Next Article in Journal
Prevalence of Health-Risk Behaviors and Mental Well-Being of ASEAN University Students in COVID-19 Pandemic
Previous Article in Journal
The Reshaping of the E-Cigarette Retail Environment: Its Evolution and Public Health Concerns
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
IJERPH
Volume 19
Issue 14
10.3390/ijerph19148525
ijerph-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Notifications on Pesticide Residues in the Rapid Alert System for Food and Feed (RASFF)

by
Marcin Pigłowski
Department of Quality Management, Faculty of Management and Quality Science, Gdynia Maritime University, Morska 81–87 Str., 81-225 Gdynia, Poland
Int. J. Environ. Res. Public Health 2022, 19(14), 8525; https://doi.org/10.3390/ijerph19148525
Submission received: 2 June 2022 / Revised: 6 July 2022 / Accepted: 8 July 2022 / Published: 12 July 2022
Browse Figures
Review Reports Versions Notes

Abstract

:
Pesticides are commonly used to protect plants against various pests and to preserve crops, but their residues can be harmful for human health. They are the third most widely reported hazard category in the European Rapid Alert System for Food and Feed (RASFF). The purpose of the study was to identify the most frequently notified pesticides in the RASFF in 1981–2020, considering: year, notification type, product category, origin country, notifying country, notification basis, distribution status and action taken. The data from the RASFF database was processed using: filtering, transposition, pivot tables and then subjected to cluster analysis: joining (tree clustering) and two-way joining methods. Pesticides were most commonly reported in fruits and vegetables and herbs and spices following border controls and rejections. The products usually came from India or Turkey and were not placed on the market or were not distributed and then destroyed. The effectiveness of the European Union border posts in terms of hazards detection and mutual information is important from the point of view of protecting the internal market and ensuring public health. It is also necessary to increase the awareness of pesticide users through training and the activity of control authorities in the use of pesticides.

1. Introduction

Pesticides are chemicals designed to protect food by controlling harmful insects, diseases, rodents, weeds, bacteria and other pests [1,2]. They can destroy, suppress or alter the life cycle of pests [3]. In a broader context, pesticides are therefore used to: kill, repel or control pests to protect crops before and after harvest, influence the life process of plants, destroy weeds and prevent their growth, and preserve plant products [4]. It is estimated that if pesticides were not used, a third of crops would be lost [2]. However, if pesticides are used in an improper way, they can also be harmful to people, animals and the environment [1].
Regulation (EC) 396/2005 on maximum residue levels (i.e., MRLs) of pesticides in or on food and feed of plant and animal origin defines pesticide residues as residues, including active substances, their metabolites and/or breakdown or reaction products of active substances currently or formerly used in plant protection products, which are present in or on products, including, in particular, those which may arise as a result of use in plant protection, in veterinary medicine and as a biocide. The MRL means the upper legal level of concentration of pesticide residues in or on food or feed established in accordance with this regulation, based on good agricultural practice and the lowest consumer exposure necessary to protect vulnerable consumers [5]. Under Regulation (EC) 396/2005, the European Food Safety Authority (EFSA) provides annual reports, which examine pesticide residue levels in food on the European Union (EU) market. The main results of these reports from the last five years available (2016–2020) are shown in Table 1. These results are based on the analysis of an average of around 90,000 product samples from both EU and non-EU countries each year [6,7,8,9,10].
The results published by the EFSA indicate that about 95% of the samples are within the legal limits, of which about 40% did not even exceed the limit of quantification (LOQ), and only in 2–3% of the samples (taking into account the measurement uncertainty) were the MRLs exceeded. In the aforementioned reports, the EFSA points out that the probability of European citizens being exposed to levels of pesticide residues that could lead to adverse health effects is low. However, it consistently recommends the need to improve the efficiency of the European control system for pesticide residues [6,7,8,9,10], including optimising traceability [8].
Due to the widespread use of pesticides, they can come into contact with humans through various routes [4]. Therefore, pesticide residues may be present not only in plants, but also in meat, milk, eggs as a result of farm animal consumption, feed from treated crops, environmental contamination and spray drift [2]. Aggregate exposure may also occur for some pesticides if, for example, their residues are present in both food and insect baits [3].
Furthermore, climatic conditions in some countries can promote plant diseases (caused by plant pathogens), plant pests (plant-feeding or -sucking insects and mites) and weeds, and thus reduce yields [11]. In this context, it is therefore very important to apply good agricultural practice (GAP), which means the nationally recommended, authorised or registered safe use of plant protection products under actual conditions at any stage of production, storage, transport, distribution and processing of food. In addition, the principles of integrated pest control in a given climate zone should be implemented, as well as the use of a minimum quantity of pesticides and the setting of MRLs/temporary MRLs at the lowest level that achieves the intended effects. However, in certain cases it is necessary to implement a critical GAP, which means more than one GAP for an active substance/product combination, leading to an increase in the highest acceptable level of pesticide residues in treated crops and the basis for establishing a MRL [5].
The EU Pesticide Database covers 1472 active substances, safeners and synergists, of which 452 are approved and 937 are not approved, whereas 64 are under evaluation. This database also includes information on pesticide residues and the MRLs that apply for such residues in food products—there are 654 records (as of 5.07.2022) [12]. Active substances that are not approved are considered obsolete, but their stockpiles are still held by third countries from where the food is imported [3]. The problem with the presence of pesticide residues in food and feed is also noticeable in the Rapid Alert System for Food and Feed (RASFF) (Figure 1) [13]. The notification on pesticide residues in the RASFF is made when a substance in question was not approved or an MRL was exceeded (but for some notifications, values are not given or several values are given, making potential analysis problematic). In 2015, the number of notifications continued to decline slightly, which may be explained by the fact that the EU entry points strengthened border checks [14]. However, in 2020 the number of these notifications increased significantly.
It is also very important to note that the hazard category “pesticide residues” is the third most frequently reported in the RASFF, lead only by pathogenic micro-organisms and mycotoxins (Table 2).
The RASFF is a tool that ensures a rapid flow of information, which enables a quick response when a risk to public health is detected in the food chain. It was created as early as 1979, but its legal basis is now the Regulation (EC) 178/2002, which lays down the general principles and requirements of food law, establishes the European Food Safety Authority (EFSA) and lays down procedures in matters of food safety [15]. Under this regulation, RASFF members are obliged to immediately notify the European Commission of any information concerning a serious health risk deriving from food or feed, and the commission transmits this information to other members of the system [16]. The members of the RASFF are the 27 countries of the EU, the European Commission, the EFSA, the European Free Trade Association Surveillance Authority (ESA), and Norway, Liechtenstein, Iceland and Switzerland.
In the RASFF, alert notifications are sent when food or feed presenting a serious health risk is already on the market and rapid action is needed (e.g., product withdrawal). A RASFF member passes on information within the system so that others can check whether the product is also in their market and take appropriate measures accordingly. Information notifications are used when a risk concerning food or feed has been identified but other RASFF members do not need to take rapid action. This is because the product may not have reached their market yet, is no longer present in their market or the nature of the risk does not require rapid action. Border rejections concern consignments of food or feed that have been tested and rejected at the external border of the European Economic Area (EEA) if a health risk has been identified. Notifications are sent to other EEA border posts to ensure that the rejected consignment does not re-enter through another border post [15].
However, in publications the problem related to pesticide residues in food and feed is addressed usually in a generalised, selective way and in a short time horizon. An exception here is the extensive analysis on pesticide residues in RASFF notifications from 2002 to 2020 recently carried out by Kuchheuser and Birringer (relating also to MRLs) [17,18], but the individual issues (variables) can be presented in an even more comprehensive and cross-sectional way. Pesticide notifications are also signalled in the annual reports of the RASFF or the EFSA, but only apply to the year for which the report is issued. Therefore, the purpose of the study was to identify the most frequently notified pesticides in the RASFF between 1981 and 2020, taking into account: year, notification type, product category, origin country, notifying country, notification basis, distribution status and action taken.

