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International Journal of Hygiene and Environmental Health 256 (2024) 114298
Contents lists available at
ScienceDirect
International Journal of Hygiene and Environmental Health
journal homepage:
www.elsevier.com/locate/ijheh
Hexavalent chromium still a concern in Sweden
Evidence from a
cross-sectional study within the SafeChrom project
Zheshun Jiang
a
, Linda Schenk
b
, Eva Assarsson
a
, Maria Albin
a, b
, Helen Bertilsson
c
,
Eva Dock
a, d
, Jessika Hagberg
e
, Lovisa E. Karlsson
f
, Pete Kines
g
, Annette M. Krais
a
,
¨
Stefan Ljunggren
h
, Thomas Lundh
a
, Lars Modig
c
, Rickie Moller
i
, Daniela Pineda
a
,
f
g
i
¨
Niklas Ricklund , Anne T. Saber , Tobias Storsjo , Evana Taher Amir
j
, Håkan Tinnerberg
i, k
,
l, m
g
Martin Tondel , Ulla Vogel , Pernilla Wiebert
b, j
, Karin Broberg
a, b, g, *
, Malin Engfeldt
a, d
a
Division of Occupational and Environmental Medicine, Department of Laboratory Medicine, Lund University, Lund, Sweden
Institute of Environmental Medicine, Karolinska Institutet, Stockholm, Sweden
c
Department of Public Health and Clinical Medicine, Sustainable Health, Umeå University, Umeå, Sweden
d
Occupational and Environmental Medicine, Region Skåne, Lund, Sweden
e
¨
¨
Department of Occupational and Environmental Health, Faculty of Business, Science and Engineering, Orebro University, Orebro, Sweden
f
¨
¨
Department of Occupational and Environmental Medicine, Orebro University Hospital, Region Orebro County, Sweden
g
National Research Centre for the Working Environment, Copenhagen, Denmark
h
Occupational and Environmental Medicine Center in Link
¨
ping, Department of Health, Medicine and Caring Sciences, Link
¨
ping University, Link
¨
ping, Sweden
o
o
o
i
Occupational and Environmental Medicine, Sahlgrenska University Hospital, Gothenburg, Sweden
j
Centre for Occupational and Environmental Medicine, Region Stockholm, Stockholm, Sweden
k
Occupational and Environmental Medicine, School of Public Health and Community Medicine, Institute of Medicine, University of Gothenburg, Gothenburg, Sweden
l
Occupational and Environmental Medicine, Department of Medical Sciences, Uppsala University, Uppsala, Sweden
m
Occupational and Environmental Medicine, Uppsala University Hospital, Uppsala, Sweden
b
A R T I C L E I N F O
Keywords:
Hexavalent chromium
Occupational cancer
Inhalable
Biomonitoring
Occupational exposure limits
A B S T R A C T
Objectives:
Hexavalent chromium (Cr(VI)) is classified as a human carcinogen. Occupational Cr(VI) exposure can
occur during different work processes, but the current exposure to Cr(VI) at Swedish workplaces is unknown.
Methods:
This cross-sectional study (SafeChrom) recruited non-smoking men and women from 14 companies with
potential Cr(VI) exposure (n
=
113) and controls from 6 companies without Cr(VI) exposure (n
=
72). Inhalable
Cr(VI) was measured by personal air sampling (outside of respiratory protection) in exposed workers. Total Cr
was measured in urine (pre- and post-shift, density-adjusted) and red blood cells (RBC) (reflecting Cr(VI)) in
exposed workers and controls. The Bayesian tool Expostats was used to assess risk and evaluate occupational
exposure limit (OEL) compliance.
Results:
The exposed workers performed processing of metal products, steel production, welding, plating, and
various chemical processes. The geometric mean concentration of inhalable Cr(VI) in exposed workers was 0.15
μ
g/m
3
(95% confidence interval: 0.11–0.21). Eight of the 113 exposed workers (7%) exceeded the Swedish OEL
of 5
μ
g/m
3
, and the Bayesian analysis estimated the share of OEL exceedances up to 19.6% for stainless steel
welders. Median post-shift urinary (0.60
μ
g/L, 5th-95th percentile 0.10–3.20) and RBC concentrations (0.73
μ
g/
L, 0.51–2.33) of Cr were significantly higher in the exposed group compared with the controls (urinary 0.10
μ
g/
L, 0.06–0.56 and RBC 0.53
μ
g/L, 0.42–0.72). Inhalable Cr(VI) correlated with urinary Cr (r
S
=
0.64) and RBC-Cr
(r
S
=
0.53). Workers within steel production showed the highest concentrations of inhalable, urinary and RBC Cr.
Workers with inferred non-acceptable local exhaustion ventilation showed significantly higher inhalable Cr(VI),
urinary and RBC Cr concentrations compared with those with inferred acceptable ventilation. Furthermore,
workers with inferred correct use of respiratory protection were exposed to significantly higher concentrations of
Cr(VI) in air and had higher levels of Cr in urine and RBC than those assessed with incorrect or no use. Based on
the Swedish job-exposure-matrix, approximately 17 900 workers were estimated to be occupationally exposed to
Cr(VI) today.
* Corresponding author. Division of Occupational and Environmental Medicine, Department of Laboratory Medicine, Lund University, SE-221 85, Lund, Sweden.
E-mail address:
[email protected]
(K. Broberg).
https://doi.org/10.1016/j.ijheh.2023.114298
Received 11 September 2023; Received in revised form 24 November 2023; Accepted 24 November 2023
1438-4639/© 2023 The Authors. Published by Elsevier GmbH. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/).
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Z. Jiang et al.
International Journal of Hygiene and Environmental Health 256 (2024) 114298
Conclusions:
Our study demonstrates that some workers in Sweden are exposed to high levels of the non-threshold
carcinogen Cr(VI). Employers and workers seem aware of Cr(VI) exposure, but more efficient exposure control
strategies are required. National strategies aligned with the European strategies are needed in order to eliminate
this cause of occupational cancer.
Abbreviations
8-h TWA 8-h time-weighted average
BLV
Biological limit value
BMI
Body mass index
CI
Confidence interval
CIS
Conical inhalable sampler
Cr
Chromium
Cr(III)
Trivalent chromium
Cr(VI)
Hexavalent chromium
EU
The European Union
EC
European Commission
EPA
Environmental Protection Agency
G-EQUAS German External Quality Assessment Scheme
GM
Geometric mean
GSP
Gesamtstaubprobenahme sampler
HBM4EU The European Human Biomonitoring Initiative
IARC
International Agency for Research on Cancer
ICP-MS Inductively coupled plasma mass spectrometry
ISCO-08 International Standard Classification of Occupation 2008
JEM
Job-Exposure-Matrix
LEV
Local exhaustion ventilation
LOD
LOQ
MAG
MIG
MMA
NIOSH
OEL
P5
P25
P75
P95
RBC
RBC-Cr
REACH
RPE
SNI
SOP
SSYK
TIG
WBC
Limit of detection
Limit of quantification
Metal active gas
Metal inert gas
Manual metal arc
National Institute for Occupational Safety and Health
Occupational exposure limit
5th percentile
25th percentile
75th percentile
95th percentile
Red blood cells
Chromium concentration in red blood cells
The Registration, Evaluation, Authorisation and
Restriction of Chemicals
Respiratory protective equipment
Swedish Standard Industrial Classification
Standard operating procedure
Swedish Standard Classification of Occupations
Tungsten inert gas
White blood cells
1. Introduction
The element chromium (Cr) is primarily present as trivalent chro-
mium (Cr(III)) and hexavalent chromium (Cr(VI)) in occupational set-
tings (Pan
et al., 2018).
Cr(VI) and its compounds are used in industrial
applications like electroplating and chromate production and Cr(VI) can
also be formed during steel production and welding (IARC,
2012).
Occupational exposure to Cr(VI) can occur through inhalation, dermal
contact and hand-to-mouth exposure (Beattie
et al., 2017).
Cr(VI) is considered to be thousand times more toxic than Cr(III) due
to its oxidizing ability and high solubility, resulting in increased cell
membrane permeability (Saha
et al., 2011; ATSDR, 2011).
Cr(VI) is
classified as a human carcinogen (Group 1) by the International Agency
for Research on Cancer (IARC) and causes lung cancer (IARC,
2012).
Epidemiological evidence suggests that workers exposed to Cr(VI) also
have an increased risk of nose and nasal sinus cancer, and non-cancer
effects, especially in the respiratory and reproductive systems, skin,
kidneys, stomach and liver (IARC,
2018).
Cr(VI) is considered a
non-threshold carcinogen and the guiding principle is that the exposure
should be ‘as low as reasonably achievable’ (Mahiout
et al., 2022).
It is
worth noting that Cr(VI) exposed workers can be occupationally
exposed to other toxic metals, such as nickel and lead, and co-exposure
could play a crucial role in development of adverse health effects
(Muller
et al., 2022).
Exposure to Cr(VI) is often assessed by measurements in air, urine or
blood (Viegas
et al., 2022).
Urinary Cr is a common biomarker with a
half-life of approximately 7 h and post-shift urine is often compared with
pre-shift urine to identify possible work-related Cr exposure (Viegas
et al., 2022).
However, urinary Cr represents total Cr and is therefore not
specific for occupational Cr(VI) exposure (Viegas
et al., 2022; Welinder
et al., 1983).
Red blood cells (RBC) take up Cr(VI) but not Cr(III), and the
Cr concentration in RBC (RBC-Cr) thus reflects the amount of Cr(VI) that
2
has entered the bloodstream in its non-reduced form (Goldoni
et al.,
2010a).
Since Cr is bound to haemoglobin within the RBC, it is assumed
that the half-life of RBC-Cr in humans corresponds to the half-life of RBC
(Franco,
2012; Ndaw et al., 2022).
