First evaluation of neustonic microplastics in Black Sea waters

Accepted Manuscript First evaluation of neustonic microplastics in Black Sea waters Ulgen Aytan, Andre Valente, Yasemen Senturk, Riza Usta, Fatma Basak Esensoy Sahin, Rahsan Evren Mazlum, Ertugrul Agirbas PII:

S0141-1136(16)30070-8

DOI:

10.1016/j.marenvres.2016.05.009

Reference:

MERE 4170

To appear in:

Marine Environmental Research

Received Date: 26 February 2016 Revised Date:

6 May 2016

Accepted Date: 7 May 2016

Please cite this article as: Aytan, U., Valente, A., Senturk, Y., Usta, R., Esensoy Sahin, F.B., Mazlum, R.E., Agirbas, E., First evaluation of neustonic microplastics in Black Sea waters, Marine Environmental Research (2016), doi: 10.1016/j.marenvres.2016.05.009. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

ACCEPTED MANUSCRIPT First evaluation of neustonic microplastics in Black Sea waters Ulgen AYTANa,*, Andre VALENTEb, Yasemen SENTURKa, Riza USTAa, Fatma Basak

4

ESENSOY SAHINa, Rahsan Evren MAZLUMa, Ertugrul AGIRBASa

5

a

Faculty of Fisheries, Recep Tayyip Erdogan University, 53100-Rize,Turkey

6

b

Marine and Environmental Sciences Centre, (MARE), Faculty of Sciences, University of

7

Lisbon, Campo Grande 1749-016 Lisbon, Portugal

8

*

Corresponding author, Email address: [email protected]

9 10

SC

11 12

M AN U

13 14 15 16 17 18

23 24 25 26 27 28 29 30 31 32 33 34 35

EP

22

AC C

21

TE D

19 20

RI PT

1 2 3

ACCEPTED MANUSCRIPT Abstract

37

The Black Sea has a high risk of plastic pollution given the high river discharge of several

38

industrialized countries into this semi-enclosed sea. Here, for the first time, the occurrence

39

and distribution of microplastics are reported for the Black Sea. Microplastics were assessed

40

from zooplankton samples taken during two cruises along the south eastern coast of the Black

41

Sea in the November of 2014 and February of 2015. In each cruise neuston samples were

42

collected at 12 stations using a WP2 net with 200 µm mesh. Microplastics (0.2-5 mm) were

43

found in 92 % of the samples. The primary shapes were fibres (49.4 %) followed by plastic

44

films (30.6 %) and fragments (20 %), and no micro beads were found. Average microplastic

45

concentration in November (1.2± 1.1x103 par. m-3) was higher than in February (0.6± 0.55x

46

103 par. m-3). Reduced concentrations in February were possibly caused by increased mixing.

47

The highest concentrations of microplastics were observed in offshore stations during

48

November sampling. The heterogeneous spatial distribution (0.2x103- 3.3x103 par. m-3 for all

49

samples) and accumulation in some stations could be associated to transport and retention

50

mechanisms linked with wind and the dynamics of the rim current, as well by different

51

sources of plastic. There were no statistically significant differences in MP concentration

52

between sampling stations and sampling periods (t-test, p< 0.05).The relatively high

53

microplastic concentrations suggest that Black Sea is a hotspot for microplastic pollution and

54

there is an urgency to understand their origins, transportation and effects on marine life.

55

Keywords: Microplastic, zooplankton, neuston, bioavailability, MSFD, Black Sea

56

Highlights

TE D

M AN U

SC

RI PT

36

•

Values of neustonic microplastic are reported for the first time in the Black Sea

58

•

Microplastics (<5 mm) were found in 92% of the neustonic samples.

59

•

The primary types were fibres and no micro beads were found.

60

•

62 63

AC C

61

EP

57

Mean microplastic concentrations were 1.2x103 par. m-3 and 0.6x103 par. m-3 in

November of 2014 and February of 2015, respectively.

1. Introduction

64

Plastic is one of the major waste disposal problems in the world. Global annual

65

production has increased over the last six decades (299 million tonnes in 2013- Plastics

66

Europe, 2015) and between 2 to 5 % of this production has been estimated to end in the

67

marine environment (Jambeck et al., 2015), making up 60–80 % of marine litter (Derraik,

68

2002). Only 10 % of plastics in the world’s oceans are estimated to originate from ships and

ACCEPTED MANUSCRIPT fishing activity. The remaining 90 % comes from land sources (Andrady, 2011). Once they

70

enter the marine environment, large items breakdown into smaller particles called as

71

microplastic (< 5mm) which further fragment into nanoplastics (< 100 nm) (Arthur et al.,

72

2009). In addition, microplastics (MPs) also include primary plastic particles produced in

73

microscopic sizes including granulates used in cosmetics, washing powders, cleaning agents

74

or pellets (Fendall and Sewell, 2009). Because of their durability, MPs then become widely

75

abundant and may require centuries to completely decompose (Barnes et al., 2009; Moore,

76

2008). Since their sizes are in the same range of plankton, MPs are bioavailable for many

77

marine organisms (Moore, 2008; Wright et al., 2013). Once MPs are ingested they can enter

78

the food web (e.g. Farrell and Nelson, 2013; Setälä et al., 2014), with potential risks to human

79

health by consumption of contaminated sea food. They have also potential to harm marine

80

biota by alteration of habitats, transport of pathogens/alien species and release of toxic

81

chemical properties (Andrady, 2011). Although many researches have been done on this

82

issue, there is still a big gap on how MPs affect the marine environment and human health.