2. Materials and Methods

2.1. Data and Its Processing

The current ongoing RASFF database, maintained by the European Commission, provides only data up to two years back, i.e., it does not include historical data [19]. Therefore, the data was extracted from the RASFF notifications pre-2021 public information database and covered 8013 notifications on pesticide residues between 1981 and 2020 (a 40-year period) [13]. These notifications were very diverse, as they concerned 257 different pesticides. Due to this wide variability, all pesticides were included only in preliminary studies (without indication of individual substances). However, detailed studies (i.e., with indication of the pesticide concerned) were carried out on only the first seventeen most frequently notified pesticides, accounting for more than half of all notifications. They covered 4061 notifications in the period 1994–2020, i.e., 27 years. All pesticides with the number of notifications were collected in Table S1 in Supplementary Materials.
The data from the RASFF pre-2021 database were processed in Microsoft Excel using: filtering, transposition, pivot tables and vertical lookup. Finally, the following eight variables were adopted in the study: year, notification type, product category, origin country, notifying country, notification basis, distribution status and action taken. In the case of the variable “notification type” three values were assumed: alert, border rejection and information as a combination of several values, i.e., information in the period 1994–2010, information for attention (from 2011) and information for follow-up (also from 2011). In turn, in the case of the variables origin country, notification basis, distribution status and action cells without values (empty cells), they were completed by the phrase “(not specified)”. To make the figures more readable, in the case of the variables product category, notification basis, distribution status and action taken, the names of some values were shortened (Table S2 in Supplementary Materials).

2.2. The Cluster Analysis

The data were then transferred to source tables in Statistica 13.3 (TIBCO Software Inc., Palo Alto, CA, USA), where they were subjected to cluster analysis by joining (tree clustering) and two-way joining methods. For the purpose of cluster analysis, years where no notifications were reported were filled in with the value “0”. In the case of the joining method, in the source tables, pesticides were in rows and values of eight variables (year, notification type, product category, origin country, notifying country, notification basis, distribution status and action taken) were in columns. The following settings were used: Euclidean distance for the distance measure and Ward’s method for amalgamation. The Euclidean distance is the geometric distance in a multidimensional space. Ward’s method uses an analysis of variance to evaluate the distances between clusters, attempting to minimise the sum of squares of any two (hypothetical) clusters, which can be formed at each step. This method is considered to be very efficient; however, it tends to create clusters of small sizes (flattening of clusters). The results of the joining cluster analysis were presented as vertical icicle plots in Figure S1 (8 charts in total) in Supplementary Materials.
Then, the source tables for the two-way joining cluster analysis were prepared. For each of the seventeen pesticide studied, seven tables were built, with years in columns and the values of the other variables (i.e., notification type, product category, origin country, notifying country, notification basis, distribution status and action taken) in rows. This method was used to discover cluster patterns that may appear simultaneously in particular years with given values of other variables. Although clusters may not be homogeneous in nature, this method is considered a useful analysis tool [20].
The results of the two-way joining cluster analysis were presented in Figures S2–S18 (with particular charts) in Supplementary Materials (119 charts in total). The clusters in the two-way joining cluster analysis were shown by coloured squares (from green, through yellow, orange and red, to brown) in contour/discrete charts. In order to increase the readability of the figures, the dark green colour (smallest clusters or no clusters) was changed to white. During the presentation of the results, attention was paid only to the largest clusters (yellow, orange, red and brown colours).
The years with the highest number of notifications for a given pesticide were determined by the variable “notification basis”. Due to the large diversity in the values of the variable “origin country”, in the case of some pesticides only the first 30 countries with the highest number of notifications were taken into account. If, for individual values (within each variable), notifications were not reported in a similar way, only years with the highest number of notifications were indicated. When preparing the charts, it was also necessary to rearrange the data matrix for some variables. Moreover, some results were discarded in order to maintain the most accurate coverage of the values in individual years for different variables.

3. Results

3.1. General Results

3.1.1. Percentage Share of Notifications

The number and percentage of notifications on pesticide residues in the RASFF, depending on the particular variables, are presented in Figure 2. In the case of notification type, all three types were presented. For the variables of product category, origin country, notifying country, notification basis, distribution status and action taken, values with notifications above the mean (from largest to smallest) were only shown and notifications for the remaining values were summarised and named “others”.
The border rejections accounted for nearly half of all notifications (48.4%), information notifications for 36.6% and alerts only for 15.0% (Figure 2a). Notifications were related mainly to fruits and vegetables (67.6%), as well as herbs and spices (10.0%), cocoa and cocoa preparations, coffee and tea (7.8%) and nuts, nut products and seeds (5.3%) (Figure 2b). The reported products originated mainly from India (18.1%) and Turkey (17.6%), as well as from China (7.8%), Thailand (6.2%), Egypt (5.8%) and Italy (3.7%) (Figure 2c). They were notified by Germany (13.3%), Bulgaria (12.1%), the United Kingdom (10.2%), the Netherlands (9.1%), France (8.2%) and Italy (8.0%) (Figure 2d).
The notifications were based on border control, after which the consignment was detained (47.2%), as well as official controls in the market (26.4%) and the company’s own checks (10.9%) (Figure 2e). Products were not placed on the market (29.0%), were not distributed (18.6%) or were distributed to other countries (13.2%) (Figure 2f) and the most common actions taken against them were destruction (26.7%), withdrawal from the market (9.9%) and re-dispatch (8.9%) (Figure 2g).

3.1.2. Results of Joining Cluster Analysis

The results presented in Figure 1 and Figure 2 were confirmed by the cluster analysis using the joining method (Figure S1 in Supplementary Materials). This analysis showed a separate cluster for 2020, when there was a sharp increase in the number of notifications, whereas the years 2002 and 2007–2019 formed a second cluster. Here, however, it can also be further noted that the notifications in 2008–2009, 2012–2013, 2014–2015 and 2018–2019 were very similar in nature (Figure S1a). It should also be pointed out that information notifications and border rejections were also similar during the period considered (Figure S1b). If the product category is taken into account, a clearly separate cluster was created by fruits and vegetables due to the significant number of notifications regarding these products. Next to them, however, there were also nuts, nut products and seeds, herbs and spices, cocoa and cocoa preparations, and coffee and tea, as well as eggs and egg products, and cereals and bakery products (Figure S1c). Notifications mostly concerned products from India and Turkey, which is why these countries created a separate cluster (Figure S1d)
The countries that made the largest number of notifications (i.e., Bulgaria, the Netherlands, the United Kingdom, Germany, France, Italy and Belgium) also formed a separate cluster (Figure S1e). Taking into account the notification basis, the border controls (after which the consignment was detained), the official controls in the market and the company’s own checks were of a similar nature (Figure S1f). In the case of distribution status, the notifications were similar for products that were not placed on the market and those that were not distributed (Figure S1g). The results of the cluster analysis using the joining method with regard to the actions taken were very varied; however, it can be seen that an action such as destruction is the first element of a separate cluster (Figure S1h).

3.2. Results of Two Way-Joining Cluster Analysis for Pesticides Studied

Results of the two-way joining cluster analysis related to notifications on pesticides in the RASFF are presented in Table 3. In this table the number of notifications on particular pesticide and the number of the figure in the Supplementary Materials are also given. If there was a particularly high number of notifications for a particular product, the name of that product was also given (this data came directly from the RASFF pre-2021 database) [13].

