Estimation of inorganic food additive (nitrite,nitrate and sulfur dioxide), antioxidant (BHA and BHT), processing agent (propylene glycol) and sweetener (sodium saccharin) concentrations in foods and their daily intake based on official inspection results in Japan in fiscal year 1998

The mean concentration and daily intake of inorganic food additives (nitrite, nitrate, and sulfur dioxide), antioxidants (BHA and BHT), a processing agent (propylene glycol), and a sweetener (sodium saccharin) were estimated based on the results of an analysis of 34,489 food samples obtained in official inspections by 106 local governments in Japan in fiscal year 1998. The ratios of mean concentrations of these seven food additives to each allowable limit were 20.0%, 53.9%, 15.5%, 6.2%, 0.4%, 18.5%, and 5.7%, respectively. The daily intakes of these food additives estimated from their concentrations in foods and the daily consumption of foods were 0.205, 0.532, 4.31, 0.119, 0.109, 77.5, and 7.27 mg per person, respectively. These amounts were 6.8%, 0.3%, 12.3%, 0.5%, 0.7%, 6.2%, and 2.6% of the acceptable daily intake (ADI), respectively, when body weight was assumed to be 50 kg. No remarkable differences in the daily intakes of these seven food additives or the ratios to the ADI were observed compared with the results based on the official inspections in fiscal years 1994 and 1996.     

Estimation of concentrations of antifungal agents allowed as food additives in foods and their daily intake based on official inspection results in Japan in fiscal year 1998

The mean concentrations and daily intake of four antifungal agents were estimated based on the results of an analysis of 7,005 samples of food obtained in official inspections by Japanese local governments in fiscal year 1998. The mean concentration of diphenyl was 0.0004% of the allowable limit, and those of imazalil, o-phenylphenol, and thiabendazole were 14.0%, 3.5%, and 5.7%, respectively. The daily intakes of these antifungal agents per person, estimated from their concentrations and the daily consumption of the foods, were 0.000326, 1.89, 11.5, and 23.3 micrograms, respectively, and assuming a body weight of 50 kg, the amounts of these antifungal agents consumed were 0.000013%, 0.15%, 0.12%, and 0.47% of the acceptable daily intake, respectively. These values are similar to the values obtained on the basis of the results of the official inspection in fiscal years 1994 and 1996, except that the amount of diphenyl is much lower (1/100).     

Estimated intake of benzoic and sorbic acids in Denmark

The monitoring of food additives and recent dietary surveys carried out in Denmark have earlier been used to estimate the intake of sweeteners and nitrite in relation to acceptable daily intakes. The ubiquitous use of the preservatives benzoic and sorbic acids raises the question of the magnitude of the intake of these preservatives in relation to acceptable daily intakes. This area is explored in this paper. The content of benzoic and sorbic acids in all food groups, where they are allowed, was monitored in Denmark 17 times between 2001 and 2006 with a total of 1526 samples. Transgressions of maximum limits, illegal use or declaration faults were found in about 3% of samples. From repeated investigations on fat-based foods (salads and dressings), marmalade and stewed fruit, it is concluded that the amounts used in industry have been relatively stable throughout the whole period, although limited data for marmalade show some variation. Most foods in the categories soft drinks, dressings, fat-based salads, pickled herrings, and marmalade contain benzoic and sorbic acid, and sliced bread also contains in some cases sorbic acid. The median daily intake and intake distribution of benzoic and sorbic acids were calculated with data from the Danish National Survey of Dietary Habits and Physical Activity (age from 4 to 75 years) conducted in 2000–2004 with 5785 participants. The median intakes of both benzoic acid and sorbic acid are well below the acceptable daily intakes of 0–5 and 0–25 mg kg^?1 body weight (bw) day^?1 for benzoic and sorbic acid, respectively. However, the 90th percentile based on the average of the samples with a content of benzoic acid is higher than the acceptable daily intake for both men and women, with the highest value of 16 mg kg^?1 bw day^?1 for both boys and girls in the 4–6-year-old age group. Based on the average of all samples, the 95th percentile is over the acceptable daily intake for men up to 34 years and for women up to 24 years, and the 90th percentile for men up to 18 years and for women up to 10 years. Soft drinks, salads and dressings are the main contributors to benzoic acid intake. The sorbic acid intake based on the average of all samples is well below the acceptable daily intake. However, for the intake based on the average of samples with content, the 95th percentile exceeds the acceptable daily intake. This is caused by the dominating contribution to the intake of sorbic acid from sliced bread, but since only seven out of 42 samples have added sorbic acid, the calculation based on the average of samples with content will exaggerate the intake. With a built-in safety factor of 100 in the acceptable daily intakes and judging from the literature, the high intakes of benzoic acid should not cause any concern for ill-effects. However, there must be a reason to reconsider the maximum limits especially for benzoic acid in soft drinks, dressings and salads and for sorbic acid in sliced bread.     