M AN U

SC

RI PT

69

The Black Sea has an increased risk for plastic pollution, because it is characterized

84

by an unusually high river discharge into a relatively small semi-enclosed sea. In addition, it

85

is surrounded by several industrialized countries (Figure 1). More than 171 million people, in

86

21 countries, live in the region draining into the Black Sea. As a consequence, Black Sea is

87

one of the most degraded ecosystems in the world (BSC, 2007). In the report of “The

88

Commission on the Protection of the Black Sea Against Pollution” the problem of marine

89

litter was considered one of the most urgent and difficult environmental problems in the

90

region (BSC, 2007). The large rivers runoff of the Black Sea (Danube, Dnieper, Bug,

91

Dniester, Don, Kuban, Rioni etc.) carry considerable loads of pollutants (Tuncer et al., 1998;

92

Bakan and Buyukgungor, 2000; Topcu et al., 2013) and a recent study estimated that 4.2

93

tonnes of plastic reach the Black Sea via the Danube per day (1533 tonnes every year)

94

(Lechner et al., 2014). Black Sea is one of the major fishing areas in the world (FAO, 2015),

95

thus, intense fishing activities can be considered as a source of plastic by fixed and floating

96

fishing gear, discarded or abandoned nets (BSC, 2007). Coastal cities, ports, shipping

97

activities, uncontrolled coastal landfills and dumping sites along the coast, are also an

98

important source of pollution (BSC, 2007; Celik, 2002; Berkun et al., 2005). Recent studies

99

showed that plastic was the major debris and was mainly originated land-based (Topcu and

100

Ozturk, 2010; Guneroglu, 2010; Topcu et al., 2013). Predictably, plastic has been reported as

101

dominant debris from the SW Black Sea seabed (Topcu and Ozturk, 2010), and from the SW

102

(Topcu et al., 2013) and SE beaches (Guneroglu, 2012). Nevertheless there is still limited

AC C

EP

TE D

83

ACCEPTED MANUSCRIPT data on marine litter for the coastal zone and MP pollution in the Black Sea region has not yet

104

been quantified. The permanent circulation feature of the region is the meandering rim

105

current (Figure 1), which encirculates the entire Black Sea in a counter-clockwise direction

106

(Oguz et al., 1993). This feature may cause a dissemination of the plastic items over the

107

basin and transport debris downstream, to less polluted regions such as the SE Black Sea. The

108

SE Black Sea, where this study is conducted, is very important for fishing (Oguz et al., 2012),

109

therefore bioavailability of microplastic has to be understand as much as possible.

RI PT

103

The objective of the present study is to evaluate, for the first time, the occurrence and

111

distribution of neustonic MPs in the surface waters of the SE Black Sea with those of

112

neustonic zooplankton and contribute to development of ideas for future research within the

113

scope of Marine Strategy Framework Directive (EC, 2008).

SC

110

M AN U

114

2. Material and methods

116

2.1. Sampling

117

Presence and distribution of MPs and zooplankton in the SE Black Sea surface waters were

118

evaluated during two research cruises in the autumn of 2014 (November 7- 9) and winter of

119

2015 (February 25- 27). Neuston samples were collected from 12 sampling station (Table 1)

120

during daylight hours (09:00-15:00), using a cylindro-conical WP2 net with 57 cm mouth

121

diameter (0.25m2), 260 cm long and 200 µm mesh (UNESCO, 1968). To determine the

122

amount of sea water filtered, net was equipped with a digital flow meter. Net were towed

123

horizontally for 5 minutes at ship speed of approximately 2 knots, in the upper 20 cm of the

124

water column. To collect all plankton and MPs, net was washed with sea water. Then samples

125

were transferred into the glass bottle and preserved in 4% borax-buffered formaldehyde. In

126

the laboratory, to reduce the risk of contamination sample preparation was performed in a

127

flow cabinet and all equipment was rinsed three times with filtered ultra-pure water. A cotton

128

lab coat and nitrile gloves were worn at all times. Samples were suspended in the graduated

129

cylinders for 48 hours and MPs were separated from the samples by gravity method

130

according to Collingon et al. (2012). MPs were visually counted using a binocular

131

microscope and classified into 3 groups: fibers (from textiles and fishing nets), fragments

132

(pieces from broken objects) and plastic films (bags, wrappings, or pieces of them) (Doyle et

133

al., 2011). This examination of the samples was repeated twice to ensure the detection of all

134

the smallest microplastic items. Remaining zooplankton samples were counted using

135

binocular microscope and classified following groups; copepoda, cladocera, chaetognatha,

AC C

EP

TE D

115

ACCEPTED MANUSCRIPT apendicularia, scyphozoa, ctenophora, tintinnids, heterotrophic dinoflagellates, crustacean

137

nauplii, micrometazoan larvae and eggs. During zooplankton enumeration, encountered MPs

138

were also added to total number of MPs. MP concentration and zooplankton abundance are

139

calculated as particles and individuals per volume of filtered water (m-3), respectively. To

140

determine whether densities of microplastic and zooplankton differed significantly in

141

different seasons and stations, one-way ANOVA tests were conducted. Prior to the statistical

142

analyses, log transformation was applied to stabilize the variances.

RI PT

136

Oceanographic conditions during the sampling periods were assessed from two high-

144

resolution (1 km2) Level-2 MODIS AQUA satellite images of sea surface temperature (SST)

145

and chlorophyll-a concentration (CHL), acquired in the days of 7th November 2014 and 23rd

146

February 2015. These days were chosen as a compromise between being cloud-free (rare in

147

the Black Sea), covering a wide region and being temporally-close to the sampling period.

148

Standard products of SST and CHL, produced and distributed by the NASA Ocean Biology

149

Processing Group (OBPG), were used (http://oceancolor.gsfc.nasa.gov/cms/atbd). Standard

150

flags were used to eliminate low-quality pixels. Data were downloaded from the NASA

151

Ocean Color website. Satellite retrievals of chlorophyll are known to exhibit significant

152

disagreement (overestimation) with in-situ data in the Black Sea (e.g. Oguz and Ediger,

153

2006), but still provide an insight into spatial patterns in the region and advective pathways of

154

passive particles. Overlaid in the satellite images of SST and CHL, are the fields of surface

155

geostrophic currents derived from altimeter satellite data. It was used the regional gridded

156

(1/8°x1/8°) Black Sea product produced by Ssalto/Duacs and distributed from the Aviso/Cnes

157

website. Wind during the sampling period, was assessed from the atmospheric NCEP/NCAR

158

Reanalysis (Kalnay et al., 1996). It was used the "4xDaily wind at 10 m" product from the

159

NCEP/NCAR website and, in particular, the closest grid-point (40.952 ºN; 39.375 ºE) to the

160

sampling area.