3.2.1. Fruits, Vegetables and Nuts from India

The most frequently notified were fruits and vegetables from India in 2012–2013. It concerned mainly okra, where the residues of pesticides such as acephate, acetamiprid, dimethoate, methamidophos, monocrotophos, profenofos and triazophos were found. The notification basis for these products was border control, after which the consignment was detained, resulting in border rejection. These products were notified by the United Kingdom and France, they were not distributed and the most common action taken against them was destruction. The notifications related to profenofos and triazophos also applied to curry (product category “herbs and spices”).
However, recently (in 2020), the Netherlands reported a very significant number of notifications for sesame seeds (product category “nuts, nut product and seeds”) from India where residues of ethylene oxide were found. These products were already on the European Union market because the notification basis was the company’s own check, and the notification type was an alert. They were also already distributed to other member countries; therefore, consignors and recipients were informed, and products were withdrawn from the market and even recalled from consumers. It is also worth noting that residues of another pesticide (carbendazim) on fruits and vegetables from India were notified by Italy in 2014–2015.

3.2.2. Fruits and Vegetables from Turkey

Bulgaria notified fruits and vegetables from Turkey. In this category, residues of acetamiprid on peppers and pomegranates (in 2012–2013 and 2020), chlorpyrifos on lemons, peppers and stuffed vine leaves (in 2015–2020) and formetanate, methomyl and oxamyl on peppers (in different years) were found. Methomyl was also reported by Germany, the Netherlands and France and oxamyl by Germany. The notification basis in this case was usually border control and the consignment was detained, and therefore it was rejected at the border. The reported peppers were not distributed and they were destroyed.

3.2.3. Vegetables from Nigeria

Dichlorvos was notified by the United Kingdom on beans (product category “fruits and vegetables”) from Nigeria in 2013–2015. Similarly, the notification basis was border control and the consignment was detained (the notification type was border rejection). The product was not placed on the market and the actions taken with regard to it consisted of official detention, re-dispatch or destruction.

3.2.4. Eggs from Italy

The last pesticide to look out for is fipronil on eggs and egg products. It was reported by Italy in 2017 on products originating from that country. The notification basis was official controls in the market and the reporting was carried out under information notifications. The distribution was restricted to the notifying country and the product was withdrawn from the market.

3.2.5. Other Notifications

Notifications related to carbofuran (2014–2019) and omethoate (2005–2013, 2018–2019) were very diverse; however, they also concerned fruits and vegetables. These products with residues of the above mentioned pesticides usually originated from Asia (mainly Thailand) and notifications were reported by the Western European countries. It is also noteworthy that when comparing the results presented in Figure 2 and Table 3, some differences with respect to some values can be seen. The most visible is the lack of the product category “cocoa and cocoa preparations, coffee and tea” in Table 3, which means that pesticides other than those most frequently reported were notified on these products.

4. Discussion

Some authors only signalled the reporting of pesticide residue hazards in the RASFF in particular years: 2004 [21], 2004–2014 [22], 2007–2013 [23], 2008 [24], before 2012 [25] and 2014 [26]. In turn, other authors indicated period, product (product category) and additional information (Table 4). Some articles pointed out only particular pesticides without indication of the products: acephate, methamidophos and monocrotophos (in 2002–2003) [27], acetamiprid and imidacloprid (in 2012–2015) [28], acetamiprid, carbendazim, carbofuran, chlorpyrifos, dichlorvos, dimethoate, formetanate and other pesticides (in 2015, notified mainly by Italy, France, Belgium and the Netherlands) [14], isofenphos-methyl and omethoate (in 2015) [2], chlorpyrifos (in 2016–2017) [29], and also boscalid, chlorpyrifos and tebuconazole in peaches and nectarines from Turkey [30] or carbendazim, cypermethrin, dimethoate, endosulfan and ethion [31].
It is worth noting that the most frequently indicated were those pesticides for which a detailed analysis of notifications in the RASFF was performed (Table 3). Fruits and vegetables and herbs and spices were the most commonly identified (this was also pointed out in Figure 2b), but the presence of pesticide residues in okra and curry leaves from India seems to be a frequently noticed problem. In fact, these products (and others) were covered by three legislations (now no longer in force): Commission Regulation (EC) 669/2009 implementing Regulation (EC) 882/2004 of the European Parliament and of the Council as regards the increased level of official controls on imports of certain feed and food of non-animal origin, Commission Implementing Regulation (EU) 91/2013 laying down specific conditions applicable to the import of groundnuts from Ghana and India, okra and curry leaves from India, and watermelon seeds from Nigeria, and then, Commission Implementing Regulation (EU) 885/2014 laying down specific conditions applicable to the import of okra and curry leaves from India. The adoption of Regulation 91/2013 was the result of an audit that was conducted in India in 2011 by the Food and Veterinary Office. At that time, it was found that there was no framework for the use of pesticides for okra, curry leaves and other products, and the Indian authorities were unable to provide the European Commission with a satisfactory action plan to address the identified shortcomings [32]. Currently, in the scope of checks for the presence of pesticide residues in okra and curry leaves from India, Commission Implementing Regulation (EU) 2019/1793 on the temporary increase in official controls and emergency measures governing the entry into the Union of certain goods from certain third countries is in force (it also applies to other products, hazards and origin countries) [33], but this regulation has also already been changed.
In recent years, however, the two biggest pesticide crises have involved other product categories. Fipronil on eggs was first reported by Belgium [55], but the most notifications were submitted by Italy (for products from this country) and there were so many of them that they were recorded among the ten most notified in the 2017 RASFF annual report [56]. Whereas in September 2020, Belgium notified in the RASFF that it had exceeded almost four thousand times the MRL set for ethylene oxide (by Regulation (EC) 396/2005) in sesame seeds imported from India [13]. The Food and Feed Crisis Coordinators meeting was organized immediately [62], and the Commission Implementing Regulation (EU) 2020/1540 amending Implementing Regulation (EU) 2019/1793 on sesame seeds originating from India was issued the following month. This Regulation required that each shipment of sesame seeds from India be accompanied by an official certificate stating that the products had been sampled and analyzed for pesticide residues, and the test results had to be attached to the certificate [63]. The number of ethylene oxide notifications was so high that it was also among the ten most reported in the annual RASFF report for 2020 [59]. In 2021, the number of notifications on pesticide residues remained at a similar high level as in 2020 (i.e., more than 1000). However, the number of notifications relating to the presence of ethylene oxide in nuts (originating from India) decreased several times, while the number of notifications referring to chlorpyrifos in fruits and vegetables increased significantly [19].

