COBISS Code 1.01
DOI: 10.2478/v10014-012-0006-3
Agrovoc descriptors: malus pumila, apples, lactuca sativa, lettuces, solanum tuberosum, potatoes, pesticides, residues, maximum residue limits, food safety, regulations, integrated pest management, integrated control, plant protection
Agris category code: H10
Pesticide residues in samples of apples, lettuce and potatoes from integrated pest management in Slovenia from 2005-2009
Helena BAŠA ČESNIK1, Špela VELIKONJA BOLTA1, Ana GREGORČIČ1
Received September 05, 2011; accepted Februay 29, 2012. Delo je prispelo 05. septembra 2011, sprejeto 29. februarja 2012.
ABSTRACT
IZVLEČEK
In the period from 2005 to 2009 225 samples of apples, lettuce and potatoes from Slovene producers included in integrated pest management (IPM) were analysed for plant protection product (PPP) residues. The samples were analysed for the presence of more than 200 different active compounds using four analytical methods. In 38.7% of apple samples residues were not detected, 58.6% of apple samples contained residues lower than or equal to Maximum Residue Levels (MRLs) while 2.7% of apple samples exceeded MRLs. In 84.6% of lettuce samples residues were not detected, 12.3% of lettuce samples contained residues lower than or equal to MRLs while 3.1% of lettuce samples exceeded MRLs. In 98.0% of potato samples residues were not detected, 2.0% of potato samples contained residues lower than or equal to MRLs and no potato samples exceeded MRLs. Multiple residues were found only in apples and lettuce. The trend observed during the years was the decrease of sample portion of samples containing multiple residues in apples from 2005 to 2008. The most frequently found active substance in apples and lettuce was dithiocarbamates. In potato only phosalone was found.
Key words: apples, lettuce, potatoes, integrated pest management, plant protection product residues, GC/MS, LC/MS/MS
OSTANKI PESTICIDOV V VZORCIH JABOLK,
SOLATE IN KROMPIRJA V INTEGRIRANI PRIDELAVI V SLOVENIJI V LETIH 2005-2009
V	obdobju od 2005 do 2009 smo na ostanke fitofarmacevtskih sredstev (FFS) analizirali 225 vzorcev jabolk, solate in krompirja slovenskih proizvajalcev vključenih v integrirano pridelavo (IP). Vse vzorce smo analizirali s štirimi analitskimi metodami na prisotnost več kot 200 različnih aktivnih spojin.
V	38,7% vzorcev jabolk ostankov nismo določili, 58,6% vzorcev jabolk je vsebovalo ostanke manjše ali enake maksimalnim dovoljenim količinam ostankov (MRL) medtem ko je 2,7% vzorcev jabolk preseglo MRL vrednosti. V 84.6% vzorcev solate ostankov nismo določili, 12,3% vzorcev solate je vsebovalo ostanke manjše ali enake MRL vrednostim medtem ko je 3,1% vzorcev solate preseglo MRL vrednosti. V 98,0% vzorcev krompirja ostankov nismo določili, 2,0% vzorcev krompirja je vsebovalo ostanke manjše ali enake MRL vrednostim in nobeden vzorec krompirja ni presegel MRL vrednosti. Ostanke dveh ali več aktivnih spojin smo določili le v jabolkih in solati. Trend, ki smo ga opazili tekom let je, da delež vzorcev, ki vsebujejo ostanke dveh ali več aktivnih spojin v jabolkih, pada od leta 2005 do 2008. Najpogosteje najdena aktivna snov v jabolkih in solati je ditiokarbamati. V krompirju smo določili le fosalon.
