Brominated flame retardants and organophosphate esters in

Subscriber access provided by Queen Mary, University of London

Article

Brominated flame retardants and organophosphate esters in preschool dust and children’s hand wipes Kristin Larsson, Cynthia A. de Wit, Ulla Sellström, Leena Sahlström, Christian H Lindh, and Marika Berglund Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.8b00184 • Publication Date (Web): 23 Mar 2018 Downloaded from http://pubs.acs.org on March 25, 2018

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 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 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.

Environmental Science & Technology 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 30

Environmental Science & Technology

1

Brominated flame retardants and organophosphate esters in

2

preschool dust and children’s hand wipes

3 4

Kristin Larsson*,†, Cynthia A. de Wit‡, Ulla Sellström‡, Leena Sahlström‡,#, Christian H. Lindh§,

5

Marika Berglund†

6

†

Institute of Environmental Medicine, Karolinska Institutet, Box 210, 171 77 Stockholm, Sweden.

7

‡

Department of Environmental Science and Analytical Chemistry (ACES), Stockholm University, 106 91

8

Stockholm, Sweden

9

§

Division of Occupational and Environmental Medicine, Lund University, 221 85 Lund, Sweden.

10 11

*

12

Kristin Larsson

13

Institute of Environmental Medicine, Karolinska Institutet

14

Box 210

15

171 77 Stockholm

16

Sweden

17

Phone: +46 707206094

18

E-mail: [email protected]

Corresponding author:

19 20

#

21

Recipharm Pharmaceutical Development AB

22

Gårdsvägen 10A

23

169 70 Solna

24

Sweden

Current address:

1 ACS Paragon Plus Environment

Environmental Science & Technology

Page 2 of 30

25

ABSTRACT: Children spend a considerable part of their day in preschool where they may be exposed

26

to hazardous chemicals in indoor dust. In this study, brominated flame retardants (BFRs) and

27

organophosphate esters (OPEs) were analyzed in preschool dust (n=100) and children’s hand wipe

28

samples (n=100) and diphenyl phosphate (DPHP) was analyzed in urine (n=113). Here, we assessed

29

children’s exposure via dust, identified predictors for chemicals in dust and studied correlations

30

between different exposure measures. The most abundant BFRs in dust were decabromodiphenyl ether

31

(BDE-209) and decabromodiphenyl ethane (DBDPE) found at median levels of 270 and 110 ng/g

32

dust, respectively. Tris(2-butoxyethyl) phosphate (TBOEP) was the most abundant OPE, found at a

33

median level of 79000 ng/g dust. For all OPEs and some BFRs, there were significant correlations

34

between the levels in dust and hand wipes. In addition, triphenyl phosphate (TPHP) in preschool dust

35

was significantly correlated with the corresponding metabolite DPHP in children’s urine. The levels of

36

pentaBDEs in dust were higher in older preschools compared to newer, whereas levels of DBDPE

37

were higher in newer preschools. Children’s estimated intakes of individual BFRs and OPEs via

38

preschool dust were below available health based reference values. However, there are uncertainties

39

about potential health effects of some emerging BFRs and OPEs.

40

2 ACS Paragon Plus Environment

Page 3 of 30

Environmental Science & Technology

41

INTRODUCTION

42

Brominated flame retardants (BFRs) are used to reduce the flammability of combustible materials,

43

such as plastics and textiles. Polybrominated diphenyl ethers (PBDEs), hexabromocyclododecane

44

(HBCDD) and tetrabromobisphenol A (TBBPA) are historically the most commonly used BFRs.

45

PBDEs are mainly used as flame retardants in electronics and upholstered furniture, whereas HBCDD

46

is used in polystyrene foams in e.g. building insulation and TBBPA is predominantly used in epoxy

47

resins found in circuit boards.1, 2

48

PBDEs and HBCDD are known to be toxic, mainly targeting the endocrine, reproductive and

49

nervous systems.3 Due to their toxic, persistent and bioaccumulative properties, the use of technical

50

pentaBDE (containing primarily BDE-47, -99, -100) and octaBDE (containing primarily BDE-183)

51

has been restricted to 0.1% by mass in preparations and articles put on the European market after

