Human Biomonitoring Initiative (HBM4EU): Human Biomonitoring Guidance Values Derived for Dimethylformamide
Abstract
:1. Introduction
2. Materials and Methods
2.1. General Methodology to Derive HBM-GVs in the Framework of the HBM4EU Project
- Selection of the relevant biomarker(s): a biomarker is defined as any substance, structure, or process that can be measured in the body or its degradation product(s) which influences or predicts the incidence of outcome or disease. Biomarkers can be classified into biomarkers of exposure (BME), biomarkers of effects, or biomarkers of susceptibility [2]. This first step consists of the data collection on the substance and its metabolites (i.e., toxicokinetic and toxicodynamic data). Based on these data, biomarkers of exposure and/or effect are identified and then chosen according to defined criteria: specificity, sensitivity, half-life, sampling conditions, invasiveness, background level, and analytical methods [15].
- The derivation of HBM-GVs for the selected biomarkers can then be conducted through three possible options (decision tree described in Figure 1). When the corresponding data are available, the preferred option is to base HBM-GV(s) identification on the relationship between internal concentrations of the selected biomarker(s) and the occurrence of adverse effects. The second possible option is to derive HBM-GVs from external limit values (i.e., Occupational Exposure Levels [OEL] or Toxicity Reference Values [TRV]) proposed by relevant European or non-European bodies. The last option consists of the derivation of HBM-GVs on the basis of critical effects observed in animal toxicological studies. These options are described in more detail in Apel et al. (2020) [2].
- Choice of the critical effect which is considered to be the most sensitive among all adverse effects that may arise from exposure to the substance (e.g., changes in morphology, physiology, growth, development, reproduction, or life span resulting in an impairment of functional capacity, an impairment of the capacity to offset additional stress, or an increase in sensitivity).
- Selection of the key study and identification of a point of departure (POD) with the most informative studies, i.e., well-conducted human studies adequately reporting measured internal concentration levels of a substance, sampling times, analytical methods used, and the relationships between concentrations of a substance or its metabolites in human biological media and the occurrence of adverse effects. If relevant and qualitatively acceptable human studies are available, a key human study together with a Point of Departure (POD) is selected.
- Application of assessment factors (AFs), when necessary, to obtain the HBM-GVs. These can be divided into an AFH for the intraspecies variability or possible other AFs to compensate for the potential remaining uncertainties in the derived HBM-GV, especially regarding the possible deficiencies or data gaps in the available data sets [2].
2.2. Methodology Used for Deriving HBM-GVWorker for DMF
- the reports by the American Conference of Governmental Industrial Hygienists (ACGIH) [16,17], the German Research Foundation or Deutsche Forschungsgemeinschaft (DFG) [18,19], the European Chemicals Agency (ECHA) [7], the International Agency for Research on Cancer (IARC) ([10]), and the Scientific committee for occupational exposure limits (SCOEL) [20];
- for more recent and specific publications, a bibliographical research, which was conducted in Medline and Scopus until 2021 with the following keywords: Dimethylformamide, DMF, guidance value, toxicity reference value (TRV), biomarker of exposure, biomonitoring, toxicokinetic, health effects, liver, carcinogenicity, and reprotoxic effects.
3. Results
3.1. Identification of Possible Biomarkers of Exposure
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- Unchanged DMF in urine;
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- total NMF or tNMF (which is the sum of HMMF and NMF) in urine;
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- AMCC in urine;
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- MCVal in blood; and
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- formamide in urine.
