Levels of nitrate, nitrite and nitrosamines in model sausages during heat treatment and in vitro digestion - The impact of adding nitrite and spinach (Spinacia oleracea L.)

Nitrite derivatives react with endogenous precursors forming N-nitrosamines associated with development of colorectal cancer. The present study aims to investigate the formation of N-nitrosamines in sausage during processing and in vitro gastrointestinal digestion after adding sodium nitrite and/or spinach emulsion. The INFOGEST digestion protocol was used to simulate the oral, gastric, and small intestinal phases of digestion, and sodium nitrite was added in the oral phase to mimic the input of nitrite from saliva as it has shown to affect the endogenous formation of N-nitrosamines. The results show that the addition of spinach emulsion, in spite of it being a source of nitrate, did not affect the nitrite content in either batter, sausage, or roasted sausage. The levels of N-nitrosamines increased with the added amount of sodium nitrite, and further formation of some volatile N-nitrosamines was observed during roasting and in vitro digestion. In general, N-nitrosamine levels in the intestinal phase followed the same trend as in the undigested products. The results further indicate that nitrite present in saliva may cause a significant increase in N-nitrosamine levels in the gastrointestinal tract and that bioactive components in spinach may protect against the formation of volatile N-nitrosamines both during roasting and digestion.

The occurrence of volatile and non-volatile N-nitrosamines in cured meat products from the Danish market

Several epidemiological studies emphasize the consumption of processed meat products as a risk factor of colorectal cancer, linking N-nitrosamines (NAs) formed during nitrite curing to this cancer risk. The occurrence of volatile N-nitrosamines (VNAs) has over the years been intensively studied while the knowledge on the occurrence and toxicity of non-volatile N-nitrosamines (NVNAs) is still limited. Therefore, this study focuses on quantification of both VNAs and NVNAs in a large selection of processed meat products. For this purpose, a robust, specific and sensitive method allowing analysis of seven VNAs and two NVNAs was optimized and validated using kassler, sausage, and salami. The limit of quantification achieved was 0.1-0.5 ng·g^-1 for most of the VNA, and 2.3-4.2 ng·g^-1 for the NVNA. In one hundred commercial samples N-nitroso-thiazolidine-4-carboxylic acid (NTCA) was the most frequently detected (97 samples) among all target NAs and it was found at concentrations ranging from 3.1 ng·g^-1 to 1660 ng·g^-1. The samples contained relatively low mean levels of the individual VNAs (≤1 ng·g^-1). The levels of N-nitrosodimethylamine (NDMA), N-nitrosopyrrolidine (NPYR), and N-nitrosopiperidine (NPIP) ranged from non-detectable to 3.8, 10.8 and 2.9 ng·g^-1, respectively. A correlation between the detected residual levels of nitrite and/or nitrate and concentrations of individual NAs could not be demonstrated. Based on principle component analysis (PCA) some correlations between salami, sausage and bacon and NAs could be shown.

Processing factors of pesticide residues in biscuits and their relation to the physicochemical properties of pesticides

Agricultural commodities are generally consumed as processed food. Therefore, it is indispensable to assess pesticide residues in processed products rather than only in the raw agricultural commodity, in order to approach a more realistic scenario of dietary exposure. Processing factors are important tools for dietary exposure risk assessments. In this study, processing factors for the baking process were derived for 41 pesticides in cereal bran-based biscuits. The raw materials used consisted of wheat, rye, oat, and barley grains with incurred pesticides, which originally was produced for test material for European Union Proficiency Tests. Information on physicochemical properties of pesticides was collected for understanding the fate of pesticides during the baking process. Average processing factors varied between 0.67 and 1.6. Most pesticide residues exhibited a reduction of pesticide residues of less than 24%, which correspond to a processing factor (PF) range between 1 and 0.76, showing resistance to the baking process. However, for polar compounds such as carbendazim and volatile compounds (chlorpyrifos-methyl, malathion, and pirimiphos-methyl) larger reduction rates were observed, up to 33% (PF: 0.67). In general, a prolonged baking time did not significantly affect the PF, because the main degradation process takes place within the first 6 min. However, this was not the case for the highly volatile compounds, highly polar compounds, and compounds of low degradation temperature. These latter were significantly reduced with prolonged baking time, resulting in a reduction rate of up to 95%, which means an almost complete elimination.

Role of Sample Processing Strategies at the European Union National Reference Laboratories (NRLs) Concerning the Analysis of Pesticide Residues

The guidance document SANTE 11945/2015 recommends that cereal samples be milled to a particle size preferably smaller than 1.0 mm and that extensive heating of the samples should be avoided. The aim of the present study was therefore to investigate the differences in milling procedures, obtained particle size distributions, and the resulting pesticide residue recovery when cereal samples were milled at the European Union National Reference Laboratories (NRLs) with their routine milling procedures. A total of 23 NRLs participated in the study. The oat and rye samples milled by each NRL were sent to the European Union Reference Laboratory on Cereals and Feedingstuff (EURL) for the determination of the particle size distribution and pesticide residue recovery. The results showed that the NRLs used several different brands and types of mills. Large variations in the particle size distributions and pesticide extraction efficiencies were observed even between samples milled by the same type of mill.