Evaluation of Endocrine Disrupting Compounds Migration in

Jul 22, 2017 - (4, 7-11). Although the migration of plasticizers and monomers to real food samples for human consumption has been studied by some auth...
0 downloads 10 Views 1MB Size
Subscriber access provided by University of Florida | Smathers Libraries

Article

Evaluation of Endocrine Disrupting Compounds Migration in Household Food Containers under Domestic Use Conditions Jorge Sáiz, and Belén Gomara J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.7b02479 • Publication Date (Web): 22 Jul 2017 Downloaded from http://pubs.acs.org on July 23, 2017

Just Accepted “Just Accepted” manuscripts have been peer-reviewed and accepted for publication. They are posted online prior to technical editing, formatting for publication and author proofing. The American Chemical Society provides “Just Accepted” as a free service to the research community to expedite the dissemination of scientific material as soon as possible after acceptance. “Just Accepted” manuscripts appear in full in PDF format accompanied by an HTML abstract. “Just Accepted” manuscripts have been fully peer reviewed, but should not be considered the official version of record. They are accessible to all readers and citable by the Digital Object Identifier (DOI®). “Just Accepted” is an optional service offered to authors. Therefore, the “Just Accepted” Web site may not include all articles that will be published in the journal. After a manuscript is technically edited and formatted, it will be removed from the “Just Accepted” Web site and published as an ASAP article. Note that technical editing may introduce minor changes to the manuscript text and/or graphics which could affect content, and all legal disclaimers and ethical guidelines that apply to the journal pertain. ACS cannot be held responsible for errors or consequences arising from the use of information contained in these “Just Accepted” manuscripts.

Journal of Agricultural and Food Chemistry is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.

Page 1 of 28

Journal of Agricultural and Food Chemistry

1

Evaluation of Endocrine Disrupting Compounds Migration in Household Food Containers under Domestic

2

Use Conditions

3 4

Jorge Sáiz, Belen Gómara*

5 6

Institute of General Organic Chemistry, Spanish National Research Council (IQOG-CSIC). Calle Juan de la

7

Cierva, 3, 28006 Madrid, Spain.

8 9

*Corresponding author:

10

Tel: +34 91 5622900

11

Fax: +34 91 5644853

12

E-mail address: [email protected] (B. Gómara).

13 14 15 16

1 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

17

Page 2 of 28

ABSTRACT

18 19

Plasticizers and plastic monomers are commonly used in packaging. Most of them act as endocrine

20

disrupters and are susceptible to migrate from the packaging to the food. We evaluated the migration of

21

endocrine disrupting compounds from three different household food containers to four food simulants

22

under different domestic treatments and for different periods of time, with the aim of reproducing real

23

domestic conditions. The results showed that the migration to the simulants increased with the storage

24

time, up to more than 50 times in certain cases. The heating power seemed to increase the migration

25

processes (up to more than 30 times) and reusing containers produced an increase or decrease of the

26

concentrations depending on the container type and the simulant. The concentrations found were lower

27

than other concentrations reported (always less than 4000 pg/mL, down to less than 20 pg/mL), which

28

might be a consequence of the domestic conditions used.

29 30

Keywords: endocrine disrupting compounds; migration; food containers; food simulants; UHPLC-MS/MS.

31

2 ACS Paragon Plus Environment

Page 3 of 28

32

Journal of Agricultural and Food Chemistry

INTRODUCTION

33 34

The presence of contaminants in food due to migration processes from packaging material is a well-known

35

issue1,2. These migration processes have been proved to occur in many different packaging of different

36

materials, such as recycled paperboard packaging,2 baby bottles,3 canned foods,4,5 or water bottles,6 among

37

many others. Nowadays, the majority of food packaging used in food industry and for home-cooked meals

38

are made of organic polymers, such as polyethylene (PE) bags, polyethylene terephthalate (PET), or

39

polypropylene (PP). In the manufacturing of these plastics, plasticizers are used as additives, which provide

40

certain characteristics to the final product, such as plasticity, viscosity, transparency, thickness, or increased

41

durability. Most of these plasticizers are phthalates, which can migrate to food and are considered to act as

42

endocrine disrupters.1 Besides, other plastic monomers, such as bisphenols and bisphenol derivatives, are

43

being used as constituent of some plastics and epoxy resins and could, therefore, also migrate to the food.

44

These compounds are also not exempt from controversy and their migration processes have also been

45

studied.4,7-11

46 47

Although the migration of plasticizers and monomers to real food samples for human consumption has

48

been studied by some authors,12-14 food simulants are commonly used in order to simplify testing and for

49

regulatory compliance purposes, since the simulants are less complex than foods.15 Moreover, their use

50

allows to easily compare results obtained in different laboratories. According to the European Union,16 food

51

simulants mimic the use of foods of different nature, such as oily food, alcoholic drinks, foods with

52

hydrophilic character, or foods with specific pH values. Commonly, migration tests are performed with

53

samples consisting of small pieces of the plastic packaging of study, which are totally immersed in the food

54

simulant. Some authors17 used four different food simulants in order to study the migration of sixteen

55

phthalic acid esters. The experimental setup consisted of cutting a piece of plastic from bottles, bags, or

56

films and soaking them with the selected simulants for a pre-defined time and temperature. Similarly,

57

other authors18 performed a study of plasticizer migration with pieces of bottles and total immersion in

58

food simulants. Another work19 studied the migration of phthalates from cork stoppers also by soaking the

3 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 4 of 28

59

corks in a food simulant. Other groups20-23 cut cling film in pieces, which were added to the selected food

60

simulant. The total immersion test was also performed10 for the evaluation of the migration of some

61

plasticizers from plastic bottles, caps, and septa to food simulants. Although the total immersion test is

62

widely performed for the evaluation of chemical migration to food, it does not faithfully reproduce real

63

storing and/or cooking conditions, since both sides of the container are in contact with the simulant and

64

because, frequently, the surface-to-volume ratio differs from real storage situations. In these regards, other

65

authors have focused their studies in reproducing specific storage conditions using the entire container for

66

it. Plastic baby bottles have attracted the interest of several authors, who studied bottles of different

67

materials filled with a milk simulant,24-27 while other food containers, such as cans, tetra-packs, or yogurt

68

containers have been studied less frequently.9 However, there is still a need for more tests that emulate

69

certain uses of specific food containers. Regarding the storage conditions, some authors kept the samples

70

at high temperatures, up to 121 ºC, in order to accelerate the experiments.19,21,22,28,29 Other studies also

71

used elevated temperatures following the indications stablished in ISO 10106,9,17,19,20,23 which simulate

72

storage at room temperature for indefinite time,30 while other authors used a combination of high

73

temperatures and long periods of time, such as 1.5 years at 40 ºC.31 Although these situations simulate

74

extreme conditions and are of interest in certain cases, they hardly simulate real domestic conditions of

75

food storage or cooking, such as freezing or heating.