3.2. Identification and Characterization of the Dangers Associated with DMF Exposure
Reference | Subjects | Exposure DMF in the Air (DMFa) Metabolites * | Results/Observations | |
---|---|---|---|---|
Lyle et al., 1979 [52] England | Workers (DMF used as solvent) N = 102) 3-year follow-up | DMFa Range: <10 to 200 ppm (30–600 mg·m−3) tNMF (tNMFu) Range: <10 to 77 µL/L (probable error in the unit) | Alcohol intolerance reactions Facial flushing and other symptoms in 19 workers 26 of the 34 episodes occurred after the workers had consumed alcoholic drinks Liver function not investigated | |
Yonemoto and Suzuki, 1980 [53] Japan | Workers (synthetic leather factory) N = 11 (biomonitoring data for 9 of them) | DMFa Range: 0–5 ppm (0–15 mg·m−3) (TWA) Post-Shift (PS) tNMFu Range: 0.4–19.56 mg·d−1 | No effect on serum biochemistry (liver enzymes) Alcohol intolerance: 6/11 workers said to be less tolerant than before | |
Lauwerys et al., 1980 [27] Belgium | Workers in an acrylic fiber factory N = 22 (+28 controls) | DMFa Mean: 13 (1.3–46.6) mg·m−3 (4.5 (0.4–15.3) ppm) Stationary sampling tNMFu <40–50 mg·g−1 cr (PS) | No effects on serum biochemistry (liver enzymes not elevated) Signs of alcohol intolerance in some workers | |
Catenacci et al., 1984 [54] Italy Quoted by SCOEL (2006) [20] | N = 54 (employed > 5 y) acrylic fiber plant 2 groups exposed and 54 controls) | Group 1 (N = 28) DMFa Mean (range): 6 (4–8) ppm (18 (12–24) mg·m−3) tNMFu 22.3 mg·L−1 | Group 2 (N = 26) DMFa Mean (range): 1 (0.6–1.6) ppm (3 (1.8–4.8) mg·m−3) tNMFu: 7 mg·L−1 | No significant effects on liver enzymes in the 2 groups |
Sakai et al., 1995 [55] Japan | Workers (N = 10) Polyurethane production 2.5-year follow-up | DMFa Geometric mean (GM): 2.5–10.4 ppm (7.5–31.2 mg·m−3) PS tNMFu Mean: 24.7 mg·g−1 cr AMCCu Mean: 22.0 mg·g−1 cr | No effects on liver enzymes | |
Fiorito et al., 1997 [50] Italy | N = 75 (employed) synthetic leather production and 75 controls (unexposed workers) | DMFa Group 1 (Washing) N = 10 GM: 21.5 mg·m−3 (7.2 ppm) Range: 5–40 mg·m−3 Group 2 (Production) N = 12 GM: 18.7 mg·m−3 (6.2 ppm) Range: 5–40 mg·m−3 tNMFu (N = 22): GM: 13.6 mg·L−1 or 13.4 mg·g−1 cr PS | Elevation of liver enzymes (12/75) [p < 0.01] Alcohol intolerance in 50% of exposed workers and facial flushing (38%), palpitations (30%), headache (22%), body flushing (15%), and tremors (14%) Gastrointestinal symptoms (stomach pain, nausea, loss of appetite) in 50% of exposed workers | |
Wrbitzky and Angerer, (1998) [47]; Wrbitzky, (1999) [48] Germany | Polyacrylic fiber production N = 126 (total of exposed workers) | DMFa Mean (SD): 4.1 ± 7.4 (<0.1–37.9) ppm (12.3 ± 22.2 mg·m−3) tNMFu Mean (SD): 14.9 ± 18.7 (0.9–100) mg·L−1 9.1 ± 11.4 (0.5–62.3) mg·g−1 cr | Effects on liver enzymes Synergetic effect of alcohol consumption on liver enzymes activity | |
Finishing N = 55 | DMFa Mean (SD): 14.2 ± 2.2 (>0.1–13.7) ppm (42.6 ± 6.6 mg·m−3) tNMFu Mean (SD): 4.5 ± 4.3 mg·g−1 cr | Effects on liver enzymes in alcohol consumers | ||
Dyeing N = 12 | DMFa Mean (SD): 2.5 ± 3.1 (0.1–9.8) ppm (7.5 ± 9.3 mg·m−3) tNMFu Mean (SD): 6.7 ± 5.4 (0.8–17.2) mg·g−1 cr | No effects on liver enzymes in workers not drinking alcohol Reduced alcohol consumption in workers drinking alcohol | ||
Dry spinning N = 28 | DMFa Mean (SD): 6.4–9.6 (0.8–36.9) ppm (19.2 ± 28.8 mg·m−3) tNMFu Mean (SD): 11.6 ± 13.1 (0.9–62.3 mg·g−1 cr) | |||
Wet spinning N = 30 | DMFa Mean (SD): 7.3 ± 10.2 (0.3–37.9) ppm (21.9 ± 30.6 mg·m−3) tNMFu Mean (SD): 16.0 ± 15.9 (0.4–54.0) mg·g−1 cr | |||