M AN U

TE D

EP

AC C

161

SC

143

162

3. Results

163

3.1. Hydrography

164

Study area exhibited typical hydrographic characteristic of the region (Agirbas et al.,

165

2015). Sea surface temperature was usually higher to the south and east part of the Black Sea

166

during both sampling (Figure 2). Overall, a well-mixed water column was observed in

167

February, whereas stratification was detected in November. Chlorophyll was usually higher

168

near the coast and advected offshore by the mesoscale eddies (Figure 2). The counter-clock

ACCEPTED MANUSCRIPT 169

wise coastal current (rim current) of the Black Sea, was apparent in both sampling periods, as

170

well as the mesoscale features associated with it (Figure 2). Wind was stronger during the

171

February sampling, and in both samplings it was from the south (Figure 3).

172 173

3.2. Distribution of Microplastic and Zooplankton MPs were widely distributed in the study area during November 2014 and February

175

2015 cruises. Twenty two out (92 %) of the twenty four samples contained MPs (Table 1).

176

The relative contribution of the different types of MP at each station (Figure 4) was similar

177

between the two sampling periods. Combining all stations from the two sampling periods,

178

fibres were the primary shapes (average ~ 49.4 %), followed by plastic films (average ~ 30.6

179

%) and fragments (average ~ 20 %), with no micro beads found (Figure 4). Average MP

180

concentration in the surface water was calculated as 1.2x 103 (± 1.1x 103) par.m-3 and 0.6x 103

181

(± 0.55x 103) par.m-3 in November and February, respectively (Figure 5). The average MP

182

concentration of all samples, irrespective of the sampling period, was 1.1x 103 (± 0.9x 103)

183

par.m-3.Their mean concentration in the inshore sites was similar in both the sampling periods

184

(Table 2). However, mean MP concentration was 2-5 times higher in sites offshore during

185

November sampling than during February (Table 2). There were no statistically significant

186

differences in MP concentration between sampling stations and the sampling periods (t-test,

187

p< 0.05).

TE D

M AN U

SC

RI PT

174

Mean zooplankton abundance was 6.9x 103 (± 10.6x 103) ind. m-3 and mainly

189

dominated by adult copepods and crustacean nauplii in November 2014 (Figure 6-A). In

190

February 2015, abundance was 5.6x 103 (± 4.3x 103) ind. m-3 with a change in the community

191

structure dominated by heterotrophic dinoflagellates Noctiluca scintillans (Figure 6-B).

192

Zooplankton abundance was higher in offshore stations in November (at 15 miles) opposed to

193

higher at inshore stations in February (Table 2). There were no statistically significant

194

differences in zooplankton abundance between sampling stations and seasons (t-test, p<

195

0.05).

AC C

196

EP

188

197

4. Discussion

198

4.1. Occurrence and distribution of microplastic

199

Our findings show that MPs are present across the SE Black Sea. Many recent studies

200

reported evidence of MPs in zooplankton samples all around the world (e.g. Moore et al.,

201

2001; Lattin et al., 2004; Collignon et al., 2012; Frias et al., 2014; Kang et al., 2015b). The

202

occurrence of plastic particles in this study (92 %) is similar to those reported from the other

ACCEPTED MANUSCRIPT regions (Table 3). Lack of the MP data in the Black Sea prevents a regional comparative

204

analysis. In other regions, MP concentrations have been represented with different unit (m-2

205

and m-3) which does not allow a comparison with many of the previous studies (e.g.

206

Collignon et al., 2014; Gago et al., 2015). The studies which reported MPs concentration as

207

par. m-3 from the surface waters were used for comparison (Table 3). MP concentrations

208

reported here are in the same order of magnitude as in the studies sampled using mesh size <

209

333µm in the coastal waters of Sweden (Noren, 2008), NE Pacific (Desforges et al., 2014),

210

Yangtze Estuary, China (Zhao et al., 2014) and in the SE Korea coastal waters (Kang et al.,

211

2015a), but nearly three order of magnitude greater than those sampled using mesh size > 333

212

µm (Table 3). To avoid to risk of net clogging, neuston nets with mesh size > 333 µm were

213

used in the many studies, however, they could have caused loss of small particles as it stated

214

in previous studies (e.g. Desforges et al., 2014; Zhao et al., 2014; Kang et al., 2015a). For

215

instance, there were several order of magnitude differences in MP concentrations when

216

sampled with < 80 µm and ≥ 330 µm mesh (Noren, 2008; Kang et al., 2015a) (Table 3).

217

Following previous methodologies (Collignon et al., 2012), density separation was used to

218

separate MPs from zooplankton, but considerable amount of MPs were encountered during

219

zooplankton enumeration (these were added to the MP enumeration). MPs can be

220

underestimated in the studies which only consider MPs enumeration. Therefore, there is an

221

urgent need to standardized sampling and enumeration techniques.

TE D

M AN U

SC

RI PT

203

Besides different sampling methods, another possible reason for the relatively high

223

MPs concentration observed is the study area. Enclosed and semi-enclosed seas have high

224

densities of plastic debris (Barnes et al., 2009) and the Black Sea is known to be one of the

225

most polluted semi-enclosed seas in the world (BSC, 2007). Large amounts of land-based

226

debris are transported to the Black Sea by rivers (Tuncer et al., 1998; Bakan and

227

Büyükgüngor, 2000; BSC, 2007; Topcu et al., 2013; Lechner et al., 2014; Suaria et al., 2015)

228

with Danube alone estimated to transport 4.2 tonnes of plastic per day (Lechner et al. 2014).

229

In the NW Black Sea, plastic items reported as most abundant floating litter (up to 140 items.