5. Conclusions

The vast majority of pesticide residue hazards reported in the RASFF in 1981–2020 concerned fruits and vegetables (67.6%), followed by herbs and spices (10.0%), cocoa and cocoa preparations, coffee and tea (7.8%), and nuts, nut products and seeds (5.3%). Notifications were mainly reported on the basis of border controls, as the consignment was detained (47.2%), resulting in border rejections (48.4%). Information notifications and alert notifications were also made, and these were mainly based on official controls in the market and the company’s own checks. The notified products originated mainly from India (18.1%) and Turkey (17.6%), as well as China, Thailand, Egypt and Italy, and were reported by Germany, Bulgaria, the United Kingdom, the Netherlands, France, Italy and Belgium. The reported products were mostly not placed on the market (29.0%), not distributed (18.6%) or distributed to other countries (13.2%), and the following actions were taken against them: destruction (26.7%), withdrawal from the market (9.9%) or re-dispatch (8.9%).
The detailed study covered half of the RASFF notifications for the seventeen most frequently notified pesticides between 1994 and 2020, i.e., a 27-year period. The two-way joining cluster analysis enabled the identification of concentrations and similarities in the notifications indicating, among others: pesticide, years, product, origin country and notifying country. A significant problem was the presence of pesticide residues in okra from India in 2012–2013 notified mainly by the United Kingdom and France (acephate, acetamiprid, dimethoate, methamidophos, monocrotophos, profenofos and triazophos). It is also worth noting that in 2020 there was a very sharp increase in the number of notifications, reported mainly by the Netherlands, due to the presence of ethylene oxide on sesame seeds from India. Notifications reported by Bulgaria on products from Turkey can also be observed (acetamiprid on peppers and pomegranates in 2012–2013 and 2020, chlorpyrifos on lemons, peppers and stuffed vine leaves in 2015–2020, and formetanate, methomyl and oxamyl on peppers in different years). There was also a serious crisis in 2017 when Italy reported fipronil on eggs originating from that country.
The analysis of notifications in the RASFF has shown that the greatest number of hazards of pesticide residues concerned products originating from Asia. Therefore, the effectiveness of the European Union border posts in terms of hazard detection and mutual information transfer is extremely important from the point of view of protecting the internal market and ensuring public health. Important elements of this safety include Regulation (EC) 396/2005 on the maximum residue levels (MRLs) of pesticides, the EU Pesticide Database including active substances, the Regulation (EU) 2019/1793 on the temporary increase in official controls and other regulations as appropriate.
It is necessary to develop cooperation between EU institutions and bodies and their counterparts in non-EU countries. Cooperation could take place at the level of working teams and include advising on the creation or amendment of laws, as well as providing training in these countries. Training should take into account the indigenous or even local nature of production in these countries, be conducted in a structured manner and with the participation of national supervisory authorities and bodies, and cover issues related to the use of pesticides permitted by the EU and that are appropriate for a given plant (season, amount, withdrawal period). This will minimise or avoid image and financial losses (e.g., costs related to transport and disposal of contaminated products) by countries exporting products to the EU market.
Further research on pesticide residues could include linking RASFF notifications to quantities of particular types of imported products (based on Eurostat data) in order to forecast possible hazards. However, this could be hampered by data gaps in the RASFF database (especially for the earlier years of the system operation) and the lack of access to historical data in the currently functioning official database. Therefore, it would be necessary to additionally connect the data from the historical database and the one currently available.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/ijerph19148525/s1, Table S1: Number of notifications on particular pesticides in the RASFF in 1981–2020; Table S2: Short names of some values of the variables: product category, notification basis, distribution status and action taken; Figure S1: Results of joining cluster analysis, (a) years, (b) notification type, (c) product categories, (d) origin countries, (e) notifying countries, (f) notification basis, (g) distribution status, (h) action taken; Figure S2: Results of two-way joining cluster analysis for acephate, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S3: Results of two-way joining cluster analysis for acetamiprid, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S4: Results of two-way joining cluster analysis for carbendazim, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S5: Results of two-way joining cluster analysis for carbofuran, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S6: Results of two-way joining cluster analysis for chlorpyrifos, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S7: Results of two-way joining cluster analysis for dichlorvos, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S8: Results of two-way joining cluster analysis for dimethoate, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S9: Results of two-way joining cluster analysis for ethylene oxide, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S10: Results of two-way joining cluster analysis for fipronil, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S11: Results of two-way joining cluster analysis for formetanate, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S12: Results of two-way joining cluster analysis for methamidophos, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S13: Results of two-way joining cluster analysis for methomyl, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S14: Results of two-way joining cluster analysis for monocrotophos, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S15: Results of two-way joining cluster analysis for omethoate, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S16: Results of two-way joining cluster analysis for oxamyl, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S17: Results of two-way joining cluster analysis for profenofos, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken; Figure S18: Results of two-way joining cluster analysis for triazophos, (a) notification type, (b) product category, (c) origin country, (d) notifying country, (e) notification basis, (f) distribution status, (g) action taken.

Funding

This research received no external funding. The APC was funded by Gdynia Maritime University, team research project “Systemic quality, environment and safety management in the product life cycle” number WZNJ/2022/PZ/04.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Conflicts of Interest

The author declares no conflict of interest.

