Paola A. Babay 1 Raúl F. Itria 2 Emiliano E. Romero Ale 1 Elena T. Becquart 1 Eduardo A. Gautier 1
1Gerencia Química, Comisión Nacional de Energía Atómica, San Martín, Buenos Aires, Argentina 2Instituto Nacional de Tecnología Industrial, San Martín, Buenos Aires, Argentina
1
Research Article
Ubiquity of Endocrine Disruptors Nonylphenol and Its Mono- and Di-Ethoxylates in Freshwater, Sediments, and Biosolids Associated with High and Low Density Populations of Buenos Aires, Argentina
In Latin America, use of alkylphenol ethoxylates is unrestricted and widespread. However, their environmental incidence is still little studied. In order to investigate the occurrence, distribution and main sources of the endocrine disruptors nonylphenol (NP), nonylphenol mono- and di-ethoxylate (NP1EO, NP2EO), we analyzed water and sediments from thirteen sites in high and low population densities regions of Argentina. Also ten biosolid samples from a municipal sewage treatment plant were analyzed. Ranges for NP were 21–6359 mg kgÀ1 in sediments, 0.1–6.2 mg LÀ1 in water and 64–112 mg kgÀ1 in sludge; for NP1EO were 7–3357 mg kgÀ1 in sediments, 0.1–9.2 mg LÀ1 in water and 8–140 mg kgÀ1 in sludge and for NP2EO were 1–437 mg kgÀ1 in sediments, 0.1–5.2 mg LÀ1 in water and 2–23 mg kgÀ1 in sludge. The highest levels were associated with proximity to industry and sewage effluents discharge. In biosolids we found predominantly NP, followed by NP1EO and NP2EO, consistently with the metabolic potential of engineered systems. Our findings are in agreement with historical reports for Europe and North America, indicating an important incidence of the xenoestrogens also in this important geographical region. Contrasted to guide values, they show a potential threat to the water and terrestrial environments.
Keywords: Micro-pollutant; Nonylphenol polyethoxylate degradation products; Recalcitrant metabolites; Sewage sludge; Surface water
Received: March 25, 2013; revised: May 3, 2013; accepted: May 19, 2013
DOI: 10.1002/clen.201300230
1 Introduction
Nonylphenol polyethoxylates (NPnEO) are among the most widely employed non-ionic surfactants [1–3]. Their biotransformation leads to the formation of recalcitrant metabolites, which are known to have harmful effects on biota such as endocrine disruption in several species [1–5]. NPnEO were early banned in Europe [6] and Canada [4]; however, the low cost and good performance for a broad number of applications, added to the lack of regulations in most countries, make these surfactants and their metabolites ever present in the environment as an “eternal flame” [7]. Little is still known on their fate and distribution in Latin America, where the use of these surfactants is widespread and unrestricted [3]. A reduced number of reports show the presence of the parent compounds and their bio-
Correspondence: Dr. P. A. Babay, Gerencia Química, Comisión Nacional de Energía Atómica, Av. General Paz 1499, San Martín, Buenos Aires, Argentina. E-mail: babay@cnea.gov.ar
Abbreviations: DCM, dichloromethane; dw, dry weight; NP, nonylphenol; NP1EO, NP mono-ethoxylate; NP2EO, NP di-ethoxylate; NPnEO, NP polyethoxylates; SPE, solid-phase extraction; STP, sewage treatment plant; TEQ, toxic equivalent
refractory metabolites in sewage and freshwater systems of Mexico [8, 9] and Brazil [10–12]. In Argentina, a qualitative study showed their presence among other micro-pollutants [13].
In previous works we reported the development and validation of analytical methods for quantification of nonylphenol (NP), nonylphenol mono- and di-ethoxylate (NP1EO, NP2EO) in natural water [14] and sediments [15], finding environmentally relevant levels.
The above precedents indicate a potential problem in this important geographical region, but there are still too scarce data to attain the knowledge on how to deal with the problem. With the aim of contributing to get a more comprehensive and representative panorama, the objective of the current study was to investigate the occurrence, main sources, and environmental significance of the endocrine disruptors NP, NP1EO, and NP2EO in areas that comprise both high and low population densities.
2 Materials and methods
2.1 Reagents and standards
Technical grade NP (85% 4-NP, Fluka, Switzerland) and a NP1EO/ NP2EO technical mixture (Igepal CO-210, Aldrich, USA) were used as analyte standards. For GC–MS analyses individual 4-NP1EO and
© 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim
www.clean-journal.com
Clean – Soil, Air, Water 2013, 41 (9999), 1–7
2
P. A. Babay et al.
4-NP2EO standards (Promochem, Germany) were employed. All solvents were HPLC grade and other chemicals were p.a. quality. Glass-fiber pre-filters were APFD 04700 from Millipore. For solid-phase extraction (SPE), glass columns and PTFE frits from Merck were employed; C-18 sorbent was CEC-18 (UCT, USA).