76 77

While plastic baby bottles have been widely studied9, 24-27 for migration tests, in homes one of the most

78

used food packaging are household food containers. They are used to store food in the refrigerator or in

79

the freezer and also to transport food, for example to the work place. Household food containers are also

80

frequently used to heat the food and they are repeatedly reused over time. While the effects of these

81

preservation and cooking actions are relatively unknown in terms of plasticizer and monomer migration,

82

the possible adverse effects of these practices on health has become a growing concern for society. There

83

exist, in fact, the general idea that food should not be heated in the food container and that quality food

84

containers should be used in order to avoid “bad” plastics. Actually, there is a big market for household

85

food containers, which offer many types of containers. The user can purchase food containers of different

4 ACS Paragon Plus Environment

Page 5 of 28

Journal of Agricultural and Food Chemistry

86

materials at very different prices, from cheap disposable containers made of plastic to very expensive glass

87

food containers. The decision on which product will be purchased will depend on economic aspects but

88

also on health concerns, based on the prejudices of the customer.

89 90

In view of this discussion, it seems important to perform new studies on the endocrine disrupting

91

compound (EDC) migration. For this reason, present paper is focused on commercially available household

92

food containers, which have scarcely been studied previously, instead of industrial packaging materials

93

such as plastic bottles, cans, stoppers, etc. Besides, the migration conditions propose in this work mimic

94

conventional domestic storing and cooking conditions instead of using accelerated conditions based on

95

high temperatures and long periods of time. Therefore, the aim of this work was to evaluate the plasticizer

96

and monomer migration from different types of household food containers to food simulants of varied

97

natures under specific conditions that simulate real situations at home, depending on different storage

98

type, times, and cooking processes. The EDCs selected for the study were dimethyl phthalate (DMP), 1,

99

diethyl phthalate (DEP), 2, dibutyl phthalate (DBP), 3, butyl benzyl phthalate (BBP), 4, diethyl hexyl

100

phthalate (DEHP), 5, and di-iso-nonyl phthalate (DiNP), 6, bisphenol A (BPA), 7, bisphenol B (BPB), 8,

101

bisphenol F (BPF), 9, bisphenol A diglycidyl ether (BADGE), 10, bisphenol F diglycidyl ether (BFDGE), 11,

102

BADGE·HCl, 12, BADGE·H2O, 13, BADGE·HCl·H2O, 14, and BADGE·2H2O, 15. In addition, three different food

103

containers (i.e. hermetic semi-disposable containers, BPA-free hermetic containers, and glass hermetic

104

containers) were also investigated.

105 106

MATERIAL AND METHODS

107 108

· Reagents and standards

109 110

Native standards of dimethyl phthalate (DMP), 1, diethyl phthalate (DEP), 2, dibutyl phthalate (DBP), 3,

111

butyl benzyl phthalate (BBP), 4, diethyl hexyl phthalate (DEHP), 5, di-iso-nonyl phthalate (DiNP), 6,

112

bisphenol A (BPA), 7, bisphenol B (BPB), 8, bisphenol F (BPF), 9, bisphenol A diglycidyl ether (BADGE), 10,

5 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 6 of 28

113

bisphenol F diglycidyl ether (BFDGE), 11, BADGE·HCl, 12, BADGE·H2O, 13, BADGE·HCl·H2O, 14, and

114

BADGE·2H2O, 15, were supplied by AccuStandard (New Haven, CT,). Chemical structures are gathered in

115

Figure 1.The isotopically labeled standards DMP-D4, DEP-D4, DBP-D4, BBP-D4, DEHP-D4, and BPA-13C12 were

116

supplied by Cambridge Isotope Laboratories (Andover, MA).

117 118

Water, acetonitrile, ethanol, and methanol, all of LC–MS Ultra CHROMASOLV® grade, formic acid, acetic

119

acid, and ammonium formate (purity ≥ 99.0%) were supplied by Sigma-Aldrich (St. Louis, MO).

120 121

· Apparatus

122 123

The ultra-high performance liquid chromatography-tandem mass spectrometry (UHPLC–MS/MS)

124

experiments were carried out in a UPLC Acquity system (Waters, Milford, MA) coupled to a Xevo TQ-S triple

125

quadrupole mass spectrometer (Waters) using an electrospray ionization (ESI) interface. A 2.1 mm × 50 mm

126

i.d., 1.7 µm, Acquity UPLC® BEH Phenyl column (Waters) was used as separation column and a 2.1 mm × 30

127

mm i.d., 1.7 µm, Kinetex C18 delay column (Phenomenex, Torrance, CA) was placed between the LC pump

128

and the injection valve, in order to retard the phthalates coming from the mobile phase and separate them

129

from the analytical peaks. Nitrogen (99.5% purity) was used as desolvation and cone gases for the MS

130

experiments, at 16.7 L/min and 2.5 L/min, respectively, and argon (99.999% purity) was used as collision

131

gas (0.17 mL/min). The ESI source was operated in the fast polarity switching mode. Phthalates, BFDGE,

132

BADGE, and derivatives were detected in the positive mode, while BPA, BPB, and BPF were recorded in the

133

negative mode. Optimization and quantitative analysis were carried out in the multiple reaction monitoring

134

(MRM) mode, using two precursor-product ion transitions for each compound. The most intense ion of the

135

ESI spectra of each analyte was selected as precursor ion. After that, the two most intense product ions

136

formed at their optimum collision energies were chosen, obtaining the two most abundant ion transitions.