Ključne besede: jabolka, solata, krompir, integrirana pridelava, ostanki fitofarmacevtskih sredstev, GC/MS, LC/MS/MS
1 Agricultural Institute of Slovenia, Hacquetova ulica 17, SI-1000 Ljubljana, Slovenia, Ph.D.
Acta agriculturae Slovenica, 99 - 1, marec 2012 str. 49 - 56
1 INTRODUCTION
The main objective of conventional farming is elimination of the pest with at least 90% effectiveness, while IPM aims to maintain a population level or balance below the tolerance threshold, intervening only when the population density exceeds an action treshold (Oliva et al., 1999). Unfortunately, conventional farming poses a negative impact on the environment, agriculture, and human health. PPP may kill pests, disease, and weed, but they also end up as residues on our food. The largest negative impact of conventional farming is its contamination of our freshwater supply, soil erosion and decreased soil fertility. PPP also enter the air and can be transported to other areas where no PPPs are used. The PPP use has a negative impact on natural predators, because they do not only kill the targeted pests but also other beneficial organisms. Regular application of PPP ends up breeding a stronger, more resistant community to PPPs (Kaul et al., 2009; Turgut et al., 2011; Vasileiadis et al., 2011)
Concerns about the negative effects of PPPs led to research and promotion of alternative crop production such as IPM.
IPM is a careful consideration of all available plant protection methods and subsequent integration of appropriate measures that discourage the development of populations of harmful organisms and keep the use of PPPs and other forms of intervention to levels that are economically and ecologically justified and reduce or minimise risks to human health and the environment (Vasileiadis et al., 2011). In other words, the IPM is a system that includes measures required for a good agricultural practice, for the safety and hygiene of workers, for the safety of products, for the full traceability of measurements and for the preservation of the environment (Danis et al., 2011).
In spite of that, IPM itself is not a guaranty that PPP residues will not be found in the environment. Also PPP residues used in IPM are found in water, soil and are transported to other areas. But with measures taken in IPM their content in water, soil and air will be better controlled and/or reduced to minimum required for food production than in conventional farming.
In Slovenia the PPPs allowed in IPM are yearly published in the Technical Guidelines for IPM in fruit, grape, vegetables and field crop growing. The main benefits are lower incidence and lower levels of PPP residues in agricultural products. To control this type of
production surveillance monitoring is required. This is why Agricultural Institute of Slovenia determined PPP residues in apple, lettuce and potato of the Slovene producers included in IPM prior to the market in accordance to the Slovenian legislation (RS 2004a, 2004b, 2007a, 2007b, 2009).The samples were taken randomly in eight production areas in Slovenia: Celje, Koper, Kranj, Nova Gorica, Novo mesto, Murska Sobota, Maribor, and Ljubljana. Apples, lettuce and potatoes were chosen because they are the most frequently consumed agricultural products in Slovenia (the Slovene Food Basket has not yet been demarcated). The results are intended to:
-	Determine the conformity with the legally prescribed MRLs
-	Determine the conformity of the production with good agricultural practice
-	Determine the sources and/or causes of residues found
For the monitoring purposes quick and reliable multiresidual methods which enable simultaneous determination of a wide spectrum of active substances are needed. Extraction is performed by ethylacetate (Berrada et al., 2006; Čajka and Hajšlova, 2004; Ferrer et al., 2005; Sharif et al., 2006), acetonitrile (method also known as QuEChERS method) (Lehotay, 2007; Maštovska et al., 2005) or acetone (Diez et al., 2006; Pizzutti et al., 2009; Stan and Linkerhagner, 1996). We used the multiresidual method in which extraction was performed with acetone, petroleumether and dichlorometane and determination with gas chromatograph coupled to mass spectrometer (GC-MS) (Baša Cesnik and Gregorčič, 2003; Baša Česnik et al., 2006). The same extraction procedure was also used for another multiresidual method in which liquid chromatography was coupled to tandem mass spectrometry (LC/MS/MS) (Bossi et al., 2002; Ortelli et all., 2004; Lehotay et al., 2005). Single residue methods were also used for the determination of maneb group and benzimidazoles. Extraction of the maneb group (dithiocarbamates) was performed with isooctane and determination with GC-MS (Baša Česnik and Gregorčič, 2006). Benzimidazoles were extracted by acetone, petroleumether and dichloromethane and determined by LC with UV and fluorescent detector (van Zoonen, 1996).