It is suggested that RBC-Cr values
reflect the exposure to Cr(VI) over the past four months (Ndaw
et al.,
2022).
In the European Union (EU), the use of Cr(VI) compounds is autho-
rized under the Registration, Evaluation, Authorisation and Restriction
of Chemicals (REACH) regulation (Viegas
et al., 2022).
The current
binding occupational exposure limit (OEL) set under EU Directive
2004/37/EC is 10
μ
g/m
3
(8-h time-weighted average, 8-h TWA) until
January 17, 2025; after that, the OEL will be 5
μ
g/m
3
(8-h TWA)
(Santonen
et al., 2022).
In France and the Netherlands, OELs of 1
μ
g/m
3
have already been set for Cr(VI) (Viegas
et al., 2022).
Denmark has also
implemented an OEL of 1
μ
g/m
3
and will consider lowering it further to
0.25
μ
g/m (Beattie
et al., 2017; Santonen et al., 2022; Beskæfti-
gelsesministeriet, 2020).
It has been estimated that exposure to air
concentrations of 5
μ
g/m
3
, the current OEL in Sweden, corresponds to
20 extra lung cancer cases per 1000 exposed workers after 40 years of
occupational exposure (i.e. lifetime risk) (C.
European, 2017).
In Ger-
many and the Netherlands, acceptable risk is considered to be an addi-
tional risk of
<4
cases per 100,000 after 40 years, and tolerable risk
(during a transitional period) is considered to be
<
4/1000 (Ding
et al.,
2014).
In the 1990s, it was estimated that around 21 000 workers in
Sweden were occupationally exposed to Cr(VI) (Kauppinen
et al., 2000).
However, despite the strong carcinogenicity of Cr(VI), it is not known
how many workers are exposed today and at what levels.
In order to characterize and minimize occupational Cr(VI) exposure
and toxicity in Sweden, all seven Occupational and Environmental
Medicine clinics in Sweden, in collaboration with the Danish National
Research Centre for the Working Environment and the Finnish Institute
of Occupational Health, initiated the SafeChrom project. Specifically,
SafeChrom aims to: 1. characterize Cr(VI) exposure at different
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Z. Jiang et al.
International Journal of Hygiene and Environmental Health 256 (2024) 114298
workplaces by air monitoring of inhalable Cr(VI) and biomonitoring of
Cr in urine and RBC and to identify adequate monitoring methods for Cr
(VI) exposure; 2. investigate toxicity of current exposure levels by
measuring early markers of Cr(VI)-related chromosome damage and
DNA modifications; 3. evaluate the perception of regulations and risk
management strategies at workplaces using Cr(VI); 4. take advantage of
the Nordic expertise and increase the study base for examining occu-
pational Cr(VI) exposure; 5. develop guidelines for minimizing Cr(VI)
exposure. Here we present the results of the first study aim of
SafeChrom.
2. Material and methods
2.1. Study participants and recruitment
This cross-sectional study of Cr(VI) exposure in the Swedish work
environment (SafeChrom) was carried out by all seven Occupational and
Environmental Medicine clinics in Sweden (Lund, Gothenburg, Link-
¨
¨
oping, Orebro, Stockholm, Uppsala, and Umeå) in collaboration with
their corresponding university divisions. The occupational exposure
assessment, along with the sampling of air, blood, and urine were per-
formed by standard operating procedures (SOPs) used by all partners.
The study and the questionnaire were designed to be as similar as
possible to The European Human Biomonitoring Initiative (HBM4EU)
chromates study protocol (Santonen
et al., 2019).
The recruitment of
study participants in the exposed group was performed between June
2021 and May 2022. Identification of suitable companies was done
either by a) request of interest sent out to customers of Cr analyses
(mainly occupational health care services or occupational safety and
health consultants distributed all over Sweden) informing about the
study or b) occupational hygienists at each clinic that identified com-
panies with potential Cr(VI) exposure in the respective region.
Recruitment was performed by each clinic in a harmonized way: 1.
occupational hygienists contacted the companies via e-mail or phone,
and invited the companies to join the project; 2. managers received an
information leaflet about the background and aim of the project and the
sampling plan; 3. managers informed employees about the study and
identified workers willing to participate in the project; 4. a work site
visit was conducted before the measurements to plan the sampling and
to provide further information about the study; and 5. finally, a visit was
scheduled to the company for air measurement, along with collecting
blood and urine samples from workers who agreed to participate. Bio-
logical sampling was performed when the study participants had worked
for at least three previous consecutive days (for those who worked
Monday to Friday, sampling was carried out on Wednesday at the
earliest).
Controls were recruited between March 2022 to October 2022 from
occupational groups that were considered to have the same gender, a
similar socioeconomic status, education, and exposure to physical
workload but no genotoxic exposures (e.g. from metals, particles or
organic chemicals) as exposed workers. The recruitment procedure of
controls was the same as for the exposed workers. The sampling for
controls was the same as for the exposed workers except that no air
measurement was performed, and biological sampling was possible each
working day. The recruitment of controls took place in southern and
middle Sweden.
The inclusion criteria for the exposed workers were potential expo-
sure to Cr(VI), being 20–68 years of age, and non-smoker
>6
months (as
tobacco smoke may contain Cr(VI) (Rowbotham
et al., 2000)).
The in-
clusion criteria of the control group were the same as the exposed group
except that they should not have a potential exposure to Cr(VI) or other
genotoxic agents via work. All study participants answered the same
questionnaire, except for questions relating to work tasks that differed
between exposed workers and controls. All study participants gave
informed written consent to participate in the study. The study was
approved by the Swedish Ethical Review Authority (Dnr 2021-00641).
3
2.2. Categorisation of companies and work tasks for exposed workers
Based on the expertise of the occupational hygienists, a catego-
risation of the companies was carried out according to the Swedish
Standard Industrial Classification (SNI 2007). In addition, companies
were categorised into four groups: manufacture/processing of metal
products, steel production, bath plating and non-categorised (two
companies that could not be classified into any of the previous cate-
gories) (Supplementary
Table 1).
One of the included companies had
two different divisions and was thus categorised into both steel pro-
duction and manufacture/processing of metal products. Based on the
expertise of the occupational hygienists and the work tasks performed
on the sampling day, a descriptive categorisation of the work tasks was
carried out according to the Swedish Standard Classification of Occu-
pations 2012 (SSYK 2012, 4-digit), which is based on the International
Standard Classification of Occupation 2008 (ISCO-08). In addition, work
tasks were categorised into four groups: welding, process operation,
machining, and others (Supplementary
Table 2).
2.3. Air monitoring
2.3.1. Sampling
The inhalable Cr(VI) fraction was collected using a conical inhalable
sampler (CIS) (Casella, Rutland, United States) mounted with a 37 mm
polyvinyl chloride filter, pore size 5
μ
m (Merck Millipore, Cork, Ireland).
Battery-powered sampling pumps were used to provide a flow rate of
3.5 L/min, which was regularly checked with a digital flow meter
before, during, and after sampling. Due to a temporary shortage of CIS
from Casella, another type of CIS was used: ten individuals were
sampled with a Gesamtstaubprobenahme sampler (GSP) mounted with
the same filter and run at the same flow rate. Measurements were
generally performed during full-shift work, with an average measure-
ment time of 6.7 h. The sampler was placed within the breathing zone.
For workers who were wearing respiratory protection equipment (RPE)
(e.g powered air-purifying respirators, full- or half mask, or filtering half
mask) during sampling, the air outside the RPE was sampled. At least
one field blank was collected per sampling day. If the number of sampled
individuals per day exceeded 10, two field blanks were collected. Field
blanks were sampled by connecting the sampler to the pump without
drawing any air through it whilst mounting and dismounting the
equipment used for the participants at the beginning and the end of the
day. Field blanks were analysed in parallel with the samples.
2.3.2. Chemical analysis
Filter samples of inhalable Cr(VI) were sent for analysis to the
Occupational and Environmental Medicine Laboratory, University
¨
Hospital, Orebro. The samples were analysed by a method modified
from the National Institute for Occupational Safety and Health (NIOSH)
(NIOSH,
2003).
The samples were placed in glass tubes and a 5 ml so-
lution containing sodium hydroxide (1 g/L) and sodium carbonate (1.5
g/L) was added to each tube. The filters were then extracted in an ul-
trasonic bath for 35 min at 40
C. Solid residues were separated from the
samples by centrifugation at 2000 rpm for 10 min. Cationic metals were
removed from the samples by solid phase extraction using Dionex
OnGuardTM II M columns (Thermo Fisher Scientific, GmbH, Bremen,
Germany) and vacuum filtration. The liquid samples were transferred to
autosampler vials. Calibration solutions in six different concentrations
(30–2000 ng/ml) were diluted from a 1000
μ
g/ml certified stock solu-
tion (Spectrascan, Ski, Norway). The calibration solutions were diluted
with the same extraction solution used for the samples. The samples
were analysed by ion chromatography with conductivity detection
(Thermo Fisher Scientific, GmbH, Bremen, Germany, Dionex ICS-2100).
The guard and separation columns used were model Dionex IonPacTM
AG15-5
μ
m and AS15-5
μ
m, respectively. Ten filter blanks (i.e.
non-exposed PVC filters) were extracted and analysed for the calculation
of limit of detection (LOD). Mean value and standard deviation were
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Z. Jiang et al.
International Journal of Hygiene and Environmental Health 256 (2024) 114298
calculated. The LOD was calculated using the following formula: LOD
=
mean value
+
3
×
standard deviation. The LOD was 0.08
μ
g/sample. The
laboratory regularly participates in LGC AXIO proficiency testing
scheme for air and stack emissions (LGC AXIO PT AIR). During the
measurement campaign, proficiency tests showed good agreement be-
tween measured Cr(VI) concentrations in quality control samples and
assigned concentrations.