137

The most abundant transition was used for quantitative purposes and the second most abundant one for

138

confirmatory purposes. The compounds, along with their retention times, ion transitions, transition ratios,

139

optimized collision energies, and polarities are shown in Table 1. The instrumental determination of DMP,

6 ACS Paragon Plus Environment

Page 7 of 28

Journal of Agricultural and Food Chemistry

140

DEP, DBP, BBP, DEHP, and BPA was already optimized,32 while the instrumental conditions for DiNP, 6, BPB,

141

8, BPF, 9, BADGE, 10, BFDGE, 11, BADGE·HCl, 12, BADGE·H2O, 13, BADGE·HCl·H2O, 14, and BADGE·2H2O, 15,

142

were optimized and characterized in this work. The first transition indicated in the table corresponds to the

143

quantitative transition and the second one to the confirmatory transition. The value of dwell time used

144

during the analysis was 0.001 s for all analytes.

145

The determinations of pH values were carried out using a pH meter that was calibrated using aqueous

146

buffers of pH 4.01, 7.00, and 9.21. Values of pH were taken in aqueous solution.

147

The confirmation of the nature of the plastic containers was carried out with a Spectrum One FT-IR

148

Spectrometer (Perkin Elmer, Shelton, CT) using a Universal Attenuated Total Reflectance (ATR) sampling

149

accessory scanning from 4000 to 650 cm-1 with a resolution of 4 cm-1.

150 151

· Migration tests and samples

152 153

Three different types of household food containers were purchased in a local supermarket (Madrid, Spain)

154

and used for the evaluation of EDC migration to food simulants: hermetic semi-disposable containers, BPA-

155

free hermetic containers, and glass hermetic containers. The food containers were washed with soap and

156

warm water before their first use, according to the manufacturers’ recommendations for their domestic

157

use. Then, they were rinsed with ultrapure water three times. Four different food simulants (A, B, C, and

158

D1) were employed, according to the Official Journal of the European Union.16 Simulant A consisted of

159

ethanol 10% (v/v), simulant B was prepared with acetic acid 3% (w/v), simulant C was ethanol 20% (v/v),

160

and simulant D1 consisted of ethanol 50% (v/v), all of them in water. All the simulants were daily prepared

161

and a volume of 250 mL of each simulant was introduced in each household food container, which were

162

then stored or treated under different experimental conditions, according to Table 2. Different sets of food

163

containers were prepared: each set was composed of three different containers (one semi-disposable, one

164

BPA-free, and another one made of glass) and each type of container was filled with the four simulants

165

described above, making a total of 12 different containers per set. Each set was kept in the refrigerator at 4

166

ºC for 1, 3, and 7 d, respectively. Another set of food containers was stored in the freezer at -18 ºC for 1, 4,

7 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 8 of 28

167

and 12 w, respectively. The experiments of heating in a microwave were as follows. The food containers

168

were heated for 2 min at 800 W. Then, each food container was heated for 1 min more at 800 W. This set

169

of food containers was reused in the same conditions (2 min + 1 min at 800 W). One more set of household

170

food containers was prepared and kept in the freezer for 1 w. Then, the defrosting of their contents was

171

carried out in a microwave at 180 W for 5 min, according to the manufacturer’s indications. A total of 132

172

experiments were carried out. After the treatments, 1 mL of the simulants were transferred to glass vials

173

for UHPLC and a volume 20 µL of a solution of 5 mg/L of the isotopically labeled standards was added to

174

the vial. The vials were kept at -18 ºC until their analysis and each sample was injected in the

175

chromatographic system without any further pre-treatment. Blank samples were prepared every day of

176

sample preparation and the EDC signals (if any) were subtracted from the signal of the samples.

177 178

RESULTS AND DISCUSSION

179 180

· MRM method development and analytical characterization

181 182

As previously mentioned, the instrumental determination of DMP, DEP, DBP, BBP, DEHP, and BPA was

183

already optimized and characterized previously,32 so here the same procedure was followed for DiNP, 6,

184

BPB, 8, BPF, 9, BADGE, 10, BFDGE, 11, BADGE·HCl, 12, BADGE·H2O, 13, BADGE·HCl·H2O, 14, and

185

BADGE·2H2O, 15, optimization. Two different ion transitions were selected for each analyte, in order to use

186

the most abundant as the quantitative transition and the other transition as the confirmatory one. In the

187

case of bisphenol derivatives (BADGE, 10, BFDGE, 11, BADGE·HCl, 12, BADGE·H2O, 13, BADGE·HCl·H2O, 14,

188

and BADGE·2H2O, 15), ammonium adducts were selected as precursor ions for showing higher intensities,

189

as experienced previously.33 The energy in the collision cell was optimized for all the transitions

190

independently, in order to gain in signal intensity. First, the energies were studied in the range from 5 to 30

191

eV (5, 10, 15, 20, 25, and 30 eV). Then a fine optimization was done around the optimal energy in a range of

192

10 eV, one by one (Table 1). Two detection windows were programmed for different groups of analytes,

193

according to their retention times, in order to enhance the global sensitivity of the analysis. The first

8 ACS Paragon Plus Environment

Page 9 of 28

Journal of Agricultural and Food Chemistry

194

detection window was from 0 to 2.3 min and included DMP, 1, BPF, 9, and BADGE·2H2O, 15. The second

195

window included the compounds eluted between 2.1 and 6.0 min and included DEP, 2, DBP, 3, BBP, 4,

196

DEHP, 5, DiNP, 6, BPA, 7, BPB, 8, BADGE, 10, BFDGE, 11, BADGE·HCl, 12, BADGE·H20, 13, and

197

BADGE·HCl·H2O, 14.

