczanie migracji benzofenonu i ftalanów przeprowadzono za pomocą chromatografii gazowej i spektrometrii mas (GC / MS). Oleje mineralne oznaczano za pomocą chromatografii gazowej z detektorem FID, a bisfenol A badano metodą chromatografii cieczowej z detektorem fluorescencyjnym (HPLC-FLD). Zastosowana metodyka umożliwiła wyselekcjonowanie materiałów zatrzymujących migrację substancji krytycznych do żywności, przy jednoczesnym braku własności barierowych w przypadku występowania kondensacji wewnątrz opakowania.
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1. Introduction Packaging in addition to basic protective function, serves increasingly as an information and marketing tool. This is achieved by a multi printing of the packaging (fig. 1). Paper and paperboard are not sufficient barriers to stop migration of harmful substances into food product which is packed in [1, 2, 3]. Development of a sorption layer between cellulose packaging and food product (fig. 2) was the goal of the SoLaPack research project realized in the framework of the CORNET [4]. Barrier coatings are made of various substances approved for contact with food, such as starch granules, cyclodextrins, latex, bentonites etc. As a critical substances for testing were selected benzophenone (BP), bisphenol A (BPA), mineral oils (MO) and phthalates (Ph), which may be present in packaging from recycled cellulose. Barrier properties were tested using migration chamber with a Tenax as a food simulant (4.0g/dm2) [5]. Determination of benzophenone and phthalates migration was carried out using gas chromatography and mass spectrometry (GC/MS) [6,7]. Mineral oils were determined by gas chromatography with FID detector (GC-FID) [8] and bisphenol A was determined by liquid chromatography with fluorescence detector (HPLC-FLD) [9]. Samples for migration studies properties where prepared by our Partners from Center of Bioimmobilisation and Innovative Packaging Materials (CBIMO), Centre de Recherche et de Contrôle agro-alimentaire, emballage, environnement et textile (CELABOR), Centre de Ressources Technologiques en Chimie (CERTECH) and Papiertechnische Stiftung (PTS). Compositions of sorption coatings contained: zeolite – ABS DEO1000, acrylate binder (Acronal), styrene-butadiene binder (Styronal), starch and γ-cyclodextrin in different combinations. A list of functionalized paper samples along with information on the composition of the applied protective layer is in the tab. 1. 2. Experimental 2.1. Migration All experiments were carried out with the use of migration cell (model FABES MC60). Where 1 gram of critical substance was placed on bottom of the migration cell (fig. 3). Then functionalized paper disc (0.32 dm2) was placed in the middle (with coating layer down). And after placing of 1.28g of Tenax on opposite side of paper, tighten cells were thermostated in temp. 40°C for BP, 70°C for MO and Ph and 100°C for BPA. Extraction of Tenax was carried out with methanol (80 mL) and 1 mL was taken for gas chromatographic analysis. For mineral oils mixture of ethanol-hexane was used as extraction solvent. In the case of BPA migration studies, before HPLC analysis methanol solution was concentrated to 1 mL and filtered through a 0.2 μm filter. 3. Chromatographic analysis 3.1. Benzophenone and phthalates The GC/MS analysis of benzophenone and phthalates was carried out with the chromatograph HP 5890 series II coupled with detector HP 5972 on HP-FFAP capillary column (30 m, 0.25mm, 25μµm). The temperature program was as follows: 1 min. at 100°C, programmed at 6°C/min. to 240°C and 5 min. at 240°C. Carrier gas helium flow was 0.95 ml/min. The temperatures of injector and detector were 240°C. Benzophenone retention time under these conditions is 19.5 min. Mass spectra detector was operating in SIM mode. Molecular ion m/z = 182 was used as quantitation ion. 3.2. Mineral oils The GC-FID analysis of mineral oils was carried out with the HP 5890 series II Plus chromatograph on ZEBRON ZB5 capillary column (15 m, 0.25mm, 25μµm). The temperature program was as