230

km-2) (Suaria et al., 2015). Municipal and industrial solid wastes are frequently dumped on

231

the river valleys or into the sea (Berkun et al., 2005) and expected to transport into the sea by

232

waves and wind (Yıldırım et al., 2004). The cyclonic rim current circulates basin-wide and

233

can cause transboundary dissemination of the plastic items over the basin. During both

234

cruises, floating macroplastics which are an important source of MPs were also observed on

235

the sea surface (personal communication). The polymer types of the microplastic have not

236

been specified in this study; therefore our results cannot determine the possible sources of the

AC C

EP

222

ACCEPTED MANUSCRIPT MPs. However, prevalence of fibres in this study provides evidence of land-based sources

238

(Sewage, run-offs, harbours, vessels, fishing gear etc.) in agreement with previous studies

239

(Thompson et al., 2004; Noren, 2008; Brown et al. 2011; Hidalgo-Ruz et al., 2012; Lusher et

240

al., 2014; Desforges et al., 2014, Zhao et al., 2014). Giresun, Trabzon, Rize, and Artvin are

241

main urban cities in the region, populated by more than 1.7 million people (TUIK, 2015) and

242

drain into the SE Black Sea. Disposal of municipal wastewater contaminated with fibres from

243

washing clothes was reported as a major source of plastic fibres (Browne et al., 2011).

RI PT

237

In this study, there was no clear pattern of higher MP concentration in in-shore

245

stations than in offshore stations. In fact, maximum MP concentrations were found in

246

November, in offshore stations. Wind was weaker during the November cruise (Figure 3)

247

which may have favoured surface stratification and accumulation of plastic at the surface, in

248

agreement with other studies that showed how vertical mixing caused dilution of MPs at the

249

surface (e.g. Lattin et al., 2004; Collignon et al., 2012). This increase of MPs in November

250

might have also been a signature of a larger-scale seasonal cycle in neustonic MPs following

251

the seasonal cycle of vertical mixing (shallower in autumn than in winter). Southerly winds

252

occurred in both cruises (Figure 3) which would have a tendency to advect near-shore waters

253

offshore. This could explain the higher MP found in offshore stations in November. A recent

254

study showed that atmospheric fall out is also a considerable land-based source of synthetic

255

fibres thus the southerly winds may have also increased wind transport of fibres from land to

256

sea (Dris et al., 2016). Nevertheless, we note that an opposite wind direction from north,

257

could also be argued (though less convincingly) as a factor to increase convergence of MPs

258

from the open ocean to these offshore stations. The heterogeneous spatial distribution is also

259

likely influenced by interactions between wind and oceanographic features such as filaments,

260

fronts and eddies, that act to transport MPs and create barriers and convergent regions where

261

MPs accumulates. No relation was found between satellite-derived geostrophic flow and MP

262

spatial distribution (Figure 5). This suggests that other processes besides large-scale

263

circulation govern MP spatial distribution. A high-resolution (1 km2) satellite image of

264

chlorophyll-a and sea surface temperature on the 7th of November (Figure 2) reveal some of

265

these large-scale and small-scale oceanographic features. Several large-scale mesoscale

266

eddies (~100km), associated with to the rim current are observed along the coast, pushing

267

coastal waters offshore and open waters in-shore. Also, several small-scale structures can be

268

found, such as long and thin (~3 km) chlorophyll filaments, as well lobular and spiralling

269

structures. Although the chlorophyll map does not represent MP concentrations, it shows

270

possible barriers and trajectories of coastal material advected offshore. The higher MPs found

AC C

EP

TE D

M AN U

SC

244

ACCEPTED MANUSCRIPT 271

in offshore stations may have been advected from the coast by these small-scale structures, or

272

advected by the larger-scale eastward rim current from more polluted areas upstream.

273

4.2. Bioavailability of microplastics

275

The potentially harmful MPs are available to many commercially and ecologically important

276

species (e.g. European anchovy and larvae) that either live, reproduce and/or feed in the

277

neustonic area. Many marine organisms are known to ingest MPs (e.g. Thomson et al., 2004;

278

Ward and Shumway, 2004; Browne et al., 2008; Boerger et al., 2010; Cole et al., 2013) by

279

not being able to differentiate MPs from plankton because of their small size. Laboratory

280

experiments demonstrated that this can result in harm on health and function (Browne et al.,

281

2008; Graham and Thompson, 2009; Cole et al., 2013). During microscopic examination,

282

many plastic particles were encountered in the gut content of ctenophore Pleurobrachia

283

pileus providing evidence that MP can be taken up by zooplankton. Other types of

284

zooplankton that are not filter feeders like ctenophores may be more selective in choosing

285

prey and less likely to ingest MPs. Noctiluca scintillans is a voracious feeder and more

286

abundant in the neuston than in subsurface layers in the Black Sea (Zaitsev, 1971). However,

287

despite a domination of N. scintillans in February (Figure 6), no MP was encountered in N.

288

scintillans food vacuole during microscopic examination. These results indicate that more

289

work (e.g. laboratory experiences) needs to be done to be able to characterise MP neustonic

290

ingestion among different types of zooplankton taxa in the Black Sea. While some

291

zooplankton taxa encountered in the neuston samples in this study were from groups or

292

species exclusively neustonic (such as larvae of some fish species), others are present only in

293

early stages of their life (such as crustacean naupli, micrometazoan larvae), and others (such

294

as copepods and chaetognaths) are present only at night owing to their vertical migration

295

(Zaitsev, 1971). Thus sampling at night would have provided a better representation of

296

facultative members of neuston (such as copepods) and their susceptibility to ingest MPs. In

297

other regions,plastic fragments have been found in the gut content of many planktivorous

298

fishes (Foekema et al., 2013; Davison and Asch, 2011; Boerger et al., 2010). European

299

anchovy (Engraulis encrasicolus) is the dominant planktivorous fish in the Southern Black

300

Sea, as well the main commercial fish stock of the Black Sea (TUIK, 2015), and can be the

301

most probable to encounter with MPs in the study area.