52

2004.4 After 2019, this restriction will also be applied to the use of technical decaBDE (containing

53

primarily BDE-209).5 HBCDD is listed in Annex XIV of the European regulation on registration,

54

evaluation, authorization and restriction of chemicals (REACH) and is thereby only allowed for

55

authorized use within the EU. TBBPA is still imported in large amounts (1000-10 000 tonnes/year) in

56

the EU.6, 7

57

The restricted use of PBDEs and HBCDD has led to their replacement with alternative BFRs by

58

industry. For example, decabromodiphenyl ethane (DBDPE) is used instead of decaBDE in

59

electronics, 2-ethylhexyl-2,3,4,5-tetrabromobenzoate (EH-TBB) and bis(2-

60

ethylhexyl)tetrabromophthalate (BEH-TEBP) substitute pentaBDE in polyurethane foam, and 1,2-

61

dibromo-4-(1,2-dibromoethyl)cyclohexane (DBE-DBCH) is used instead of HBCDD in polystyrene

62

insulation. However, these alternative or emerging BFRs have similar physiochemical properties as

63

the banned or restricted legacy BFRs and sufficient exposure and toxicity data are often lacking.1, 8, 9

64

The legacy BFRs have also been replaced by organophosphate esters (OPEs). Halogenated OPEs,

65

such as tris(1,3-dichloroisopropyl) phosphate (TDCIPP), tris(2-chloroethyl) phosphate (TCEP) and

66

tris(2-chloroisopropyl) phosphate (TCIPP), are mainly used as flame retardants in e.g. plastics, textiles

67

and polyurethane foam. Non-halogenated OPEs, such as tris(2-butoxyethyl) phosphate (TBOEP) and

3 ACS Paragon Plus Environment

Environmental Science & Technology

Page 4 of 30

68

triphenyl phosphate (TPHP), are also used for other applications, for example in plastics, hydraulic

69

fluids and floor polish.10 Some OPEs are suspected to be neurotoxic and/or reprotoxic.10-12 In addition,

70

TCEP and TDCIPP are suspected to be carcinogenic.11, 13-15 Because of the aforementioned toxicity,

71

TCEP has been phased out since the 1980s and is no longer produced within the EU.11, 16 The other

72

OPEs are still used, but TCIPP and TDCIPP are not allowed in toys produced in the EU.16

73

The major exposure source for BFRs is fatty foods, primarily fish.17 Humans are also exposed to

74

BFRs via indoor dust, which is considered to be an important exposure source especially for young

75

children and for populations living in areas where the environmental levels of some BFRs are high,

76

e.g. pentaBDE in North America.1, 17 There is less information about exposure to OPEs, but ingestion

77

of dust and food as well as inhalation of air have been suggested to be important exposure sources to

78

OPEs.18-21

79

Biomonitoring studies have shown that children have a higher exposure to PBDEs and OPEs than

80

adults,22-24 which makes them a particularly relevant group to include in exposure assessments.

81

Although children spend the majority of their time at home, small children spend up to a third of their

82

weekdays in the preschool, which makes it an important microenvironment to consider when

83

characterizing children’s exposure to both legacy and emerging chemicals. Although PBDEs and

84

HBCDD are no longer used, old consumer products and building materials which contain these

85

compounds may still be present in preschools. Therefore, to achieve the Swedish governmental goal of

86

a “non-toxic environment” for children, preschools have been advised to remove old products which

87

may contain hazardous chemicals. However, there is little knowledge about the importance of such

88

products and other factors in the preschool environment for children’s exposure to chemicals. During

89

the last 15 years, BFRs and/or OPEs have been measured in dust from European preschools in six

90

individual studies.20, 25-32 However, most of these studies included an insufficient number of preschools

91

to reliably identify which factors and sources that are important for the levels of chemicals in indoor

92

dust.

93

The objectives of this study were to evaluate the levels of legacy and emerging BFRs as well as

94

OPEs in preschool dust and identify important factors for these chemicals in the preschool

95

environment. Based on the measured levels, children’s intakes via preschool dust were calculated and 4 ACS Paragon Plus Environment

Page 5 of 30

Environmental Science & Technology

96

related to health based reference values. Also, correlations between BFRs and OPEs in different

97

exposure measures (dust, hand wipes, urine) were studied.