Exposure assessment of food preservatives (sulphites, benzoic and sorbic acid) in Austria

An exposure assessment was performed to estimate the potential intake of preservatives in the Austrian population. Food consumption data of different population groups, such as preschool children aged 3-6 years, female and male adults aged 19-65 years were used for calculation. Levels of the preservatives in food were derived from analyses conducted from January 2007 to August 2010. Dietary intakes of the preservatives were estimated and compared to the respective acceptable daily intakes (ADIs). In the average-intake scenario, assuming that consumers randomly consume food products that do or do not contain food additives, estimated dietary intakes of all studied preservatives are well below the ADI for all population groups. Sulphite exposure accounted for 34%, 84% and 89% of the ADI in preschool children, females and males, respectively. The mean estimated daily intake of benzoic acid was 32% (preschool children), 31% (males) and 36% (females) of the ADI. Sorbic acid intakes correspond to 7% of the ADI in preschool children and 6% of the ADI in adults. In the high-intake scenario assuming that consumers always consume food products that contain additives and considering a kind of brand loyalty of consumers, the ADI is exceeded for sulphites among adults (119 and 124%, respectively). Major contributors to the total intake of sulphites were wine and dried fruits for adults. Mean estimated dietary intakes of benzoic acid exceeded the ADI in all population groups, 135% in preschool children, 124% in females and 118% of the ADI in males, respectively. Dietary intakes of sorbic acid are well below the ADI, accounting for a maximum of 30% of the ADI in preschool children. The highest contributors to benzoic and sorbic acid exposure were fish and fish products mainly caused by high consumption data of this large food group, including also mayonnaise-containing fish salads. Other important sources of sorbic acid were bread, buns and toast bread and fruit and vegetable juices.     

Exposure assessment of food preservatives (sulphites,benzoic and sorbic acid) in Austria

An exposure assessment was performed to estimate the potential intake of preservatives in the Austrian population. Food consumption data of different population groups, such as preschool children aged 3–6 years, female and male adults aged 19–65 years were used for calculation. Levels of the preservatives in food were derived from analyses conducted from January 2007 to August 2010. Dietary intakes of the preservatives were estimated and compared to the respective acceptable daily intakes (ADIs). In the average-intake scenario, assuming that consumers randomly consume food products that do or do not contain food additives, estimated dietary intakes of all studied preservatives are well below the ADI for all population groups. Sulphite exposure accounted for 34%, 84% and 89% of the ADI in preschool children, females and males, respectively. The mean estimated daily intake of benzoic acid was 32% (preschool children), 31% (males) and 36% (females) of the ADI. Sorbic acid intakes correspond to 7% of the ADI in preschool children and 6% of the ADI in adults. In the high-intake scenario assuming that consumers always consume food products that contain additives and considering a kind of brand loyalty of consumers, the ADI is exceeded for sulphites among adults (119 and 124%, respectively). Major contributors to the total intake of sulphites were wine and dried fruits for adults. Mean estimated dietary intakes of benzoic acid exceeded the ADI in all population groups, 135% in preschool children, 124% in females and 118% of the ADI in males, respectively. Dietary intakes of sorbic acid are well below the ADI, accounting for a maximum of 30% of the ADI in preschool children. The highest contributors to benzoic and sorbic acid exposure were fish and fish products mainly caused by high consumption data of this large food group, including also mayonnaise-containing fish salads. Other important sources of sorbic acid were bread, buns and toast bread and fruit and vegetable juices.     

DETERMINATION OF BENZOIC AND SORBIC ACID IN TURKISH FOOD USING HIGH-PERFORMANCE LIQUID CHROMATOGRAPHY

Benzoic and sorbic acid levels in different brands of jam, candied chestnut, carbonated drink, pickle, black table olive, green table olive, wholemeal/brown bread and white bread, which are available on the Turkish market, were determined by high-performance liquid chromatography with diode array detector (235–254 nm). Chromatographic separation was achieved with a C18 column and acetate buffer (pH 4.74)–methanol mixture (70:30) as a mobile phase. The levels of benzoic and sorbic acid in the analyzed samples were in the range of not detected to 662 mg/kg or L, and not detected to 432 mg/kg or L, respectively. Only one sample (jam) presented a preservative although not permitted by the legislation enforced in Turkey. The levels of preservative in the other samples were determined in legal limitations. According to the results, the utilization of benzoic and sorbic acid is lower than the certain legal limitations permitted by legislation to be used.