198

As previously reported,32 once the MRM method was developed for DiNP, 6, BPB, 8, BPF, 9, and bisphenol

199

derivatives, 10-15, it was characterized in terms of precision, instrumental limits of detection and

200

quantitation (iLODs and iLOQs), and linear dynamic ranges. Precision was evaluated at two different levels,

201

the repeatability (calculated as the relative standard deviation, RSD (%), of three consecutive injections)

202

and the intermediate precision (calculated as the RSD of four injections carried out on different days

203

covering two different weeks), at three different concentration levels, i.e. 5, 50, and 500 pg on column for

204

all the compounds except DiNP, 6, (50, 500, and 5000 pg on column) and BADGE·HCl·H2O, 14, (10, 100, and

205

1000 pg on column). RSD values were lower than 12% and 16% for repeatability and intermediate

206

precision, respectively, except in the case of DiNP, 6, BADGE·HCl, 12, and BADGE·HCl·H2O, 14, which RSD

207

values were quite higher. iLOD and iLOQ calculations were based on the measure of the standard deviation

208

(sb) of the signal of a standard in which the analytes are spiked at a concentration close to iLOQ and the

209

slope of the calibration equation for each compound (m) using the formulas 3sb/m and 10sb/m for iLOD and

210

iLOQ, respectively.32 iLOD values were between 0.12 and 2.2 pg on column, for all the compounds

211

characterized, except for BADGE·HCl·H2O, 14, and DiNP, 6, which presented higher iLOD (6.4 and 12 pg on

212

column, respectively). Dynamic ranges were tested using nine calibration points in the interval from 5 to

213

2500 pg on column, and different linear ranges were observed for the different compounds. Calibration

214

curves adjusted to a linear fit between 5 and 500 pg on column for all the compounds, except BPF (5-2500

215

pg on column) and DiNP, 6, and BADGE·HCl·H2O, 14, (50-2500 pg on column). In all cases, correlations

216

coefficients were higher than 0.98.

217

Characterization parameters for DMP, 1, DEP, 2, DBP, 3, BBP, 4, DEHP, 5, and BPA, 7, can be found in the

218

previous paper .32

219 220

· Migration test

9 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 10 of 28

221 222

In order to test the migration of EDCs, food simulants were used in accordance with the European Union

223

regulations.16 Simulants A, B, and C were used to simulate foods with hydrophilic character. Food simulant

224

B simulated the use of foods with pH values below 4.5. Simulant C was for those foods containing a

225

relevant amount of organic ingredients, which make the food to show a more lipophilic character and for

226

foods with alcohol content of up to 20%. Simulant D1 simulated the use of food that has lipophilic

227

character. In particular, this simulant was for oil-in-water emulsions and alcoholic foods with alcohol

228

content above 20%. Food simulant A was used to simulate the rest of general foods.

229 230

Three different food containers (semi-disposable plastic, bisphenol A-free plastic, and glass) were selected

231

for this work, which form a representative sample of commercially available household containers found in

232

supermarkets to be used for food storage and transportation. ATR-IR analyses showed that semi-disposable

233

food containers were made of flexible polypropylene (PP), both body and lid, and, according to the

234

manufacturer’s specification, they should not be used more than five times. BPA-free food containers were

235

made of rigid PP (the body of the container as well as the lid), with a piece of ethylene propylene diene

236

monomer (EPDM) rubber in the lid to guarantee the hermetic sealing and, according to the manufacturer,

237

BPA is not used in their fabrication. These containers were 15 times more expensive than the semi-

238

disposable ones. Glass food containers had a glass body, while the lid was made of rigid PP with an EPDM

239

rubber piece to ensure a hermetic closing, similar to the BPA-free food containers. Glass food containers

240

were 25 times more expensive than semi-disposable food containers. Figure 2 shows, as an example, the

241

ATR-IR spectra of the body of semi-disposable and BPA-Free containers compared to PP library spectra. The

242

household food containers were filled with 250 mL of simulant, which is the approximate volume of a meal

243

portion.

244 245

For the common population, household food containers are usually employed to store food in the

246

refrigerator for short periods of time or in the freezer for longer periods, in order to preserve it. They are

247

also used to transport food, the work place being the most common. Then, the food is heated up, most of

10 ACS Paragon Plus Environment

Page 11 of 28

Journal of Agricultural and Food Chemistry

248

the times inside the food container and using microwave ovens. Food containers are repeatedly used over

249

time for the same purposes. In certain cases, microwaves are also employed to defrost the food inside the

250

food container, before using it. In order to reproduce, as faithfully as possible, the use that consumers

251

make of the food containers, all these situations were covered in the experimental design (Table 2), in

252

which all the possible combinations of food containers with food simulants were prepared. Therefore, the

253

household food containers were stored in the refrigerator for three different periods of time within a

254

normal use, from 1 d to 7 d, and inside the freezer also for three different typical times, from 1 w to 12 w,

255

with the aim of studying the effect of the time of storage on the migration of EDCs. The food simulants

256

were also heated, firstly, for 2 min and then it was heated for 1 min more in a microwave at maximum

257

power (800 W), in order to study the migration of EDCs depending on the temperature reached and the

258

same food containers were used again to study the migration depending on the aging of the container. The

259

microwave was also used to defrost the simulants stored in the freezer at the power specified by the

260

manufacturer (180 W) during 5 min, with the aim of evaluating the effect of the microwave when it is used

261

for longer periods of time with lower power.

262 263

Most of the studies reviewed in the introductory part of this manuscript have focused on specific food

264

containers under extreme conditions. Unlike those references, the experiments performed in this work

265

were designed to consider the most common food containers used daily by regular users and their habitual

266

practices. The aim was to reproduce real situations that any user might experience at home every day in

267

order to offer valuable information about the EDC migration occurring during these habitual practices.

268 269

· Concentration levels of EDCs

270 271

Tables 3 and 4 show the total concentration of EDCs found in the migration tests, expressed in pg/mL of

272

simulant and calculated as the sum of the concentrations of the fifteen compounds included in the study.

