Reference values of hair toxic trace elements content in occupationally non-exposed Russian population

Reference values of hair toxic trace elements content in occupationally non-exposed Russian population

Accepted Manuscript Title: Reference values of hair toxic trace elements content in occupationally non-exposed Russian population Author: Anatoly V. S...

337KB Sizes 1 Downloads 46 Views

Accepted Manuscript Title: Reference values of hair toxic trace elements content in occupationally non-exposed Russian population Author: Anatoly V. Skalny Margarita G. Skalnaya Alexey A. Tinkov Eugeny P. Serebryansky Vasily A. Demidov Yulia N. Lobanova Andrei R. Grabeklis Elena S. Berezkina Irina V. Gryazeva Andrey A. Skalny Alexandr A. Nikonorov PII: DOI: Reference:

S1382-6689(15)00119-2 http://dx.doi.org/doi:10.1016/j.etap.2015.05.004 ENVTOX 2260

To appear in:

Environmental Toxicology and Pharmacology

Received date: Revised date: Accepted date:

21-3-2015 8-5-2015 10-5-2015

Please cite this article as: Skalny, A.V., Skalnaya, M.G., Tinkov, A.A., Serebryansky, E.P., Demidov, V.A., Lobanova, Y.N., Grabeklis, A.R., Berezkina, E.S., Gryazeva, I.V., Skalny, A.A., Nikonorov, A.A.,Reference values of hair toxic trace elements content in occupationally non-exposed Russian population, Environmental Toxicology and Pharmacology (2015), http://dx.doi.org/10.1016/j.etap.2015.05.004 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.

1

Reference values of hair toxic trace elements content in occupationally non-exposed

2

Russian population

3 4

Anatoly V. Skalny 1,2,3, Margarita G. Skalnaya 2,3, Alexey A. Tinkov 1,4, Eugeny P. Serebryansky

5

3

6

Irina V. Gryazeva 3, Andrey A. Skalny 3,5, Alexandr A. Nikonorov 4

, Elena S. Berezkina

8

1

9

Sovetskaya st., 14, Yaroslavl, 150000, Russia

,

us

Laboratory of biotechnology and applied bioelementology, Yaroslavl State University,

10

2

11

UNESCO), Orenburg State University, Pobedy Ave. 13, Orenburg 460352, Russia

12

3

13

Zemlyanoy Val St. 46, Moscow 105064, Russia

14

4

15

460000, Russia

16

5

17

Agency, Bekhtereva str. 1, St. Petersburg 192019, Russia

an

Institute of Bioelementology (Russian Satellite Centre of Trace Element – Institute for

M

Russian Society of Trace Elements in Medicine, ANO “Centre for Biotic Medicine”,

te

d

Department of Biochemistry, Orenburg State Medical University, Sovetskaya St., 6, Orenburg,

Federal State Scientific Institution “Institute of Toxicology”, Federal Medico-Biological

Ac ce p

18

3,5

cr

7

3,5

ip t

, Vasily A. Demidov 3, Yulia N. Lobanova 3, Andrei R. Grabeklis

19

Corresponding author

20

Alexey A. Tinkov, MD, PhD

21

Laboratory of biotechnology and applied bioelementology, Yaroslavl State University,

22

Sovetskaya st., 14, Yaroslavl, 150000, Russia

23

Tel: +7-961-937-81-98

24

E-mail: [email protected]

25 26

1 Page 1 of 11

Abstract

2

A total of 5908 occupationally non-exposed adults (4384 women and 1524 men) living in

3

Moscow and Moscow region were involved in the current investigation. Hair Al, As, Be, Bi, Cd,

4

Hg, Li, Ni, Pb, Sn, Sr content was estimated by inductively-coupled plasma mass spectrometry

5

using NexION 300D. Men are characterized by significantly higher hair Al, As, Cd, Hg, Li, and

6

Pb content. At the same time, hair levels of Bi, Ni, Sn, and Sr were significantly higher in

7

women. Consequently, the reference ranges were estimated for male, female, and general cohort

8

as coverage intervals in accordance with IUPAC recommendations.

us

cr

ip t

1

9

Key words: inductively coupled plasma mass spectrometry; trace elements; hair; reference

11

ranges; coverage intervals; IUPAC recommendations

an

10

M

12

1. Introduction

14

Heavy metal exposure has been shown to be associated with a number of diseases (Järup, 2003)

15

and its monitoring is an essential part of environmental and health care (Wolterbeek, 2002). Hair

16

has been widely used as a bioindicator of human exposure to heavy metals (Bencko, 1995). It

17

has been shown that hair may successfully reflect environmental and occupational exposure to

18

lead (Sen, 1996), mercury (Kruzikova et al., 2009), aluminium (Yokel, 1982) and combination of

19

multiple metals (Wang and Fu, 2009). At the same time, a number of side factors like

20

demography, lifestyle and geography (Christensen, 1995) may affect hair trace element content.