Due to delayed delivery of solid phase extraction columns, four
samples were analysed by ALS Scandinavia AB in Luleå by a method
based upon SS-EN ISO 17294-2:2016 (CEN) and EPA Method
200.8:1994 (EPA
US, 1994)
using inductively coupled plasma mass
spectrometry (ICP-MS) after alkaline leaching of Cr(VI) according to ISO
15192:2006 (CEN,
2006).
The ALS laboratory used the limit of quanti-
fication (LOQ) as limit of the applied method and six filter blank samples
were extracted and analysed for the calculation of LOQ. Mean value and
standard deviation were calculated. The LOD was calculated using the
following formula: LOQ
=
mean value
+
10
×
standard deviation. The
LOQ was 0.3
μ
g/sample.
2.4. Biological monitoring
2.4.1. Sampling
An informed consent form and a urine sampling kit (including in-
struction, two acid-washed tubes, and one acid-washed cup) for the pre-
shift urine was sent out to every participant before the sampling day. On
the day of the visit, trained nurses collected the signed informed con-
sent, the pre-shift urine sample and sampled blood and post-shift urine
(after the workers had worked at least 4 h). The biological sampling was
performed on the same day as the measurements of inhalable Cr(VI)
fraction. Blood samples were collected in four vacutainer tubes (Becton,
Dickinson and Company, Plymouth, UK): one sodium-heparin tube for
analysis of metals, one lithium-heparin tube for micronuclei, one
vacutainer EDTA tube for other biomarkers of genotoxicity, and one
PAXgene blood RNA tube for RNA (the last three tubes were not
included in this study). Urine and blood samples were kept at 4
C and
transported to the laboratory at the Div. of Occupational and Environ-
mental Medicine, Lund University. After separating blood cells and
plasma from whole blood in the sodium-heparin tubes (details described
below), all blood and urine samples were stored at 20
C until analysis.
In the exposed group, three participants abstained from providing
blood samples, and one abstained from providing pre-shift urine sample.
2.4.2. Chemical analysis
Tubes and tips used in the chemical analysis were washed with acid
(5% HNO
3
and 5% HCl) to remove potential metal contamination. To
avoid haemolysis, plasma and RBC separation was conducted following
the method described by
Devoy et al. (2016).
Blood samples were
separated for 10 min at 1300 g, and the plasma supernatant was
removed. After the separation, a wash step was conducted by adding
0.9% isotonic saline (with a volume corresponding to the initial blood
volume) to the RBC, gently rocked for 5–10 min, separated for 10 min at
1300 g, whereafter the supernatant was removed. The wash was per-
formed two more times before the RBC were processed for metal
analysis.
Cr(VI) exposed workers can be exposed to other toxic metals during
work, thus manganese, cobalt, nickel, copper, zinc, selenium, cadmium,
antimony, mercury, and lead were measured along with Cr. All de-
terminations were performed with ICP-MS (iCAP Q, Thermo Fisher
Scientific, Bremen, accuracy GmbH) equipped with collision cell with
kinetic energy discrimination and helium as collision gas. A sample
volume of 100
μ
L (RBC) and 250
μ
L (urine) was diluted 20 times with an
alkaline solution according to
Barany et al. (1997)
and analysed in
peak-jumping mode, with scandium, rhodium, terbium, and iridium
used as internal standards. The detection limits were calculated as three
times the standard deviation (SD) of the blank and were 0.20
μ
g/L both
for Cr in blood and urine. All analysed samples were prepared and
4
measured in duplicate, and the mean value was used in subsequent
statistical analyses. During the measurement campaign, the laboratory
participated in the German External Quality Assessment Scheme
(G-EQUAS), with good agreement between obtained element concen-
trations in quality control samples used and expected values. The
analytical accuracy was verified towards certified reference materials
from G-EQUAS and SERO AS, Billingstad, Norway (Seronorm). The re-
sults (
μ
g/L, mean
±
SD) obtained for Seronorm (Lot. 2011920) were for
Cr in blood 0.63
±
0.06 vs. recommended 0.48–0.75 and for G-EQUAS
Cr in blood (Lot. R64 1A) 1.80
±
0.21 (n
=
49) vs. recommended
1.1–2.3. For G-EQUAS Cr in urine (Lot. R64 8A and R64 2A) the results
obtained were 0.22
±
0.03 vs. recommended 0.16–0.34 and 3.67
±
0.28
vs. recommended 2.8–4.0, respectively. Quality data for the other
metals analysed are shown in
Supplementary Table 3.
2.5. Measurement of creatinine and density in urine
Density and creatinine were measured in all urine samples for
correction of dilution. The density was measured with a hand-held
refractometer (30PX; Mettler Toledo, USA). The density adjustment
was calculated using the following formula: C(
density-adjusted
)
=
C
×
(1-
ρ
mean
)/(1-
ρ
sample density
), where C
=
the determined Cr concentration in
the sample,
ρ
mean
=
the mean of the urinary density of all participants,
and
ρ
sample density
=
the density of the urine sample. Creatinine was
measured with Atellica (Siemens Healthcare Diagnostics, Munich, Ger-
many; accredited analysis) at the Clinical Chemistry University Hospital,
Lund. Since creatinine excretion often is higher in men (due to gender
differences in muscle mass (Thomas
et al., 2012)),
density adjustment
was more appropriate for the correction of urinary dilution. Neverthe-
less, we also present the creatinine-adjusted urinary Cr for comparison
with other studies.
2.6. Questionnaire and occupational hygienist protocol
A questionnaire was sent to each participant in advance. On the day
of the visit, trained nurses checked that the questionnaires were
completed. The questionnaire contained questions about birth year,
height, weight, residential area, smoking (current smoker, former
smoker, party smoker, and non-smoker), use of electronic cigarettes and
snuff, consumption of alcoholic beverages, coffee, tea, energy drinks,
and supplements, diet, implants, and any leisure activities that may
result in exposure to Cr (e.g. welding, spray painting and metal work).
Moreover, the questionnaire inquired about the respondent’s working
situation, including working years, working tasks, working place (out-
door or indoor), working shift, and hygiene options (changing rooms
and opportunity to shower and wash hands). In addition, the question-
naire given to the exposed group enquired about the details of their
working tasks (i.e.
“plating”, “painting”, “grinding”, “welding”, “ther-
mal spraying”,
“metal
production”, and
“working
in close connection
with the tasks above”), working hour (5 categories, from never to about
3/4 of the working time), performing tasks manually or automatically,
and use of personal protective equipment (nothing, compressed air or
fresh air supplied breathing apparatus, fan-assisted respiratory protec-
tion, reusable respirators (half mask or full mask), disposable protection
(filtering half mask), full protective overalls, gloves, apron), and use of
stationary fume extraction.
During air sampling, the occupational hygienist filled in an obser-
vation protocol for the workplace, as well as an individual observation
protocol for each sampled individual. The occupational hygienist asked
about details of the company (number of employees, production, num-
ber of Cr exposed workers, working shift and working hours), produc-
tion conditions during measurement (3 categories; low, normal, high),
description of the design of the premises, general ventilation (mechan-
ical, windows, doors, and no ventilation), and process ventilation
(containment of emission source and point extraction at emission
source) were recorded. Further, the occupational hygienist made an
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Z. Jiang et al.
International Journal of Hygiene and Environmental Health 256 (2024) 114298
ocular assessment of the use and standard of local exhaustion ventilation
(LEV) and RPE on sampling day. Based on these ocular observations LEV
was categorised as either
“inferred
acceptable” or
“inferred
non-
acceptable” while use of RPE was categorised as
“yes
and correctly”,
“yes
but not correctly” or
“no”.
Acceptable LEV was defined as working
conditions inferred as providing air quality in which additional RPE was
not needed. The workplaces where LEV was considered as not adding
additional value beyond the general ventilation were also categorised as
“inferred
acceptable” LEV for the analyses herein. Inferred correct use of
RPE was defined as: 1. using RPE when needed; 2. using the correct type
of filter; 3. regular filter changes, and 4. correct storage of RPE when not
used.
2.7. Risk assessment
In order to assess risk and evaluate OEL compliance, the Bayesian
tool Expostats (Tool 1) was employed to assess the expected extent of
OEL exceedances in the sampled population (Lavou
´
et al., 2019).
The
e
occupational and workplace categories were used in the present work to
identify similar exposure groups. The category ‘other work tasks’ was
not included as it does not represent the same work tasks across com-
panies. We evaluated compliance with the current Swedish OEL (5
μ
g/m
3
) and also estimated the share that would be expected to exceed 1
μ
g/m
3
and 0.25
μ
g/m
3
, respectively. We defined overexposure as 5% of
the population exceeding the exposure limit, and evaluated the proba-
bility of overexposure using the thresholds 30% (as proposed by e.g.
CEN 2019 (CEN).
The estimations of workers exposed to Cr(VI) in Sweden was per-
formed using a job-exposure-matrix (JEM) linked to register data on
occupation from Statistics Sweden. The JEM was originally based on the
Finnish JEM (Kauppinen
et al., 1998)
and later updates (Kauppinen
et al., 2014).
The estimated prevalence is for workers ever exposed
during a year, meaning that some of them can have very low prevalence,
maybe one time per year. Adaptions to Swedish working conditions have
been made by Wiebert and Tinnerberg et al. (Gustavsson
et al., 2022).
2.8. Statistical analysis
¨
For inhalable Cr(VI), 51 samples analysed in Orebro (concentrations
below the LOD (0.08
μ
g/sample)) and 2 samples analysed in Luleå
(below the LOQ (0.3
μ
g/sample)) were substituted by values equal to
half of the LOD (0.04
μ
g/sample) or LOQ (0.15
μ
g/sample) (Hornung
and Reed, 1990).