References

  1. Nielsen, S.S. US Government Regulations and International Standards Related to Food Analysis. In Food Analysis, 5th ed.; Nielsen, S.S., Ed.; Springer: Cham, Switzerland, 2017; pp. 17–34. [Google Scholar] [CrossRef]
  2. Ismail, B.P.; Nielsen, S.S. Analysis of Food Contaminants, Residues, and Chemical Constituents of Concern. In Food Analysis, 5th ed.; Nielsen, S.S., Ed.; Springer: Cham, Switzerland, 2017; pp. 573–597. [Google Scholar] [CrossRef]
  3. Sieke, C. Pesticide residues (In Exposure to Substances via Food Consumption). In The Practice of Consumer Exposure Assessment; Heinemeyer, G., Jantunen, M., Hakkinen, P., Eds.; Springer: Cham, Switzerland, 2019; pp. 309–322. [Google Scholar] [CrossRef]
  4. Donati, C. Risk Analysis, Contaminants and Impact on Health in Imports of Non-animal Origin: The EU Context. In Risk Regulation in Non-Animal Food Imports. The European Union Approach; Montanari, F., Jezsó, V., Donati, C., Eds.; Springer: Cham, Switzlerland, 2015; pp. 1–27. [Google Scholar] [CrossRef]
  5. European Parliament; Council of the European Union. Regulation (EC) 396/2005 of the European Parliament and of the Council of 23 February 2005 on Maximum Residue Levels of Pesticides in or on Food and Feed of Plant and Animal Origin and Amending Council Directive 91/414/EEC (Text with EEA Relevance); OJ L 70, 16 March 2005; European Parliament and Council of the European Union: Brussels, Belgium, 2005; pp. 1–16. [Google Scholar]
  6. European Food Safety Authority. The 2016 European Union report on pesticide residues in food. EFSA J. 2018, 16, e05348. [Google Scholar] [CrossRef] [Green Version]
  7. European Food Safety Authority. The 2017 European Union report on pesticide residues in food. EFSA J. 2019, 17, e05743. [Google Scholar] [CrossRef] [Green Version]
  8. European Food Safety Authority. The 2018 European Union report on pesticide residues in food. EFSA J. 2020, 18, e06057. [Google Scholar] [CrossRef] [Green Version]
  9. European Food Safety Authority. The 2019 European Union report on pesticide residues in food. EFSA J. 2021, 19, e06491. [Google Scholar] [CrossRef]
  10. European Food Safety Authority. The 2020 European Union report on pesticide residues in food. EFSA J. 2022, 20, e07215. [Google Scholar] [CrossRef]
  11. Reinholds, I.; Bartkevics, V.; Silvis, I.; Ruth, S.; Esslinger, S. Analytical techniques combined with chemometrics for authentication and determination of contaminants in condiments: A review. J. Food Compos. Anal. 2015, 44, 56–72. [Google Scholar] [CrossRef]
  12. The UE Pesticide Database. Available online: https://ec.europa.eu/food/plant/pesticides/eu-pesticides-database (accessed on 5 July 2022).
  13. RASFF Notifications Pre-2021 Public Information. Available online: https://data.europa.eu/data/datasets/restored_rasff?locale=en (accessed on 25 March 2022).
  14. Badea, M.; Floroian, L.; Marculescu, A.; Gaceu, L.; Moga, M.; Gaman, L.; Codruta, C.; Chang, Q.; Xue, J.; Restani, P. Classic/Recommended Methods and Development of new Methods to Control Residues and Contaminants of Botanicals. In Food Supplements Containing Botanicals: Benefits, Side Effects and Regulatory Aspects; Restani, P., Ed.; Springer: Cham, Switzerland, 2018; pp. 349–378. [Google Scholar] [CrossRef]
  15. RASFF—Food and Feed Safety Alerts. Available online: https://ec.europa.eu/food/safety/rasff-food-and-feed-safety-alerts_en (accessed on 11 May 2022).
  16. European Parliament; Council of the European Union. Regulation (EC) 178/2002 of the European Parliament and of the Council of 28 January 2002 Laying Down the General Principles and Requirements of Food Law, Establishing the European Food Safety Authority and Laying Down Procedures in Matters of Food Safety; OJ L 31, 1 February 2002; European Parliament and Council of the European Union: Brussels, Belgium, 2002; pp. 1–24. [Google Scholar]
  17. Kuchheuser, P.; Birringer, M. Pesticide residues in food in the European Union: Analysis of notifications in the European Rapid Alert System for Food and Feed from 2002 to 2020. Food Control 2022, 133 Pt A, 108575. [Google Scholar] [CrossRef]
  18. Kuchheuser, P.; Birringer, M. Evaluation of specific import provisions for food products from third countries based on an analysis of RASFF notifications on pesticide residues. Food Control 2022, 133 Pt B, 108581. [Google Scholar] [CrossRef]
  19. RASFF Window. Available online: https://webgate.ec.europa.eu/rasff-window/screen/search (accessed on 11 May 2022).
  20. TIBCO Statistica® User’s Guide. Available online: https://docs.tibco.com/pub/stat/14.0.0/doc/html/UsersGuide/ (accessed on 21 April 2022).
  21. Wiig, A.; Kolstad, I. Lowering barriers to agricultural exports through technical assistance. Food Policy 2005, 30, 185–204. [Google Scholar] [CrossRef]
  22. Banach, J.L.; Stratakou, I.; Van Der Fels-Klerx, H.J.; Den Besten, H.M.W.; Zwietering, M.H. European alerting and monitoring data as inputs for the risk assessment of microbiological and chemical hazards in spices and herbs. Food Control 2016, 69, 237–249. [Google Scholar] [CrossRef] [Green Version]
  23. Dzantiev, B.B.; Byzova, N.A.; Urusov, A.E.; Zherdev, A.V. Immunochromatographic methods in food analysis. TRAC-Trends Anal. Chem. 2014, 55, 81–93. [Google Scholar] [CrossRef]
  24. Cheftel, J.C. Emerging Risks Related to Food Technology. In Advances in Food Protection. NATO Science for Peace and Security Series A: Chemistry and Biology; Hefnawy, M., Ed.; Springer: Dordrecht, The Netherlands, 2011; pp. 223–254. [Google Scholar] [CrossRef]
  25. Cajka, T.; Sandy, C.; Bachanova, V.; Drábová, L.; Kalachova, K.; Pulkrabová, J.; Hajslova, J. Streamlining Sample Preparation and Gas Chromatography–Tandem Mass Spectrometry Analysis of Multiple Pesticide Residues in Tea. Anal. Chim. Acta 2012, 743, 51–60. [Google Scholar] [CrossRef]
  26. Pose-Juan, E.; Fernández-Cruz, T.; Simal-Gándara, J. State of the Art on Public Risk Assessment of Combined Human Exposure to Multiple Chemical Contaminants. Trends Food Sci. Technol. 2016, 55, 11–28. [Google Scholar] [CrossRef]
  27. Patel, K.; Fussell, R.J.; Macarthur, R.; Goodall, D.M.; Keely, B.J. Method validation of resistive heating—Gas chromatography with flame photometric detection for the rapid screening of organophosphorus pesticides in fruit and vegetables. J. Chromatogr. A 2004, 1046, 225–234. [Google Scholar] [CrossRef]
  28. Cladière, M.; Delaporte, G.; Roux, E.; Camel, V. Multi-class analysis for simultaneous determination of pesticides, mycotoxins, process-induced toxicants and packaging contaminants in tea. Food Chem. 2018, 242, 113–121. [Google Scholar] [CrossRef]
  29. Mekonnen, T.F.; Byrne, L.; Panne, U.; Koch, M. Investigation of Chlorpyrifos and Its Transformation Products in Fruits and Spices by Combining Electrochemistry and Liquid Chromatography Coupled to Tandem Mass Spectrometry. Food Anal. Method 2018, 11, 2657–2665. [Google Scholar] [CrossRef]
  30. Dülger, H.; Tiryaki, O. Investigation of pesticide residues in peach and nectarine sampled from Çanakkale, Turkey, and consumer dietary risk assessment. Environ. Monit. Assess 2021, 193, 1–10. [Google Scholar] [CrossRef]
  31. Vázquez, P.P.; Ferrer, C.; Martínez Bueno, M.J.; Fernández-Alba, A.R. Pesticide residues in spices and herbs: Sample preparation methods and determination by chromatographic techniques. TRAC-Trends Anal. Chem. 2019, 115, 13–22. [Google Scholar] [CrossRef]