2.2 Sample collection and extraction procedures
2.2.1 Water and sediments
Water samples were collected in 1-L amber-glass bottles, added with 1% v/v formaldehyde and stored at 4°C until analysis. Grab sediment samples, mostly clay (except for sample S3, sandy) were collected from the water courses margins with a steel shovel, placed in 500 mL glass flasks with the addition of 2% v/v formaldehyde and stored at À20°C until analysis.
Since details on the extraction conditions are given elsewhere [14, 15] only the outline of the procedures is described here. After filtration through glass-fiber pre-filters and addition of NaCl to the acidified water samples, enrichment of the analytes was carried out by SPE on C-18 and elution with ethyl acetate (EtAc). Following addition of anhydrous Na2SO4 and evaporation of the SPE solvent, the extracts were re-dissolved in HPLC mobile phase and analyzed. Sediment samples were dried at 60°C until constant weight and homogenized, obtaining a solid that passed through a 20 mesh sieve. Extraction with EtAc was ultrasound assisted. The extracts were dried under N2 and re-dissolved in the HPLC elution mixture for measurement. No clean-up operations were performed.
Performance of the extraction procedures with real samples was evaluated through recovery assays at different concentration levels.
2.2.2 Sewage sludge
Biosolids were collected in 250 mL glass flasks, immediately preserved with 2% formaldehyde and stored at À20°C until analysis.
Method development experiments were carried out with a blank material from a laboratory scale reactor operated as semi-continuous activated sludge. The water phase was discarded after settlement and the remaining solid was oven dried at 55–60°C for 2 h. The dried sludge was treated with liquid N2 to allow mortar disintegration. A stock solution of the three target compounds in hexane/2-propanol (50:50) was spiked into the conditioned sludge and left at room temperature in the dark for 48–72 h, in order to obtain a final concentration of 550 mg NP, 534 mg NP1EO, and 328 mg NP2EO per gram of sludge dry weight (dw). Ultrasonic-assisted extraction was employed. Mixtures of dichloromethane (DCM), methanol (MeOH), and ethyl acetate (EtAC) were assayed as extraction solvents. Three sonication cycles of 5 min each were applied to 0.15 g of spiked blank together with 0.45 mL of the corresponding extraction solvent. The extracts were evaporated to dryness under N2 and re-dissolved in the HPLC elution mixture for analysis.
A drying period of 50–60 h at 60°C was necessary to achieve constant weight for the decanted solids of real sewage sludge samples (water phase also discarded). Once dried, a homogeneous material (20 mesh) was obtained. Three sonication cycles of 5 min were applied to 0.15 g of dried sample with 0.45 mL of an extraction mixture of MeOH/EtAc 25:75, selected during method development. Performance of the extraction procedures with real samples was evaluated through recovery assays.
2.3 Chromatographic analysis
Quantification of NP, NP1EO, and NP2EO extracted from water, sediments and sludge was carried out by normal-phase HPLC with fluorescence detection (HPLC-FL), following our previous procedures [14, 15]. A SpectraSERIES P200 binary pump (Thermo Separation Products, USA) with a Linear LC-305 fluorescence detector (Linear Instruments, USA) was employed. Separations were performed on an aminopropyl-silica column (5 mm particle, 250 Â 4.6 mm, APS-2 Hypersil, Thermo Scientific, USA) at 35°C, using isocratic elution with 4% 2-propanol in hexane. Excitation and emission wavelengths were 230 and 300 nm, respectively. Injection volume was 50 mL, with instrumental detection limits of 0.8 mg LÀ1 for NP1EO and NP2EO, and 1.3 mg LÀ1 for NP. In all cases, the analytes were positively identified by means of standard spiking.
Further confirmation of compounds identities was obtained by GC–MS. For the real samples, every HPLC peak attributed to the analytes was collected as eluted, evaporated to dryness and redissolved in cyclohexane for GC–MS analysis. A Shimadzu GC-17A split–splitless gas chromatograph coupled to a MS-QP5050A mass spectrometer was used. A Zebron ZB-1 capillary column (60 m  0.32 mm id, 0.50 mm film thickness, Phenomenex, USA) was employed. Instrumental conditions for separate measurement of the three analytes are described elsewhere [14].
Laboratory blanks were run among the samples, in order to verify the absence of crossed contamination during the sample preparation and analysis procedures.
2.4 Study area and sampling strategy
Water and sediment samples from 13 sites selected near potential sources of NPnEO, as well as ten biosolid samples from a sewage treatment plant (STP), were collected. Also, a number of locations where no sources were anticipated were studied in order to establish background levels, amounting to a total area of approximately 3000 km2.
In order to track the origin of NPnEO derived contamination and detect hot spots, a survey of low, middle and high density population areas was carried out. Sites were sampled along three selected natural water courses (Fig. 1), whose main characteristics are summarized.