98

MATERIALS AND METHODS

99

Ethical permission for this study was granted by the regional ethical review board in Stockholm (Dnr

100 101

2015/128-31/1). Dust sample collection. Dust samples were collected from a total of 100 preschools visited

102

between February and April 2015 or between September and November 2015. Characteristics of the

103

participating preschools are described in the supporting information and in Larsson et al. 2017.33 Six

104

of the preschools were Waldorf preschools (based on the Steiner education philosophy) having no

105

plastics, electronics or foam mattresses in the indoor environment. From each participating preschool,

106

one settled dust sample was collected in a play room where 4-year-old children usually played. The

107

dust sample was collected on a pre-weighted cellulose filter (7 cm diameter) fixed in a styrene-

108

acrylonitrile holder (Krim.Teknisk Materiel AB, Bålsta, Sweden). A sieve was placed on top of the

109

filter before the filter holder was inserted in a nozzle made of polypropylene (Krim.Teknisk Materiel

110

AB, Bålsta, Sweden) and mounted on the intake nozzle of a vacuum cleaner. Settled dust was

111

collected from surfaces 50-250 cm above the floor, until there was a sufficient amount of dust on the

112

filter. After sampling, the filter holder lid was replaced, the holder was wrapped in aluminum foil and

113

then sealed in a polyethylene plastic bag. The samples were stored at -20°C until analysis. Field blank

114

samples were collected in one third of the preschools. The field blank samples were collected

115

following standard procedure, but instead of vacuuming surfaces, the vacuum nozzle was held up in

116

the air for a second while the vacuum cleaner was turned on.

117

At the time of the dust sampling, a field worker gathered information about the preschool building,

118

routines, presence of certain products, etc. The field worker also asked the preschool personnel to

119

estimate the age of certain items, such as mattresses and furniture.

120

Urine sample collection. Four-year-old children, attending any of the 30 preschools visited in the

121

first sampling round in spring of 2015, were recruited via a written invitation. Children were eligible

5 ACS Paragon Plus Environment

Environmental Science & Technology

Page 6 of 30

122

to participate if they were born between June 2010 and November 2011 and attended preschool more

123

than 20 hours/week. An informed consent form was signed by the parents before the sample

124

collection. Urine samples were collected between March and May 2015, within a month after the

125

collection of dust at the respective preschool. A median number of 4 (range 1-13) children per

126

preschool from a total of 28 preschools participated, resulting in a total of 113 children. The parents

127

collected the child’s first morning urine in a polypropylene tube (Sarstedt, Numbrecht, Germany) on a

128

Thursday morning. The urine samples were stored at -20°C until analysis. Details about the

129

recruitment and sampling procedure are described in the supporting information.

130

Hand wipe sample collection. Among the children who provided urine samples, a total of 100

131

children from 27 preschools also provided hand wipe samples. The number of participating children

132

per preschool ranged between 1 and 7 children, with a median of 3 children per preschool.

133

Hand wipe samples were collected at the preschool, normally at mid-day or afternoon. Prior to

134

sampling, the children had been engaged in indoor activities and had not washed their hands for at

135

least 30 minutes. A sterile 5x5 cm gauze compress soaked in 3 mL >99.5% isopropanol (Sigma-

136

Aldrich) was used to wipe the palm, back of the hand and between the fingers on both hands of the

137

child. The compress was enclosed in a glass jar and stored at -20°C until analysis. Field blank samples

138

were collected from one third of the preschools by soaking a gauze compress in isopropanol and

139

placing it directly into the glass jar.

140

Chemical analysis of dust and hand wipes. The dust and hand wipe samples were analyzed at the

141

Department of Environmental Science and Analytical Chemistry (ACES) at Stockholm University,

142

Sweden. Details of the chemicals and materials used, sample treatment, extraction, clean up,

143

instrumental analysis, quality control, recovery and analysis of standard reference material (SRM

144

2585) can be found in the supporting information.