  32. Jezsó, V. Managing Risks in Imports of Non-animal Origin: EU Emergency Measures. In Risk Regulation in Non-Animal Food Imports. The European Union Approach; Montanari, F., Jezsó, V., Donati, C., Eds.; Springer: Cham, Switzerland, 2015; pp. 57–95. [Google Scholar] [CrossRef]
  33. European Commission. Commission Implementing Regulation (EU) 2019/1793 of 22 October 2019 on the Temporary Increase of Official Controls and Emergency Measures Governing the entry into the Union of Certain Goods from Certain Third Countries Implementing Regulations (EU) 2017/625 and (EC) No 178/2002 of the EUROPEAN Parliament and of the Council and Repealing Commission Regulations (EC) No 669/2009, (EU) No 884/2014, (EU) 2015/175, (EU) 2017/186 and (EU) 2018/1660 (Text with EEA Relevance); OJ L 277, 29 October 2019; European Commission, Directorate-General for Health and Food Safety: Brussels, Belgium, 2019; pp. 89–129. [Google Scholar]
  34. McEvoy, J. Emerging food safety issues: An EU perspective. Drug Test Anal. 2016, 8, 511–520. [Google Scholar] [CrossRef] [Green Version]
  35. Golge, O.; Cinpolat, S.; Kabak, B. Quantification of pesticide residues in gherkins by liquid and gas chromatography coupled to tandem mass spectrometry. J. Food Compos. Anal. 2021, 96, 103755. [Google Scholar] [CrossRef]
  36. Kleter, G.A.; Prandini, A.; Filippi, L.; Marvin, H.J.P. Identification of potentially emerging food safety issues by analysis of reports published by the European Community’s Rapid Alert System for Food and Feed (RASFF) during a four-year period. Food Chem. Toxicol. 2009, 47, 932–950. [Google Scholar] [CrossRef] [PubMed]
  37. Moreno-Gonzalez, D.; Huertas-Pérez, J.F.; García-Campaña, A.M.; Bosque-Sendra, J.M.; Gámiz-Gracia, L. Ultrasound-assisted surfactant-enhanced emulsification microextraction for the determination of carbamates in wines by ultra-high performance liquid chromatography-tandem mass spectrometry. J. Chromatogr. A 2013, 1315, 1–7. [Google Scholar] [CrossRef] [PubMed]
  38. Van Asselt, E.D.; Banach, J.L.; Van Der Fels-Klerx, H.J. Prioritization of chemical hazards in spices and herbs for European monitoring programs. Food Control 2018, 83, 7–17. [Google Scholar] [CrossRef]
  39. Bouzembrak, Y.; Marvin, H.J.P. Impact of drivers of change, including climatic factors, on the occurrence of chemical food safety hazards in fruits and vegetables: A Bayesian Network approach. Food Control 2018, 97, 67–76. [Google Scholar] [CrossRef]
  40. DeMaria, F.; Drogué, S. EU Trade Regulation for Baby Food: Protecting Health or Trade? World Econ. 2016, 40, 1430–1453. [Google Scholar] [CrossRef] [Green Version]
  41. Van Boxstael, S.; Habib, I.; Jacxsens, L.; De Vocht, M.; Baert, L.; Van De Perre, E.; Rajkovic, A.; Lopez-Galvez, F.; Sampers, I.; Spanoghe, P.; et al. Food safety issues in fresh produce: Bacterial pathogens, viruses and pesticide residues indicated as major concerns by stakeholders in the fresh produce chain. Food Control 2013, 32, 190–197. [Google Scholar] [CrossRef] [Green Version]
  42. Uyttendaele, M.; Jacxsens, L.; Van Boxstael, S. Issues surrounding the European fresh produce trade: A global perspective. In Global Safety of Fresh Produce. A Handbook of Best Practice, Innovative Commercial Solutions and Case Studies; Hoorfar, J., Ed.; Woodhead Publishing Limited: Oxford, UK; Cambridge, UK; Philadelphia, PA, USA; New Delhi, India, 2014; pp. 35–51. [Google Scholar] [CrossRef]
  43. Kareem, F.; Brümmer, B.; Martínez-Zarzoso, I. European Union Market Access Conditions and Africa’s Extensive Margin of Food Trade. World Econ. 2016, 40, 2277–2300. [Google Scholar] [CrossRef] [Green Version]
  44. Tauseef, M.; Rafique, N.; Ahmad, I.; Ishtiaq, M.; Samad, A.; Saba, S.; Ahad, K.; Mehboob, F. Analysis of multiple pesticide residues in rice by LC–MS/MS. Chem. Pap. 2021, 75, 2871–2879. [Google Scholar] [CrossRef]
  45. Engelbert, T.; De Jong, B.; Brockmeier, M. Moving Toward the EU or the Middle East? An Assessment of Alternative Turkish Foreign Policies Utilizing the GTAP Framework. Food Policy 2014, 47, 46–61. [Google Scholar] [CrossRef]
  46. European Union. RASFF-The Rapid Alert System for Food and Feed-2012 Annual Report; Publications Office of the European Union: Luxembourg, 2013. [Google Scholar] [CrossRef]
  47. Brandão, D.; Liébana, S.; Pividori, M.I. Multiplexed detection of foodborne pathogens based on magnetic particles. New Biotechnol. 2015, 32, 511–520. [Google Scholar] [CrossRef]
  48. Rubio, L.; Sarabia, L.A.; Ortiz, M.C. Standard addition method based on four-way PARAFAC decomposition to solve the matrix interferences in the determination of carbamate pesticides in lettuce using excitation-emission fluorescence data. Talanta 2015, 138, 86–99. [Google Scholar] [CrossRef] [Green Version]
  49. Sawant, I.S. Tapping the marvelous power of microorganisms for sustainable disease management. Indian Phytopathol. 2018, 71, 3–8. [Google Scholar] [CrossRef]
  50. European Union. RASFF for Safer Food-The Rapid Alert System for Food and Feed-2014 Annual Report; Publications Office of the European Union: Luxembourg, 2015. [Google Scholar] [CrossRef]
  51. Hakme, E.; Lozano, A.; Uclés, S.; Gómez-Ramos, M.M.; Fernández-Alba, A.R. High-throughput Gas chromatography-Mass spectrometry analysis of pesticide residues in spices by using the Enhanced Matrix Removal-lipid and the sample dilution approach. J. Chromatogr. A 2018, 1573, 28–41. [Google Scholar] [CrossRef]
  52. Girame, R.; Shabeer, T.P.; Ghosh, B.; Hingmire, S.; Natarajan, R.; Dubey, P. Multi-residue method validation and safety evaluation of pesticide residues in seed spices cumin (Cuminum cyminum) and coriander (Coriandrum sativum) by gas chromatography tandem mass spectrometry (GC-MS/MS). Food Chem. 2022, 374, 131782. [Google Scholar] [CrossRef]
  53. Pan, Y.; Ren, Y.; Luning, P. Factors influencing Chinese farmers’ proper pesticide application in agricultural products—A review. Food Control 2021, 122, 107788. [Google Scholar] [CrossRef]
  54. European Union. RASFF-The Rapid Alert System for Food and Feed-2016 Annual Report; Publications Office of the European Union: Luxembourg, 2017. [Google Scholar] [CrossRef]
  55. Anagnostopoulos, C.; Ampadogiannis, G.; Bempelou, E.; Liapis, K.; Kastellanou, E. The 2017 fipronil egg contamination incident: The case of Greece. J. Food Saf. 2020, 40, e12727. [Google Scholar] [CrossRef]
  56. European Union. RASFF-The Rapid Alert System for Food and Feed-2017 Annual Report; Publications Office of the European Union: Luxembourg, 2018. [Google Scholar] [CrossRef]
  57. Średnicka, P.; Juszczuk-Kubiak, E.; Wójcicki, M.; Akimowicz, M.; Roszko, M.Ł. Probiotics as a biological detoxification tool of food chemical contamination: A review. Food Chem. Toxicol. 2021, 153, 112306. [Google Scholar] [CrossRef]
  58. Ali, S.; Younas, N.; Akhtar, S.; Taj, T.; Mehboob, F. Analysis of multiple pesticide residues in market samples of okra and associated dietary risk assessment for consumers. Environ. Sci. Pollut. Res. 2022, 29, 47561–47570. [Google Scholar] [CrossRef]
  59. European Union. RASFF-The Rapid Alert System for Food and Feed-2020 Annual Report; Publications Office of the European Union: Luxembourg, 2021. [Google Scholar] [CrossRef]
  60. Dudkiewicz, A.; Dutta, P.; Kołożyn-Krajewska, D. Ethylene oxide in foods: Current approach to the risk assessment and practical considerations based on the European food business operator perspective. Eur. Food Res. Technol. 2022, 248, 1951–1958. [Google Scholar] [CrossRef]
  61. Visciano, P.; Schirone, M. Food frauds: Global incidents and misleading situations. Trends Food Sci. Technol. 2021, 114, 424–442. [Google Scholar] [CrossRef]