273

BPB, 8, BFDGE, 11, and BADGE·HCl, 12, were not detected in any of the analyzed samples. DMP, 1, DiNP, 6,

274

BBP, 4, BADGE·H2O, 13, and BADGE·HCl·H2O, 14, were found in less than 1% of the experiments. On the

11 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 12 of 28

275

other hand, DEP, 2, and DBP, 3, were the most frequently detected EDCs, being present in more than 33%

276

and 63% of the experiments, respectively. This might be due to the extensive use of these EDCs in the

277

formulations of plastics for household food containers. It is also remarkable that BPA-free containers did

278

not show the use of BPA or other alternative bisphenols, such as BPB, 8, and BPF, 9, which was in

279

agreement with the specifications from the manufacturer.

280 281

The migration of EDCs depended on the type of simulant, the type of food container, as well as the type of

282

storage, time, and use in the microwave. However, some general trends can be drawn from the results

283

obtained in the present study. Considering the storage experiments (in the refrigerator and in the freezer),

284

an increasing tendency along the storage time was observed for all the containers tested. In Figure 3A it

285

can be seen this increase in the EDCs concentration, which behaved similarly in the three types of food

286

container and that was more intense in simulants B and C after the storage. The total EDC concentrations

287

found in each particular experiment and time are quite similar for the three containers investigated (i.e.,

288

semi-disposable, BPA-free, and glass) showing a similar behavior independently of the nature of the

289

container (plastic of different characteristics or glass). Although it was not expected to find plasticizers in

290

glass containers, their presence might be explained by the plastic lids with the EPDM rubber sealing used to

291

close the glass body. This could indicate that, although the body is made of glass, the lids also contribute to

292

EDC migration. A similar trend can be observed for the different simulants in the storage experiments

293

(Figure 3B). The total migration increases with the storage time for all the simulants tested, mainly for

294

those with a low percentage of ethanol and acetic acid (simulants A, B, and C). This increase is less

295

pronounced in the case of simulant D1, which corresponds to food with highly lipophilic character.

296 297

In the case of the heating experiments carried out in the microwave, a wide variation was observed for

298

both, the type of container used and the simulant employed (Figure 4A and 4B, respectively). In the first

299

case (Figure 4A), semi-disposable containers showed higher migration after the first use, the total ECD

300

concentrations decreasing after the second use. This might indicate that, although the migration of EDCs to

301

food simulants can be prolonged in time, the intensity of this migration is different and might be more

12 ACS Paragon Plus Environment

Page 13 of 28

Journal of Agricultural and Food Chemistry

302

intense after the first stages of heating than after subsequent uses of the containers. On the other hand,

303

although for all types of containers the concentrations of EDCs found decreased after the 2 min of reuse,

304

the concentrations of EDCs were increased again after the 2+1-min-reuse experiments. This seems to

305

indicate that the EDC migration will be increased at the high temperatures reached during the experiments

306

and longer heating times. In all cases, the lowest migration was observed for the defrosting experiments,

307

which used lower heating energies. As it has been stated above, an increase in the microwave power will

308

lead to more intense EDC migrations into the food simulants. When the different simulants are considered

309

(Figure 4B), the most remarkable finding is that, contrary to that observed in the storage experiments, the

310

highest migration was produced when simulant D1 was used. Simulants B and C showed a similar behavior,

311

the migration increasing with the heating time in the first use, then decreasing in the experiments of 2-min-

312

reuse and increasing again, reaching the maximum concentrations in the experiments of 2+1-min-reuse.

313

Simulant D1 behaved similarly. However, the concentrations of EDCs found in this simulant were much

314

higher in general than in simulants B and C. On the other hand, the migration processes found for simulant

315

A were completely different. The total concentrations found in this case were the lowest among all the

316

food simulants used. Moreover, after the first heating for 2 min, the concentrations of EDCs decreased

317

after the following experiments. This indicates that simulant A is the simulant with least extracting capacity

318

and, therefore, the foods simulated by simulants B, C, and D1 (foods with pH below 4.5 and foods with

319

lipophilic characters) have more extracting capacity of EDCs from household food containers and might be

320

less appropriate for their storage in these types of food containers.

321

In general, the concentration levels for the analytes found in the present work were lower than those

322

reported in previous works where the migration of the same endocrine disruptors were evaluated10, 12, 17, 24-

323

29

324

comparison with the milder but real domestic conditions used in this work.

. This is probably due the strong conditions (temperature, storage time, etc.) used in those works in

325 326

ACKNOWLEDGMENTS

327

Authors thank Mrs. Sagrario Calvarro for instrumental maintenance and control and Enrique Blázquez for

328

ATR-IR analyses.

13 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 14 of 28

329 330

ABBREVIATIONS USED

331

ATR, attenuated total reflectance; BADGE, bisphenol A diglycidyl ether; BADGE·2H2O, bisphenol A bis(2,3-

332

dihydroxypropyl) glycidyl ether; BADGE·H2O, bisphenol A (2,3-dihydroxypropyl) glycidyl ether; BADGE·HCl,

333

bisphenol A (3-chloro-2-hydroxypropyl) (2,3-dihydroxypropyl) ether; BADGE·HCl·H2O, bisphenol A (3-

334

chloro-2-hydroxypropyl) (2,3-dihydroxypropyl) ether; BBP, butyl benzyl phthalate; BFDGE, bisphenol F

335

diglycidyl ether; BPA, bisphenol A; BPB, bisphenol B; BPF, bisphenol F; DBP, dibutyl phthalate; DEHP, diethyl

336

hexyl phthalate; DEP, diethyl phthalate; DiNP, di-iso-nonyl phthalate; DMP, dimethyl phthalate; EDCs,

337

endocrine disrupting compounds; EPDM, ethylene propylene diene monomer; iLODs, instrumental limits of

338

detection; iLOQs, instrumental limits of quantitation; PE, polyethylene; PET, polyethylene terephthalate;

339

PP, polypropylene; RSD, relative standard deviation.

340 341

FOUNDING SOURCES

342

Financial support was obtained from MICINN (project AGL2012-37201) and Community of Madrid (Spain),

343

and European funding from FEDER program (project S2013/ABI-3028-AVANSECAL).

