Scientific Opinion on Mineral Oil Hydrocarbons in Food

,

doi:10.2903/j.efsa.2012.2704

Cited by 105 publications

(108 citation statements)

References 236 publications

(379 reference statements)

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“…Hydrogenated poly-1-decene is a member of a more general family of hydrocarbons known as POSH which in turn is a subgroup of MOSH and more generally MOH. MOH and MOSH were evaluated by the EFSA CONTAM Panel (EFSA CONTAM Panel, 2012a;Cravedi et al, 2017).…”

Section: Discussionmentioning

confidence: 99%

Re‐evaluation of name of hydrogenated poly‐1‐decene (E 907) as food additive

Flavourings¹,

Younes²,

Aquilina³

et al. 2020

EFS2

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The Panel on Food Additives and Flavourings added to food (FAF) provided a scientific opinion re‐evaluating the safety of hydrogenated poly‐1‐decene (E 907) when used as a food additive. Hydrogenated poly‐1‐decene (E 907) is authorised as a food additive in the EU in accordance with Annex II to Regulation (EC) No 1333/2008. Hydrogenated poly‐1‐decene is of low acute toxicity and does not raise concern for genotoxicity. Toxicity and carcinogenicity, as well as reproductive and developmental toxicological studies, were not available; therefore, the Panel based the derivation of the acceptable daily intake (ADI) on the no observed adverse effect level (NOAEL) identified in the subchronic study in rats and established an ADI of 20 mg/kg bw per day. Dietary exposure to hydrogenated poly‐1‐decene (E 907) from its use as a food additive was calculated based on regulatory maximum level exposure assessment scenario. Mean exposure to hydrogenated poly‐1‐decene (E 907) from its use as a food additive ranged from no exposure in infants to 2.35 mg/kg bw per day in toddlers. The high exposure to hydrogenated poly‐1‐decene (E 907) ranged from 0 mg/kg bw per day in infants and adults to 6.69 mg/kg bw per day in toddlers. The exposure estimates in the regulatory maximum level exposure assessment scenario did not exceed the ADI of 20 mg/kg bw per day for all population groups. The Panel concluded that the exposure to hydrogenated poly‐1‐decene (E 907) does not raise a safety concern when used at the maximum permitted levels.

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Section: Discussionmentioning

confidence: 99%

Re‐evaluation of name of hydrogenated poly‐1‐decene (E 907) as food additive

Flavourings¹,

Younes²,

Aquilina³

et al. 2020

EFS2

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“…A series of paperboards and pastas was analyzed, using the methods discussed in Section 2 (reference and fast methods, nonstop and multitransfer modes), to countercheck the reliability of all the approaches when carried out on real samples. Quantification was carried out up to the retention time corresponding to the n-alkane C 35 (important from a toxicological viewpoint [25]), performing a cut at C 25 for both kinds of sample, to highlight possible differences in the more volatile and heavy fractions among the methods.…”

Section: Real Samplesmentioning

confidence: 99%

“…Quantification values (below C25 and in the C 25 -C 35 range) relative to the MOSH and the MOAH fractions, in paperboard and pasta samples using the fast and reference methods in nonstop and multitransfer (MTR) modes…”

mentioning

confidence: 99%

A high-sample-throughput LC-GC method for mineral oil determination

2013

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The present investigation deals with a method improvement to increase data throughput and reduce solvent consumption for both saturated and aromatic mineral oil hydrocarbon determination using a coupled liquid-gas chromatographic system. The starting point of this work was the method proposed by Biedermann, Fiselier, and Grob in 2009. A total time and solvent reduction of 34 and 23%, respectively, was obtained by speeding up the GC run and reducing the LC-reconditioning step. The band broadening, occurring in the LC column during stop-flow in the multitransfer mode, was assessed by comparing the variances of the perylene peak width recorded in the stop-flow and normal modes. Band broadening directly proportional to the stop time of the LC pumps was observed, however, it did not affect the analytical reliability. A series of real samples (paperboards and pasta) was analyzed obtaining comparable results using both the reference and proposed method, both in the normal and multitransfer modes.

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“…For monitoring of cosmetic products and medicinal products aiming for health risk assessment, a scarcity of analytical methods was noted. This may be explained because the analysis of mineral oil constituents is extremely difficult, and because of their complexity it has been generally unfeasible to resolve the hydrocarbon mixtures into individual components for quantification 3 . The current method of choice for analysis of hydrocarbons is the application of an online coupled liquid chromatography-gas chromatography with flame ionization detection (LC-GC-FID), which leads to two fractions quantified as sum parameters, MOSH and MOAH 4 .…”

Section: Introductionmentioning

confidence: 99%

Evaluation of mineral oil saturated hydrocarbons (MOSH) and mineral oil aromatic hydrocarbons (MOAH) in pure mineral hydrocarbon-based cosmetics and cosmetic raw materials using 1H NMR spectroscopy

et al. 2017

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Mineral hydrocarbons consist of two fractions, mineral oil saturated hydrocarbons (MOSH) and mineral oil aromatic hydrocarbons (MOAH). MOAH is a potential public health hazard because it may include carcinogenic polycyclic compounds. In the present study, 400 MHz nuclear magnetic resonance (NMR) spectroscopy was introduced, in the context of official controls, to measure MOSH and MOAH in raw materials or pure mineral hydrocarbon final products (cosmetics and medicinal products). Quantitative determination (qNMR) has been established using the ERETIC methodology (electronic reference to access in vivo concentrations) based on the PULCON principle (pulse length based concentration determination). Various mineral hydrocarbons (e.g., white oils, paraffins or petroleum jelly) were dissolved in deuterated chloroform. The ERETIC factor was established using a quantification reference sample containing ethylbenzene and tetrachloronitrobenzene. The following spectral regions were integrated: MOSH δ 3.0 – 0.2 ppm and MOAH δ 9.2 - 6.5, excluding solvent signals. Validation showed a sufficient precision of the method with a coefficient of variation <6% and a limit of detection <0.1 g/100 g. The applicability of the method was proven by analysing 27 authentic samples with MOSH and MOAH contents in the range of 90-109 g/100 g and 0.02-1.10 g/100 g, respectively. It is important to distinguish this new NMR-approach from the hyphenated liquid chromatography-gas chromatography methodology previously used to characterize MOSH/MOAH amounts in cosmetic products. For mineral hydrocarbon raw materials or pure mineral hydrocarbon-based cosmetic products, NMR delivers higher specificity without any sample preparation besides dilution. Our sample survey shows that previous methods may have overestimated the MOAH amount in mineral oil products and opens new paths to characterize this fraction. Therefore, the developed method can be applied for routine monitoring of consumer products aiming to minimize public health risks.

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Scientific Opinion on Mineral Oil Hydrocarbons in Food

Cited by 105 publications

References 236 publications

Re‐evaluation of name of hydrogenated poly‐1‐decene (E 907) as food additive

Re‐evaluation of name of hydrogenated poly‐1‐decene (E 907) as food additive

A high-sample-throughput LC-GC method for mineral oil determination

Evaluation of mineral oil saturated hydrocarbons (MOSH) and mineral oil aromatic hydrocarbons (MOAH) in pure mineral hydrocarbon-based cosmetics and cosmetic raw materials using 1H NMR spectroscopy

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