follows: 9 min. at 60°C, programmed at 22°C/min. to 240°C then programmed at 30°C/min. to 380°C and kept in this temperature for 12 min. The temperatures of injector was 280°C and FID detector was 365°C. 3.3. Bisphenol A HPLC separation of bisphenol A was performed with Agilent Technologies 1100 coupled with fluorescence detector (excitation 335 nm, emission 317 nm) on Spherisorb ODS2 Waters column (250 x 4.6 mm, 5 µm) thermostated at temp. of 30˚C and with isocratic elution: 20% water – 80% methanol. The flow rate of the mobile phase was 0.5 ml/min. Sample injection volume was 10 µl. BPA retention time under these conditions is 6.7 min. 4. Results Parallel with the functionalized papers was performed testing of reference paper containing no sorption layer. All samples were analyzed under identical conditions. Absorption properties were calculated by comparison of integrated peaks of critical substances with reference sample peak (fig. 4). Table 1 presents the results of effectiveness of the sorption layers in retaining critical substances from the migration into Tenax® as a food simulant, expressed as the percentage with respect to the reference sample. In three cases (marked with asterisk) for bisphenol A was very low, which was caused by instability of coating sorption (micro-cracks) under experiment conditions (100˚C) necessary for the application due to the low volatility of BPA. 5. Conclusion Chromatographic studies (GC/MS, GC/FID or HPLC) of specific migration of benzophenone, phthalates, mineral oils and bisphenol A to Tenax through the packaging material with a protective layer, allowed for predicting materials with the best barrier properties and to choose the best coated papers for further technological and industrial testing [10]. These materials with sorption layers are stopping migration of critical substances while are not a barrier where condensation in the packaging can occur. This research was financially supported by the NCBiR – project CORNET /1/12/11/2012 Sources [1] Council of Europe Resolution ResAP (2002) 1, Paper and board materials and articles intended to come into contact with food, Version 2 – 13.04.2005. [2] Ozaki A., Yamaguchi Y., Fujita T., Kuroda K., and Endo G., Safety assessment of paper and board food packaging: Chemical analysis and genotoxicity of possible contaminants in packaging, „Food Additives and Contaminants”, 2005, 22, pp. 1053-60. [3] Richter T., Gude T., Simat T., Migration of novel offset printing inks from cardboard packaging into food, „Food Additives and Contaminants”, 2009, 26, pp. 1574-1580. [4] Bal K., Kaszuba A., Projekt SoLaPack – zapobieganie migracji substancji szkodliwych z opakowań pochodzenia celulozowego, „Przegląd Papierniczy”, 2014, 70, pp. 79-83. [5] Kaszuba A., Bal K., Zastosowanie Tenaxu do optymalizacji powłok barierowych dla opakowań z papieru i tektury, „Opakowanie” issue 8 / 2014, pp. 76-78. [6] Bal K., Mielniczuk Z., Pawlicka M., Zastosowanie chromatografii gazowej i spektrometrii mas do badania migracji benzofenonu i 4-metylobenzofenonu z zadrukowanych opakowań do żywności, „Opakowanie” issue 12/2010, pp. 14-17. [7] Kaszuba A., Bal K., Pawlicka M., Badanie migracji plastyfikatorów do Tenaxu z opakowań przeznaczonych do kontaktu z żywnością, „Opakowanie” issue 7/2013, pp. 72-797. [8] Zurfluh M., Biedermann M., Grob K., Simulation of the migration of mineral oil from recycled paperboard into dry foods by Tenax®?, „Food Additives and Contaminants” Part A, 2013, 30, pp. 909-918. [9] Nerín C., Philo M. R., Salafranca J. and Castle L., Determination of bisphenol-type contaminants from food packaging materials in aqueous foods by solid-phase microextraction-high performance liquid chromatography, „Journal of Chromatography A”, 2002, 963, pp. 375-380. [10] Bal K., Kaczmarczyk M., Kaszuba A., Cellulose food packaging materials with sorption layer. Determination of critical substances migration by chromatographic methods, 27th IAPRI Symposium on Packaging 2015, 8-11 June 2015, Valencia, Spain, Book of Proceedings of 27th IAPRI Symposium, p. 415.