344 345

SUPPORTING INFORMATION DESCRIPTION

346

Analytical characteristics of the developed UHPLC-QqQ(MRM) method in terms of instrumental

347

repeatability (relative standard deviation, RSD), instrumental intermediate precision, and instrumental

348

limits of detection (iLOD) and quantitation (iLOQ), for the analytes characterized in the present study (Table

349

S.1.).

350 351

REFERENCES

352

1. Giulivo, M.; Lopez de Alda, M.; Capri, E.; Barceló, D. Human exposure to endocrine disrupting

353

compounds: Their role in reproductive systems, metabolic syndrome and breast cancer. A review. Environ.

354

Res. 2016, 151, 251–264.

14 ACS Paragon Plus Environment

Page 15 of 28

Journal of Agricultural and Food Chemistry

355

2. Arvanitoyannis, I. S.; Bosnea, L. Migration of substances from food packaging materials to foods. Crit.

356

Rev. Food Sci. Nutr. 2004, 44, 63-76.

357

3. Benhamada, M.; Bouzid, D.; Boyron, O.; Taam, M. The relationship between the aging of polycarbonate

358

characterized by SEC and the release of bisphenol A quantified by HPLC–UV. Eur. Food Res. Technol. 2016,

359

242, 227-232.

360

4. Geens, T.; Apelbaum, T. Z.; Goeyens, L.; Neels, H.; Covaci, A. Intake of bisphenol A from canned

361

beverages and foods on the Belgian market. Food Addit. Contam., 2010, 27, 1627–1637.

362

5. Theobald, A.; Simoneau, C.; Hannaert, P.; Roncari, P.; Roncari, A.; Rudolph, T.; Anklam, E. Occurrence of

363

bisphenol-F-diglycidyl ether (BFDGE) in fish canned in oil. Food Addit. Contam. 2000, 17, 881-887.

364

6. Cooper, J. E.; Kendig, E. L.; Belcher, S. M. Assessment of bisphenol A released from reusable plastic,

365

aluminium and stainless steel water bottles. Chemosphere 2011, 85, 943–947.

366

7. Hoekstra, E. J.; Simoneau, C. Release of bisphenol A from polycarbonate - A review. Crit. Rev. Food Sci.

367

Nutr. 2013, 53, 386-402.

368

8. González-Castro, M. I.; Olea-Serrano, M. F.; Rivas-Velasco, A. M.; Medina-Rivero, E.; Ordoñez-Acevedo, L.

369

G.; de León-Rodríguez, A. Phthalates and bisphenols migration in Mexican food cans and plastic food

370

containers. B. Environ. Contam. Tox. 2011, 86, 627–631.

371

9. Fasano, E.; Bono-Blay, F.; Cirillo, T.; Montuori, P.; Lacorte, S. Migration of phthalates, alkylphenols,

372

bisphenol A and di(2-ethylhexyl)adipate from food packaging. Food Control 2012, 27, 132-138.

373

10. Guart, A.; Bono-Blay, F.; Borrell, A.; Lacorte, S. Migration of plasticizersphthalates, bisphenol A and

374

alkylphenols from plastic containers and evaluation of risk. Food Addit. Contam. 2011, 28, 676–685.

375

11. Goodson, A.; Robin, H.; Summerfield W.; Cooper, I. Migration of bisphenol A from can coatings—effects

376

of damage, storage conditions and heating. Food Addit. Contam. 2004, 21, 1015–1026.

377

12. Avelino Moreira, M.; Coelho André, L.; de Lourdes Cardeal, Z. Analysis of plasticiser migration to meat

378

roasted in plastic bags by SPME–GC/MS. Food Chem. 2015, 178, 195–200.

379

13. Fasano, E.; Cirillo, T.; Esposito, F.; Lacorte, S. Migration of monomers and plasticizers from packed foods

380

and heated microwave foods using QuEChERS sample preparation and gas chromatography/mass

381

spectrometry. LWT Food Sci. Technol. 2015, 64, 1015-1021.

15 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 16 of 28

382

14. Lambertini, F.; Catellani, D.; Vindigni M.; Suman, M. Multiresidual LC–MS analysis of plasticizers used in

383

PVC gaskets of lids and assessment of their migration into food sauces. J. Mass Spectrom. 2016, 51, 805–

384

813.

385

15. Bhunia, K.; Sablani, S. S.; Tang, J.; Rasco, B. Migration of chemical compounds from packaging polymers

386

during microwave, conventional heat treatment, and storage. Compr. Rev. Food Sci. Food Saf. 2013, 12,

387

523-545.

388

16. European Union. Commission Regulation (EU) No. 10/2011 of 14 January 2011 on plastic materials and

389

articles intended to come into contact with food. Off. J. Eur. Union, 2011, L12, 1-89.

390

17. Li, X.; Xiong, W.; Lin, H.; Zhuo, L.; Lv, S.; Tang, X.; Chen, M.; Zou, Z.; Lin, Z.; Qiu, B.; Chen, G. Analysis of

391

16 phthalic acid esters in food simulants from plastic food contact materials by LC-ESI-MS/MS. J. Sep. Sci.

392

2013, 36, 477–484.

393

18. Li, B.; Wang, Z-W.; Lin, Q-B.; Hu, C-Y. Study of the migration of stabilizer and plasticizer from

394

polyethylene terephthalate into food simulants. J. Chromatogr. Sci. 2016, 54, 939–951.

395

19. Sendón, R.; Sanches-Silva, A.; Bustos, J.; Martín, P.; Martínez, N.; Cirugeda. Mª. E. Detection of

396

migration of phthalates from agglomerated cork stoppers using HPLC-MS/MS. J. Sep. Sci. 2012, 35, 1319–

397

1326.

398

20. Morelli-Cardoso, M. H. W.; Lachter, E. R.; Tabak, D. Determination of the specific migration of DEHP into

399

food simulants using high performance liquid chromatography. J. High Resolut. Chromatogr. 1999, 22, 70–

400

72.

401

21. Wang, S.; Yang, W.; Shi, M.; Sun, X.; Pang, W.; Wang, G. GC-MS assisted with chemometric methods

402

applied for investigation of migration behavior of phthalate plasticizers in fatty foods simulant.

403

Chromatographia 2013, 76, 529–534.