  62. European Commission. Food and Feed Crisis Coordinators Meeting of 9 October 2020 on High Levels of Ethylene Oxide Detected in Sesame Seeds Imported from India Summary Record; European Commission: Brussels, Belgium, 2021. [Google Scholar]
  63. European Commission. Commission Implementing Regulation (EU) 2020/1540 of 22 October 2020 Amending Implementing Regulation (EU) 2019/1793 as Regards Sesamum Seeds Originating in India (Text with EEA Relevance); OJ L 353, 23 October 2020; European Commission, Directorate-General for Health and Food Safety: Brussels, Belgium, 2020; pp. 4–7. [Google Scholar]
Ijerph 19 08525 g001 550
Figure 1. Number of notifications on pesticide residues in the RASFF in 1981–2020.
Figure 1. Number of notifications on pesticide residues in the RASFF in 1981–2020.
Ijerph 19 08525 g001
Ijerph 19 08525 g002a 550Ijerph 19 08525 g002b 550Ijerph 19 08525 g002c 550
Figure 2. Number and percentage of notifications on pesticide residues in the RASFF by variable.
Figure 2. Number and percentage of notifications on pesticide residues in the RASFF by variable.
Ijerph 19 08525 g002aIjerph 19 08525 g002bIjerph 19 08525 g002c
Table
Table 1. The main results presented in annual reports of the European Food Safety Authority on pesticide residues in food in 2016–2020 (percentage).
Table 1. The main results presented in annual reports of the European Food Safety Authority on pesticide residues in food in 2016–2020 (percentage).
YearWithin the Legal LimitsBelow the LOQ *Not Exceeding MRLs **Exceeding MRLs (***)
201696.2%50.7%45.5%3.8% (2.2%)
201795.9%54.1%41.8%4.1% (2.5%)
201895.5%NDANDA4.5% (2.7%)
201996.1%NDANDA3.9% (2.3%)
202094.9%54.6%40.3%5.1% (3.6%)
* LOQ—limit of quantification, ** MRLs—maximum residue levels, *** taking into account the measurement uncertainty.
Table
Table 2. Number of notifications and percentage in particular hazard categories in the RASFF in 1981–2020.
Table 2. Number of notifications and percentage in particular hazard categories in the RASFF in 1981–2020.
Hazard CategoryNumber of NotificationsPercentageHazard CategoryNumber of NotificationsPercentage
Adulteration/fraud21392.8%Natural toxins (other)8711.1%
Allergens24523.2%Not determined/other5710.7%
Biological contaminants (other)8991.2%Novel food10651.4%
Chemical contaminants (other)27below 0.05%Organoleptic aspects11041.4%
Composition47806.3%Packaging defective/incorrect5020.7%
Environmental pollutants15862.1%Parasitic infestation8221.1%
Feed additives1980.3%Pathogenic micro-organisms14,17718.6%
Food additives and
flavourings		36594.8%Pesticide residues801310.5%
Foreign bodies26363.5%Poor or insufficient controls17912.3%
Genetically modified food or feed8891.2%Process contaminants2540.3%
Industrial contaminants1680.2%Radiation6160.8%
Labelling absent/incomplete/incorrect5820.8%Residues of veterinary
medicinal products		26973.5%
Metals35854.7%Transmissible spongiform
encephalopathy (TSE)		2090.3%
Microbial contaminants (other)25913.4%
Migration40425.3%(Not specified)27below 0.05%
Mycotoxins13,33217.5%Total76,284100.0%
Table
Table 3. Results of two-way joining cluster analysis related to notifications on pesticides in the RASFF.
Table 3. Results of two-way joining cluster analysis related to notifications on pesticides in the RASFF.
Pesticide
(Number of Notifications)		Value (Figure)
Variable
Acephate (172)Year2012–2013
Notification typeBorder rejection (Figure S2a)
Product categoryFruits and vegetables (Figure S2b) (okra)
Origin countryIndia (Figure S2c)
Notified countryThe United Kingdom (Figure S2d)
Notification basisBorder control—consignment detained (Figure S2e)
Distribution statusNo distribution (Figure S2f)
Action takenDestruction (Figure S2g)
Acetamiprid (257)Year2012–2013, 2020
Notification typeBorder rejection (Figure S3a)
Product categoryFruits and vegetables (Figure S3b) (okra—India; peppers, pomegranates—Turkey)
Origin countryIndia (2012–2013), Turkey (2020) (Figure S3c)
Notified countryFrance, the United Kingdom (2012–2013), Bulgaria (2020) (Figure S3d)
Notification basisBorder control—consignment detained (Figure S3e)
Distribution statusNo distribution, product not (yet) placed on the market (2012–2013, 2020) (Figure S3f)
Action takenDestruction (Figure S3g)
Carbendazim (333)Year2014–2015
Notification typeBorder rejection (Figure S4a)
Product categoryFruits and vegetables (Figure S4b)
Origin countryIndia (Figure S4c)
Notified countryItaly (Figure S4d)
Notification basisBorder control—consignment detained (Figure S4e)
Distribution statusProduct not (yet) placed on the market (2014), product forwarded to destination (2015) (Figure S4f)
Action takenDestruction (2014–2015), re-dispatch (2015) (Figure S4g)
Carbofuran (184) Year2014–2019
Notification typeInformation (2014–2017), border rejection (2018–2019), alert (2018) (Figure S5a)
Product categoryFruits and vegetables (Figure S5b) (aubergines—The Dominican Republic; goji berries—China)
Origin countryThe Dominican Republic (2014, 2017–2019), Vietnam (2015), Thailand (2016), China (2017–2018) (Figure S5c)
Notified countrySwitzerland (2014–2016), the Netherlands (2017–2018) (Figure S5d)
Notification basisOfficial control in the market (2016–2018), border control—consignment detained (2018–2019) (Figure S5e)
Distribution statusProduct not (yet) placed on the market (2014, 2018–2019), distribution restricted (2015–2016), distribution to other member countries (2017–2018) (Figure S5f)
Action takenDestruction (2014, 2018–2019), official detention (2016), withdrawal from the market (2017–2018) (Figure S5g)
Chlorpyrifos (460)Year2015–2020
Notification typeBorder rejection (Figure S6a)
Product categoryFruits and vegetables (Figure S6b) (lemons, peppers, stuffed vine leaves)
Origin countryTurkey (2016–2017) (Figure S6c)
Notified countryBulgaria (2016–2017) (Figure S6d)
Notification basisBorder control—consignment detained (Figure S6e)
Distribution statusProduct not (yet) placed on the market (Figure S6f)
Action takenDestruction (2016–2019) (Figure S6g)
Dichlorvos (112)Year2013–2015
Notification typeBorder rejection (Figure S7a)
Product categoryFruits and vegetables (Figure S7b) (beans)
Origin countryNigeria (Figure S7c)
Notified countryThe United Kingdom (Figure S7d)
Notification basisBorder control—consignment detained (Figure S7e)
Distribution statusProduct not (yet) placed on the market (Figure S7f)
Action takenOfficial detention (2013), re-dispatch (2014), destruction (2014–2015) (Figure S7g)
Dimethoate (326)Year2012–2013
Notification typeBorder rejection (Figure S8a)
Product categoryFruits and vegetables (Figure S8b) (okra—India; oranges—Egypt)
Origin countryIndia (2012–2013), Egypt (2013), Kenya (2013) (Figure S8c)
Notified countryThe United Kingdom (2012–2013), France (2013) (Figure S8d)
Notification basisBorder control—consignment detained (Figure S8e)
Distribution statusNo distribution (2012), product not (yet) placed on the market (2013) (Figure S8f)
Action takenDestruction (Figure S8g)
Ethylene oxide (494)Year2020
Notification typeAlert (Figure S9a)
Product categoryNuts, nut products and seeds (Figure S9b) (sesame seeds)
Origin countryIndia (Figure S9c)
Notified countryThe Netherlands (Figure S9d)
Notification basisCompany’s own check (Figure S9e)
Distribution statusDistribution to other member countries (Figure S9f)
Action takenInforming consignor, informing recipient(s), withdrawal from market, recall from consumers (Figure S9g)
Fipronil (186)Year2017
Notification typeInformation (Figure S10a)