Age was calculated based on birth and recruitment
dates. Body mass index (BMI) was obtained using the formula BMI
=
weight in kilograms/(height in meters) (IARC,
2012).
Descriptive sta-
tistics including geometric mean (GM), 95% confidence interval (CI),
median, 5th and 95th percentiles (P5, P95) were calculated.
Mann-Whitney
U
test, Kruskal-Wallis test and Wilcoxon signed ranks
test were used to compare differences between continuous variables.
The Chi-square test and Fisher’s exact test were used to compare dif-
ferences in distribution of categorical variables between groups.
Spearman’s correlation was used to examine correlations between
variables.
Multiple regression models were built to evaluate differences in Cr
concentration between the exposure group and controls, adjusting for
potential covariates and confounders. Possible confounders of exposure
¨¨ ¨
to Cr(VI) or Cr(III) were: smoking (P
aakko et al., 1989),
coffee (Olechno
et al., 2021)
and tea (Barman
et al., 2020)
drinking, diet (Smart
and
Sherlock, 1985),
supplement (Saper
et al., 2004),
implant (Campbell
and
Estey, 2013)
and leisure activity with Cr. Three models were built:
model 1 without adjustment; model 2 adjusted for variables that had a
significant difference in the bivariate analysis between exposed workers
and controls; model 3 adjusted for all potential confounders. To deal
with skewed data, log transformation was used for the urinary and RBC
Cr.
The statistical analyses above were conducted with SPSS 28.0 (IBM
5
SPSS Statistics, NY) and statistical significance (two-tailed) was denoted
at
P
value
<
0.05.
3. Results
3.1. Characteristics of the study participants
A total number of 44 companies with potential occupational expo-
sure to Cr(VI) were contacted by the occupational hygienists, and 14
companies, geographically distributed from north to south of Sweden,
agreed to participate (company participation rate 31.8%). Companies
that did not participate did either: 1. not reply to the occupational hy-
gienists; 2. not want to participate; or 3. not fulfill the inclusion criteria
because of ceased or sporadic exposure to Cr(VI). The tasks performed
by workers at the participating companies included production of
stainless steel, welding, grinding, plating, surface treatment, and various
chemical processes. The volunteers in the control group were recruited
from one agricultural operator, one care home, two construction com-
panies, one storage company, and one restaurant (company participa-
tion rate 66.7%).
One hundred and sixteen air samples were collected, but one pump
did not work, thus 115 valid inhalable Cr(VI) results were obtained.
Three exposed workers only provided air samples, and the remaining
113 workers completed the questionnaire and donated biological sam-
ples. Categorisation, number of individuals for each company, and their
work tasks are shown in
Table 1.
The demographic characteristics, lifestyle, and work-related factors
of the exposed workers and controls are summarised in
Table 2.
The
exposed workers and controls were similar in BMI, smoking history,
coffee drinking, use of supplements, presence of implants, and leisure
activities with Cr. However, significant differences (P
<
0.05) were
found with respect to age, sex, and tea drinking between the two groups.
Participants in the exposed group were younger, more likely to be male
and less likely to drink tea than those in the control group. There were
35.4% exposed workers with inferred non-acceptable LEV, and 54% did
not use RPE on the sampling day. Fifteen exposed workers (13.2%) had
non-acceptable LEV and did not use RPE.
3.2. Cr(VI) in air
The inhalable Cr(VI) concentrations are presented in
Table 3.
There
were 74 samples below 0.25
μ
g/m
3
, 20 samples between 0.25 and 1
μ
g/
m
3
, 13 samples between 1 and 5
μ
g/m
3
and eight samples higher than 5
μ
g/m
3
(Fig.
1A).
The GM and 95% CI of inhalable Cr(VI) in the exposed
group were 0.15 and 0.11–0.21
μ
g/m
3
, but the P95 was 8.03
μ
g/m
3
(Table
3).
At company level, steel production had the highest GM and
non-categorised companies had the lowest (P
<
0.05). In relation to
work tasks, process operators had the highest GM, and machining
workers the lowest GM, but no significant difference was found between
work tasks (Table
3
and
Fig. 1B).
Workers with inferred non-acceptable
LEV were exposed to around two times higher levels of inhalable Cr(VI)
compared with those with inferred acceptable LEV (P
<
0.05), and
workers with inferred correct use of RPE on the sampling day were
exposed to significantly higher inhalable Cr(VI) compared with those
who did not use RPE or had inferred incorrect use (P
<
0.001) (Fig.
2A).
Stratified analysis showed that among workers with acceptable LEV, a
significant difference in inhalable Cr(VI) was found between different
usage of RPE. A significant difference was also found between different
usage of RPE among the workers with non-acceptable LEV (Supple-
mentary Fig. 1A).
3.3. Risk assessment
Table 4
shows the estimated likelihood of overexposure when using
the Bayesian analysis performed by Expostats. The estimated fractions of
exceedances over the Swedish OEL ranged from 0.02 % for machining in
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Z. Jiang et al.
International Journal of Hygiene and Environmental Health 256 (2024) 114298
Table 1
Categorisation in SafeChrom of 14 companies (15 work sites) and work task for individuals (n
=
116, exposed group) for whom air sampling was performed.
SafeChrom Categorisation
Manufacture/processing of metal products
Steel production
Bath plating
Non-categorised
b
Total
a
b
Companies
a
n
7
3
3
2
15
Work task on sampling day
Welding
32
Process operation
14
28
9
7
58
Machining
6
5
11
Others
6
4
4
1
15
Total individuals n
58
32
18
8
116
32
One company with two different work sites was categorised into both steel production and manufacture/processing of metal products.
Two companies that could not be classified in manufacture/processing of metal products, steel production or bath plating were classified as non-categorised
(details in
Supplementary Table 1).
Table 2
Characteristics of the study groups in SafeChrom.
Exposed group
n
=
113
Age, median (P5, P95)
Female, n (%)
BMI
d
, median (P5, P95)
Smoking, n (%)
Never smoker
Previous smoker
Party smoker
Current smoker
Coffee drinking (yes/no), n (%)
Tea drinking (yes/no), n (%)
Diet (mix, vegetarian, vegan), n
(%)
Supplement (yes/no), n (%)
Implant (yes/no), n (%)
Leisure activity with Cr (yes/
no), n (%)
LEV
e
(inferred acceptable/non-
acceptable), n (%)
RPE
f
(yes and correctly/yes but
not correctly/no), n (%)
a
b
c
d
e
f
Controls group
n
=
72
43.5 (27.7,60.4)
22 (30.6)
27.2 (20.6,
35.1)
45 (62.5)
23 (31.9)
2 (2.8)
2 (2.8)
56/16 (77.8/
22.2)
34/38 (47.2/
52.8)
70/1/1 (97.2/
1.4/1.4)
21/51 (29.2/
70.8)
12/60 (16.7/
83.3)
4/68 (5.6/94.4)
P
0.016
a
<0.001
b
0.368
a
0.854
c
Table 3
Concentrations of inhalable hexavalent chromium (Cr(VI);
μ
g/m
3
) measured in
the exposed group and stratified by company and work task.
<LOD/
LOQ n
(%)
Exposed group, N
=
115
Company
Manufacture/
processing of metal
products, n
=
57
Steel production, n
=
32
Bath plating, n
=
18
Non-categorised, n
=
8
Work task
Welding, n
=
31
Process operation,
n
=
58
Machining, n
=
11
Others, n
=
15
a
GM (CI)
b,c
Median
39 (21.7, 60.3)
15 (13.3)
27.9 (20, 37.6)
68 (60.2)
35 (31)
6 (5.3)
4 (3.5)
96/17 (85/15)
35/77 (31.9/
68.1)
113/0/0 (100/
0/0)
32/81 (27.4/
72.6)
11/102 (11.5/
88.5)
10/103 (8.8/
91.2)
73/40 (64.6/
35.4)
30/22/61
(26.5/19.5/54)
P5,
P95
0.02,
8.03
0.02,
13.58
0.03,
9.78
0.03,
1.92
0.02,
0.28
0.02,
14.73
0.02,
6.93
0.02,
0.44
0.02,
2.55
P
54 (47)
0.15
(0.11–0.21)
0.12
(0.07–0.21)
0.30
(0.17–0.55)
0.15
(0.07–0.29)
0.04
(0.02–0.08)
0.17
(0.08–0.37)
0.19
(0.12–0.31)
0.05
(0.03–0.11)
0.09
(0.04–0.21)
0.1
33
(57.9)
8 (25)
7 (38.9)
6 (75)
0.03
0.25
0.10
0.02
0.001
a
0.24
b
0.042
b
0.205
c
1
b
0.177
b
0.571
b
15
(48.4)
22
(37.9)
8 (72.7)
9 (60)
0.10
0.16
0.04
0.04
0.151
a
Mann-Whitney
U
test.
Chi-square test.
Fisher’s exact test.
BMI, body mass index.
LEV, Local exhaustion ventilation.
Using respiratory protective equipment (RPE) on sampling day.
Kruskal-Wallis test.
GM, Geometric mean, CI: 95% confidence interval of the geometric mean.
c
Concentrations below the limit of detection (LOD) and limit of quantification
(LOQ) were substituted by a value equal to half of the LOD/LOQ.
b
manufacture/processing to 8.8 % for welding in manufacture/process-
ing with the 95% credible interval ranging up to 19.6% for the welders.
Only three groups had less than 30% probability of overexposure of the
Swedish OEL (shown by the shading in
Table 4),
defined as 5% or more
exceeding the OEL. All groups had more than 30% probability of over-
exposure for the upcoming Danish OEL (0.25
μ
g/m3).