AC C

EP

TE D

M AN U

SC

RI PT

274

302

Sinking rate of microplastic is known to depend on their size and density (Moore et

303

al., 2008). Because of the brackish waters of Black Sea and relatively lower density of

ACCEPTED MANUSCRIPT surface waters, MPs may sink faster compared to oceanic waters. However, Black Sea is

305

characterised by a permanent halocline (~ 100m) that significantly constrains exchanges

306

between surface and deeper water. This might cause a long-term accumulation of MPs in

307

intermediate layers between surface and halocline which might increase bioavailability of

308

MPs during daily vertical migration of zooplankton, in particular of copepods. They can be

309

harmed either by ingestion or adsorption (e.g. Cole et al., 2013) which can negatively affect

310

their energy balance. Thus, there is an urgent need to monitor MPs in the Black Sea and

311

understand their fate and transfer mechanisms within the pelagic/benthic food web.

RI PT

304

312

5. Conclusions

SC

313

This work presents preliminary data on occurrence and distribution of MPs in the SE

315

Black Sea, becoming the first contributor to assess MPs within the scope of Marine Strategy

316

Framework (EC, 2008). Results provide that there is a potential for MPs to enter the pelagic

317

and benthic food webs of the Black Sea. Further work including FTIR examination is needed

318

to provide more information regarding potential origins of MPs. There is an urgency to fully

319

understand how MPs behave in the permanently stratified Black Sea environment and basin

320

wide routine studies are needed to investigate their effects on marine life with emphasis on

321

risks for human health.

TE D

322

M AN U

314

Acknowledgements

324

This work was partly supported by TUBITAK (The Scientific and Technological Research

325

Council of Turkey) (Project No: 113Y189). We are grateful to Dr. Ilknur YILDIZ, Dr. Ahmet

326

SAHIN, Mustafa BAKIRCI, and Yusuf Ozden for their help during sampling. We also thank

327

to captain and crew of the R/V SURAT ARASTIRMA I for their support at sea.

AC C

328

EP

323

329 330

References Agırbas, E., Feyzıoglu, A. M., Aytan, U., Valente, A., and Kurt Yıldız, I., 2015. Are trends in

331

SST, surface Chlorophyll-a, primary production and wind stress similar or different over the

332

decadal scale in the south-eastern Black Sea? Cahiers de Biologie Marine 56(4):329-336

333

Andrady, A. L., 2011. Microplastics in the marine environment. Marine Pullution Bulletin,

334

62: 8, 1596–1605.

335

Arthur, C., Baker, J., and Bamford, H. (eds.), 2009. Proceedings of the International Research

336

Workshop on the Occurrence, Effects, and Fate of Microplastic Marine Debris, September 9-

ACCEPTED MANUSCRIPT 11, 2008. National Oceanic and Atmospheric Administration Technical Memorandum NOS-

338

OR&R-30

339

Bakan, G., and Buyukgungor, H., 2000. The Black Sea. Mar. Pollut. Bull. 41 (1), 24-43.

340

Barnes, D.K.A., Galgani, F., Thompson, R.C., and Barlaz, M.A., 2009. Accumulation and

341

fragmentation of plastic debris in global environments. Philos. Trans. R. Soc. Lond. 364

342

(1526), 1985-1998.

343

Berkun M., Aras E., and Nemlioglu S. 2005. Disposal of solid waste in Istanbul and along the

344

Black Sea coast of Turkey. Waste Management, 25: 847–855.

345

Browne, M.A., Dissanayake, A., Galloway, T.S., and Lowe, D.M., 2008. Ingested

346

microscopic plastic translocates to the circulatory system of the mussel. Mytilus edulis.

347

Environ. Sci. Technol. 42 (13), 5026–5031 .

348

Browne, M.A., Crump, P., Niven, S.J., Teuten, E., Tonkin, A., Galloway, T., and Thompson,

349

R., 2011. Accumulation of microplastic on shorelines worldwide: sources and sinks. Environ.

350

Sci. Technol. 45, 9175-9179.

351

BSC, 2007. Marine Litter in the Black Sea Region: A review of the problem. Black Sea

352

Commission Publications 2007-1, Istanbul-Turkey, 160 pp.

353

Boerger, C.M., Lattin, G.L., Moore, S.L., and Moore, C.J., 2010. Plastic ingestion by

354

planktivorous fishes in the North Pacific Central Gyre. Mar. Pollut. Bull. 60 (12), 2275–2278.

355

doi: 10.1016/j.marpolbul.2010.08.007

356

Celik, F. 2002. A case study: Interstate highway in the Black Sea coast. Proc. 4th Conf. on

357

Turkish Coast and Coastal Areas (Izmir, Turkey, 5-8 November 2002), Vol. II, P.847-856.

358

(In Turkish).

359

Cole, M., Lindeque, P., Fileman, E., Halsband, C., Goodhead, R., Moger, J., and Galloway,

360

T. S., 2013. Microplastic ingestion by zooplankton. Environ. Sci. Technol., 47, 6646−6655,

361

dx.doi.org/10.1021/es400663f

362

Collignon, A., Hecq, J. H., Glagani, F., Voisin, P., Collard, F., and Goffart, A., 2012.

363

Neustonic microplastic and zooplankton in the North Western Mediterranean Sea. Mar.

364

Pollut. Bull. 64, 861–864. http://dx.doi.org/10.1016/j.marpolbul.2012.01.011.

365

Collignon, A., Hecq, J. H., Glagani, F., Collard, F., and Goffart, A., 2014. Annual variation in

366

neustonic micro- and meso-plastic particles and zooplankton in the Bay of Calvi

367

(Mediterranean–Corsica).

368

http://dx.doi.org/10.1016/j.marpolbul.2013.11.023.

369

Davison, P., and Asch, R.G., 2011. Plastic ingestion by mesopelagic fishes in the North

370

Pacific Subtropical Gyre. Mar. Ecol. Prog. Ser. 432, 173–180. doi: 10.3354/meps09142

AC C

EP

TE D

M AN U

SC

RI PT

337

Marine

Pollution

Bulletin

79,

293-298.