2.4.1 Luján River
It emerges from the confluence of Los Leones and El Durazno creeks and runs 128 km through an area of 2690 km2. Three sections can be distinguished: higher basin (40 km long from the source), with low population density and agricultural and cattle activities; then middle and lower basins, running through regions of increasingly higher population densities and intense industrial activities, receiving wastewater of both industrial and municipal origins. The lower basin, running through the highest population density area, receives the most significant contamination charge, either directly or by means of its tributaries, specially the Reconquista River (www.atlasdebuenosaires.gov.ar) [13]. The higher basin was sampled at El Durazno creek (point N1) and the middle basin was sampled in the nearby of the municipal sewage treatment facility of Luján City (LSTP), namely upstream (N2), directly from the end-pipe (N3), close to the outlet (N4), and downstream the plant (N5).
Taking into account the potential use of biosolids for soil amendment, a survey of the aforementioned pollutants was performed. A new method of analysis was proposed for the study
© 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim
www.clean-journal.com
Clean – Soil, Air, Water 2013, 41 (9999), 1–7
Endocrine Disruptors in Freshwater and Sewage Systems of Buenos Aires
3
Figure 1. Sampling sites location at the Norwest (N1–N5), West (W1–W5), and South (S1–S3) of the city of Buenos Aires. L-STP, Luján sewage treatment plant; N-STP, North sewage treatment plant; W-STP, West sewage treatment plant. Dashed line represents the piped section of Morón creek. Alleviator of Jiménez creek is pointed by an arrow. Please note that only the water streams and cities or towns relevant for this work are shown in the map.
of biologic sludge. This method was applied in the analysis of the biosolids resulting from a mesophilic anaerobic digestion of secondary sludge (at 35–37°C with a retention time of 21 days) from the main municipal STP of San Fernando district, at the lower basin of Luján River (N-STP). This activated sludge facility serves a population of 270 000 inhabitants, has a capacity of 0.9 m3 sÀ1 and discharges the liquid effluents into the highly polluted Reconquista River at its confluence with Luján River.
2.4.2 Morón creek
It runs 16 km through one of the most densely urbanized and industrialized zones in the Metropolitan Area of Buenos Aires. The first 4.5 km are piped and the open stream section receives the input of a vast number of human activities. It belongs to the Reconquista River basin and is recognized as one of the most highly polluted ecosystems in the whole country (www.atlasdebuenosaires.gov.ar). Sampling was focused on the nearby of a chemical industry (close to the outlet (W1) and downstream the discharge (W2)) and a municipal STP (W-STP; upstream (W3), close to the end-pipe (W4) and downstream the plant (W5)).
2.4.3 Jiménez creek and its alleviator Jiménez channel
The creek rises as an intermittent water course and is one of the several water courses that are recognized to be highly polluted due the lack of control in effluent discharges. It flows into de la Plata River estuary. Its basin covers an area of 80 km2 and runs through highly urbanized and industrialized districts. All along its course, it receives discharges from industrial and domestic effluents. The points investigated, located at the city of Quilmes, are indicated as S1 (Jiménez creek), S2 (Jiménez channel), and S3 (irrigation channel).
3 Results and discussion
3.1 Water and sediments
3.1.1 Occurrence and distribution of NPnEO metabolites
The concentrations measured by HPLC-FL are shown in Tab. 1. Recovery rates obtained after standard addition resulted always >80% and therefore no correction factor was applied to the quantitative results. As reported before [1, 16], concentrations of the analytes in the solids were 1–3 orders of magnitude higher than the aqueous levels, reflecting accumulation due to their lipophilic nature. Figure 2a and b shows their molar distribution in water and sediments. Partitioning of organic compounds between these two phases is usually controlled by physical, chemical, and biological processes; fully de-ethoxylated NP and short-chain NP1EO and NP2EO would display different behaviors because of their different physicochemical properties [17]. The less water soluble the metabolite the higher the enrichment of the sediment that may be expected [16]. As stems from the figure, there is not a clear tendency in terms of a major compound in the water phase: NP, NP1EO, or NP2EO are present at the highest molar fractions in the different sites, talking about varying compositions of the discharges affecting the water compartment. However, accumulation of NP in the sediments becomes apparent; NP is always the major compound, with percent molar fractions mostly >50%, followed by NP1EO and much smaller amounts of NP2EO, except for point N1. In the latter site, a major proportion of longer chain NP2EO is observed, probably due to the presence of less adapted micro-biota in a slightly impacted site (as this rural area is) in contrast with the metabolisms found in engineered systems.