In order to identify how many workers are at risk for exceeding the
Swedish OEL, the total number of workers exposed to Cr(VI) in Sweden
was estimated. Initially, different branch organizations were contacted
but no information on numbers of exposed workers could be retrieved.
Thus, estimations were done using the Swedish JEM: in 2021, approx-
imately 16 000 men and 1900 women distributed within 14 different
occupations were estimated to be exposed to Cr(VI). Among those, 2570
were welders.
3.4. Cr in urine and red blood cells
The Cr concentrations in urine and RBC are presented in
Table 5.
Both pre-shift and post-shift urinary Cr in the exposed group were
significantly higher compared with controls (P
<
0.001). In the exposed
6
group, but not among the controls, Cr concentrations in after-work urine
were statistically significantly higher than in the pre-shift urine. In
addition, the difference between post-shift and pre-shift urinary Cr
concentrations in the exposed group were significantly higher than the
controls (Supplementary
Table 4).
The median RBC-Cr in the exposed
group was significantly higher than in the controls.
The workers in non-categorised companies had the lowest post-shift
urinary Cr/density and RBC-Cr, while those working in steel production
had the highest urinary and RBC Cr (P
<
0.01). Among different work
tasks, machining workers had the lowest post-shift urinary Cr/density. It
was significantly lower than the welders, but non-significantly higher
than the controls (P
=
0.068). For RBC-Cr, machining workers had
significantly higher concentrations than the controls, but not signifi-
cantly different from exposed workers doing other work tasks
(Fig.
1C–D).
Regarding using LEV and RPE, urinary and RBC Cr concentrations
showed a similar trend as the inhalable Cr(VI). Workers with inferred
non-acceptable LEV had higher urinary and RBC concentrations than
those with inferred acceptable LEV. Contrarily, workers who were
assessed to use RPE correctly on the sampling day had higher concen-
trations of Cr in urinary and RBC than workers who did not (Fig.
2B–C).
Stratified analysis for acceptable and non-acceptable LEV, showed that
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Z. Jiang et al.
International Journal of Hygiene and Environmental Health 256 (2024) 114298
Fig. 1. Inhalable hexavalent chromium (Cr(VI)), urinary and red blood
cells (RBC) Cr in controls and exposed workers across company and work
task.
A. Frequency distribution histogram for inhalable Cr(VI). B. Inhalable Cr
(VI). Kruskal-Wallis Test, *P
<
0.05. C. Post-shift urinary Cr/density. Kruskal-
Wallis Test and Mann-Whitney
U
test, **P
<
0.01, ***P
<
0.001. D. RBC-Cr.
Kruskal-Wallis Test and Mann-Whitney
U
test, **P
<
0.01, ***P
<
0.001. The
data are presented as geometric mean and 95% CI for inhalable Cr(VI), median
and interquartile range for post-shift urinary Cr/density and RBC-Cr. (For
interpretation of the references to colour in this figure legend, the reader is
referred to the Web version of this article.)
Fig. 2. Inhalable hexavalent chromium (Cr(VI)), urinary and red blood
cells (RBC) Cr in exposed group according to the local exhaustion venti-
lation (LEV) and using respiratory protective equipment (RPE).
A. Inhal-
able Cr(VI). B. Post-shift urinary Cr/density. C. RBC-Cr. Mann-Whitney
U
test,
*P
<
0.05, **P
<
0.01, ***P
<
0.001. The data are presented as geometric mean
and 95% CI for inhalable Cr(VI), median and interquartile range for post-shift
urinary Cr/density and RBC-Cr. LEV and RPE centered under inferred
acceptable/non-acceptable and yes, and correctly/yes, but not correctly/no,
respectively. (For interpretation of the references to colour in this figure legend,
the reader is referred to the Web version of this article.)
among workers with acceptable LEV, there were less pronounced dif-
ferences in urinary and RBC Cr between usage of RPE. However, with
non-acceptable LEV, workers using RPE correctly still showed the
highest urinary and RBC Cr (Supplementary
Figs. 1B–C).
When urinary and RBC Cr concentrations were compared to the P95
7
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Z. Jiang et al.
International Journal of Hygiene and Environmental Health 256 (2024) 114298
Table 4
Estimated exceedance fractions of hexavalent chromium for 5, 1 and 0.25
μ
g/m
3
across the different expo-
sure groups using Expostats.
The shading indicates that the probability of overexposure (defined as an exceedance fraction
>5%)
is more
than 30%.
Table 5
Chromium (Cr) concentration in urine and red blood cells.
Median (P5, P95)
Pre-shift urine
a
Post-shift urine
b
Red blood cells
c
a
b
3.6. Further elements in red blood cells and post-shift urine
Control group
0.10 (0.01, 0.45)
0.08 (0.01, 0.54)
0.10 (0.01, 0.84)
0.11 (0.04, 0.30)
0.10 (0.03, 0.58)
0.10 (0.06, 0.56)
0.53 (0.42, 0.72)
Exposed group
0.54 (0.08, 2.91)
d
0.33 (0.05, 1.75)
d
0.51 (0.07, 2.44)
d
0.55 (0.10, 3.83)
d, e
0.41 (0.08, 2.12)
d, g
0.60 (0.10, 3.20)
d, f
0.73 (0.51, 2.33)
d
Cr (
μ
g/L)
Cr (
μ
g/g creatinine)
Cr/density
Cr (
μ
g/L)
Cr (
μ
g/g creatinine)
Cr/density
Cr (
μ
g/L)
Pre-shift urine (exposed group n
=
112, control group n
=
72).
Post-shift urine (exposed group n
=
113, control group n
=
72).
c
Red blood cells sample was collected with post-shift urine (exposed group n
=
110, control group n
=
72).
d
Exposed group vs. control group, Mann-Whitney
U
test,
P
<
0.001.
e
Post-shift urine vs. pre-shift urine in exposed group, Wilcoxon signed ranks
test, P
<
0.05
f
Post-shift urine vs. pre-shift urine in exposed group, Wilcoxon signed ranks
test, P
<
0.01
g
Post-shift urine vs. pre-shift urine in exposed group, Wilcoxon signed ranks
test, P
<
0.001
of controls (reference value), 42 exposed workers were below the P95 of
controls’ urinary and RBC Cr; 10 exceeded the P95 of urinary Cr but
were below the P95 of RBC-Cr; 13 exceeded P95 of RBC-Cr but were
below the P95 of urinary Cr; 45 exceeded both P95 of urinary and RBC
Cr. Among the latter 45 individuals, 15 had exposure measurements of
less than 0.25
μ
g/m
3
of inhalable Cr(VI) (Supplementary
Table 5).
3.5. Inhalable Cr(VI), urinary and RBC Cr in welders
Four types of welding processes (manual metal arc (MMA), metal
active gas (MAG), metal inert gas (MIG) and tungsten inert gas (TIG))
were performed by 30 welders, including 14 welders that performed
more than one type of welding (data not shown). The most common
welding process reported was TIG (n
=
24). Workers using TIG had the
lowest level of inhalable Cr(VI) (GM 0.11
μ
g/m
3
) and workers welding
using MMA had the highest (GM 1.13
μ
g/m
3
) (P
=
0.02). The same
pattern was found in urinary and RBC Cr: workers using TIG had the
lowest (median 0.54 and 0.74 for urinary and RBC Cr, respectively) and
workers using MMA had the highest (median 1.45 and 0.82 for urinary
and RBC Cr, respectively), but without significant difference between
types of welding (P
=
0.41 for urinary Cr and
P
=
0.33 for RBC-Cr).
For workers exposed to Cr(VI), they might be exposed to other
metals. Hence manganese, cobalt, nickel, copper, zinc, selenium, cad-
mium, antimony, mercury, and lead were also measured in urine (den-
sity-adjusted) and RBC (Supplementary
Table 6).
Post-shift urinary
copper concentrations were significantly higher in Cr(VI)-exposed
workers (median 9.77
μ
g/L) compared with controls (8.41
μ
g/L). Uri-
nary nickel and lead were non-significantly higher in Cr(VI)-exposed
workers. In RBC, copper and zinc concentrations were significantly
higher in the Cr(VI)-exposed workers (571
μ
g/L for copper and 10728
μ
g/L for zinc) compared with the controls (525
μ
g/L for copper and
10496
μ
g/L for zinc). Cr(VI)-exposed workers had higher RBC concen-
trations of cobalt and lead than controls, but not statistically significant.
Controls had significantly higher antimony concentrations both in urine
(0.57
μ
g/L) and RBC (5.30
μ
g/L) compared with Cr(VI)-exposed workers
(0.08
μ
g/L in urine and 4.46
μ
g/L in RBC).
Similar to Cr, we divided other metals in urine and RBC according to
the company and work task (Supplementary
Table 7).
There were sig-
nificant differences between companies in median urinary concentra-
tions of nickel (highest in steel production and lowest in bath plating),
copper (highest in non-categorised and lowest in bath plating), zinc
(highest in non-categorised and lowest in bath plating), and lead
(highest in steel production and lowest in manufacture/processing of
metal products. There were significant differences between companies
in median RBC concentrations of antimony (highest in manufacture/
processing of metal products and lowest in non-categorised) and lead
(highest in steel production and lowest in non-categorised). Further-
more, for work tasks, there was a significant difference in urinary me-
dian concentrations of cobalt (highest in welding and lowest in
machining). For work tasks median RBC concentrations differed for
nickel (highest in others and lowest in machining) and mercury (highest
in others and lowest in process operation).
Correlations between metals in RBC in Cr(VI)-exposed workers are
presented in
Supplementary Fig. 2.