ACCEPTED MANUSCRIPT Derraik, J.G.B., 2002. The pollution of the marine environment by plastic debris: a review.

372

Mar. Pollut. Bull. 44, 842–852.

373

Desforges, J.P.W., Galbraith, M., Dangerfield, N., and Ross, P.S., 2014. Widespread

374

distribution of microplastics in subsurface seawater in the NE Pacific Ocean. Marine

375

Pollution Bulletin 79, 94–99. http://dx.doi.org/10.1016/j.marpolbul.2013.12.035

376

Doyle, M., Watson, W., Bowlin, N., and Sheavly, S., 2011. Plastic particles in coastal pelagic

377

ecosystems

378

doi:10.1016/j.marenvres.2010.10.001.

379

Dris, R., Gasperi, J., Saad, M., Mirande, C., and Tassin, B., 2016. Synthetic fibers in

380

atmospheric fallout: A source of microplastics in the environment?. Marine Pollution

381

Bulletin, 104, 1-2: 290-3. doi: 10.1016/j.marpolbul.2016.01.006.

382

EC, 2008. EC Directive, 2008/56/EC of the European Parliament and the Council of 17 June

383

2008 establishing a framework for community action in the field of marine environmental

384

policy (Marine Strategy Framework Directive). Official Journal of the European Union, L

385

164/19, 25.06.2008.

386 387

Farrell, P. and Nelson, K., 2013. Trophic level transfer of microplastic: Mytilus edulis (L.) to Carcinus maenas (L.). Environ Pollut., 177:1–3. doi: 10.1016/j.envpol.2013.01.046.

388

FAO, 2015. Food and Agriculture Organization of the United Nations, Fisheries and

389

Aquaculture 22/01/2016. http://www.fao.org/fishery/area/Area37/en.

390

Fendall, L. S., and Sewell, M. A., 2009. Contributing to marine pollution by washing your

391

face: Microplastics in facial cleansers. Mar. Pollut. Bull., 58 (8), 1225−1228.

392

Frias, J.P.G.L., Otero, V., and Sobral, P., 2014. Evidence of microplastics in samples of

393

zooplankton from Portuguese coastal waters. Marine Environmental Research 95, 89-95.

394

http://dx.doi.org/10.1016/j.marenvres.2014.01.001

395

Guneroglu, A., 2010. Marine litter transportation and composition in the Coastal Southern

396

Black Sea Region. Scientific Research and Essays Vol. 5(3), pp. 296-303.

397

Hidalgo-Ruz, V., Gutow, L., Thompson, R.C., and Thiel, M., 2012. Microplastics in the

398

Marine Environment: A Review of the Methods Used for Identification and Quantification.

399

Environmental Science & Technology, 46:3060-3075.http://dx.doi.org/10.1021/es2031505

400

Jambeck, J. R., Geyer, R., Wilcox,C., Siegler, T. R., Perryman, M., Andrady, A., Narayan,

401

R., and Lavender Law, K., 2015. Plastic waste inputs from land into the ocean. Marine

402

Pollution, 347; 6223, 768-771.

403

Kalnay, E., Kanamitsu, M., Kistler, R., Collins, W., Deaven, D., Gandin, L., Iredell, M.,

404

Saha, S., White, G., Woollen, J., Zhu, Y., Leetmaa, A., Reynolds, R., Chelliah, M.,

the

Northeast

Pacific

ocean.

Mar.

Environ.

Res.

71,

41–52.

AC C

EP

TE D

M AN U

SC

of

RI PT

371

ACCEPTED MANUSCRIPT Ebisuzaki, W., Higgins, W., Janowiak, J., Mo, K., C., Ropelewski, C., Wang, J., Jenne, R.,

406

and Joseph, D., 1996: The NCEP/NCAR 40-year reanalysis project, Bull. Amer. Meteor.

407

Soc., 77, 437-470, doi: 10.1175/1520-0477(1996)077<0437:TNYRP>2.0.CO;2.

408

Kang, J. H., Kwon, O. Y., Lee, K. W., Song, Y. K., and Shim, W., J., 2015 a. Marine

409

neustonic microplastics around the southeastern coast of Korea. Marine Pollution Bulletin 96,

410

304–312. http://dx.doi.org/10.1016/j.marpolbul.2015.04.054

411

Kang, J. H., Kwon, O. Y., and Shim, W., J., 2015 b. Potential Threat of Microplastics to

412

Zooplanktivores in the Surface Waters of the Southern Sea of Korea. Arch Environ Contam

413

Toxicol. http://dx.doi.org/10.1007/s00244-015-0210-3

414

Lattin, G.L., Moore, C.J., Zellers, A.F., Moore, S.L., and Weisberg, S.B., 2004. A

415

comparison of neustonic plastic and zooplankton at different depths near the southern

416

California shore. Mar. Pollut. Bull. 49, 291–294. doi:10.1016/j.marpolbul.2004.01.020

417

Lechner, A., Keckeis, H., Lumesberger-Loisl, F., Zens, B., Krusch, R., Tritthart, M., Glas,

418

M., and Schludermann, E. 2014. The Danube so colourful: a potpourri of plastic litter

419

outnumbers fish larvae in Europe’s second largest river. Environ. Pollut., 188: 177-181.