© 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim
www.clean-journal.com
Clean – Soil, Air, Water 2013, 41 (9999), 1–7
4
P. A. Babay et al.
Table 1. Quantitative results for water, sediment, and biosolid samples
NP
NP1EO
NP2EO
Sample
Liquid (mg LÀ1)
Solida)
Liquid (mg LÀ1)
Solida)
Liquid (mg LÀ1) Solida)
(S1) Jiménez creek – motorway (S2) Jiménez channel – motorway (S3) Irrigation channel – mouth (W1) Morón creek – industry discharge (W2) Morón creek – railway (W3) Morón creek – cemetery (W4) Morón creek – STP discharge (W5) Morón creek – motorway (N1) El Durazno creek (N2) Luján River – upstream STP (N3) Discharge of Luján STP (N4) Luján River – Luján STP discharge (N5) Luján River – downstream Luján STP (B1) San Fernando STP biosolid
(B2) San Fernando STP biosolid
(B3) San Fernando STP biosolid
(B4) San Fernando STP biosolid
(B5) San Fernando STP biosolid
(B6) San Fernando STP biosolid
(B7) San Fernando STP biosolid
(B8) San Fernando STP biosolid
(B9) San Fernando STP biosolid
(B10) San Fernando STP biosolid
0.9 Æ 0.2 (2) 1.6 Æ 0.1 (5) 0.7 Æ 0.1 (5) 1.9 Æ 0.1 (3) 2.3 Æ 0.2 (3) 0.5 Æ 0.02 (2) 6.2 Æ 0.6 (4) 4.2 Æ 0.9 (3) 0.1 Æ 0.005 (2) 0.4 Æ 0.03 (4) 7.0 Æ 0.3 (4) 3.0 Æ 0.06 (2) 0.3 Æ 0.03 (5)
– – – – – – – – – –
21 Æ 2 (2) 249 Æ 13 (8) 437 Æ 17 (3) 384 Æ 28 (4) 2229 Æ 47 (2) 1436 Æ 107 (2) 6359 Æ 1058 (3)
– 21 Æ 2 (2) 544 Æ 2 (2)
– 985 Æ 9 (2) 606 Æ 62 (3) 112 Æ 10 (2) 64 Æ 2 (2) 69 Æ 7 (2) 79 Æ 15 (2)
71 (1) 101 Æ 9 (4) 91 Æ 3 (2)
62 (1)
97 (1) 101 Æ 12 (2)
0.4 Æ 0.06 (2) 3.3 Æ 0.2 (5) 0.5 Æ 0.07 (5) 8.2 Æ 0.3 (3) 9.2 Æ 0.1 (3) 5.1 Æ 0.06 (2) 7.0 Æ 0.3 (4) 8.6 Æ 0.2 (3) 0.1 Æ 0.002 (2) 0.3 Æ 0.02 (4) 7.0 Æ 0.2 (4) 3.0 Æ 0.3 (2) 0.4 Æ 0.03 (5)
– – – – – – – – – –
7 Æ 0.6 (2) 173 Æ 29 (8) 120 Æ 9 (3) 163 Æ 22 (4) 1372 Æ 34 (2) 642 Æ 89 (2) 3357 Æ 614 (3)
– 11 Æ 3 (2) 370 Æ 10 (2)
– 847 Æ 7 (2) 197 Æ 44 (3) 35 Æ 0.2 (2) 8 Æ 0.1 (2) 10 Æ 0.6 (2) 24 Æ 4 (2)
140 (1) 30 Æ 3 (4) 25 Æ 1 (2)
38 (1)
54 (1) 107 Æ 7 (2)
0.7 Æ 0.02 (2) 2.5 Æ 0.05 (5) 0.8 Æ 0.1 (5) 4.8 Æ 0.3 (3) 5.2 Æ 0.02 (3) 3.8 Æ 0.1 (2) 4.9 Æ 0.2 (4) 2.8 Æ 0.05 (3) 0.2 Æ 0.008 (2) 0.1 Æ 0.01 (4) 5.4 Æ 0.7 (4) 2.4 Æ 0.2 (2) 0.3 Æ 0.02 (5)
– – – – – – – – – –
1 Æ 0.09 (2) 84 Æ 10 (8) 72 Æ 4 (3) 33 Æ 5 (4) 217 Æ 5 (2) 350 Æ 72 (2) 437 Æ 55 (3)
– 22 Æ 3 (2) 148 Æ 6 (2)
– 214 Æ 27 (2)
24 Æ 2 (3) 7 Æ 0.6 (2) 2 Æ 0.07 (2) 2 Æ 0.07 (2) 6 Æ 0.8 (2)
3 (1) 6 Æ 0.8 (4) 4 Æ 0.1 (2)
5 (1)
13 (1) 23 Æ 2 (2)
In brackets are given the number of replicate samples analyzed for each site (n). Blank space (À) indicates that no sample was analyzed. a) Solid phase concentrations (dry basis) are expressed in mg kgÀ1 for sediments and mg kgÀ1 for biosolids.