The strongest correlations were
found between cobalt and nickel (r
S
=
0.53). Positive correlations be-
tween zinc and copper as well as between zinc and selenium were also
observed (r
S
=
0.46 and r
S
=
0.44, respectively). The strongest corre-
lation with Cr was observed with nickel (r
S
=
0.37) and other moderate
correlations were found between Cr and cobalt, copper, zinc, selenium
and lead (0.2< r
S
<
0.4).
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Z. Jiang et al.
International Journal of Hygiene and Environmental Health 256 (2024) 114298
3.7. Correlations between exposure biomarkers and multivariate analysis
There were strong correlations between pre-shift and post-shift uri-
nary Cr concentrations in exposed workers (r
S
=
0.89 both for
creatinine-adjusted Cr and density-adjusted Cr,
Supplementary Table 8).
Inhalable Cr(VI) correlated with urinary Cr (density-adjusted) (r
S
=
0.64) and RBC (r
S
=
0.53). Urinary Cr (density-adjusted) correlated with
RBC-Cr (r
S
=
0.72) (Supplementary
Table 8
and
Supplementary Fig. 3).
In multivariate regression analysis, post-shift urinary and RBC Cr
concentrations were significantly higher in the exposed group compared
with the controls (Table
6
A, model 1). After adjustment for sex, age and
tea drinking (model 2), and further adjustment for smoking, coffee
drinking, supplements consumption, implants, and leisure activities
exposed to Cr (model 3), the results remained statistically significant.
Regression analysis showed that post-shift urinary Cr was higher after
welding, process operation and other work tasks, than after machining
(P
<
0.05). Workers doing other work tasks also had higher RBC-Cr than
machining workers (Table
6
B). At company level, urinary and RBC Cr
for workers in steel production companies were higher than for workers
in non-categorised companies (P
<
0.05) (Table
6
B).
4. Discussion
We have, by short-term and long-term markers of Cr(VI) exposure,
identified workplaces and various occupations throughout Sweden
where employees are exposed to Cr(VI).
4.1. Comparison with previous studies and risk assessment
Our study was designed to be similar to the HBM4EU chromates
study, hence the results of our study and HBM4EU chromates study are
comparable. However, it should be noted that differences in methods of
Table 6
Linear regression models for logarithm-transformed red blood cells (RBC) and
density adjusted post-shift urinary chromium (Cr).
A. Multiple linear regression models with beta coefficient (β) were to evaluate
differences between exposed group and controls.
Model 1
β
(95% CI)
Exposed
group
a
Urinary
Cr
RBCCr
1.57 (1.26,
1.89)
b
0.40 (0.30,
0.50)
b
Model 2
β
(95% CI)
1.63 (1.30,
1.96)
b
0.41 (0.30,
0.51)
b
Model 3
β
(95% CI)
1.60 (1.26,
1.93)
b
0.40 (0.30,
0.51)
b
air-sampling and biomonitoring could potentially influence compara-
bility with other studies.
4.1.1. Inhalable Cr(VI)
Airborne Cr has been commonly measured as inhalable total Cr,
inhalable Cr(VI), respirable total Cr or respirable Cr(VI). Several studies
have measured airborne Cr(VI) without specifying which particle frac-
tion has been measured. A study conducted in Iran reported a mean
value of 2
μ
g/m
3
for welding and 5
μ
g/m
3
for back welding (welding
inside pipes as confined space) (Golbabaei
et al., 2012).
Studies in India
and Egypt measured airborne Cr(VI) in the leather tanning industry with
a mean value of 21
μ
g/m
3
(Balachandar
et al., 2010)
and 10.4
μ
g/m
3
(Abdel
Rasoul et al., 2017),
respectively. HBM4EU carried out a study on
occupational exposure to Cr(VI) and involving nine countries (Belgium,
Finland, France, Italy, Luxembourg, the Netherlands, Poland, Portugal,
and United Kingdom) (Santonen
et al., 2022).
The median concentration
of inhalable Cr(VI) in HBM4EU chromates study (0.43
μ
g/m
3
) was
higher compared with our study (0.1
μ
g/m
3
), but their P95 value was
lower (5.13
μ
g/m
3
versus 8.03
μ
g/m
3
). The same trend was also
observed if only welders were considered. The median and P95 of
inhalable Cr(VI) for welders in HBM4EU chromates study were 0.5 and
4.06
μ
g/m
3
, while in our study they were 0.1 and 14.73
μ
g/m
3
. The
lower median value in our study suggests that, on average, the inhalable
Cr(VI) concentrations among exposed workers were relatively low in
Sweden. However, the higher P95 value indicates a higher upper range
of exposure. These studies clearly show that the distribution and range
of inhalable Cr(VI) concentrations among Cr(VI) exposed workers vary
between different countries, and further, the necessity to perform na-
tional exposure assessment.
4.1.2. Risk assessment
In our study, 5 individuals (4.3%) exceeded 10
μ
g/m
3
of inhalable Cr
(VI) (i.e. current EU OEL), 8 (7.0%) exceeded 5
μ
g/m
3
(the current
Swedish OEL), 22 (19.1%) exceeded 1
μ
g/m
3
(the current Danish,
French and Dutch OEL) and 42 (36.5%) exceeded 0.25
μ
g/m
3
(the ex-
pected future Danish OEL). Further, the Bayesian tool Expostats analysis
indicates that there is a non-negligible, and often high, probability that
the Swedish OEL is exceeded for at least 5% of the occupational groups
we investigated, assuming similar conditions as during the performed
measurements. However, the broad definitions of and the low number of
samples in our similar exposure groups contribute to the variability and
hence the high estimates of probability of overexposure.
In the present study, 7% of workers exceeded the current Swedish
OEL of 5
μ
g/m
3
and we estimated that 17 900 workers were exposed to
Cr(VI) in Sweden. Therefore, we can speculate that around 1250
workers in Sweden are at risk of exceeding the Swedish OEL (17 900 *
7%
1250). However, it should be noted that the Swedish JEM includes
everyone exposed to Cr(VI) regardless of exposure level. Thus, occupa-
tions with low and/or very intermittent exposure are also included. On
the other hand, a recent time trend study of exposure to respirable
crystalline silica, welding fumes, wood dust, and chlorinated hydro-
carbon solvents in Sweden showed that occupational exposures tended
to shift from large companies to small companies (Gustavsson
et al.,
2022).
Technological progress and automatization have eliminated
many hazards in large companies, however, without supervision by an
occupational physician and limited resources for preventive work in
many small and middle-sized companies, high-risk workplaces may still
prevail (Funke,
2007).
Most participated companies (86%) in our study are considered big
companies (more than 100 employees), and this could be the reason that
the inhalable Cr(VI) concentrations among exposed workers were rela-
tively low. However, the working situation in small companies and the
shifting of the exposure indicative of more serious negative health ef-
fects on the individual level even though the exposure level and prev-
alence overall diminished. Thereby, one can speculate that the
exceedance of the OEL in the participating companies is an
9
B. Linear regression model with
β
were to evaluate differences between companies in
exposed group. All analyses are unadjusted.
Urinary Cr
β
(95% CI)
Work task
c
Welding
Process operation
Others
Company
d
Manufacture/processing of
metal products
Steel production
Bath plating
a
RBC-Cr
β
(95% CI)
0.08 ( 0.19,
0.36)
0.04 ( 0.22,
0.30)
0.33 (0.02,
0.64)
b
0.24 ( 0.05,
0.52)
0.53 (0.23,
0.82)
b
0.29 ( 0.04,
0.61)
1.15 (0.31,
1.98)
b
0.90 (0.12,
1.68)
b
1.06 (0.12,
2.00)
b
0.83 ( 0.06,
1.71)
1.42 (0.50,
2.34)
b
0.95 ( 0.06,
1.94)
Model 1 is unadjusted; model 2 is adjusted for sex, age and tea drinking;
model 3 is adjusted for sex, age, tea drinking, smoking, coffee drinking, using of
supplements, implants, and leisure activities exposed to Cr. The reference is
controls.
c
The reference is machining.
d
The reference is non-categorised companies.
b
P
<
0.05
 BEU, Alm.del - 2023-24 - Bilag 61: Orientering om svensk undersøgelse af luftmålinger om krom-6 på svenske virksomheder
Z. Jiang et al.
International Journal of Hygiene and Environmental Health 256 (2024) 114298
underestimation in comparison with companies without resources for
preventive work. Our estimate of the number of workers currently
exposed to Cr(VI) is lower than the numbers estimated in the 1990s, 17
900 today vs. 21 000 in the 1990s (Kauppinen
et al., 2000).
Comparison
is somewhat difficult since it is not known if the former estimation also
included low or intermittently exposed occupations. However, as
pointed out above although the prevalence of exposure to Cr(VI) has
decreased it does not mean the exposure level also has declined.
In our study, exposure was assessed according to four work tasks
(welding, machining, process operation and others). Welder was the
only homogenous occupation with known Cr(VI) exposure that could be
easily assessed in the register from Statistics Sweden (Statistikdataba-
sen, 2021).
In 2021, there were 12 703 registered welders (SSYK code
7212) in Sweden and based on the estimation in the Swedish JEM that
20% of welders are exposed to Cr(VI), we estimate that approximately
2570 welders are exposed to Cr(VI) today. However, many workers
¨
perform welding without having the job title welder. Sjogren and Gus-
tavsson estimated that in 2013 there were 20 000–25 000 workers
¨
welding in their profession (Sj
ogren, 2013)
but 70 306 workers exposed
to welding fumes (Gustavsson
et al., 2022).