420

doi:10.1016/j.envpol.2014.02.006

421

Lucia, G. A., Caliani, I., Marra, S., Camedda, A., Coppa, S., Alcaro, L., Campani, T.,

422

Giannetti, M., Coppola, D., Cicero, A. M., Panti,C., Baini, M., Guerranti, C., Marsili, L.,

423

Massaro, G., Fossi, M. C., and Matiddi, M., 2014. Amount and distribution of neustonic

424

micro-plastic off the western Sardinian coast (Central-Western Mediterranean Sea). Marine

425

Environmental Research 100, 10-16. http://dx.doi.org/10.1016/j.marenvres.2014.03.017

426

Lusher, A. L., Burke, A., O’Connor, I., and Officer, R., 2014. Microplastic pollution in the

427

Northeast Atlantic Ocean: Validated and opportunistic sampling. Marine Pollution Bulletin

428

88, 325-333. http://dx.doi.org/10.1016/j.marpolbul.2014.08.023

429

Mazlum, R. E., Aytan, U., Özden, Y., and Agirbas, E. Trophic ecology of Pleurobrachia

430

pileus (O. F. Müller, 1776) in the South Eastern Black Sea. Manuscript in preparation.

431

Moore C. J., 2008. Synthetic polymers in the marine environment: a rapidly increasing, long-

432

term threat. Environmental Research, 108, 131-139. doi: 10.1016/j.envres.2008.07.025

433

Moore C. J., Moore S. L., Leecaster M. K., and Weisberg S. B. 2001. A comparison of plastic

434

and plankton in the North Pacific Central Gyre. Mar. Pollut. Bull. 42, 1297–1300.

435

(doi:10.1016/S0025-326X(01)00114-X)

436

Norén, F., 2008. Small plastic particles in coastal Swedish waters. N-Research report,

437

commissioned by KIMO Sweden. 11 pp.

AC C

EP

TE D

M AN U

SC

RI PT

405

ACCEPTED MANUSCRIPT Oguz, T., Latun, V., Latif, M., Vladimirov, V., Sur, H., Markov, A., Ozsoy, E.,

439

Kotovshchikov, B., Eremeev, V., and Unluata, U., 1993. Circulation in the surface and

440

intermediate layers of the Black Sea. Deep Sea Res. Part I: Oceanogr. Res. Pap. 40 (8), 1597-

441

1612.

442

Oguz, T. and Ediger, D., 2006. Comparison of in-situ and satellite-derived chlorophyll

443

pigment concentrations, and impact of phytoplankton bloom on the suboxic layer structure in

444

the western Black Sea during May-June 2001. Deep Sea Research Part II: Topical Studies in

445

Oceanography, 53(17-19): 1923-1933

446

Oguz, T., Akoglu, E. and Salihoglu, B., 2012. Current state of over- fishing and its regional

447

differences in the Black Sea. Ocean and Coastal Management, 58, 47–56.

448

Plastics Europe, 2015. Plastics-the Facts 2014/2015. Plastic Europe, Belgium, pp. 1–40.

449

11/11/2015, http://www.plasticseurope.org/Document/plastics-the-facts-20142015.aspx

450

Zaitsev, Yu., P., 1971. Marine Neustonology, IPST, Jerusalem, 207 pp.

451 452 453

Setälä, O., Fleming-Lehtinen, V., and Lehtiniemi, M., 2014. Ingestion and transfer of microplastics in the planktonic food web. Environmental Pollution, 185, 77-83. http://dx.doi.org/10.1016/j.envpol.2013.10.013

454

Suaria, G., Melinte-Dobrinescu, M. C., Ion, G., and Aliani, S., 2015. First observations on

455

the abundance and composition of floating debris in the North-western Black Sea. Marine

456

Environmental Research 107:45-49. http://dx.doi.org/10.1016/j.marenvres.2015.03.011

457

Thompson R. C., Olsen Y., Mitchell R. P., Davis A., Rowland S. J., John A. W. G.,

458

McGonigle D., and Russell A. E., 2004. Lost at sea: where is all the plastic? Science 304,

459

838. doi:10.1126/science.1094559

460

Topcu, E.N., and Oztürk, B., 2010. Abundance and composition of solid waste materials on

461

the western part of the Turkish Black Sea seabed. Aquatic Ecosyst. Health & Manag. 13 (3),

462

301-306.

463

Topcu, E.N., Tonay, A.M., Dede, A., Ozturk, A.A., and Ozturk, B., 2013. Origin and

464

abundance of marine litter along sandy beaches of the Turkish Western Black Sea coast. Mar.

465

Environ. Res. 85, 21-28.

466

Tuncer, G., Karakas, T., Balkas, T.I., Gokcay, C.F., Aygun, S., Yurteri, C., and Tuncel, G.,

467

1998. Land-based sources of pollution along the Black Sea coast of Turkey: concentrations

468

and annual loads to the Black Sea. Mar. Pollut. Bull. 36 (6), 409-423.

469

TUIK, 2015. 18/11/2015. http://www.tuik.gov.tr/VeriTabanlari.do?ust_id=109&vt_id=28

470

UNESCO, 1968. UNESCO Report. Monograph of Oceanographic Methodology, 2, 153-159.

AC C

EP

TE D

M AN U

SC

RI PT

438

ACCEPTED MANUSCRIPT Ward, J.E., and Shumway, S.E., 2004. Separating the grain from the chaff: Particle selection

472

in suspension- and deposit-feeding bivalves. J. Exp. Mar. Biol. Ecol. 300, 83-130.

473

Wright, S. L., Thompson, R. C., and Galloway, T. S., 2013. The physical impacts of

474

microplastic s on marine organism s: A review. Environmental Pollution 178, 4 83-492.

475

Yıldırım Y., Ozolcer I.H., and Capar O.F. 2004. A case study of rehabilitation of

476

uncontrolled municipal solid waste landfill site in the province of Zonguldak. In: 6th

477

International Congress on Advances in Civil Engineering (Istanbul, Turkey, 6-8 October

478

2004), 10 pp.

479

Zhao, S., Zhu, L., Wang, T., and Li, D., 2014. Suspended microplastics in the surface water

480

of the Yangtze Estuary System, China: First observations on occurrence, distribution. Marine

481

Pollution Bulletin 86, 562–568.