PRACTICAL APPLICATIONS

The amount of the sorbic and benzoic acid used as preservatives during food processing is important for consumer health. Determination of the amounts of the preservatives mentioned above will be possible in a short period of time (11 min) with the methods used in this study (high-performance liquid chromatography). According to the results obtained from study and data about food consumption, daily intake amount of these preservatives (benzoic and sorbic acid) will be able to be defined in Turkey, separately.     

高效液相色谱法同时检测酱油中7种防腐剂

建立利用高效液相色谱法同时测定调味品中苯甲酸、山梨酸、脱氢乙酸及对羟基苯甲酸甲、乙、丙、丁酯7种防腐剂的方法。该方法中酱油样品经Oasis HLB柱进行固相萃取净化后用Warters-C18柱(4.6mm×250mm,5μm),乙酸铵-乙腈溶液为流动相进行梯度洗脱,并在230、260nm波长处检测,结果在0.4～100mg/L的线性范围内测得7种物质的线性相关系数均大于0.9994,方法检出限介于0.28～0.55mg/L之间,各个组分的回收率范围在84.4%～102.3%之间。该方法可以应用于测定这7种物质在酱油中的含量。     

Simultaneous determination of benzoic and sorbic acids in quince jam by HPLC

An isocratic HPLC technique is described for the determination of benzoic acid and sorbic acid in industrial quince jam. The preparation procedure was optimized. Precipitation of proteins and fat by the addition of methanol, followed by centrifugation and/or filtration provided an extract suitable for chromatographic analysis. The chromatographic separation was achieved with a C18 column and acetate buffer (pH=4.4) - methanol (65:35) as the mobile phase. The effluent was monitored at 235 nm. Effective separation and quantification was achieved in less than 7 min. Specificity of the method was checked against common food additives added to industrial quince jam, such as l-ascorbic acid and citric acid. Diode array detection was used for confirmation of the preservatives. Mean recoveries of 95–104% were obtained with a precision less than 2.6%, detection limits of 25 and 6.25 mg/kg were obtained for benzoic and sorbic acids, respectively. Results were in good agreement with the reference methods. The presence of benzoic and sorbic acids in quince jams available on the Portuguese market, was also determined. Eleven commercial brands of quince jam were analysed. All contained benzoic acid. The concentration ranged from 413.9±10.4 to 1501±4.2 mg of benzoic acid/kg of quince jam. Only two brands also contained sorbic acid. The concentrations were 515.0±7.0 and 908.3±5.3 mg of sorbic acid/kg of quince jam.     

Estimates of the mean per capita daily intake of benzoic and sorbic acids in Brazil.

The daily intakes of benzoates and sorbates from selected food categories were estimated in Brazil in 1999. The Budget method was used as a first screening procedure for the estimation of the safety aspects of the maximum permitted levels of benzoates and sorbates established by the Brazilian food legislation. This screening indicated that benzoates should be further investigated. In a second step, the daily intakes of these preservatives were assessed by combining measured levels of these additives with national food consumption data derived from a household economic survey and a packaged good market survey. Benzoate and sorbate levels in soft drinks, fruit juices, margarine, yoghurt and cheese were determined by HPLC with a photodiode array detector (detection at 228 nm for benzoic acid, 260 nm for sorbic acid). The estimated intakes of benzoates and sorbates for the average consumer were below the ADIs, ranging from 0.3 to 0.9 and 0.2 to 0.3 mg kg(-1) body weight, respectively. Soft drinks were identified as the main source of benzoates representing >80% of the estimated intake.     

Naturally occurring benzoic,sorbic, and propionic acid in vegetables

ABSTRACT

Benzoic, sorbic and propionic acid are used as preservatives in foods and can also be naturally present in processed foods. The levels of preservatives in 939 vegetables were determined. Benzoic and sorbic acid were analysed by high-performance liquid chromatography with a diode-array detector and further confirmed by liquid chromatography-tandem mass spectrometry, whereas propionic acid was analysed using a gas chromatography-flame ionization detector and further confirmed by gas chromatography-mass spectrometry. Benzoic and propionic acid were found in 10.9% and 36.2%, respectively, of the samples. In contrast, sorbic acid was not found in any of the samples. The highest amounts of benzoic and propionic acid were found in perilla leaves (0.33?298 mg kg^–1) and ginseng (<LOD?32.8 mg kg^–1), respectively. The background concentration ranges of naturally occurring preservatives in vegetables determined in this study could be used for inspection services of standard criteria to address consumer complaints or trade disputes.     