21

Despite the presence of a number of studies indicating reference ranges of hair metal content, the

22

existing data are inconsistent (Mikulewicz et al., 2013). Therefore, the primary aim of the current

23

study is estimation of reference ranges of hair toxic trace elements content in adult Russian

24

population.

Ac ce p

te

d

13

25 26

2. Materials and methods 2 Page 2 of 11

A total of 5908 occupationally non-exposed adults (4384 women and 1524 men) aged from 20 to

2

60 years and living in Moscow and Moscow region were involved in current investigation. The

3

investigation has been carried out in accordance with the principles of the Declaration of

4

Helsinki for studies involving humans and was approved by the Local Ethics Committee. All

5

examinees gave their informed consent prior to the inclusion in the study.

6

The participants were selected for the study with the use of the following exclusion criteria: i)

7

occupational exposure to toxic metals; ii) smoking (both present and former smokers); iii) acute

8

inflammatory diseases; iv) endocrine disorders; v) metallic implants; vi) pregnancy and lactation;

9

vii) vegetarian diet, viii) alcohol abuse.

us

cr

ip t

1

Proximal parts of occipital scalp hair (0.1 gram) were collected. Briefly, hair samples were

11

washed with acetone and then rinsed thrice with deionized water (Zhao et al., 2012). After

12

washing hair samples were dried at 60°C on air with subsequent microwave degradation. Briefly,

13

0.05 g of hair samples were introduced into Teflon tubes and added with concentrated HNO3.

14

Digestion was performed in a Berghof speedwave four system during 20 minutes at 170-180°C.

15

The obtained solutions were added with distilled deionized water to a final volume of 15 ml.

16

Hair toxic trace element content (Al, As, Be, Bi, Cd, Hg, Li, Ni, Pb, Sn, Sr) was estimated by

17

inductively-coupled plasma mass spectrometry with NexION 300D (PerkinElmer Inc., Shelton,

18

CT 06484, USA) using Dynamic Reaction Cell technology removing the majority of

19

interferences with minimal loss of analyte sensitivity and equipped with ESI SC-2 DX4

20

autosampler (Elemental Scientific Inc., Omaha, NE 68122, USA).

21

Manufacturer’s specifications were used for ICP-MS system preparation. Calibration was

22

performed using standards containing 0.5, 5, 10, and 50 μg/l ultra-trace elements prepared from

23

Universal Data Acquisition Standards Kit (PerkinElmer Inc., Shelton, CT 06484, USA) by

24

dilution with distilled deionized water acidified with 1% HNO3. An internal online

25

standardization using yttrium-89 isotope was also performed. Internal standard containing 10

26

μg/l yttrium was prepared from Yttrium (Y) Pure Single-Element Standard (PerkinElmer Inc.,

Ac ce p

te

d

M

an

10

3 Page 3 of 11

Shelton, CT 06484, USA) on a matrix containing 8% 1-butanol (Merck KGaA), 0.8% Triton X-

2

100 (Sigma-Aldrich, Co.), 0.02% tetramethylammonium hydroxide (Alfa-Aesar, Ward Hill, MA

3

01835 USA), and 0.02% ethylenediaminetetraacetic acid (Sigma-Aldrich, Co). For laboratory

4

quality control the certified reference material of human hair GBW09101 (Shanghai Institute of

5

Nuclear Research, Shanghai, China) was used.

6

All analyses were performed in accredited clinic-diagnostic laboratory of autonomous non-profit

7

organization “Centre for Biotic Medicine” (Moscow, Russia), International Union of Pure and

8

Applied Chemistry (IUPAC) company associate.

9

The obtained data were treated with Statistica 11 software (Statsoft, USA). Data distribution was

10

evaluated by the Shapiro-Wilk test. As the distribution was not Gaussian, all variables were log

11

transformed to approximate a normal distribution. Natural logarithms were used for further

12

statistical analyses. One-way ANOVA with Fisher’s LSD post hoc test were used for group

13

comparisons. The values were considered significantly different at p < 0.05.