SC

RI PT

471

482

AC C

EP

TE D

M AN U

483

ACCEPTED MANUSCRIPT Table 1. Sampling stations, their distance from the coast, coordinates and microplastic concentrations Stations G2

Distance (nautical.mile) 2

Longitude (N) 41º 01’ 51”

Latitude (E) 38º 38’ 14”

T2

2

41o 10’ 24”

39o 25’ 23”

o

o

MP concentration (x103 par. m-3) November February 0.31 1.88 1.02

0.41

2

40 59’ 44”

40 14’ 27”

1.24

0.60

P2

2

41o 14’ 27”

40º 54’ 32”

0.48

0.21

K2

2

41o 31’ 48”

41º 30’ 29”

0.39

G8 T8

o

8

41 06’ 07” o

41 15’ 37”

8

o

o

38 34’ 39” o

39 21’ 07 o

2.59 0.16

C8

8

41 04’ 02”

40 07’ 46”

1.38

P8

8

41o 19’ 28”

40o 49’ 09”

3.28

T15

41 35’ 11” o

15

41 21’ 04” o

15

41 24’ 33”

40 23’ 42” o

39 15’ 27” o

40 42’ 52”

0.67

TE D EP AC C

1.01 -

0.98 1.09

0.16

-

0.38

2.68

0.19

M AN U

P15

8

o

0.20

SC

K8

o

RI PT

C2

ACCEPTED MANUSCRIPT Table 2. Mean microplastic concentration (± standard deviation) and zooplankton abundance (± standard deviation) in the inshore (2 miles) and offshore (8 and 15 miles) stations during November 2014 and February 2015.

Zooplankton abundance 3 -3 (x10 ind. m ) November February

2 miles

0.69 (±0.42)

0.66 (±0.70)

4.37 (±2.05)

11.42 (±16.05)

8 miles

1.62 (±1.30)

0.65 (±0.52)

4.43 (±1.98)

2.93 (±1.70)

15 miles

1.34 (±1.89)

0.28 (±0.14)

11.43 (±9.40)

5.64 (±1.36)

AC C

EP

TE D

M AN U

SC

Stations distance

RI PT

MP concentration 3 -3 (x10 par. m ) November February

ACCEPTED MANUSCRIPT Table 3. Comparison with previous studies

China, Yangtze Estuary

Mesh size (µm) 32

Mean MP (par. m-3) 500-10200

Occurrence (%) 100

microplastic/zooplankton (par. m-3/ ind. m-3)

SE Korea, coast

50

592-1299

84

Sweden, coast

80

150-2400

NE Pacific (off British Columbia CA) SE Black Sea

62.5-250

8- 9180

100

200

600-1200

92

NE Atlantic

250

2.46

94

Portugal, coast

180-335

0.002-0.036

93

0.04-0.14

Southern California coast

333

5-7.25

100

0.6

Moore et al. 2002

Southern California offshore Sweden, coast

333

3.92

0.3

Latin et al., 2004

450

0.01 -0.04

Kang et al., 2015a Norén et al. 2008 Desforges et al. 2014*

Lusher et al. 2014*

0.116

90

500

0.15

100

China, Yangtze Estuary

333

0.03-0.455

SE Korea, coast

330

4.22-44.28

SE Korea

330

1.92-5.51

0.5

M AN U

333

Central-W Mediterranean

0.004-0.086

TE D

*the studies used water pump to collect subsurface water (1-5m) for MP concentration

EP

This study

RI PT

0.25

Frias et al. 2014

Norén et al. 2008

NW Mediterranean

AC C

References Zhao et al. 2014*

SC

Study area

Collignon et al. 2012

Lucia et al. 2014 Zhao et al. 2014* Kang et al., 2015a Kang et al., 2015b

AC C

EP

TE D

M AN U

SC

RI PT

ACCEPTED MANUSCRIPT

ACCEPTED MANUSCRIPT Figure 5. Microplastic concentration (x103 par. m-3) and zooplankton abundance (x103 ind. m3

) in the inshore (2 miles) and offshore (8 and 15 miles) stations during November 2014 and

February 2015. Stations numbers are shown in the map of MP in November. Stations where no microplastic was found are represented with a cross. Overlaid on the image are the bathymetric contours at depths of 200 meters (black line) and 1000 meters (grey line). Surface

AC C

EP

TE D

M AN U

SC

RI PT

geostrophic currents (zoomed from Figure 2) during the sampling period are also shown.

M AN U

SC

RI PT

ACCEPTED MANUSCRIPT

AC C

EP

TE D

Figure 1. Map showing countries, major cities (main land-based sources), hot spots of marine pollution (adapted from BSC, 2007), rivers (1-Danube, 2-Dniester, 3- Bug, 4- Dnieper and 5Don) that flow into the Black Sea basin, sampling stations, bathymetry and a basic schematic representation of the Rim Current in the Black Sea.

AC C

EP

TE D

M AN U

SC

RI PT

ACCEPTED MANUSCRIPT

ACCEPTED MANUSCRIPT

AC C

EP

TE D

M AN U

SC

RI PT

Figure 2. Satellite derived Sea surface temperature (SST), Chl-a and surface geostrophic currents during the sampling period in the region.

SC

RI PT

ACCEPTED MANUSCRIPT

AC C

EP

TE D

M AN U

Figure 3. Wind speed (bars) and direction (arrows) during the sampling period in the region.

RI PT

ACCEPTED MANUSCRIPT

SC

Figure 4. Relative contribution of fragments, films and fibers to total microplastic

AC C

EP

TE D

M AN U

concentrations during November 2014 (A) and February 2015 (B).

EP

TE D

M AN U

SC

RI PT

ACCEPTED MANUSCRIPT

AC C

Figure 6 .Relative contributions of main groups to the total zooplankton abundance during November 2014 (A) and February 2015 (B).

ACCEPTED MANUSCRIPT Highlights Values of neustonic microplastic are reported for the first time in the Black Sea

•

Microplastics (<5 mm) were found in 92% of the neustonic samples.

•

The primary types were fibres and no micro beads were found.

•

Mean microplastic concentrations were 1.2x103 par. m-3 and 0.6x103 par. m-3 in November of 2014 and February of 2015, respectively

AC C

EP

TE D

M AN U

SC

RI PT

•