ELEMENT RESIDUES IN FOOD CONTACT PLASTICS AND THEIR MIGRATION INTO FOOD SIMULANTS, MEASURED BY INDUCTIVELY-COUPLED PLASMA-MASS SPECTROMETRY

被引：34

作者：

FORDHAM, PJ ^{[1
]}

GRAMSHAW, JW ^{[1
]}

CREWS, HM ^{[1
]}

CASTLE, L ^{[1
]}

机构：

[1] MAFF,CSL,FOOD SCI LAB,NORWICH NR4 7UQ,NORFOLK,ENGLAND

来源：

FOOD ADDITIVES AND CONTAMINANTS | 1995年 / 12卷 / 05期

关键词：

AIDS TO POLYMERIZATION; ELEMENT RESIDUES; MIGRATION; ICP-MS; PLASTICS;

D O I：

10.1080/02652039509374354

中图分类号：

O69 [应用化学];

学科分类号：

081704 ;

摘要：

Polymers intended for food contact use have been analysed for inorganic residues which can be attributed to a range of substances employed as polymerization aids (e.g. catalysts), or to additives incorporated into the polymer to fulfil a specific task (e.g. lubricants). The migration of these residues into food simulants was studied. Residues were determined by using the multi-element capability of Inductively-Coupled Plasma-Mass Spectrometry (ICP-MS). Semi-quantitative analysis was carried out on acid digests of polymer materials, obtained by microwave heating in sealed Teflon(R) containers. Limits of detection in the polymer were generally less than 1 mg/kg. Migration experiments were carried out with three food simulants and under two sets of conditions. Analysis for element residues was performed directly or, in the case of olive oil, on an emulsion of the simulant. Migration of certain elements into aqueous simulants was observed: Zr from polystyrene (650 mu g/kg), Sb from polyethylene terephthalate (4 mu g/kg) and Mg from acrylonitrile/butadiene/styrene copolymer (50 mu g/kg). In all cases, where limits of detection permit, the levels which migrated from polymer to stimulant were less than proposed limits on migration.

引用

页码：651 / 669

页数：19

共 13 条

[1]

Amarasiriwardena C.J., Gercken B., Argentine M.D., Barnes R.M., Semi-quantitative analysis by inductively coupled plasma mass spectrometry, Journal of Analytical Atomic Spectrometry, 5, pp. 457-462, (1990)

[2]

Ashby R., Migration from poly(ethylene terephthalate)under all conditions of use, Food Additives and Contaminants, 5, pp. 485-492, (1988)

[3]

Bieber W.-D., Freytag W., Figge K., Vom Bruck C.G., Transfer of additives from plastic materials into foodstuffs and into food simulants—a comparison, Food and Chemical Toxicology, 22, pp. 737-742, (1984)

[4]

European Community Council Directive No. 85/572/EEC Council Directive of 19 December 1985 laying down the list of simulants to be used for testing migration of constituents of plastic materials intended to come into contact with foodstuffs, Official Journal of the European Communities, (1985)

[5]

(1992)

[6]

Ekimoff D., Van Norstrand A.M., Mowers D.A., Semiquantitative survey capabilities of ICP-MS, Applied Spectroscopy, 43, pp. 1252-1257, (1989)

[7]

Gilbert J., Startin J.R., McGuinness J.D., Compositional analysis of commercial PVC bottles and studies of aspects of specific and overall migration into foods and simulants, Food Additives and Contaminants, 3, pp. 133-144, (1986)

[8]

Jarvis K.E., Gray A.L., Houk R.S., Sample preparation for ICP-MS, Handbook of Inductively Coupled Plasma Mass Spectroscopy

[9]

Longerich H.P., Effect of nitric acid, acetic acid and ethanol on inductively coupled plasma mass spectrometric ion signals as a function of nebuliser gas flow, with implications on matrix suppression and enhancements, Journal of Analytical Atomic Spectrometry, 5, pp. 346R-359R, (1989)

[10]

Lord C.J., Determination of trace metals in crude oil by ICP-MS with micro emulsion sample introduction, Analytical Chemistry, 63, pp. 1594-1599, (1991)

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