404

22. Xia, Y.; Rubino, M. Kinetic study of bisphenol A migration from low-density polyethylene films into food

405

simulants. Ind. Eng. Chem. Res. 2015, 54, 3711−3716.

406

23. Coltro, L.; Borghetti Pitta, J.; Afonso da Costa, P.; Ângela Fávaro Perez, M.; Aparecida de Araújo, V.;

407

Rodrigues, R. Migration of conventional and new plasticizers from PVC films into food simulants: A

408

comparative study. Food Control 2014, 44, 118-129.

16 ACS Paragon Plus Environment

Page 17 of 28

Journal of Agricultural and Food Chemistry

409

24. Onghena, M.; Negreira, N.; van Hoeck, E.; Quirynen, L.; van Loco, J.; Covaci, A. Quantitative

410

determination of migrating compounds from plastic baby bottles by validated GC-QqQ-MS and LC-QqQ-MS

411

methods. Food Anal. Methods 2016, 9, 2600–2612.

412

25. Onghena, M.; van Hoeck, E.; Negreira, N.; Quirynena, L.; Van Loco, J.; Covaci, A. Evaluation of the

413

migration of chemicals from baby bottles under standardised and duration testing conditions. Food Anal.

414

Methods 2016, 2012, 33, 893–904.

415

26. Simoneau, C.; Van den Eede, L.; Valzacchi, S. Identification and quantification of the migration of

416

chemicals from plastic baby bottles used as substitutes for polycarbonate. Food Addit. Contam. 2012, 29,

417

469–480.

418

27. Onghena, M.; van Hoeck, E.; Vervliet, P.; Scippo, M. L.; Simon, C.; van Loco J.; Covaci, A. Development

419

and application of a non-targeted extraction method for the analysis of migrating compounds from plastic

420

baby bottles by GC-MS. Food Addit. Contam.: Part A 2014, 31, 2090–2102.

421

28. Oca, M. L.; Sarabia, L. A.; Herrero, A.; Ortiz, M. C. Optimum pH for the determination of bisphenols and

422

their corresponding diglycidyl ethers by gas chromatography–mass spectrometry. Migration kinetics of

423

bisphenol A from polycarbonate glasses. J. Chromatogr. A 2014, 1360, 23–38.

424

29. Xie, Y.; Bao, Y.; Wang, H.; Cheng, Y.; Qian, H.; Yao, W. Release of bisphenols from can coatings into

425

canned beer in China market. J. Sci. Food Agric. 2015, 95, 764–770.

426

30. Grob, K. The future of simulants in compliance testing regarding the migration from food contact

427

materials into food, Food Control 2008, 19, 263–268

428

31. Vaclavikova, M.; Paseiro-Cerrato; R., Vaclavik, L.; Noonan, G. O.; DeVries, J.; Begley, T. H. Target and

429

non-target analysis of migrants from PVC-coated cans using UHPLC-Q-Orbitrap MS: evaluation of long-term

430

migration testing, Food Addit. Contam. 2016, 33, 352–363.

431

32. Esteve, C.; Herrero, L.; Gómara, B.; Quintanilla-López, J. E. Fast and simultaneous determination of

432

endocrine disrupting compounds by ultra-high performance liquid chromatography– tandem mass

433

spectrometry. Talanta 2016, 146, 326–334.

17 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 18 of 28

434

33. Gallart-Ayala, H.; Moyano, E.; Galceran, M. T. Multiple-stage mass spectrometry analysis of bisphenol A

435

diglycidyl ether, bisphenol F diglycidyl ether and their derivatives. Rapid Commun. Mass Spectrom. 2010,

436

24, 3469–3477.

437

18 ACS Paragon Plus Environment

Page 19 of 28

Journal of Agricultural and Food Chemistry

438

FIGURE CAPTIONS

439

Figure 1. Chemical structures of EDC studied.

440

Figure 2. ATR-IR spectra of the body of semi-disposable and BPA-Free containers compared to PP library

441

spectra.

442

Figure 3. Variation of total EDC concentrations (pg/mL of simulant) with time in storage experiments

443

(refrigerator and freezer) considering A, the container and B, the simulant used.

444

Figure 4. Variation of total EDC concentrations (pg/mL of simulant) with time in heating experiments

445

(defrost and heat in the microwave) considering A, the container and B, the simulant used.

446

19 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 20 of 28

Table 1. MRM parameters for the studied analytes. Compound DMP, 1

Retention time (min) 1.44

Transitiona

Ion transitionb

162.9-76.9

4.2

162.9-91.9 DEP, 2

2.50

223.1-177.0

1.3

223.1-148.9 DBP, 3

3.60

279.2-205.1

3.5

279.2-149.0 BBP, 4

3.63

313.2-149.0

2.6

313.2-90.9 DEHP, 5

4.04

391.3-279.1

10.3

391.3-149.0 DiNP, 6

4.10

419.6-85.0

1.05

419.6-149.2 BPA, 7

2.33

227.0-211.9

3.1

227.0-132.9 BPB, 8

2.72

241.1-212.1

2.3

241.1-211.1 BPF, 9

1.58

199.1-93.0

1.6

199.1-105.0 BADGE, 10

3.51

358.2-191.1

5.3

358.2-135.1 BADGE·H2O, 13

2.87

376.2-209.1

1.6

376.2-135.1 BADGE·2H2O, 15

1.92

394.2-209.1

1.6

394.2-135.1 BADGE·HCl, 12

3.54

394.2-227.3

1.7

394.2-167.2 BADGE·HCl·H2O, 14

3.09

412.2-167.4

1.2

412.2-131.0 BFDGE, 11

3.34

330.2-163.3

1.1

330.2-133.1

CID voltage (eV) 23

ESI mode

26

POS

17

POS

7

POS

7

POS

13

POS

20

POS

22

POS

7

POS

23

POS

13

POS

28

POS

21

NEG

19

NEG

18

NEG

29

NEG

20

NEG

20

NEG

11

POS

28

POS

12

POS

31

POS

15

POS

33

POS

13

POS

22

POS

26

POS

31

POS

11

POS

16

POS

POS

a

The first transition corresponds to the quantitation transition and the second one to the confirmatory transition. b Calculated as quantitation transition/confirmatory transition intensities.