3.1.2 Sources and impact of NPnEO metabolites
Since NP, NP1EO, and NP2EO occur together, their combined impact was assessed through calculation of NP-toxic equivalents (NP-TEQs), as described in Canadian guidelines for water [18] and sediments [19]. Relative toxicity values, or NP-toxic equivalency factors (TEFs) are as follows: NP is assigned a TEF value of 1 and the shorter NPnEO oligomers (with n up to 8) have TEFs of 0.5. Then, the total concentration of NP-TEQs was calculated as:
NP À TEQs ¼ CNP þ 0:5 CNP1EO þ 0:5 CNP2EO
(sites N2 and N5); however, there is a clear disturbance caused by the
discharge of Luján City STP effluent into Luján River (sites N3 and N4). The end-pipe water sample (N3) reached 13.2 mg TEQs LÀ1, affecting the river water with 5.7 mg TEQs LÀ1 and also the sediments with 1516 mg TEQs kgÀ1 (N4). Those were the maximum values accounted
for these two areas. Finally, when comparing the results for Jiménez
creek and Jiménez channel, it is interesting to note the significantly higher values found in the alleviator channel (4.5 mg TEQs LÀ1 in water and 378 mg TEQs kgÀ1in sediments), possibly due to surrepti-
tious discharges that could be happening into this water stream.
where CNP, CNP1EO, and CNP2EO are the concentrations of the respective analytes in the sample. This was compared against the corresponding guidelines (1 mg LÀ1 for freshwater and 1.4 mg kgÀ1 dw for freshwater sediment, according to the aforementioned Canadian documents).
The results are graphically depicted in Fig. 2a and b. In Tab. 2 we gathered the sites characteristics and their related NP-TEQs. Not surprisingly, the most impacted area was Morón creek (sites W1–W5), a water body strongly influenced by untreated municipal and industrial wastewater, turning it into an “open sewer”. The highest TEQs seem to be associated with proximity to industry and sewage treatment effluents discharges; levels both in the aqueous and solid phases reached maximum values at the point of the creek that receives the STP effluent. All in all, the levels found are coherent with a densely populated area, dominated by the continuous discharge of industrial and domestic (many times untreated or deficiently treated) residual water.
The water samples of Quilmes (sites S1–S3) present higher TEQs than those from the comparatively less urbanized Luján River zone
3.2 Sewage sludge
3.2.1 Extraction method
Published literature shows that the most widely employed extractants for this or similar purposes have been for a long time DCM, MeOH, acetone, and hexane, either alone or in binary mixtures [1, 17, 20–22]. Based on our previous experience with sediment extraction [15], performance of MeOH, DCM, and EtAc, individually and in mixtures, was comparatively evaluated, the latter thought as a potentially suitable solvent in replacement of DCM (an environmentally and toxicologically harmful solvent).
Similar extraction performances were achieved with DCM and EtAc when mixed with MeOH, the latter showing to be an essential component of the binary mixtures in order to obtain high recovery rates. Therefore and in accordance with the idea of replacing DCM with a more environmentally friendly and less toxic solvent, and also reducing laboratory manipulation of toxic MeOH, the extraction media selected was a mixture of MeOH/EtAc 25:75, for which
© 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim
www.clean-journal.com
Clean – Soil, Air, Water 2013, 41 (9999), 1–7
Endocrine Disruptors in Freshwater and Sewage Systems of Buenos Aires
5
recoveries higher than 80% were obtained for the three analytes. Percentage relative standard deviations for duplicate experiments were always <10%. As no interfering signals were detected during chromatographic analyses of blank extracts, no clean-up procedures were included in the extraction protocol.
Recovery rates in real samples were assessed by spiking two biosolids in the concentration range from 4000 to 55 000 mg kgÀ1 (dw), resulting always >85%.
3.2.2 Occurrence and distribution of NPnEO metabolites
Table 1 presents the concentrations found. In terms of molar ratios (Fig. 2c), NP prevailed followed by NP1EO and minute amounts of NP2EO, consistently with the metabolic potential generally found in engineered systems. Output pathways of organic compounds from STPs may be outlined as a sum of biodegradation processes, adsorption on sludge and release via final effluents. Nonylphenolic substances are usually incompletely degraded, leaving relatively high amounts adsorbed onto sludge flocks [17]. As generally observed, the more hydrophobic a molecule the greater the amount that will be retained by the particulate phase. The high proportion of NP, followed by NP1EO and NP2EO found in the sludge samples can be derived therefore from their partitioning to the particulate matter during the earlier stages of wastewater treatment. Further removal of residual oxyethylene groups takes place during anaerobic digestion, making NP to persist in digested sludge [3, 23].