Pesticide residues in samples of apples, lettuce and potatoes from integrated pest management in Slovenia from 2005-2009
2 MATERIALS AND METHODS
	2005	2006	2007	2008	2009	sum
apples	15	30	37	29	I	111
lettuce	12	12	17	12	12	65
potatoes	3	12	6	8	20	49
From 2005 to 2009, 225 samples of apples, lettuce and potatoes from IPM were analysed. The sampling is presented in Table 1.
Table 1. Number of IPM samples of apple, lettuce and potato.
For the determination of PPP residues we used four different testing methods:
-	method for the determination of benzimidazoles: tiabendazol and the sum of benomyl and carbendazim (in 2005-2007) (van Zoonen, 1996),
-	method for the determination of the maneb group: maneb, mancozeb, metiram, propineb, thiram, ziram and zineb, the sum is expressed as carbon disulfide (in the years 2005-2009) (Baša Česnik and Gregorčič, 2006)
-	multiresidual GC/MS method (in 2005-2009) (Baša Česnik and Gregorčič, 2003; Baša Česnik et al., 2006)
In 2005 the scope was: acephate, aldrin, azinphos-methyl, azoxystrobin, bifenthrin, bromopropylate, bupirimate, captan, carbaryl, carbofuran, chlorothalonil, chlorpropham, chlorpyriphos, chlorpyriphos-methyl, cyhalotrin-lambda, cypermethrin, cyprodinil, DDT, deltamethrin, diazinon, dichlofluanid, dimethoate, diphenylamine, endosulfan, endrin, fenitrothion, fenthion, fludioxonil, folpet, HCH-alpha, heptachlor, heptenophos, imazalil, iprodione, kresoxim-methyl, lindane, malathion, mecarbam, metalaxyl, methamidophos, methidathion, myclobutanil, omethoate, oxydemeton-methyl, parathion, permethrin, phorate, phosalone, pirimicarb, pirimiphos-methyl, procymidone, propargite, propyzamide, pyridaphenthion, pyrimethanil, quinalphos, spiroxamine, thiabendazole, tolclofos-methyl, tolylfluanid, triadimefon triazophos, triadimenol and vinclozolin.
In 2006 the scope was extended with the following active substances: cyromazine, penconazole, trifloxystrobin.
In 2007 the scope was extended with the following active substances: boscalid, dichlorvos, fenamidone, quinoxyfen, tebuconazole. Cyromazine was removed.
In 2008 the scope was extended with the following active substances: carboxin, chloridazon, clomazone, cyproconazole, diniconazole, fenbuconazole, indoxacarb, metconazole, methacrifos, metribuzin.
In 2009 the scope was extended with the following active substances: acrinathrin, dazomet, desmethylpirimicarb, dimethachlor, esfenvalerate, fenvalerate, flonicamid, fluquinconazole,	HCH-betha,	HCH-deltha,
hexachlorobenzene, metalaxyl-M, metrafenone, oxadixyl, parathion-methyl, profenofos, quinoclamine, tetraconazole, tetradifon.
- multiresidual LC/MS/MS method (in 2006-2009) (Bossi et al., 2002; Ortelli et al., 2004; Lehotay et al., 2005).
In 2006 the scope of analyses was: aldicarb, bentazone, cymoxanil, difenoconazole, fenazaquin, fenhexamid, fluroxypyr, imidacloprid, methiocarb, methomyl, phoxim, pymetrozine, spirodiclofen, tebufenozide, thiacloprid, thiamethoxam and zoxamide.
In 2007 the scope was extended with the following active substances: acetamiprid, amidosulfuron, benalaxyl, bitertanol, clofentezine, cyromazine, dimethomorph, epoxiconazole, ethofumesate, famoxadone, fenpropidin, fenpropimorph, fenpyroximate, flufenacet, fluquinconazole, hexythiazox, iprovalicarb, lufenuron, metosulam, pendimethalin, prochloraz, propamocarb, propiconazole, pyridate, spinosad, terbuthylazine, thiophanate-methyl and trichlorfon.