Modelling the inhibition of sorbic and benzoic acids on a native yeast cocktail from table olives

The single and combined effects, in a synthetic medium at selected pH values, of sorbic and benzoic acids on a yeast cocktail (Saccharomyces cerevisiae, Pichia anomala, Issatchenkia occidentalis, and Candida diddensiae, isolated from table olives) have been studied. Applying the checkerboard method the minimum inhibitory concentration (MIC) obtained for the respective individual preservatives (expressed as undissociated acid) were: sorbic acid, 5.94, 3.85 and 3.19 mM at pH of 4.5, 4.0, and 3.5, respectively; and benzoic acid, not detected (at total 20.5 mM), 10.40 and 6.83 mM, respectively, for the same pH levels. The estimated fractional inhibitory concentrations (FIC) indexes showed additive effects between inhibitors. Fractional area (fa), modelled by the (extended) Lambert and Lambert [2003. A model for the efficacy of combined inhibitors. J. Appl. Microbiol. 95, 734-743] equation (ELPM), also showed additives of both preservatives but different shapes in the dose-response curves; the individual MIC (as undissociated acid) deduced from this method were: 5.60, 3.31, and 3.26 mM for sorbic acid at pH of 4.5, 4.0, and 3.5, respectively; and 29.65 (extrapolated), 10.00, and 6.25 mM for benzoic acid at the same pH levels. Mixtures above the curves connecting the limits (MIC) at each pH were also inhibitory. There was agreement between MIC values from FIC and ELPM, although the last one provided further information on the inhibition behaviour. I. occidentalis was the most resistant yeast of the cocktail to sorbic and benzoic acids.     

毛细柱气相色谱法测定饮料中的山梨酸、苯甲酸

探讨了采用毛细柱气相色谱法测定饮料中作为防腐剂的山梨酸、苯甲酸，此方法可使各组分得到良好分离，分析时间短，准确度高，山梨酸、苯甲酸测定的检出限为0．1mg／kg，相对标准偏差小于3％，样品加标回收率为89％～99％。     

Sorbic,benzoic and propionic acids in fishery products: a survey of the South Korean market

This study was conducted to provide basic data as part of a project to distinguish naturally occurring organic acids from added preservatives. Accordingly, we investigated naturally occurring levels of sorbic, benzoic and propionic acids in fish and their processed commodities. The levels of sorbic, benzoic and propionic acids in 265 fish and their processed commodities were determined by high-performance liquid chromatography–photodiode detection array (HPLC-PDA) of sorbic and benzoic acids and gas chromatography-mass spectrometry (GC/MS) of propionic acid. For propionic acid, GC-MS was used because of its high sensitivity and selectivity in complicated matrix samples. Propionic acid was detected in 36.6% of fish samples and 50.4% of processed fish commodities. In contrast, benzoic acid was detected in 5.6% of fish samples, and sorbic acid was not detected in any sample. According to the Korean Food and Drug Administration (KFDA), fishery products and salted fish may only contain sorbic acid in amounts up to 2.0 g kg^?1 and 1.0 g kg^?1, respectively. The results of the monitoring in this study can be considered violations of KFDA regulations (total 124; benzoic acid 8, propionic acid 116). However, it is difficult to distinguish naturally generated organic acids and artificially added preservatives in fishery products. Therefore, further studies are needed to extend the database for distinction of naturally generated organic acids and added preservatives.     

气相色谱内标法测定食品中防腐剂脱氢乙酸、苯甲酸和山梨酸

选用正十一烷酸为内标,采用毛细管气相色谱内标法测定食品中防腐剂脱氢乙酸、苯甲酸和山梨酸,样品回收率均在96％～104％之间,标准线性关系良好,样品测定的变异系数小,脱氢乙酸为0.71％,苯甲酸为0.82％和山梨酸为0.62％;本方法具有简便、快速、准确的特点。     

高效液相色谱法测定酱油及食醋中的苯甲酸和山梨酸

建立了一种用高效液相色谱法快速测定酱油及食醋中苯甲酸和山梨酸的方法.使用的色谱柱为Agillent C18柱,流动相为乙酸胺:甲醇(93:7,v/v),检测波长230nm.苯甲酸和山梨酸标准溶液在2.5mg/L～50mg/L内线性良好,其线性相关系数分别0.9991和0.9984.加标回收率分别为91.7％和98.7％,测量结果的相对标准偏差(RSD)为2.77％和3.55％,苯甲酸和山梨酸的检测限分别为0.90mg/kg和0.85mg/kg.该法简单,快速,具有良好的准确度和灵敏度.     

