Natural elemental impurities are recognized as a threat for safety and quality of edible salt and have adverse effects on public health. In the current study, fiftysamples of packages containing 1 kg of salt from 25 different brands were collected from retailers in Semnan city (Iran). The concentrations of main impurities of edible salt including magnesium (Mg), calcium (Ca), and sulphate (SO4-2) ions were quantified by the aid of an Ion Chromatography with conductivity detector. According to findings, the maximum concentrations of Mg, Ca, and SO4-2 ions in salt samples were 0.067, 0.226, and 0.888 % w/w (dry matter basis), respectively. In addition, the concentration of Mg in 16%, Ca in 4%, and SO4-2 in 28% of samples suppressed the acceptable limit proposed by the Institute of Standards and Industrial Research of Iran (ISIRI) (0.15% for Ca, 0.03% for Mg, and 0.46% for SO4-2). Moreover, the maximum and minimum levels of purity in the salt samples were recorded as 99.940 and 97.730%, respectively. Moreover, the purity in 12% of the investigated samples was lower than that of the minimum acceptable limit suggested by ISIRI, while the purity of 97% samples met the acceptable Codex Alimentarius limit (97% Min). Based on results of the current investigation, the routine purification processes used in some factories of Iran did not reduce impurities. Hence, purification process bedsides constant monitoring and safety management should be improved to promote the health quality of edible salt. Manuscript profile

In this research chemical composition and antimicrobial effects of Elaeagnus angustifolia L. (E. angustifolia L.) whole fruit ethanolic extract was investigated on common pathogenic microorganisms (Staphylococcus aureus, Escherichia coli, Enterococcus faecalis, and Candida albicans). The phytochemical composition of E. angustifolia was screened by Gas Chromatography-Mass Spectrometry (GC/MS). The minimum inhibitory concentration (MIC) and the minimal bactericidal concentration (MBC) of the extract were determined using the broth dilution technique. According to the results, 13 major compounds such as flavonoid, aldehyde, alcoholic and fatty acids were identified by GC/MS. In addition, the extract could inhibit the growth of all examined pathogenic strains. The MIC was 3.75 to 1.87 mg ml-1 while maximum activity was found against Staphylococcus aureus. Besides, the MBC was ranging from 7.5 to 3.75 mg ml-1. Since E. angustifolia whole fruit ethanolic extract contains phytochemical compounds and has antimicrobial potential it can be recommended as a natural active agent for application in the food industry. Manuscript profile

Cold plasma is a high-end technology that offers favorable opportunities for microorganism inactivation in contaminated food. This review aimed to evaluate the efficacy of cold plasma treatment to reduce different pathogen and spoilage microorganisms in various foods. In addition, the effect of influential factors related to plasma processing, including microorganism type, gas type, treatment time, and treatment voltage, on the reduction rate of microorganisms was assessed using principal component analysis and hierarchical cluster analysis. The extracted data showed that most researcher investigated plasma efficiency on the inactivation of Escherichia coli in different food samples. Also in most studies the plasma was generated using air as plasma gas. The microorganism inactivation rate obtained by cold plasma treatments was raging from -0.90 to 8.00 log CFU. The plasma voltage (0.7) and plasma gas (0.66) had a significant correlation with principal component 1 and had a negative correlation coefficient with treatment time (-0.76). The reduction rate (0.68) and microorganism (0.7) were positively correlated with principal components 2. The findings indicated that cold plasma has an excellent potential to decontaminate hazardous organisms in different food. Besides, plasma treatment conditions should be considered to optimize the effective inactivation rates. The reduction rate of microorganisms in different foods is strongly influenced by microbial factors and technical plasma performance factors. Regarding the crucial damage to microorganism cell components using plasma, this novel technology could efficiently apply for preservation and also promote the shelf life of food products. Manuscript profile