14

The reference values of hair toxic trace elements content were based on calculation of the 0.95

15

coverage intervals with 0.95 confidence intervals for the upper and lower limits in accordance

16

with IUPAC recommendations (Poulsen et al., 1997).

cr

us

an

M

d

te

Ac ce p

17

ip t

1

18

3. Results and discussion

19

The descriptive statistics of the male and female cohorts (Table 1) indicates that age of the

20

examinees was not statistically different between the gender groups (p = 0.245). Hair trace

21

elements analysis in men and women (Table 1) indicated that the hair level of certain trace

22

elements is sex-related. In particular, men are characterized by significantly higher hair

23

aluminium (p < 0.001), arsenic (p < 0.001), cadmium (p < 0.001), lithium (p = 0.001), mercury

24

(p = 0.002), and lead (p < 0.001) content. At the same time, hair levels of bismuth (p < 0.001),

25

nickel (p < 0.001), tin (p < 0.001), and strontium (p < 0.001) were significantly higher in women

26

in comparison to the respective values in men. No significant difference was found between men 4 Page 4 of 11

and women in hair beryllium content (p = 0.222). Hypothetically, significantly increased hair

2

mercury, lead, arsenic, and aluminium content in males may result from increased outdoor

3

activity in men. The obtained data is in agreement with earlier studies indicating sex-related

4

difference in hair cadmium, lead (DiPietro et al., 1989), arsenic (Wolfsperger et al., 1994),

5

mercury (Shimomura et al., 1980), nickel (Michalak et al., 2012), aluminium (Chojnacka et al.,

6

2010), and strontium (Dongarra et al., 2011). At the same time, our research data on hair tin

7

content are in contrast to the study of Chojnacka et al. (2010), who have failed to detect a

8

significant gender difference in hair Sn levels. Consequently, sex-specific reference ranges

9

should be used while using hair as an indicator of environmental exposure.

us

cr

ip t

1

Reference ranges calculated as coverage intervals for hair toxic element content in a males,

11

females and general cohort are provided in Table 2. The obtained data on adults’ hair metal

12

content reference ranges are generally comparable with earlier published studies performed in

13

Sweden (Rodushkin and Axelsson, 2000), France (Goullé et al., 2005), and Poland (Chojnacka et

14

al., 2010). At the same time, the most significant difference between our reference ranges and the

15

recently published ones were observed in the case of hair cadmium, lead, mercury, and strontium

16

content. It is notable that in the studied cohort hair cadmium and lead content was significantly

17

lower than the respective values postulated in all three previous studies (Rodushkin and

18

Axelsson, 2000; Goullé et al., 2005; Chojnacka et al., 2010). The opposite situation was

19

observed in the case of hair mercury and strontium. In particular, our reference values were

20

higher than the reference values obtained for hair levels of these metals by Rodushkin and

21

Axelsson, 2000, Goullé et al., 2005, and Chojnacka et al., 2010. It should be noted that our

22

recent data is generally comparable with our earlier published reference values obtained by

23

means of inductively coupled plasma atomic emission spectrometry (Skalny, 2003). The

24

observed difference in reference ranges of hair trace element content may be a consequence of a

25

number of factors, like geographical location, climate, and the overall development of industry in

26

the selected location (Christensen, 1995). Moreover, all four studies involved examinees of

Ac ce p

te

d

M

an

10

5 Page 5 of 11

different ages that may also have a significant influence on hair trace elements content

2

(Ambeskovic et al., 2013). Finally, various statistical approaches to estimation of the reference

3

ranges may also result in some contradictions.

4

Generally, the reference ranges for hair toxic trace element in male, female, and general samples

5

have been estimated. Consistency of the obtained data with previously published studies, a large

6

number of samples examined, and the use of Dynamic Reaction Cell technology during analysis

7

indicate high quality of the data obtained. The estimated reference ranges may be used in

8

environmental risk assessment (Tamburo et al., 2011).

us

cr

ip t

1

9

Conclusions

11

The present study has demonstrated that men are characterized by significantly higher hair Al,

12

As, Cd, Hg, Li, and Pb content. Hair levels of Bi, Ni, Sn, and Sr were significantly higher in

13

women. Consequently, the reference ranges calculated as coverage intervals in accordance with

14

IUPAC recommendations are different for males, females, and the general cohort.

15

te

d

M

an

10

Acknowledgements

17

The current research is supported by Russian Ministry of Education and Science within project

18

No. 2014/258-544. The authors would like to thank the anonymous reviewers for their helpful

19

comments and suggestions that significantly improved the manuscript quality.

20

Ac ce p

16

21

Conflict of interest

22

The authors declare that there are no conflicts of interest

23 24

References

6 Page 6 of 11

1

1. Ambeskovic, M., Fuchs, E., Beaumier, P., Gerken, M., Metz, G.A., 2013. Hair trace

2

elementary profiles in aging rodents and primates: links to altered cell homeodynamics

3

and disease. Biogerontology 14, 557-567.