In 2008 the scope was extended with the following active substances: aldicarb sulfon, aldicarb sulfoxid, buprofezin, carbendazim, clopyralid, clothianidin, cycloxydim, desmedipham, flutriafol, foramsulfuron, iodosulfuron-methyl-sodium, isoxaflutole, linuron, malaoxon, metamitron, metazachlor, methiocarb sulfon, methiocarb sulfoxid, methoxyfenozide, napropamide, phenmedipham, prosulfocarb, prosulfuron, pyraclostrobin, rimsulfuron, tetraconazole, thifensulfuron-methyl, thiodicarb, triasulfuron, trifluralin and triflusulfuron-methyl.
In 2009 the scope was extended with the following active substances: 2,4-D, amitrole, azinphos-ethyl, beflubutamid, benalaxyl M, bromoxynil, carbosulfan, chlortoluron, cyazofamid, demeton-S-methyl sulphone, dichloprop-P, diflufenican, dimethenamid-P, fenarimol, fenoxaprop-P-ethyl, fenoxycarb, fenthion sulfone, fenthion sulfoxide, fipronil, florasulam, fluazifop-P-butyl, fluazinam, fluorochloridone, flusilazole, hexaconazole, isoproturon, mandipropamid, MCPA, monocrotophos, nicosulfuron, oxamyl, paraoxon-methyl, phorate sulfone, phorate sulfoxide, propaquizafop, pyrazophos, teflubenzuron, tribenuron-methyl and trinexapac-ethyl. Fluquinconazole and tetraconazole were removed.
The trueness of testing methods was verified by recoveries which had to be from 70% to 120%.
The trueness was additionally verified by participation in the French inter-laboratory proficiency testing scheme BIPEA (Bureau interprofessionnel d'etudes analytiques) and CRL European Proficiency Tests.
In January 2005 determination of PPP residues was accredited by the French accreditation body COFRAC.
3 RESULTS AND DISCUSSION
During the period from 2005 to 2009, 225 IPM samples and sample portions above MRLs are presented in Table were analysed. Sample portions below the reporting 2. level (RL), sample portions below or equal to MRLs
Table 2. Sample portions of PPP residues for each analysed matrix from 2005 to 2009
	Sample portion <RL (%)	Sample portion <MRL (%)	Sample portion >MRL (%)
apples	38.7	58.6	2.7
lettuce	84.6	12.3	3.1
potatoes	98.0	2.0	0.0
The highest portion of PPP residues exceeding MRLs was found in lettuce (3.1%). The highest portion of PPP residues found but not exceeded, i.e. 58.6%, was found in apples. The farmers have to protect apples against rot,
mould and insects otherwise they would not be able to grow them. Potatoes were an agricultural product with very little residues found.
Annual results for apples are presented in Table 3.
Table 3. PPP residues in apple samples for the period from 2005 to 2008
	Sample portion <RL (%)	Sample portion <MRL (%)	Sample portion >MRL (%)
2005	0.0	93.3	6.7
2006	6.7	86.7	6.7
2007	10.8	89.2	0.0
2008	27.6	72.4	0.0
The highest percentage of apple samples with detected but not exceeding PPP residues was found in 2005 (93.3%) and the lowest in 2008 (72.4%). The highest MRL exceedances in apple samples were found in 2005 and 2006 (6.7%). The trend observed during the years
was exceedances that were no longer determined at the end.
Annual results for lettuce are presented in Table 4.
Table 4. PPP residues in lettuce samples for the period from 2005 to 2009
	Sample portion <RL (%)	Sample portion <MRL (%)	Sample portion >MRL (%)
2005	100.0	0.0	0.0
2006	91.7	8.3	0.0
2007	76.5	17.6	5.9
2008	83.3	8.3	8.3
2009	75.0	25.0	0.0
In comparison to apples lettuce is an agricultural product with less PPP residues found. The highest percentage of lettuce samples with detected but not exceeding PPP residues was found in 2009 (25.0%) and the lowest in 2005 (0.0%). The highest MRL exceedances in lettuce samples were found in 2008 (8.3%).