In the present study, 12.5%
of welders exceeded the Swedish OEL of inhalable Cr(VI). Therefore, in
the case of conservative estimation (exposure of non-welders to welding
fumes was not considered), around 625 welders are at risk of exceeding
the Swedish OEL nationally (25 000 welders * 20% * 12.5%
=
625
welders) when welding. The Bayesian analysis’ 95% credible interval for
welders’ overexposure of the Swedish OEL was 3.1%–19.6%. This
translates to between 155 and 980 welders being at risk of exceeding the
Swedish OEL nationally (25000 welders * 20% * 3.1%
=
155 welders;
25000 * 20% * 19.6%
=
980 welders).
The current OEL for Cr(VI) in Sweden corresponds to 20 extra lung
cancer cases per 1000 exposed after 40 years of exposure (i.e. lifetime
risk) (C.
European, 2017).
In Germany and the Netherlands, acceptable
risk is considered to be an additional risk of
<4
cases per 100,000 after
40 years and tolerable risk (during a transitional period) is considered to
be
<
4/1000 (Ding
et al., 2014).
It should be noted that the Swedish OEL
corresponds to much higher levels of Cr(VI) and thus substantially
higher risks. Further, the fact that 7.0% of workers in our study exceeded
the Swedish OEL and 4.3% exceeded the EU OEL, suggests that a sub-
population of the Cr(VI)-exposed workers may be at even higher risk of
lung cancer in Sweden. To lower the Cr(VI) exposure, there is a need for
more effective risk management measures and increased incentives for
workplaces to implement them. Important actions towards this aim are
reduction of the current OEL and subsequent enforcement of it,
including directed information campaigns supporting the adoption of
proper risk management.
4.1.3. Urinary Cr
In a recent systematic review of biomonitoring data on occupational
exposure to Cr(VI) (Verdonck
et al., 2021),
the median or mean urinary
Cr levels were lower in European countries (ranging from 0.96
μ
g/L to
5.81
μ
g/L) compared with non-European countries (ranging from 1.66
μ
g/L to 48.4
μ
g/L). In HBM4EU chromates study, the median and P95
concentration of post-shift urinary Cr in exposed workers were 1.7 and
5.1
μ
g/g creatinine. In our study, the median urinary Cr was 0.55
μ
g/L,
and after creatinine adjustment, the median and P95 were 0.41 and 2.12
μ
g/g creatinine, which are lower than all studies above. In HBM4EU
chromates study, reference values were obtained by recruiting controls
from the same companies as the exposed workers (within company
controls) or from other companies without associated with Cr(VI)
exposure (outwith (external) company controls). The values of the
controls’ urinary Cr in our study (median and P95, 0.08 and 0.54
μ
g/g
creatinine) are similar with the outwith company controls in HBM4EU
chromates study (0.1 and 0.4
μ
g/g creatinine) (Viegas
et al., 2022).
France and the Netherlands have set a biological limit value (BLV) of
2.5
μ
g/L of Cr in urine based on their OEL of 1
μ
g/m
3
for Cr(VI) in air,
and Finland has derived a BLV of 0.2
μ
mol/L (ca. 10
μ
g/L) in urine
10
corresponding to its OEL of 5
μ
g/m
3
in air (Verdonck
et al., 2021).
In our
study, two participants (1.8%) exceeded 10
μ
g/L of urinary Cr and 13
(11.5%) exceeded 2.5
μ
g/L.
4.1.4. RBC-Cr
RBC-Cr (median, 0.73
μ
g/L and mean, 0.89
μ
g/L) was lower in our
study compared to welders in a German study (median, 1.95
μ
g/L)
(Weiss
et al., 2013),
electroplaters in Italy (median, 3.4
μ
g/L) (Goldoni
et al., 2010a)
and China (median, 4.41
μ
g/L) (Zhang
et al., 2011),
and
chromate production workers in China (mean, 12.45
μ
g/L). The median
value of RBC-Cr in HBM4EU chromates study (0.73
μ
g/L) was the same
as in our study but they had higher P95 (5.83
μ
g/L versus 2.33
μ
g/L)
(Ndaw
et al., 2022).
With respect to controls, one study in China
measured RBC-Cr in 93 controls (median, 1.54
μ
g/L) (Zhang
et al.,
2011)
and HBM4EU chromates study measured 175 controls (median,
0.63
μ
g/L) (Ndaw
et al., 2022).
The median concentration of RBC-Cr in
our controls was 0.53
μ
g/L, similar to in HBM4EU chromates study.
Despite that Cr in RBC is considered a specific biomarker of Cr(VI),
there is no established BLV for RBC-Cr. It is worth mentioning that, in
our study, plasma was removed from whole blood, and the blood cells
were washed to eliminate interfering residual plasma-Cr. However,
white blood cells (WBC) were retained along with RBC, which might
increase the background level of RBC-Cr from Cr(III) accumulated in
WBC.
4.2. Efficiency of using LEV and RPE
In earlier studies, LEV significantly influenced exposure to Cr(VI)
during welding, resulting in a 68% reduction in median Cr(VI) con-
centrations (Meeker
et al., 2010).
In the HBM4EU chromates study, the
use of LEV corresponded to about one third lower airborne Cr concen-
trations (Viegas
et al., 2022).
In our study, the reduction was around
50%. An inferred acceptable LEV also led to a reduction to half of the
urinary Cr and corresponded to a statistically significantly lower con-
centration of RBC-Cr.
Compared to other preventive and protective measures (e.g., elimi-
nation of the high-risk substance, substitution by a less toxic alternative
or separating the substance from the workers), RPE should be regarded
as the last resort in the hierarchy of controls (Viegas
et al., 2022).
In
HBM4EU chromates study, the use of RPE was associated with lower
urinary Cr (except for machining workers). In addition, in
chrome-platers, a stronger correlation between internal Cr and airborne
Cr(VI) was observed in the group without RPE (Ndaw
et al., 2022).
In
our study, workers who correctly used RPE were exposed to around four
times higher inhalable Cr(VI) compared with those who did not, and
higher concentrations of urinary and RBC Cr were found in workers who
used RPE correctly. Stratified analysis showed that LEV had a greater
protective effect compared with RPE, and among workers with
non-acceptable LEV, the correct usage of RPE was still associated with
the highest level of inhalable Cr(VI), and urinary and RBC Cr. There may
be several explanations for the dysfunction of RPE: the exposed workers
may have irregularly worn RPE over time; they may have been exposed
to Cr(VI) via the skin; or workers may have been subject to secondary
exposure. Furthermore, RPE only guarantees protection if no leaking
occurs, and only works when it fits properly to the wearer’s face (Viegas
et al., 2022).
Fit test is not formally required in Sweden as opposed to
many other countries. Only around half of the workers who correctly
used RPE used loose-fitting powered air-purifying respirators, which
does not require the fit test. For the other workers, a reason for the low
efficiency of RPE protection could be that no fit test was performed.
Our findings show that most employers and workers are aware of the
risk of high levels of Cr(VI) in the air and thus use RPE, but that this is
not enough to reduce the Cr(VI) exposure and more efficient exposure
control strategies are needed.
 BEU, Alm.del - 2023-24 - Bilag 61: Orientering om svensk undersøgelse af luftmålinger om krom-6 på svenske virksomheder
Z. Jiang et al.
International Journal of Hygiene and Environmental Health 256 (2024) 114298
4.3. Other metals
Apart from Cr, workers may be exposed to other toxic metals in their
working environment. It was reported that urinary (Golbabaei
et al.,
2012; Stanislawska et al., 2020),
serum (El
Safty et al., 2018)
and blood
(Muller
et al., 2022)
nickel in Cr(VI)-exposed workers were significantly
higher than controls. In our study, post-shift urinary nickel in the Cr
(VI)-exposed group was non-significantly higher than controls (P
=
0.09), and nickel concentrations in RBC showed no significant difference
between the two groups (P
=
0.36). However, nickel concentrations in
RBC was significantly higher in welders than in controls (P
=
0.02). In
addition, among all metals in RBC, we observed the strongest correlation
with Cr for nickel (r
S
=
0.37). The finding of co-exposure to nickel
among some Cr(VI)-exposed workers indicate exposure to multiple
carcinogens. We found some differences in urinary and RBC metal
concentrations between companies and work tasks as well. This may
lead to more serious health consequences than exposure only to one
carcinogen, and thus, a more complex risk assessment is needed
including monitoring of multiple carcinogens.
We also found significantly higher concentrations of post-shift uri-
nary and RBC copper in Cr(VI)-exposed workers compared with con-
trols. On the contrary, Song et al. reported significantly lower levels of
copper in whole blood in chromate production workers in China (Song
et al., 2012).
Besides that, our result for zinc concentrations in RBC was
in line with Song et al., i.e. higher zinc among Cr(VI)-exposed workers.
Unexpectedly, antimony was found to be significantly higher in urine
and RBC in the control group. A potential explanation for the higher
levels of antimony in controls could be exposure to antimony trisulfide; a
lubricant in friction material and widely used in disc brake pads (Uex-
küll et al., 2005).
In our study, 33 controls (45.8%) had the work task of
car driving car, truck, forklift truck, or excavator. Other controls
recruited from the same company as drivers may share the same work
environment and be exposed to antimony-containing dust as well.
4.4. Correlations between exposure markers and monitoring strategy
The positive correlation between airborne Cr(VI) and urinary Cr
concentrations (r
S
=
0.64) in our study indicates that exposures to Cr(VI)
occurred mainly via inhalation (Were,
2013).
Moderate correlations
were also found between inhalable Cr(VI) and urinary Cr in welders in
Poland (r
S
=
0.58) (Stanislawska
et al., 2020),
electroplaters in Great
Britain (r
S
=
0.62) (Beattie
et al., 2017)
and in the HBM4EU chromates
study (r
S
=
0.46) (Viegas
et al., 2022).