食品中防腐剂山梨酸和苯甲酸的气相色谱内标法测定

选用癸酸作内标物，气相色谱内标法同时测定食品中防腐剂山梨酸和苯甲酸，定量准确，标准回收率均在96％～103％之间，样品测定的变异系数小，山梨酸为0．529％，苯甲酸为0．311％。     

Spectrophotometric estimation of benzoic and sorbic acids.

A spectrophotometric method is described for estimations of benzoic and sorbic acids in materials with background absorption in the ultraviolet region. The estimation can be done when both preservatives are present in equal or nonequal ratios. The coefficients of variation (average standard deviation) are 0.23–1.98% for benzoic acid and 0.40–1.58% for sorbic acid. The recovery factors are 95.5–103% for benzoic acid and 81.5–89% for sorbic acid.     

Optimized Dispersive Liquid–Liquid Microextraction and Determination of Sorbic Acid and Benzoic Acid in Beverage Samples by Gas Chromatography

A new rapid method for direct determination of trace levels of sorbic and benzoic acids was developed by dispersive liquid–liquid microextraction and gas chromatography with flame ionization detection. In the proposed approach, the separation procedure of sorbic and benzoic acids was performed on a general chromatographic column without any prior derivatization processes. Some effective parameters on the microextraction recovery were studied and optimized utilizing multilevel factorial and central composite experimental designs. The best concurrent extraction efficiency acquired using ethanol and chloroform as dispersive and extraction solvents. Central composite design (CCD) resulted in the optimized values of microextraction parameters as follows: 1.0 mL of dispersive and 0.1 mL of extraction solvents, ionic salt concentration of 50 g?L^?1 at pH 4. Under optimum conditions, the calibration curve was linear over the range 0.5–20 mg L^?1. Relative standard deviation was 11% and 13% for five repeated determinations for sorbic and benzoic acids, respectively. Limits of detection were acquired as 0.2 mg L^?1 for sorbic acid and 0.5 mg L^?1 for benzoic acid. The average recoveries were 31% and 39% for sorbic and benzoic acids, respectively. The method was successfully applied to the determination of sorbic and benzoic acids as preservatives in beverage samples.     

高效液相色谱法同时测定酱油中6种防腐剂

建立高效液相色谱法同时测定酱油中6种常见防腐剂(苯甲酸、山梨酸、脱氢乙酸、3种对羟基苯甲酸酯)的检测方法。样品经20%甲醇溶液提取后,C18色谱柱分离,以甲醇-1.55g/L乙酸铵溶液为流动相梯度洗脱,采用二极管阵列检测器检测,结果显示,6种组分分离完全,线性良好,加标回收率为89%～103%,相对标准偏差为1.09%～2.81%。该方法灵敏度高、选择性好、回收率高、简单快捷,能满足常规检测及酱油食品的安全控制需要。     

The response of Gluconobacter oxydans to sorbic and benzoic acids

The minimal inhibitory concentrations (MIC) of sorbic and benzoic acids for Gluconobacter oxydans were 1000 mg/l and 900 mg/l respectively at pH 3.8. A reduction in the pH of the test medium to 3.3 reduced the MIC of both preservatives by about 300 mg/l. When G. oxydans was grown in the presence of sublethal concentrations of sorbic or benzoic acids before the MIC was determined, the MIC of both compounds increased substantially within 1 h. Growth of G. oxydans was modified in several ways by the presence of sorbic acid in the medium. The duration of the lag phase increased and there was a substantial decrease in the viable count during the lag phase in the presence of high concentrations. The generation time increased and the viable count at the end of the logarithmic phase was reduced. At 1 degree C, G. oxydans grew in the absence of sorbic acid but was inactivated by 400 mg sorbic acid/l. At 37 degrees C the viable count of suspensions of G. oxydans decreased in both the absence and presence of sorbic acid. Sorbic acid increased the death rate. Growth of G. oxydans was prevented by eliminating air from culture vessels, combined with the addition of ascorbate to the medium containing 400 mg sorbic acid/l.