The least PPP residues were found in potato. In 2005, 2007, 2008 and 2009 no residues were found in potato
samples. In 2006 the percentage of samples with determined but not exceeding PPP residues was 8.3%.
Multiple residues were found only in apples and lettuce. The results for apples are presented in Figure 1. The highest number of active substances found per one apple sample was 7 in 2006. The trend observed during the years was that the sample portion of samples containing multiple residues in apples decreased from 2005 to 2008
Pesticide residues in samples of apples, lettuce and potatoes from integrated pest management in Slovenia from 2005-2009 in spite of the larger number of active substances sought.
2008
2007
2006
2005

mvpvàpm—f'-------
mmmàm
mmmmm*.......}
20
40
60
Sample portion (%)
80
100
□ 2 a.s.
□ 3 a.s.
14 or more a.s.
0 sum
0
Figure 1.: Multiple residues found in apples from 2001 to 2008
In lettuce, maximum 2 active substances were found per Active substances found in apples are presented in sample: in 2007 in 5.9% of samples and in 2009 in Table 5. The most frequently found active substance 16.7% of samples.	was dithiocarbamates (maneb group).
Table 5. Active substances found in apples in the years from 2005 to 2008
	Sample portion (%)				
Active substance	2005	2006	2007	2008	average
Acetamiprid	n.a.	n.a.	2.7	24.1	7.2
Bitertanol	n.a.	n.a.	5.4	n.d.	1.8
Boscalid	n.a.	n.a.	8.1	31.0	10.8
Captan	33.3	26.7	27.0	17.2	25.2
Chlorpyrifos	26.7	16.7	40.5	13.8	25.2
Chlorpyrifos-methyl	6.7	n.d.	n.d.	n.d.	0.9
Cyprodinil	13.3	3.3	2.7	n.d.	3.6
Diazinon	40.0	30.0	24.3	n.d.	21.6
Difenoconazole	n.a.	n.d.	n.d.	3.4	0.9
Diphenylamine	n.d.	3.3	n.d.	n.d.	0.9
Dithiocarbamates	93.3	73.3	32.4	37.9	53.2
Fenazaquin	n.a.	3.3	n.d.	n.d.	0.9
Fluquinconazole	n.a.	n.a.	n.d.	3.4	0.9
Folpet	6.7	n.d.	n.d.	n.d.	0.9
Lufenuron	n.a.	n.a.	5.4	n.d.	1.8
Methoxyfenozide	n.a.	n.a.	n.a.	13.8	3.6
Phosalone	20.0	46.7	45.9	n.d.	30.6
Pirimicarb	6.7	n.d.	n.d.	3.4	1.8
Pyraclostrobin	n.a.	n.a.	n.a.	31.0	8.1
Pyrimethanil	n.d.	20.0	10.8	10.3	11.7
Spirodiclofen	n.a.	16.7	21.6	10.3	14.4
Tebufenozide	n.a.	3.3	n.d.	10.3	3.6
Thiacloprid	n.a.	6.7	2.7	6.9	4,5
Tolylfluanid	73.3	30.0	n.d.	n.d.	18.0
Trifloxystrobin	n.a.	n.a.	2.7	n.d.	0.9
n.a. means not analysed, n.d. means not detected
PPPs allowed in IPM of apples, which contained active presented in Table 6. substances from maneb group in years 2006-2008 are
Table 6. PPPs allowed in IPM of apple which contained active substances from maneb group from 2006 to 2008
year	PPP	active substance
2006	Bakreni dithane	mancozeb
2006 - 2008	Dithane Dg neotec	mancozeb
2006-2008	Dithane M-45	mancozeb
2006-2008	Kor DG	mancozeb
2006	Mancozeb 80 WP	mancozeb
2006	Mazeb	mancozeb
2006-2007	Penncozeb 75 DG	mancozeb
2006-2007	Penncozeb 80 WP	mancozeb
2006-2008	Polyram DF	metiram
2006-2008	Thiram 80 WG	thiram
2006-2007	Triscobal DG	ziram
2006-2007	Ziram 76 WG	ziram
Active substances found in lettuce are presented in Table 6. The most frequently found active substance was dithiocarbamates (maneb group).