Figure 2. Molar fractions of NP, NP1EO and NP2EO and NP-toxic equivalents (TEQs) in: (a) sediments, (b) water and (c) biosolids. Solid lines indicate the Canadian Water [18], Sediment [19], and Soil [26] Guidelines (NP-TEQs of 1 mg LÀ1, 1.4 mg kgÀ1, and 5.7 mg kgÀ1, respectively).
3.3 Environmental significance and literature comparison
As previously pointed out, there are scarce data on micropollutants concentrations in Latin America. Furthermore, there is a lack of regulations related to the environmental hazard of NP and its ethoxylates in the region. However, regarding the environmental significance of the levels measured in this work, we can say that in most cases they are very close or surpass the guidelines for protection
Table 2. Summary of sites characteristics and their related NP-TEQs
Site
(N1) El Durazno creek (N2) Luján River (N3) Luján STP
(N4) Luján River (N5) Luján River (S1) Jiménez creek (S2) Jiménez channel (S3) Irrigation channel (W1) Morón creek
(W2) Morón creek
(W3) Morón creek (W4) Morón creek
(W5) Morón creek
Location characteristics/potential sources of high NP-TEQs
Low population density; mostly agricultural and cattle activities Middle to high population density; industrial activities Middle to high population density; industrial activities/Luján City municipal STP
discharge (directly from the end-pipe) Middle to high population density; industrial activities/Luján STP discharge Middle population density; agricultural activities Highly urbanized and industrialized districts Highly urbanized and industrialized districts/surreptitious discharges Highly urbanized and industrialized districts Among the most densely urbanized and industrialized zones in the Metropolitan Area of
Buenos Aires (MABA)/industry discharge Among the most densely urbanized and industrialized zones in the MABA/downstream
industry discharge Among the most densely urbanized and industrialized zones in the MABA Among the most densely urbanized and industrialized zones in the MABA/municipal STP
discharge Among the most densely urbanized and industrialized zones in the Metropolitan Area of
Buenos Aires/downstream municipal STP
Blank space (À) indicates that no sample was analyzed.
NP-TEQs water (mg LÀ1)
0.2 0.7 13.2
5.7 0.7 1.5 4.5 1.3 8.4
9.5
5.0 12.2
9.9
NP-TEQs sediment (mg kgÀ1)
0.04 0.8 –
1.5 0.7 0.03 0.4 0.54 0.5
3.0
1.9 8.3
–
© 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim
www.clean-journal.com
Clean – Soil, Air, Water 2013, 41 (9999), 1–7
6
P. A. Babay et al.
of freshwater ecosystems established in other countries. A graphical comparison of measured NP-TEQs with the Canadian guidelines (Fig. 2a and b), shows that water levels fairly approach or widely surpass safe values in all but one sample; in the case of sediments, this occurs in about 40% of the samples. When we contrast our results for instance with the Dutch Environmental Risk Limits [16], they cause even higher concern. We found that in all cases, with exception of El Durazno creek (N1), NP levels widely exceed maximum permissible concentrations (MPCs) for surface water (0.33 mg LÀ1), by a factor of 10–20 in the worst cases, always related with the vicinity to STP discharges. Also for NP1EO and NP2EO, a combined MPC of 0.12 mg LÀ1 is surpassed by all samples, with no exceptions. Talking about the sediments, MPCs of 105 mg kgÀ1 (dw) for NP and 150 mg kgÀ1 (dw) for NP1EO þ NP2EO were mostly widely exceeded, except for the samples taken at Jiménez (S1) and El Durazno (N1) creeks.
Concentrations found in the current study are in accordance with data published for water streams and sediments of highly urbanized and/or industrialized countries (i.e., USA, Canada, Switzerland, Germany, Korea, Spain), which have been extensively reviewed [3]. In those cases the higher values were associated with STP discharges, as well as with urbanized and industrialized areas, a fact that was also observed in our research. This is exalted in the case of Morón creek, where the analytes show high values all throughout its course, consistently with the high anthropogenic impact mentioned above.
Analyte concentrations in the biosolids ranged from 62 to 112 mg kgÀ1 (dw) for NP, from 7.6 to 107 mg kgÀ1 (dw) for NP1EO and from 1.65 to 23 mg kgÀ1 (dw) for NP2EO. Even when these levels did not reach values as high as those eventually found in other countries [3], sometimes one order of magnitude superiors [24], they deserve enough attention because of the increasing, widely spread use of nutrients and organic matter contained in sludge for agricultural purposes [3, 17]. Application of dehydrated stabilized sludge in agriculture is considered a potential input way of alkyphenols into the terrestrial environment. These degradation products have been encountered in soil and also in ground water as a consequence of leaching of sludge fertilized fields [23]. In this regard, the EU proposed a limit value of 50 mg kgÀ1 (dw) for the sum of NP, NP1EO and NP2EO in sludge intended for use in agriculture land [25]. The values measured in the present work certainly surpass this safe limit, raising concern about the possible disposal or final use of the generated biosolids. Finally, when contrasted with the Canadian NPTEQ of 5.7 mg kgÀ1 (dw) for agricultural use of soil, our results are at least 10 orders of magnitude above safe limits (Fig. 2c) [26].