Regression analyses are
commonly used to study the relationship between airborne Cr(VI) levels
and urinary Cr levels. Published regression formulas could be used to
convert the measured biomonitoring data, representing internal expo-
sure, into corresponding Cr(VI) air levels (Mahiout
et al., 2022),
and
conversely set BLVs corresponding to OELs. The regression analysis
published by Lindberg and Vesterberg has been used as a basis for
deriving a BLV for Cr(VI) in bath plating where a value of 13
μ
g/g
creatinine (an average creatinine excretion of 1.36 g/L was used) cor-
responds to the OEL of 5
μ
g/m
3
(Lindberg
and Vesterberg, 1983).
Another widely used regression analysis for Cr(VI) in electroplating was
published by Chen et al. in which the same OEL corresponds to urinary
Cr of 8.8
μ
g/g creatinine (Chen
et al., 2002).
HBM4EU chromates study
reported two regression analysis (Viegas
et al., 2022),
for platers the
OEL of 5
μ
g/m
3
corresponds to a urinary Cr level of 6.9
μ
g/g creatinine
and for welders it corresponds to 3.4
μ
g/g creatinine. In our study the
Swedish OEL corresponds to 2.44
μ
g/g creatinine for all exposed
workers and 1.26
μ
g/g creatinine for welders, respectively. It should be
noted that we observed a low goodness-of-fit value (0.02) for all exposed
workers. Furthermore, 21 workers exceeded the reference P95 of uri-
nary Cr but had less than 0.25
μ
g/m
3
of inhalable Cr(VI) (Supplementary
Table 5B).
This indicates that the Cr(VI) exposure might not have
occurred only via inhalation. Thus, aspects to asses for the relationships
between exposure via air and biomarkers are sources and variations in
11
Cr(VI) emissions, but also solubility of Cr(VI) compounds in water and
particle size, which are expected to impact the toxicokinetic of Cr and
subsequently influence the levels of chromium excreted in the urine
(Wilbur
et al., 2012).
More studies are needed to establish the most
suitable regression analysis to set up the BLV.
A few studies investigated the correlation between urinary and RBC
Cr. A significant positive correlation between urinary and RBC Cr (r
S
=
0.74) was found in chrome-platers in Italy (Goldoni
et al., 2010a)
However, in chromate production workers in China, the correlation was
weak (r
S
=
0.21) (Wang
et al., 2011).
Also, poor correlation between
urinary and RBC Cr was found in HBM4EU chromates study, but when
only considering chrome-platers, the r
S
coefficient became higher (only
shown in figure, approximately r
S
=
0.1 for all workers and r
S
=
0.5 for
chrome-platers) (Santonen
et al., 2022).
The correlation between uri-
nary and RBC Cr in our study is relatively strong (r
S
=
0.72). To date,
only a few studies have investigated the correlation between inhalable
Cr(VI) and RBC-Cr concentrations. No correlation (r
S
=
0.06;
P
=
0.73)
was reported for Polish welders (Stanislawska
et al., 2020).
In HBM4EU
chromates study, no correlation was also reported for all worker groups
combined, but among chrome-platers, the correlation between inhalable
Cr(VI) and RBC-Cr was stronger (r
S
=
0.54) (Ndaw
et al., 2022).
A
similar correlation was found in our study for all exposed workers (r
S
=
0.53). RBC-Cr may primarily reflect exposure to water-soluble Cr and
less to welding fumes, but there is also evidence that stainless steel
welding fumes are retained in the lungs longer than mild steel welding
fumes (Antonini
et al., 2004).
In our project, 97% of welders were
welding stainless steel, and this could be a plausible explication of the
high correlation observed between inhalable Cr(VI) and RBC-Cr. How-
ever, it should be noted that 27 workers exceeded the reference P95 of
RBC-Cr but had less than 0.25
μ
g/m
3
of inhalable Cr(VI), among them,
12 workers even had normal levels of urinary Cr (Supplementary
Table 5B).
This indicates that RBC-Cr reflects elevated exposure in air
prior to our exposure measurements. Since the air monitoring is tran-
sient and the short-term nature of total urinary Cr may mislead exposure
to Cr(VI), a better strategy when assessing long-term Cr(VI) exposure
would be repeated air measurement combined with biomonitoring of
RBC-Cr.
4.5. Strengths and limitations
This is a comprehensive study of occupational exposure to Cr(VI),
and, to the best of our knowledge, the very first in Sweden. The
nationwide cover allowed us to obtain a more complete dataset of
different types of companies across the country. Additionally, this study
included environmental and biological monitoring information at the
individual level. Overall, our results corroborate with previous pub-
lished studies. The study design and the questionnaire were adapted
from HBM4EU chromates study, and therefore our data should be
directly comparable to the data from HBM4EU chromates study. In the
present study, statistically significant relationships between RBC-Cr and
different exposure biomarkers provided evidence that RBC-Cr is an
appropriate biomarker for monitoring occupational Cr(VI) exposure.
This study has the potential to enhance the significance of different
biological indicators in monitoring Cr levels and contributes valuable
data to bolster regulatory risk assessment and decision-making
processes.
There were several limitations of the present study. The relatively
low company participation rate indicates that the participating com-
panies may not be representative for Cr(VI) exposure in Sweden. There
may be bias due to unbalanced covariates in the exposed and control
groups. Airborne Cr(VI) was measured only for one working day. There
were higher Cr concentrations in pre-shift urine since pre-shift urine was
sampled when workers had worked for at least three days. The wide
range of work tasks and sectors has, because of different emission
sources and exposure routes, influenced the analysis of correlations
between inhalable Cr(VI) and biomarkers. Further, this study only
 BEU, Alm.del - 2023-24 - Bilag 61: Orientering om svensk undersøgelse af luftmålinger om krom-6 på svenske virksomheder
Z. Jiang et al.
International Journal of Hygiene and Environmental Health 256 (2024) 114298
measured inhalable Cr(VI), and dermal exposure was not assessed
although dermal contamination is considered an important Cr(VI)
exposure route. Finally, there may be uncertainties about usage of RPE
over time.
5. Conclusions
Our study showed that although a majority of the individual air
measurements were relatively low, some workers are exposed to high
levels of Cr(VI), and 7.0% of participants’ measured exposures exceeded
the current Swedish OEL. Furthermore, the existing protective measures
implemented at workplaces are inadequate and insufficient, and sig-
nificant action to lower Cr(VI) exposure is warranted. Several workers
showed higher concentrations of Cr in urine and RBC, but not in air,
suggesting that a combination of workplace environmental and biolog-
ical monitoring is necessary to assess Cr(VI) exposure. LEV showed
promising protection efficiency, while further studies are needed to
evaluate how RPE best should be used in preventing Cr(VI) exposure
when other exposure control measures have been exhausted. Risk
assessment and risk reduction need to be improved at the companies and
supplemented with national policies to support risk awareness for non-
threshold carcinogens as well as surveillance of exposure levels, in order
to eliminate occupational cancer. Further studies are needed to clarify
the health consequences of the current Cr(VI) exposure.
CRediT authorship contribution statement
Zheshun Jiang:
Data curation, Formal analysis, Investigation,
Visualization, Writing
original draft, Writing
review
&
editing.
Linda
Schenk:
Formal analysis, Investigation, Methodology, Writing
original
draft, Writing
review
&
editing.
Eva Assarsson:
Investigation, Writing
review
&
editing.
Maria Albin:
Conceptualization, Funding acquisi-
tion, Project administration, Resources, Supervision, Writing
review
&
editing.
Helen Bertilsson:
Investigation, Writing
review
&
editing.
Eva Dock:
Investigation, Writing
review
&
editing.
Jessika Hagberg:
Investigation, Resources, Writing
review
&
editing.
Lovisa E. Karls-
son:
Formal analysis, Methodology, Writing
review
&
editing.
Pete
Kines:
Investigation, Writing
review
&
editing.
Annette M. Krais:
Investigation, Writing
review
&
editing.
Stefan Ljunggren:
Data
curation, Investigation, Methodology, Writing
review
&
editing.
Thomas Lundh:
Formal analysis, Investigation, Methodology, Super-
vision, Writing
review
&
editing.
Lars Modig:
Funding acquisition,
¨
Investigation, Writing
review
&
editing.
Rickie Moller:
Investigation,
Writing
review
&
editing.
Daniela Pineda:
Formal analysis, Meth-
odology, Project administration, Writing
review
&
editing.
Niklas
Ricklund:
Data curation, Investigation, Writing
review
&
editing.
Anne T. Saber:
Investigation, Writing
review
&
editing.
Tobias
¨
Storsjo:
Investigation, Writing
review
&
editing.
Evana Taher Amir:
Investigation, Writing
review
&
editing.
Håkan Tinnerberg:
Conceptualization, Investigation, Methodology, Writing
review
&
editing.
Martin Tondel:
Investigation, Methodology, Writing
review
&
editing.
Ulla Vogel:
Conceptualization, Investigation, Writing
re-
view
&
editing.
Pernilla Wiebert:
Data curation, Investigation, Writing
review
&
editing.
Karin Broberg:
Conceptualization, Funding acqui-
sition, Investigation, Methodology, Project administration, Resources,
Supervision, Writing
review
&
editing.
Malin Engfeldt:
Conceptuali-
zation, Data curation, Formal analysis, Investigation, Methodology,
Project administration, Resources, Supervision, Validation, Writing
review
&
editing.
Declaration of Competing interest
The authors declare no conflicts of interest.
Acknowledgments
¨
¨
This study has received funding from Forskningsrådet for halsa,
¨
lfard (Forte) (2020-00208) and Afa Forsakring
¨
¨ ¨
arbetsliv och va
(200279).
The project team would like to thank all the companies and workers
who participated in the SafeChrom study.
Appendix A. Supplementary data
Supplementary data to this article can be found online at
https://doi.
org/10.1016/j.ijheh.2023.114298.
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