145

Briefly, the samples were spiked with isotopic labelled standards of BDE-155, BDE-209, EH-TBB,

146

BEH-TEBP, α-, β-, and γ-HBCDD, TBBPA, TCEP, TPHP, and TBOEP and extracted repeatedly with

147

a mixture of n-hexane/acetone 1:1. The first step in the clean-up of all raw extracts was done by

148

fractionation on a silica column. The first set of 30 dust samples were fractionated into three fractions

149

according to Ionas and Covaci.34 The clean-up of each fraction is described in Figure SI-1. The silica 6 ACS Paragon Plus Environment

Page 7 of 30

Environmental Science & Technology

150

column in this clean-up method was found to behave unreliably as analytes sometimes eluted in other

151

fractions than expected, which resulted in some missing data for BEH-TEBP and HBCDD. Therefore,

152

for the remaining 70 dust samples and the hand wipes, the first fractionation column was changed to

153

the silica column described by Sahlström et al. 201235 with some modifications. The clean-up for each

154

fraction by this method is described in Figure SI-2.

155

After the clean-up, the sample volumes were reduced under a gentle stream of nitrogen and

156

transferred to autosampler vials containing a recovery standard. Fractions containing PBDEs, α- and β-

157

DBE-DBCH, DBDPE, EH-TBB and BEH-TEBP were analyzed using a gas chromatograph (GC)

158

(Trace GC Ultra) coupled to a mass spectrometer (MS) (DSQ II MS; both Thermo Scientific,

159

Waltham, USA). Fractions containing PFRs were analyzed with a Trace 1310 GC coupled to an ISQ

160

MS (both Thermo Scientific). Fractions containing HBCDDs and TBBPA were analyzed using an

161

ultra-performance LC (ACQUITY™ UPLC) coupled to a tandem-quadrupole MS (Xevo™ TQ-S).

162

The UPLC/MS instrument and columns used were from Waters (Milford, USA). Details on GC-MS

163

and UPLC/MS parameters are described in Table SI-3 and SI-4.

164

Six quality control samples (SRM 2585), 8 solvent blanks and 26 field blanks were processed

165

together with the dust samples, which were divided into 6 batches. Data were corrected for the mean

166

levels detected in the blanks (BDE-209, TCEP, TCIPP, TPHP and TBOEP; Table SI-5). The filter

167

holders that were used to collect the dust samples were found to contain TCEP and TCIPP, leading to

168

high levels of these in the field blanks. Therefore the mean field blank levels were used in the data

169

correction for TCEP and TCIPP. Together with the hand wipes, 10 solvent blanks and 10 field blanks

170

were processed, divided into 5 batches. The hand wipe field blanks contained TDCIPP that was not

171

present in the solvent blanks. The source for this is unknown. The hand wipe results were corrected for

172

the mean blank levels of BEH-TEBP, BDE-209, TCEP, TCIPP, TDCIPP, TPHP and TBOEP (Table

173

SI-5). Limits of quantification and detection (LOQ and LOD) for compounds present in the blanks

174

were set as 5 and 3 times the standard deviation (for LOQ and LOD values, see Table SI-6). If not

175

present in the blanks, signal to noise (s/n) ratios of 10 and 3 were used as LOQ and LOD, respectively.

176

The absolute recovery of the different surrogate standards were generally above 60% for dust and

177

hand wipes (Table SI-7). For MTBBPA in hand wipes, the average recovery was only 41%, caused by 7 ACS Paragon Plus Environment

Environmental Science & Technology

Page 8 of 30

178

low recoveries in two of the five sample batches. The reason for this is unknown. Also, the recovery of

179

Mα-HBCDD was lower than or just above 60% (54% and 62% for hand wipes and dust, respectively)

180

when using clean-up method B. This is due to the partial elution in fraction II from the silica column

181

used. For analytes lacking a labelled equivalent (α- and β-DBE-DBCH, DBDPE, TCIPP, TDCIPP),

182

the relative recovery versus the surrogate standard was established with spiked samples and used to

183

correct the final concentrations (Table SI-7).

184

The dust reference material SRM 2585 is certified for some of the analytes (BDE-47, -99, -100, -

185

153 and -209)36 and the concentrations obtained in this study were comparable with the certified

186

values (Table SI-8). For the other analytes in this study there are no certified values but for most of

187

them there exist values published by others and our data were in line with published values.