4 Concluding remarks
In the nearby of Buenos Aires City there exist a vast number of industrial, municipal, and domestic facilities discharging their wastewater into rivers and creeks. These effluents are in some cases treated streams and many other times they correspond to direct discharges of untreated water. Therefore, this area appeared as an important environment to investigate the occurrence of degradation products of NPnEO, given that this is one of the major classes of nonionic surfactants still employed in all kind of industrial and domestic applications in the country. In addition, the use of NPnEO as a coadjuvant in several agricultural preparations increases the risk of occurrence of these substances in theoretically slightly impacted areas, such countryside zones. This kind of research had not been carried out before in the country, what acquires even highest relevance taking into account the small number of works of its type
for the whole Latin America, in a context of widespread and unregulated use and disposal of NPnEO. We think that comprehensive information on the occurrence and fate of pollutants should serve for evaluation and management purposes. Concentrations and behavior of NP, NP1EO, and NP2EO found in surface water and sediments, as well as in sewage systems, are in agreement with those reported for several sites of Europe and North America along the last decades, and reflect an important incidence of the target xenoestrogens also in this region. The metabolites of NPnEO were present in all the sites and compartments sampled at concentration levels which contrasted to guide values show a potential threat to the water and terrestrial environments.
Acknowledgments
Special thanks are given to O. Schenone and the workers of COMACO, to F. Meijide, F. de la Torre, J. Magallanes, and M. J. Fernández Sturla for invaluable collaboration.
The authors have declared no conflict of interest.
References
[1] B. Thiele, K. Gunther, M. J. Schwuger, Alkylphenol Ethoxylates: Trace Analysis and Environmental Behavior, Chem. Rev. 1997, 97 (8), 3247–3272.
[2] G. G. Ying, B. Williams, R. Kookana, Environmental Fate of Alkylphenols and Alkylphenol Ethoxylates – a Review, Environ. Int. 2002, 28 (3), 215–226.
[3] A. Soares, B. Guieysse, B. Jefferson, E. Cartmell, J. N. Lester, Nonylphenol in the Environment: A Critical Review on Occurrence, Fate, Toxicity and Treatment in Wastewaters, Environ. Int. 2008, 34 (7), 1033–1049.
[4] (CEPA) Canadian Environmental Protection Act, Proposed Notice Requiring the Preparation and Implementation of Pollution Prevention Plans in Respect of Nonylphenol and Its Ethoxylates Contained in Products, Minister of Public Works and Government Services, Canada Gazette 2003.
[5] N. Jonkers, A. Sousa, S. Galante-Oliveira, C. Barroso, H. P. Kohler, W. Giger, Occurrence and Sources of Selected Phenolic Endocrine Disruptors in Ria de Aveiro, Portugal, Environ. Sci. Pollut. Res. 2010, 17 (4), 834–843.
[6] European Parliament and the Council, Directive 2003/53/EC of the European Parliament and of the Council of 18 June 2003 Amending for the 26th Time Council Directive 76/769/EEC Relating to Restrictions on the Marketing and Use of Certain Dangerous Substances and Preparations (Nonylphenol, Nonylphenol Ethoxylate and Cement), Off. J. Eur. Union 2003, L178, 24–26.
[7] J. P. Sumpter, A. C. Johnson, 10th Anniversary Perspective: Reflections on Endocrine Disruption in the Aquatic Environment: from Known Knowns to Unknown Unknowns (and Many Things in between), J. Environ. Monit. 2008, 10 (12), 1476–1485.
[8] M. A. Belmont, M. Ikonomou, C. D. Metcalfe, Presence of Nonylphenol Ethoxylate Surfactants in a Watershed in Central Mexico and Removal from Domestic Sewage in a Treatment Wetland, Environ. Toxicol. Chem. 2006, 25 (1), 29–35.
[9] R. Gibson, E. Becerril-Bravo, V. Silva-Castro, B. Jiménez, Determination of Acidic Pharmaceuticals and Potential Endocrine Disrupting Compounds in Wastewaters and Spring Waters by Selective Elution and Analysis by Gas Chromatography–Mass Spectrometry, J. Chromatogr. A 2007, 1169 (1–2), 31–39.
[10] R. P. Araujo, C. M. Botta-Paschoal, P. F. Silverio, F. V. Almeida, P. F. Rodrigues, G. A. Umbuzeiro, et al., Application of Toxicity Identification Evaluation to Sediment in a Highly Contaminated Water Reservoir in Southeastern Brazil, Environ. Toxicol. Chem. 2006, 25 (2), 581–588.