7 8 9

ip t

6

pollutants in occupational and environmental settings. Toxicology 101, 29-39.

3. Chojnacka, K., Zielińska, A., Górecka, H., Dobrzański, Z., Górecki, H., 2010. Reference values for hair minerals of Polish students. Environ. Toxicol. Pharmacol. 29, 314-9.

cr

5

2. Bencko, V., 1995. Use of human hair as a biomarker in the assessment of exposure to

4. Christensen, J.M., 1995 Human exposure to toxic metals: factors influencing

us

4

interpretation of biomonitoring results. Sci. Total Environ. 166, 89-135. 5. DiPietro, E.S., Phillips, D.L., Paschal, D.C., Neese, J.W., 1989. Determination of trace

11

elements in human hair. Reference intervals for 28 elements in nonoccupationally

12

exposed adults in the US and effects of hair treatments. Biol. Trace Elem. Res. 22, 83-

13

100.

M

an

10

6. Dongarrà, G., Lombardo, M., Tamburo, E., Varrica, D., Cibella, F., Cuttitta, G., 2011.

15

Concentration and reference interval of trace elements in human hair from students living

16

in Palermo, Sicily (Italy). Environ. Toxicol. Pharmacol. 32, 27-34.

18 19 20 21 22

te

Ac ce p

17

d

14

7. Goullé, J.P., Mahieu, L., Castermant, J., Neveu, N., Bonneau, L., Lainé, G., Bouige, D., Lacroix, C., 2005. Metal and metalloid multi-elementary ICP-MS validation in whole blood, plasma, urine and hair. Reference values. Forensic Sci. Int. 153, 39-44.

8. Järup, L., 2003. Hazards of heavy metal contamination. Br. Med. Bull. 68, 167-82. 9. Kruzikova, K., Kensova, R., Blahova, J., Harustiakova, D., Svobodova, Z., 2009. Using human hair as an indicator for exposure to mercury. Neuro Endocrinol. Lett. 30, 177-81.

23

10. Michalak, I., Mikulewicz, M., Chojnacka, K., Wołowiec, P., Saeid, A., Górecki, H.,

24

2012. Exposure to nickel by hair mineral analysis. Environ. Toxicol. Pharmacol. 34,

25

727-34.

7 Page 7 of 11

1 2

11. Mikulewicz, M., Chojnacka, K., Gedrange, T., Górecki, H., 2013. Reference values of elements in human hair: a systematic review. Environ. Toxicol. Pharmacol. 36, 1077-86. 12. Poulsen, O.M., Holst, E., Christensen, J.M., 1997. Calculation and application of

4

coverage intervals for biological reference values. Pure Appl. Chem. 69, 1601-1611.

5

13. Rodushkin, I., Axelsson, M.D., 2000. Application of double focusing sector field ICP-MS

6

for multielemental characterization of human hair and nails. Part II. A study of the

7

inhabitants of northern Sweden. Sci. Total. Environ. 262, 21-36.

10 11

cr

Lead Exposure. J. Hum. Ecol. 7, 133-141.

us

9

14. Sen, J., 1996. Human Scalp Hair As An Indicator of Environmental Lead Pollution and

15. Shimomura, S., Kimura, A., Nakagawa, H., Takao, M.., 1980. Mercury levels in human

an

8

ip t

3

hair and sex factors. Environ. Res. 22, 22-30.

16. Skalny, A. V., 2003. Reference values of chemical elements concentration in hair,

13

obtained by means of ICP-AES method in ANO Centre for Biotic Medicine. Trace.

14

Elem. Med. 4, 55-56.

d

M

12

17. Tamburo, E., Dongarrà, G., Varrica, D., D’Andrea, D., 2011. Trace elements in hair of

16

urban schoolboys: a diagnostic tool in environmental risk assessment. Geophysical

18 19 20 21

Ac ce p

17

te

15

Research Abstracts 13, 1157

18. Wang, T., Fu, J., Wang, Y., Liao, C., Tao, Y., Jiang, G., 2009. Use of scalp hair as indicator of human exposure to heavy metals in an electronic waste recycling area. Environ. Pollut. 157, 2445-51.

19. Wolfsperger, M., Hauser, G., Gössler, W., Schlagenhaufen, C., 1994. Heavy metals in

22

human hair samples from Austria and Italy: influence of sex and smoking habits. Sci.

23

Total Environ. 156, 235-42.