Table 7. Active substances found in lettuce in the years from 2005 to 2009
	Sample portion (%)					
Active substance	2005	2006	2007	2008	2009	average
Chlorothalonil	n.d.	n.d.	5.9	n.d.	n.d.	1.5
Difenoconazole	n.a.	n.d.	5.9	n.d.	n.d.	1.5
Dithiocarbamates	n.d.	8.3	5.9	8.3	8.3	6.2
Iprodione	n.d.	n.d.	n.d.	n.d.	16.7	3.1
Pendimethalin	n.a.	n.a.	n.d.	8.3	n.d.	1.5
Propyzamide	n.d.	n.d.	5.9	n.d.	n.d.	1.5
Thiamethoxam	n.a.	n.d.	5.9	n.d.	16.7	4.6
n.a. means not analysed, n.d. means not detected
PPPs allowed in IPM of lettuce, which contained active substances from maneb group in years 2006-2009 are presented in Table 8.
Table 8. PPPs allowed in IPM of lettuce which contained active substances from maneb group from 2006 to 2009
year	PPP	active substance
2006-2009	Aliette flash	metiram
2006-2009	Aviso DF	mancozeb
2006-2009	Polyram DF	metiram
2006-2009	Ridomil gold MZ Pepite	mancozeb
In potato only one active substance was found: phosalone in one sample in 2006 (8.3% in 2006 and average for 2005-2009 2.0%). Only one PPP with active substance phosalone was allowed in IPM of potatoes in 2006 and 2007: Zolone.
Active substances that exceeded MRLs werethe following: tolylfluanid in 2005 (1 apple sample, residue=0.73 mgkg-1, MRL=0.21 mgkg-1) and in 2006 (2 apple samples, residue=0.24 and 0.26 mgkg-1, MRL=0.21 mgkg-1), chlorothalonil in 2007 (1 lettuce sample, residue=0.05 mgkg-1, MRL=0.01 mgkg-1) and
Pesticide residues in samples of apples, lettuce and potatoes from integrated pest management in Slovenia from 2005-2009
pendimethalin in 2008 (1 lettuce sample, residue= 0.06 mgkg-1, MRL=0.05 mgkg-1).
Considering the non-conformities in IPM (the use of PPP which was not allowed in IPM) we observed only one violation: in 2005 the use of PPP with the active substance folpet on apples (1 sample).
4 CONCLUSIONS
The levels of PPP residues in IPM samples of agricultural products in Slovenia in 2005 to 2009 do not give any cause for alarm. We compared our results with those of monitoring of PPP residues in the products of plant origin in 27 European Union Member States (EU MS) and 2 European Free Trade Association (EFTA) States	(Norway	and	Iceland)
(http://www.efsa.europa.eu/cs/) in 2007 (apples and lettuce) and in 2008 (potatoes). The type of production
in EU is unknown. In EU the MRL exceedances in apples in 2007 match the average exceedances in IPM apples in Slovenia from 2005 to 2008 (2.7%). In EU, the MRL exceedances in lettuce in 2007 (2.9%) are slightly lower than the average exceedances in IPM lettuce in Slovenia from 2005 to 2009 (3.1%). In EU, the MRL exceedances in potatoes in 2008 (0.5%) are higher than the average exceedances in IPM potatoes in Slovenia from 2005 to 2009 (0.0%).
5 ACKNOWLEGEMENTS
The authors would like to thank those who contributed to the work: Ms. Mateja Fortuna and other co-workers at the Central Laboratories of Agricultural Institute of Slovenia. For financial support we express our thanks to
the Phytosanitary Administration of the Republic of Slovenia (MAFF) and Inspectorate of the Republic of Slovenia for Agriculture, Forestry and Food (MAFF).
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