He et al., 2010 [45] China | Synthetic leather and other resins production N = 79 (58 men and 21 women) | Group 1 (N = 33): Low exposure DMFa Min-Max: Not detected- <4.55 mg·m−3 (1.6 ppm) DMFu GM: 0.26 mg·g−1 creatinine tNMFu GM: 1.80 mg·g−1 creatinine AMCCu GM: 4.25 mg·g−1 creatinine Group 2 (N = 24): Medium exposure DMFa (Mean): 9 mg·m−3 (3 ppm) DMFu (GM): 0.53 mg·g−1 creatinine tNMFu (GM): 9.6 mg·g−1 creatinine AMCCu (GM): 25.4 mg·g−1 creatinine Group 3 (N = 22): High exposure DMFa (Mean): 36 mg·m−3 (12 ppm) DMFu (GM): 1.78 mg·g−1 creatinine tNMFu (GM): 26.5 mg·g−1 creatinine AMCCu (GM): 45.5 mg·g−1 creatinine | About 60% of subjects with urine AMCC concentration above 40 mg·g−1 cr had raised liver enzyme activities Statistically more workers with raised liver enzymes in group 3 (high exposure group) than in group 1 (administrative staff of the factory); p < 0.05 | |
Kilo et al., 2016 [51] Germany | Synthetic fiber production N = 220 workers and 175 Controls | Mean ± SD DMFa: 6.2 ± 7.6 mg·m−3; 2.1 ± 2.5 ppm tNMFu: 7.75 (±8.82) mg·L−1 AMCCu: 9.42 (±10.42) mg·g−1 cr McVal: 83.3 (±83.1) nmol·g−1 globin | None of the tested liver enzyme activities showed a positive association with any of the three exposure markers Alcohol intolerance reactions (not influencing alcohol consumption behavior) | |
Wu et al., 2017 [46] China | Synthetic leather production N = 698 And 188 controls | 3 exposure groups: Median (range) Low exposure group tNMFu (N = 228): 0.0025 mg·L−1 (ND-0.11) AMCCu (N = 227): 2.18 mg·L−1 (ND-16,95) MCVal (N = 232): 15.19 nmol·mol−1 globin (ND-29.37) Moderate exposure groups tNMFu (N = 227): 1.78 mg·L−1 (0.11–3.88) AMCCu (N = 228): 44.9 mg·L−1 (16.95–86.62) MCVal (N = 234): 46.00 (29.37–63.95) nmol·mol−1 globin High exposure groups tNMFu (N = 227): 9.59 mg·L−1 (>3.88) AMCCu (N = 227): 148.01 mg·L−1 (>86.62) MCVal (N = 232): 87.01 (63.95–) nmol/mol globin | Liver injury assessed by measurement of liver enzyme levels and compared to reference value ranges (AST and ALT: 0–45, γGT: 8–58U/L) Statistically more workers with raised liver enzymes only in high-exposure group for tNMF, in both moderate- and high-exposure groups for AMCCu and MCVal (p < 0.05) |
3.3. Choice of the Critical Effect
3.4. Choice of Relevant Biomarkers
3.4.1. Unchanged DMF in Urine
3.4.2. Total NMF in Urine
3.4.3. AMCC in Urine
3.4.4. MCVal Adducts to Globin in Blood
3.4.5. Formamide in Urine
3.4.6. Conclusion on BME Selection
3.4.7. Analytical Methods
3.5. Published Limit Values for Urine tNMF and AMCC in Occupational Setting
3.6. Choice of Key Studies and Identification of a POD for tNMF in Urine
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- Lauwerys et al. (1980) [27] observed no effect on liver enzymes up to 40–50 mg·g−1 creatinine (cr) tNMF in urine of 22 workers exposed to DMF during five consecutive days. The authors underlined that in the factory, the selection criteria (not disclosed) at the beginning of employment were rather severe and could have led to recruitment bias so that the results obtained may not reflect responses in any worker [16];
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- The two publications by Wrbitzky and Angerer (1998) and Wrbitzky (1999) reporting on the same study conducted in a cohort of 126 workers showed that liver damage was significantly more frequent in the exposed group than in controls. Mean tNMF concentration in the exposed group was 9.1 mg·g−1 creatinine (14.9 mg·L−1). However, considering the working areas, it was observed that liver damage was unexpectedly associated with the lowest exposure group (mean urine tNMF: 4.5 mg·g−1 creatinine) and could be explained by a higher alcohol consumption. In the other three areas, no excess of liver damage was observed for mean urine tNMF concentrations of 6.7, 11.6, and 16 mg·g−1 creatinine [47,48].