© 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim
www.clean-journal.com
Clean – Soil, Air, Water 2013, 41 (9999), 1–7
Endocrine Disruptors in Freshwater and Sewage Systems of Buenos Aires
7
[11] S. Fiedler, M. Foerster, B. Glaser, W. Zech, Alkylphenols in Sediments of the Atlantic Rainforest South-West of São Paulo, Brazil, Chemosphere 2007, 66 (2), 212–218.
[12] D. Moreira, S. Aquino, R. Afonso, E. Santos, V. de Padua, Occurrence of Endocrine Disrupting Compounds in Water Sources of Belo Horizonte Metropolitan Area, Brazil, Environ. Technol. 2009, 30 (10), 1041–1049.
[13] W. D. Di Marzio, M. Sáenz, J. Alberdi, M. Tortorelli, S. Galassi, Risk Assessment of Domestic and Industrial Effluents Unloaded into a Freshwater Environment, Ecotoxicol. Environ. Saf. 2005, 61 (3), 380– 391.
[14] P. A. Babay, E. E. Romero-Ale, R. F. Itria, E. T. Becquart, B. Thiele, D. A. Batistoni, Simplified Determination of Lipophilic Metabolites of Nonylphenol Ethoxylates: Method Development and Application in Aqueous Samples from Buenos Aires, Argentina, J. Environ. Monit. 2008, 10 (4), 443–452.
[15] E. E. Romero-Ale, P. A. Babay, J. Magallanes, E. Becquart, G. Polla, E. Gautier, Performance of Different Extraction Media for the Ultrasonic-Assisted Extraction of Nonylphenol and Nonylphenol Mono- and Diethoxylates from Sediments, Int. J. Environ. Anal. Chem. 2009, 89 (14), 1005–1021.
[16] P. L. A. van Vlaardingen, R. Posthumus, T. P. Traas, Environmental Risk Limits for Alkylphenols and Alkylphenol Ethoxylates, RIVM Report 601501019/2003, National Institute of Public Health and the Environment (RIVM), Bilthoven 2003.
[17] J. Lian, J. X. Liu, Y. S. Wei, Fate of Nonylphenol Polyethoxylates and Their Metabolites in Four Beijing Wastewater Treatment Plants, Sci. Total Environ. 2009, 407 (14), 4261–4268.
[18] Canadian Council of Ministers of the Environment, Canadian water quality guidelines for the protection of aquatic life: Nonylphenol and its ethoxylates, in Canadian Environmental Quality Guidelines, Canadian Council of Ministers of the Environment, Winnipeg 2002.
[19] Canadian Council of Ministers of the Environment, Canadian sediment quality guidelines for the protection of aquatic life: Nonylphenol and its ethoxylates, in Canadian Environmental Quality Guidelines, Canadian Council of Ministers of the Environment, Winnipeg 2002.
[20] M. Fountoulakis, P. Drillia, C. Pakou, A. Kampioti, K. Stamatelatou, G. Lyberatos, Analysis of Nonylphenol and Nonylphenol Ethoxylates in Sewage Sludge by High Performance Liquid Chromatography Following Microwave-Assisted Extraction, J. Chromatogr. A 2005, 1089 (1–2), 45–51.
[21] M. Fernández-Sanjuan, A. Rigol, A. Sahuquillo, S. Rodríguez-Cruz, S. Lacorte, Determination of Alkylphenols and Alkylphenol Ethoxylates in Sewage Sludge: Effect of Sample Pre-Treatment, Anal. Bioanal. Chem. 2009, 394 (6), 1525–3153.
[22] T. Vega-Morales, M. E. Torres-Padrón, Z. Sosa-Ferrera, J. J. SantanaRodríguez, Determination of Alkylphenol Ethoxylates and Their Degradation Products in Liquid and Solid Samples, Trends Anal. Chem. 2009, 28 (10), 1186–1200.
[23] R. Céspedes, S. Lacorte, A. Ginebreda, D. Barceló, Occurrence and Fate of Alkylphenols and Alkylphenol Ethoxylates in Sewage Treatment Plants and Impact on Receiving Waters along the Ter River (Catalonia, NE Spain), Environ. Pollut. 2008, 153 (2), 384–392.
[24] W. Giger, P. Brunner, C. Schaffner, 4-Nonylphenol in Sewage Sludge: Accumulation of Toxic Metabolites from Nonionic Surfactants, Science 1984, 225 (4662), 623–625.
[25] European Commission Environment, Working Document on Sludge, 3rd Draft in Environment, European Commission, Brussels 2000.
[26] Canadian Council of Ministers of the Environment, Canadian soil quality guidelines for the protection of environmental and human health: Nonylphenol and its ethoxylates, in Canadian Environmental Quality Guidelines, Canadian Council of Ministers of the Environment, Winnipeg 2002.
© 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim
www.clean-journal.com
Clean – Soil, Air, Water 2013, 41 (9999), 1–7
Ver+/-