24 25

20. Wolterbeek, B., 2002. Biomonitoring of trace element air pollution: principles, possibilities and perspectives. Environ. Pollut. 120, 11-21.

8 Page 8 of 11

1 2

21. Yokel, R.A., 1982. Hair as an indicator of excessive aluminum exposure. Clin. Chem. 28, 662-5. 22. Zhao, L.J., Ren, T., Zhong, R.G., 2012. Determination of lead in human hair by high

4

resolution continuum source graphite furnace atomic absorption spectrometry with

5

microwave digestion and solid sampling. Analyt. Lett. 45, 2467-81.

ip t

3

Ac ce p

te

d

M

an

us

cr

6

9 Page 9 of 11

cr

ip t

Table 1

Men (n = 1524)

Women (n = 4384)

Parameter Mean

SD

Median P5

P95

an

P95

Mean

General sample (n = 5908) SD

Median P5

P95

Mean

SD

37.026

22.575 56.306 37.914 10.306

36.314

22.969 55.894 37.560 10.198

36.506

22.844 56.008 37.651 8.646

Al, μg/g

5.704

1.926

21.436 7.876

8.439

4.876

1.742

16.020 6.609

8.694

6.936

1.785

16.958 6.936

0.110

As, μg/g

0.046

0.019

0.213

0.074

0.149

0.021

0.006

0.097

0.035

0.091

0.045

0.007

0.135

0.045

0.026

Be, μg/g

0.002

0.000

0.014

0.003

0.008

0.002

0.000

0.010

0.003

0.030

0.003

0.000

0.011

0.003

1.931

Bi, μg/g

0.036

0.007

0.342

0.187

1.917

0.043

0.007

0.735

0.251

1.937

0.234

0.007

0.674

0.234

0.309

Cd, μg/g

0.015

0.004

0.168

0.063

0.594

0.011

0.003

0.070

0.024

0.074

0.034

0.003

0.090

0.034

1.003

Hg, μg/g

0.566

0.076

2.744

0.891

1.086

0.498

0.112

2.002

0.734

0.969

0.775

0.106

2.212

0.775

0.115

Li, μg/g

0.013

0.005

0.070

0.026

0.167

0.010

0.005

0.063

0.023

0.091

0.024

0.005

0.065

0.024

1.057

Ni, μg/g

0.198

0.078

0.809

0.303

0.504

0.265

0.091

1.167

0.451

1.188

0.413

0.087

1.057

0.413

14.943

Pb, μg/g

0.501

0.121

4.689

2.528

29.289

0.295

0.083

1.462

0.532

1.408

1.046

0.088

2.142

1.046

2.568

Sn, μg/g

0.088

0.028

0.402

0.212

2.938

0.133

0.025

2.760

0.647

2.416

0.535

0.026

2.151

0.535

18.468

Sr, μg/g

1.119

0.313

6.624

2.102

4.097

3.990

0.683

25.370 8.696

21.157

6.935

0.455

20.319 6.935

ep te

d

M

Age, years

Ac c

Median P5

us

Table 1. Descriptive statistics of age and hair toxic trace elements content in adult men and women

8.646

P5, P95 – 5 and 95 percentile boundaries; SD – standard deviation;

Page 10 of 11

Table 2

Table 2. Coverage intervals for hair trace elements content in adult Russian population calculated in accordance with IUPAC recommendations. Men (n = 1524)

Women (n = 4384)

General sample (n = 5908)

Al, μg/g

3.355-15.279

2.778-10.545

2.913-11.627

As, μg/g

0.036-0.117

0.008-0.062

0.010-0.078

Be, μg/g

0.000-0.007

0.000-0.005

0.000-0.005

Bi, μg/g

0.017-0.234

0.017-0.336

0.014-0.342

Cd, μg/g

0.009-0.088

0.005-0.042

0.006-0.056

Hg, μg/g

0.130-1.365

0.185-1.094

0.168-1.189

Li, μg/g

0.009-0.039

0.009-0.040

Ni, μg/g

0.132-0.540

0.168-0.779

0.159-0.704

Pb, μg/g

0.291-2.358

0.160-0.917

0.187-1.389

Sn, μg/g

0.051-0.265

0.082-1.158

0.076-1.009

Sr, μg/g

0.650-4.173

1.570-15.181

1.148-10.929

δ

0.008

cr

us

an

M

ed

0.005

0.009-0.040

0.004

ce pt

δ – coverage uncertainty;

ip t

Metal content

β level of expectation in coverage interval - 0.95;

Ac

γ level of confidence of the coverage uncertainty - 0.95.

Page 11 of 11