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- In a recent European study by Kilo et al. (2017), no excess risk of liver damage was observed in a cohort of 220 workers exposed to DMF with a mean concentration of 7.75 mg·L−1 tNMF in urine, compared with 175 controls [51].
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- The other three studies were conducted in Asian people:
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- Sakai et al. (1995) reported no effects on liver enzymes of DMF exposure in 10 workers during à 2.5-year-follow-up. The mean tNMF concentration in the urine of these workers was 24.47 mg·g−1·cr [55];
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- He et al. (2010) also reported that, when their cohort of 79 workers was divided into three groups, a significantly elevated risk of liver damage (liver enzyme elevation) according to DMF exposure was observed only in the group with the highest exposure (mean tNMF concentration: 26.5 mg·g−1·cr) [45]; and
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- Wu et al. (2017) measured liver enzyme activity in a cohort of 698 workers exposed to DMF and in 188 controls. They also measured tNMF urine concentration in exposed workers. A significantly elevated risk of liver damage was observed only for the third tertile of tNMF distribution (median tNMF concentration: 9.59 mg·L−1). The lower limit for the benchmark dose with a benchmark response of 10% above the adverse response rate of liver injury seen in the control group (BMDL10) was 14 mg·L−1 (tNMF) [46].
3.7. Choice of the Key Study and POD for AMCC in Urine
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- In the German study by Kilo et al. (2016), no effects on liver enzymes were observed in a cohort of 220 workers with a mean AMCC urine concentration of 9.42 mg·g−1 cr when they were compared to 175 controls; however, the range of the measured AMCC urine concentrations was very large (standard deviation: 10.42 mg·g−1 cr) [51];
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- in the Japanese study by Sakaï et al. (1995), no effects on liver enzymes were observed in 10 workers exposed to DMF during à 2.5-year follow-up. The mean AMCC concentration in the urine of these workers was 22 mg·g−1·cr [55];
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- in the study from China, He et al. (2010) also reported that, when their cohort of 79 workers was divided into three groups, a significantly elevated risk of liver damage (liver enzyme elevation) according to DMF exposure was observed only in the group with the highest exposure (mean AMCC concentration in urine: 45.5 mg·g−1 cr). Geometric mean values for the concentration of AMCC in urine of workers from the low and medium exposure groups were 4.25 mg·g−1·cr and 25.4 mg·g−1·cr, respectively [45];
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- a second Chinese study by Wu et al. (2017) measured liver enzyme activity in a cohort of 698 workers exposed to DMF and in 188 controls. They also measured AMCC urine concentration in exposed workers. A significantly elevated risk of liver damage was observed only for the second and the third tertiles of the AMCC distribution (median AMCC concentrations: 44.09 mg·L−1 and 148.01 mg·L−1, respectively). The median and maximal AMCC concentrations in the low exposure group (1st tertile), with no detectable liver damage excess, were 2.18 mg·L−1 and 16.95 mg·L−1, respectively. The lower limit for the benchmark dose with a benchmark response of 10% above the adverse response rate of liver injury seen in the control group (BMDL10) was 155 mg·L−1 (AMCC) [46].