20 ACS Paragon Plus Environment

Page 21 of 28

Journal of Agricultural and Food Chemistry

Table 2. Different food containers, food simulants, treatments, and times used in the 132 experiments carried out. Experimental conditions Containera S-Dis BPA-Free Glass S-Dis BPA-Free Glass S-Dis BPA-Free Glass S-Dis BPA-Free Glass

Simulant

Refrigerator

Refrigerator

Refrigerator

Freezer

Freezer

Freezer

Defrost

Heat (800 W)

Heat (800 W)b

Heat (800 W)

Heat (800 W) b

A

1d

3d

7d

1w

4w

12 w

180 W 5 min

First use 2 min

First use +1 min

Reuse 2 min

Reuse +1 min

B

1d

3d

7d

1w

4w

12 w

180 W 5 min

First use 2 min

First use +1 min

Reuse 2 min

Reuse +1 min

C

1d

3d

7d

1w

4w

12 w

180 W 5 min

First use 2 min

First use +1 min

Reuse 2 min

Reuse +1 min

D1

1d

3d

7d

1w

4w

12 w

180 W 5 min

First use 2 min

First use +1 min

Reuse 2 min

Reuse +1 min

a b

S-Dis, semi-disposable food container; BPA-Free, BPA-free food container; Glass, glass food container. Containers were firstly heated in the microwave for 2 min at 800 W and then they were heated for 1 more min at 800 W.

21 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 22 of 28

Table 3. Total EDC content in food simulants stored in refrigerator or freezer in different containers for three different periods of time.

Containera

Refrigerator Refrigerator Refrigerator 1d 3d 7d

Freezer 1w

Freezer 4w

Freezer 12 w

pg/mL of simulant

Simulant A

Simulant B

Simulant C

S-Dis

114

393

250

1025

-

1652

BPA-Free

295

113

34

478

-

1435

Glass

203

-

101

995

-

1268

S-Dis

50

-

-

448

772

2602

BPA-Free

51

146

59

814

816

3140

Glass

94

69

35

611

-

2441

S-Dis

37

-

126

361

469

1981

BPA-Free

112

138

28

396

1057

2600

Glass

77

84

99

38

488

3747

S-Dis

464

90

217

112

37

431

63

107

215

336

348

633

286

160

106

216

-

1412

Simulant D1 BPA-Free Glass a

S-Dis, semi-disposable food container; BPA-Free, BPA-free food container; Glass, glass food container.

22 ACS Paragon Plus Environment

Page 23 of 28

Journal of Agricultural and Food Chemistry

Table 4. Total EDC content in food simulants after heating the different containers in the microwave oven.

Containera

Defrost (180 W)

First use (800 W) 2 min

First use (800 W) 3 min

Reuse (800 W) 2 min

Reuse (800 W) 3 min

pg/mL of simulant

Simulant A

Simulant B

Simulant C

Simulant D1

a

S-Dis

118

284

200

124

55

BPA-Free

76

419

106

176

53

Glass

14

242

130

52

33

S-Dis

-

338

207

219

531

BPA-Free

-

29

-

196

182

Glass

-

263

352

278

1309

S-Dis

54

518

649

270

555

BPA-Free

559

200

135

84

361

Glass

54

147

277

147

440

S-Dis

376

412

1374

805

549

BPA-Free

56

483

763

404

1059

Glass

22

739

952

787

818

S-Dis, semi-disposable food container; BPA-Free, BPA-free food container; Glass, glass food container.

23 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 24 of 28

TOC Graphic

24 ACS Paragon Plus Environment

Page 25 of 28

Journal of Agricultural and Food Chemistry

Figure 1.

Bisphenol B (BPB), 8

Dimethyl phthalate (DMP), 1

Bisphenol F (BPF), 9 Diethyl phthalate (DEP), 2

Bisphenol A diglycidyl ether (BADGE), 10 Dibutyl phthalate (DBP), 3

Bisphenol F diglycidyl ether (BFDGE), 11

Butyl benzyl phthalate (BBP), 4

BADGE·HCl, 12

Diethyl hexyl phthalate (DEHP), 5

BADGE·H2O, 13

Di-iso-nonyl phthalate (DiNP), 6

BADGE·HCl·H2O, 14

Bisphenol A (BPA), 7 BADGE·2H2O, 15

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 26 of 28

Figure 2.

100

80

T (%)

60

40

20

PP (library) S-Dis BPA-Free

0 1000

1500

2000

2500

cm

3000

-1

ACS Paragon Plus Environment

3500

4000

Page 27 of 28

Journal of Agricultural and Food Chemistry

Figure 3.

A

Total EDC concentration (pg/mL of simulant)

S-Dis

BPA-Free

Glass

2500

2000

1500

1000

500

0 1d Refrigerator

3d Refrigerator

7d Refrigerator

1w Freezer

4w Freezer

12 w Freezer

Storage experiments

B

Total EDC concentration (pg/mL of simulant)

Simulant A

Simulant B

Simulant C

Simulant D1

3000 2500

2000 1500 1000 500 0

1d Refrigerator

3d Refrigerator

7d Refrigerator

1w Freezer

Storage experiments

ACS Paragon Plus Environment

4w Freezer

12 w Freezer

Journal of Agricultural and Food Chemistry

Page 28 of 28

Figure 4.

A

Total EDC concentration (pg/mL of simulant)

S-Dis

BPA-Free

Glass

700 600 500 400 300

200 100 0 (180 W) Defrost

2 min First use (800 W)

3 min (800 W) First use

2 min (800 W) Reuse

3 min (800 W) Reuse

Heating experiments

B

Total EDC concentration (pg/mL of simulant)

Simulant A

Simulant B

Simulant C

Simulant D1

1200 1000 800 600 400 200 0 (180 W) Defrost

2 min First use (800 W)

3 min (800 W) First use Heating experiments

ACS Paragon Plus Environment

2 min (800 W) Reuse

3 min (800 W) Reuse