188

Chemical analysis of urine. Urine concentrations of the metabolite of TPHP, diphenyl phosphate

189

(DPHP), were analyzed at the laboratory of Occupational and Environmental Medicine in Lund,

190

Sweden, using liquid chromatography-tandem-mass-spectrometry (LC/MS/MS) by a modified method

191

described in Bornehag et al 2015.37 Briefly, urine was added with 3H10-DPHP as internal standard and

192

treated with glucoronidase. The samples were thereafter analyzed without any further work-up. A C18

193

column was used prior to the injector to reduce the interferences of contaminants in the mobile phase.

194

The DPHP metabolite was separated on a Genesis Lightn. C18 column (4µm, 50x2.1mm) using 0.1%

195

ammonium hydroxid in water and methanol as mobile phase. The samples were thereafter centrifuged

196

and 4 µl of the supernatant was analyzed using a LC (UFLCXR, Shimadzu Corporation, Kyoto, Japan)

197

connected to the MS/MS (QTRAP 5500, AB Sciex, Foster City, CA, USA). The samples were

198

analyzed in duplicate. The limit of detection, determined as the concentration corresponding to three

199

times the standard deviation of the response in chemical blanks, was 0.04 ng/ml. In the analysis, two

200

homemade quality control samples were used. Coefficient of variation of the samples were 12% at 0.8

201

ng/ml and 9% at 2 ng/ml. Urine density was determined using a hand refractometer.

202 203

Exposure assessment. The daily exposures doses (DED) of BFRs and OPEs from preschool dust ingestion in 4-year-old children were calculated using the following equation:38

 =

 ∗    8

ACS Paragon Plus Environment

Page 9 of 30

Environmental Science & Technology

204

Cdust is the concentration of chemicals in dust. Idust is the daily intake of dust from the preschool

205

environment (30 mg), assuming that the total daily dust intake during the waking hours is 60 mg and

206

that children spend half of that time in the preschool.39 BW is the mean body weight of the children in

207

our study (17.6 kg). We assumed the absorption to be 100%.

208 209

The daily intake of BFRs and OPEs in preschool dust via dermal absorption was calculated using the following equation:38



 = 210

 ∗  ∗
 ∗  ∗   ∗ 

BSA is the exposed body surface area (hands, arms, legs) of children, equal to 3380 cm2.39 DA is the

211

amount of dust adhered to the skin, weighted for the exposed body parts (0.03 mg/cm2).39 The

212

absorption factors (AF) were 0.03 for all BFRs, 38 0.28 for TCEP, 0.25 for TCIPP, 0.13 for TDCIPP

213

and 0.22 (average of the other OPEs) for TPHP and TBOEP.40 TF is the fraction of the day spent in

214

the preschool (8/24 hours).

215

Statistical analysis. The data were analyzed using the statistical software SPSS 22 (IBM Inc.) and

216

STATA 13 (Statacorp 220 TX, USA).Values below the LOD were replaced by LOD/√2 and values

217

between the LOD and the LOQ were replaced by LOQ/√2. Due to high LODs and LOQs for single

218

dust samples, we did not include one value for BDE-99, BDE-209, TBBPA and TPHP, three values

219

for BDE-100 and four values for DBDPE in the statistical analysis. Compounds with more than 50%

220

of the values below the LOQ were not included in the statistical analysis.

221

To correct for the degree of dilution in the urine samples, levels of DPHP were adjusted to

222

children’s mean density of 1.023 kg/L according to the formula Csample x (1.023-1)/(Dsample-1), where

223

Csample is the concentration of DPHP in the sample and Dsample is the density of the sample.

224

The data were not normally distributed and non-parametric tests were therefore used. Associations

225

between factors in the preschool environment and levels of flame retardants in preschool dust were

226

analyzed using the Mann Whitney U-test. Variables from this univariate analysis having significance

227

levels LOQ >LOD

N

GM

a

HAND WIPE SAMPLES

Median P95

Range

% % >LOQ >LOD

N

ng/g dust

GM

a

Median

P95

Range

pg/hand wipe

BDE-47

99%

100%

100

9.6

7.7

110