4. Discussion
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Route | Effects on Liver | Reproductive Effects | Carcinogenic Effects on Liver |
---|---|---|---|
Inhalation | NOAEL: 25 ppm LOAEL: 100 ppm (Rats and mice) [68] | NOAEL: 25 ppm LOAEC: 150 ppm (Rabbits) [76] | LOAEC: 200 ppm (mice) LOAEC: 400 ppm (rats) [67] |
Oral | NOAEL = 238 mg/kg bw/d LOAEL = 475 mg/kg bw/d (Rats) (BASF (1977) unpublished data, quoted by ECHA [7]) | NOAEL = 166 mg/kg bw/d LOAEL = 503 mg/kg bw/d (Rats) [76] NOAEL: 44.1 mg/kg bw/d (Rabbits) [78] | LOAEL = 800 ppm (Rats) [69] |
Dermal | - | LOAEL: 94 mg/kg/d (Rats) 100 mg/kg/d (Rabbits) [76] | - |
Analyte | Biological Matrix | Advantages | Limits |
---|---|---|---|
Total NMF | Urine |
|
|
AMCC | Urine |
|
|
MCVal | Blood |
|
|
DMF | Urine |
|
|
Formamide | Urine | None |
|
Agency | Reference Value for Airborne DMF (Key Studies and Critical Effect) | Biomarker | Approach/ Endpoint | Key Study | Internal TRV and Sampling Time |
---|---|---|---|---|---|
SCOEL, 2006 [20] | 8h-TWA = 5 ppm (Liver damage in rats and mice, exposed by inhalation, whole body) [68] | tNMF in urine | Correlation based on the OEL of 5 ppm | Studies in workers [32,48,55,79,80,81,89,90] | BLV = 15 mg·L−1 Post-shift |
ACGIH, 2017 [16] | TLV-TWA = 5 ppm Liver damage in rats and mice and irritation in humans (eyes and upper respiratory tract) [49,68,91,92] | tNMF in urine | Relation between BME levels and effects on liver | Studies in workers [27,45,48,55] | BEI = 30 mg·L−1 End of shift |
AMCC in urine | Relation between BME levels and effects on liver | Studies in workers [45,55] | BEI = 30 mg·L−1 End of shift and end of workweek | ||
DFG, 2019 [19] | MAK value = 5 ppm (Liver damage in rats and mice, exposed by inhalation, whole body) [68] | tNMF in urine | Correlation based on the MAK value of 5 ppm | Studies in workers [82] | BAT = 20 mg·L−1 End of exposure or end of shift |
AMCC in urine | BAT = 25 mg·g−1·cr End of exposure or end of shift; Long-term exposure indicator: sampling at the end of a shift after several previous shifts |
Urinary tNMF | Urinary AMCC | |
---|---|---|
Regarding the nature and quality of the toxicological data | The database on DMF is based on a large number of both human and animal studies, and data on tNMF are robust and consistent. LoC: High | The database on DMF is based on a large number of both human and animal studies, but available studies reporting results for AMCC are limited. LoC: Medium |
Regarding the critical endpoint and mode of action | The confidence in the evidence of effects on the liver function is high. The effects on the liver after DMF exposure are well-studied in humans (workplace) and animals. LoC: High | The confidence in the evidence of effects on the liver function is high. The effects on the liver after DMF exposure are well-studied (in humans and animals). LoC: High |
Regarding the selected key studies for identification of the POD and their results | The database gives several robust occupational studies with many subjects and consistent results for tNMF. The approach consists of the selection of a pool of studies (from 1980 to 2017) carried out on Asians and Caucasian people (to consider the genetic variability due to ethnicity). LoC: High | The HBM-GVWorker is based on a the same four studies used for the derivation of tNMF HBM-GVWorker. However, the results of these studies indicate a large interval of NOAEL values together with a large margin between NOAEL and LOAEL values. LoC: Low |
Global LoC | High | Low-medium |
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Lamkarkach, F.; Meslin, M.; Kolossa-Gehring, M.; Apel, P.; Garnier, R. Human Biomonitoring Initiative (HBM4EU): Human Biomonitoring Guidance Values Derived for Dimethylformamide. Toxics 2022, 10, 298. https://doi.org/10.3390/toxics10060298
Lamkarkach F, Meslin M, Kolossa-Gehring M, Apel P, Garnier R. Human Biomonitoring Initiative (HBM4EU): Human Biomonitoring Guidance Values Derived for Dimethylformamide. Toxics. 2022; 10(6):298. https://doi.org/10.3390/toxics10060298
Chicago/Turabian StyleLamkarkach, Farida, Matthieu Meslin, Marike Kolossa-Gehring, Petra Apel, and Robert Garnier. 2022. "Human Biomonitoring Initiative (HBM4EU): Human Biomonitoring Guidance Values Derived for Dimethylformamide" Toxics 10, no. 6: 298. https://doi.org/10.3390/toxics10060298
APA StyleLamkarkach, F., Meslin, M., Kolossa-Gehring, M., Apel, P., & Garnier, R. (2022). Human Biomonitoring Initiative (HBM4EU): Human Biomonitoring Guidance Values Derived for Dimethylformamide. Toxics, 10(6), 298. https://doi.org/10.3390/toxics10060298