Product categoryEggs and egg product (Figure S10b)
Origin countryItaly (Figure S10c)
Notified countryItaly (Figure S10d)
Notification basisOfficial control in the market (Figure S10e)
Distribution statusDistribution restricted to notifying country (Figure S10f)
Action takenWithdrawal from the market (Figure S10g)
Formetanate (203)Year2012, 2014, 2018–2020
Notification typeBorder rejections (Figure S11a)
Product categoryFruits and vegetables (Figure S11b) (peppers)
Origin countryTurkey (Figure S11c)
Notified countryBulgaria (Figure S11d)
Notification basisBorder control—consignment detained (Figure S11e)
Distribution statusNo distribution (2012), product not (yet) placed on the market (2014, 2018–2020) (Figure S11f)
Action takenPlaced under customs seals (2012), destruction (2014, 2018–2020) (Figure S11g)
Methamidophos (176)Year2002, 2011–2013
Notification typeInformation (2002), border rejection (2011–2013) (Figure S12a)
Product categoryFruits and vegetables (2002, 2013) (Figure S12b) (okra—India)
Origin countryTurkey (2002), India (2011–2012) (Figure S12c)
Notified countryGermany (2002), France (2012) (Figure S12d)
Notification basis(not specified) (2002), border control—consignment detained (2012) (Figure S12e)
Distribution status(not specified) (2002), no distribution (2012) (Figure S12f)
Action taken(not specified), complaint (2002), destruction (2011–2013) (Figure S12g)
Methomyl (260)Year2007–2008, 2010–2013, 2018
Notification typeInformation (2007–2008), border rejection (2010–2013, 2018) (Figure S13a)
Product categoryFruits and vegetables (Figure S13b) (peppers—Turkey)
Origin countryTurkey (2010–2011, 2018), the Dominican Republic (2012) (Figure S13c)
Notified countryBulgaria (2010–2011, 2018), Germany, the Netherlands (2012), France (2013) (Figure S13d)
Notification basisOfficial control in the market (2007–2008), border control—consignment detained (2010–2013, 2018) (Figure S13e)
Distribution statusNo distribution (2010–2013) (Figure S13f)
Action takenDestruction (Figure S13g)
Monocrotophos (159)Year2012–2013
Notification typeBorder rejection (Figure S14a)
Product categoryFruits and vegetables (Figure S14b) (okra)
Origin countryIndia (Figure S14c)
Notified countryThe United Kingdom (Figure S14d)
Notification basisBorder control—consignment detained (Figure S14e)
Distribution statusNo distribution (Figure S14f)
Action takenDestruction (Figure S14g)
Omethoate (223)Year2005–2013, 2018–2019
Notification typeBorder rejection (2009–2013, 2018–2019), information (2005–2013, 2019) (Figure S15a)
Product categoryFruits and vegetables (2008–2013, 2018–2019) (Figure S15b)
Origin countryThailand (2008–2010) (Figure S15c) (aubergines, beans)
Notified countryThe Netherlands (2008, 2010–2011), Germany (2010), France (2013), the United Kingdom (2013, 2019) (Figure S15d)
Notification basisOfficial control in the market (2005–2008, 2010–2011), border control—consignment detained (2009–2013, 2018–2019) (Figure S15e)
Distribution statusNo distribution (2008–2012), product already consumed (2011), product not (yet) placed on the market (2013, 2018–2019) (Figure S15f)
Action taken(not specified) (2007), withdrawal from the market (2009, 2011), destruction (2009–2010, 2013, 2018–2019), inform authorities (2012–2013) (Figure S15g)
Oxamyl (160)Year2007, 2011
Notification typeInformation (2007), border rejection (2011) (Figure S16a)
Product categoryFruits and vegetables (Figure S16b) (peppers)
Origin countryTurkey (Figure S16c)
Notified countryGermany (2007), Bulgaria (2011) (Figure S16d)
Notification basisOfficial control in the market (2007), border control—consignment detained (2011) (Figure S16e)
Distribution statusProduct already consumed (2007), no distribution (2011) (Figure S16f)
Action taken(not specified), no stock left, reinforced checking (2007), destruction, inform authorities, re-dispatch or destruction (2011) (Figure S16g)
Profenofos (143)Year2012–2013
Notification typeBorder rejection (Figure S17a)
Product categoryHerbs and spices (2012), fruits and vegetables (2013) (Figure S17b) (curry, okra)
Origin countryIndia (Figure S17c)
Notified countryFrance (Figure S17d)
Notification basisBorder control—consignment detained (Figure S17e)
Distribution statusNo distribution (Figure S17f)
Action takenDestruction (Figure S17g)
Triazophos (213)Year2012–2013
Notification typeBorder rejection (Figure S18a)
Product categoryHerbs and spices (2012), fruits and vegetables (2012–2013) (Figure S18b) (curry, okra)
Origin countryIndia (Figure S18c)
Notified countryFrance (2012), the United Kingdom (2012–2013) (Figure S18d)
Notification basisBorder control—consignment detained (Figure S18e)
Distribution statusNo distribution (Figure S18f)
Action takenDestruction (Figure S18g)
Table
Table 4. Information on notifications of pesticide residues in the RASFF according to different authors.
Table 4. Information on notifications of pesticide residues in the RASFF according to different authors.
PeriodProduct (Product Category)Pesticide(s)Origin CountryNotifying CountryReference
2002–2015Food of non-animal and animal originNDANDANDA[34]
2002–2019GherkinsOxamylTurkeyNDA[35]
2003–2007Fruits and vegetablesDimethoate, isofenphos-methyl, omethoate, oxamyl, methamidophos, methomyl, monocrotophosNDANDA[36]
2003–2013GrapesCarbendazim, methomyl, oxamylNDANDA[37]
2004–2014Herbs and spicesChlorpyrifos, triazophosNDANDA[38]
2005–2015Fruits and vegetablesNDANDANDA[39]
2006–2013Baby or infant productsNDAThe European UnionNDA[40]
2008–2011Fruits and vegetables, herbs and spicesNDANDANDA[41]
2008–2011Fruits and vegetables, herbs and spices, nuts and nut productsNDANDANDA[42]
2008–2013Fruits and vegetablesNDAAfricaNDA[43]
2009–2020RiceNDAPakistanNDA[44]
before 2011Okra, curry leavesNDAIndiaNDA[32]
2012Fresh pepperNDATurkeyNDA[45]
2012Fruits and vegetablesMonocrotophosIndiaNDA[46]
2013Fruits and vegetablesNDANDANDA[47]
2013–2014Fresh mintCarbendazimNDANDA[48]
2013–2015Fruits and vegetables, spicesNDAIndiaNDA[49]
before 2014Okra, curry leavesNDAIndiaNDA[4]
2014Fruits and vegetablesDichlorvosNigeriaUnited Kingdom[50]
2014–2018Herbs and spicesChlorpyrifosNDANDA[51]
2015–2015CuminNDAIndiaNDA[52]
2015–2020Fruits and vegetablesNDANDANDA[53]
2016Fruits and vegetablesNDATurkeyBulgaria, the Netherlands[54]
2016Black and green teasPropargiteNDANDA[28]
2017EggsFipronilBelgiumBelgium[55]
2017Eggs and egg productsFipronilItalyItaly[56]
2019Fruits and vegetablesChlorpyrifosNDANDA[57]
before 2020OkraNDAIndiaNDA[58]
2020Fruits and vegetablesNDATurkeyBulgaria[59]
2020Sesame seedsEthylene oxideIndiaBelgium[60]
2020Sesame seedsEthylene oxideIndiaThe Netherlands[61]
2020Nuts, nut products and seedsEthylene oxideIndiaGermany, The Netherlands[59]
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Pigłowski, M. Notifications on Pesticide Residues in the Rapid Alert System for Food and Feed (RASFF). Int. J. Environ. Res. Public Health 2022, 19, 8525. https://doi.org/10.3390/ijerph19148525

AMA Style

Pigłowski M. Notifications on Pesticide Residues in the Rapid Alert System for Food and Feed (RASFF). International Journal of Environmental Research and Public Health. 2022; 19(14):8525. https://doi.org/10.3390/ijerph19148525

Chicago/Turabian Style

Pigłowski, Marcin. 2022. "Notifications on Pesticide Residues in the Rapid Alert System for Food and Feed (RASFF)" International Journal of Environmental Research and Public Health 19, no. 14: 8525. https://doi.org/10.3390/ijerph19148525

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop