Statements

Second draft statement on the effects of lead on maternal health

TOX/2022/47

Last updated: 26 August 2022

This is a paper for discussion.

This does not represent the views of the Committee and should not be cited.

Second draft statement on the effects of lead on maternal health

1.  The Scientific Advisory Committee on Nutrition (SACN) last considered maternal diet and nutrition in relation to offspring health in its reports on ‘The influence of maternal, fetal and child nutrition on the development of chronic disease in later life’ (SACN, 2011) and on ‘Feeding in the first year of life’ (SACN, 2018). In the latter report, the impact of breastfeeding on maternal health was also considered.

2.             In 2019, SACN agreed to conduct a risk assessment on nutrition and maternal health focusing on maternal outcomes during pregnancy, childbirth and up to 24 months after delivery; this would include the effects of chemical contaminants and excess nutrients in the diet.

3.             SACN agreed that, where appropriate, other expert Committees would be consulted and asked to complete relevant risk assessments e.g. in the area of food safety advice. This subject was initially discussed during the horizon scanning item at the January 2020 COT meeting with a scoping paper being presented to the Committee in July 2020. This included background information on a provisional list of chemicals proposed by SACN. It was noted that the provisional list of chemicals was subject to change following discussion by COT who would be guiding the toxicological risk assessment process: candidate chemicals or chemical classes can be added or removed as the COT considered appropriate. The list was brought back to the COT with additional information in September 2020. Following a discussion at the COT meeting in September 2020, it was agreed that papers on a number of components should be prioritised and to this end, papers on iodine, vitamin D and dietary supplements have been or will be presented to the Committee. The remaining list of compounds were to be triaged on the basis of toxicity and exposure.

4.             Following discussion of the first prioritisation paper on substances to be considered for risk assessment by the COT, the Committee decided that each of the heavy metals (lead, mercury, cadmium and arsenic) should be considered in separate papers. The following paper discusses the risks posed to maternal health by lead (Pb) in the diet and the environment.

5.             From their conversations on the 1st draft statement on lead in the maternal diet, the Committee concluded that for clarity of understanding the risk of lead in the maternal diet, an aggregate exposure and characterisation should be included.

6.             Members requested an overview be included of the results from studies that had assessed the toxicology of lead, specifically in the context of pregnancy outcomes and its effects on maternal health.

7.             Members further requested that more clarity should be provided on the role of pica in lead exposure in the maternal diet.

Questions for the Committee

8.             The Committee are asked to consider the following question:

a)             Does the Committee have any comments on the structure or content of the draft Statement?

b)             Does the Committee have any comments on the additional information presented in this draft statement regarding pica?

c)             Does the Committee have any comments on the additional information presented in this draft statement regarding the aggregate exposure assessment?

Secretariat

September 2022

Annex A

Introduction

1.             The Scientific Advisory Committee on Nutrition (SACN) last considered maternal diet and nutrition in relation to offspring health in its reports on ‘The influence of maternal, fetal and child nutrition on the development of chronic disease in later life’ (SACN, 2011) and on ‘Feeding in the first year of life’ (SACN, 2018). In the latter report, the impact of breastfeeding on maternal health was also considered.

2.             In 2019, SACN agreed to conduct a risk assessment on nutrition and maternal health focusing on maternal outcomes during pregnancy, childbirth and up to 24 months after delivery; this would include the effects of chemical contaminants and excess nutrients in the diet.

3.             SACN agreed that, where appropriate, other expert Committees would be consulted and asked to complete relevant risk assessments e.g., in the area of food safety advice. This subject was initially discussed during the horizon scanning item at the January 2020 meeting with a scoping paper being presented to the Committee in July 2020. This included background information on a provisional list of chemicals proposed by SACN. It was noted that the provisional list of chemicals was subject to change following discussion by COT who would be guiding the toxicological risk assessment process: candidate chemicals or chemical classes can be added or removed as the COT considered appropriate. The list was brought back to the COT with additional information in September 2020. Following a discussion at the COT meeting in September 2020, it was agreed that papers on a number of components should be prioritised and to this end, papers on iodine, vitamin D and dietary supplements have been or will be presented to the Committee. The remaining list of compounds were to be triaged on the basis of toxicity and exposure.

4.             Following discussion of the first prioritisation paper on substances to be considered for risk assessment by the COT, the Committee decided that each of the heavy metals (lead, mercury, cadmium and arsenic) should be considered in separate papers. The following paper discusses the risks posed to maternal health by lead in the diet and the environment.

Background

5.             The Merck Index (12th Edition, 1996) describes lead (Pb) as a bluish-white-to-silvery grey Group 14 metal, with atomic number 82 and a relative atomic mass of its most abundant isotope of 208. It occurs naturally in the Earth’s crust at an abundance of about 0.002%, chiefly as lead sulphide (PbS), It is very soft and malleable and has a long history of use in domestic articles such as drinking vessels and plates and in water and drainage pipes (plumbing, from “plumbum”, the Latin word for lead). More recently it has been used in paints, ceramic pigments and as the “anti-knock” agent tetraethyl lead in petrol. Due to its long-known toxicity, many of these uses have been substituted with less toxic alternatives but lead is still used in various applications such as car batteries and as radiation shielding in the nuclear industry.

6.             The Joint FAO/WHO Committee on Food Additives (JECFA) (FAO/WHO, 2011) state that lead contamination of food arises mainly from the environment or from food processing, handling and packaging. Atmospheric lead can contaminate food through deposition on agricultural crops.  Water is another source of lead contamination of food. Although lead exists in both organic and inorganic forms, only inorganic lead has been detected in food.  Specifically, the major contributors to lead exposure are: cereal products, potatoes, cereal grains (except rice), cereal-based mixed dishes and leafy vegetables.

Previous evaluations

7.             The safety of lead in food has previously been evaluated by the European Food Safety Authority (EFSA) Panel on Contaminants in the Food Chain (CONTAM Panel) (EFSA, 2010, updated 2013) and JECFA (2011).  The US Agency for Toxic Substances and Disease Registry has also reviewed the toxicity of lead (ATSDR,1999).  These evaluations are discussed in more detail in the discussion paper for Lead on the Maternal Diet (COT, 2022).  

ADME

8.             Lead absorption has been measured in a number of studies, and in adult humans is approximately 10% of the ingested dose (Rabinowitz et al., 1976). Lead absorption from the gastrointestinal tract appears to be higher in infants and children than in adults, with an average lead absorption in infants of about 42 % of intake (Ziegler et al., 1978). This is supported by animal studies which indicate that gastrointestinal absorption rates for lead are greater in the very young than in older animals (Forbes et al., 1972; McMichael et al., 1986).

9.             Approximately 95 % of lead in adult tissues and 70 % in children resides in mineralised tissues such as bones and teeth. This reflects changing turnover rates throughout an individual’s lifetime, with a slower turn-over of lead in the bones of adults than those of children. The lead which has accumulated in adult bone can replenish lead eliminated from blood by excretion, long after the external exposure has ended. It can also be a source of lead transfer to the fetus when the maternal skeleton is resorbed for the production of the fetal skeleton. Naylor et al. (2009) found that by week 36 of pregnancy there was an increase in levels of bone resorption markers between 58 % and 202 % and a change in bone formation markers of between -58 % and +88 % suggesting a significant change in the rate of bone turnover during the gestation and post-partum period.  Gulson et al. (1997) found 20 % increases in blood lead (bPb) were detected in the mother during pregnancy.  Additionally, it is worth noting that previous studies have suggested that bPb levels have increased only in the second half of pregnancy, however, Gulson (1997) found two subjects with increased bPb levels in the first trimester of pregnancy.  Skeletal contribution to bPb level was shown to be 31 % ± 19 % (mean ± SD), with the remaining increase suggested to be due to increased absorption of dietary lead and decreased elimination of absorbed lead.  These results showed that mobilisation from long-term stores (i.e. bone) was a significant contributor to bPb levels during pregnancy.  However, it is pertinent to clarify that lead levels in bone accumulate over a period of many years before pregnancy and are largely contributed to by the pre-maternal rather than maternal diet and as such falls beyond the remit of this paper.   

10.          Bolan et al (2021) examined the intestinal permeability of lead, as influenced by gut microbes and chelating agents using an in vitro gastrointestinal/Caco-2 cell intestinal epithelium model. The results showed that in the presence of gut microbes and chelating agents, there was a significant decrease of 7.9 % in the permeability coefficient of lead, therefore indicating a decrease in lead reabsorption from the gut. 

11.          Rădulescu and Lundgren (2019) reviewed the recent pharmacokinetic models for lead. Absorption takes place via ingestion, inhalation and to a lesser extent through the skin. The effectiveness of the gastrointestinal absorption depends on the quantity and type of food consumed prior to lead ingestion. The efficiency of gastrointestinal absorption of water-soluble lead is also age-dependent and is higher in children than in adults. The authors cited several older studies regarding the different distributions of lead in human soft tissues, highlighting that the major organ is the liver (Barry, 1975; Gross et al. (1975); Schroeder, H. A. & Tipton, I. H. 1968; Barregård et al. 1999; and Gerhardsson et al. 1995).

Toxicity

12.          The acute effects of lead, from intense exposure of short duration, can manifest as muscle pain, fatigue, abdominal pain, headache, vomiting, seizures, and coma. While there are not enough data to establish a sufficient dose-response relationship for acute toxicity relative to bPb, anecdotally, symptoms that cause individuals to seek medical intervention can occur at bPb levels of ~30 µg/dL with signs and symptoms increasing in severity with increasing bPb. Chronic lead poisoning from low level, repeated exposure gives clinical signs of persistent vomiting, encephalopathy, lethargy, delirium, convulsions and coma. Depending on the location or organ being assessed, chronic adverse effects can occur at bPb levels 5 µg/dL (ATSDR, 2020).

13.           The International Agency for Research on Cancer (IARC) classified lead compounds as probably carcinogenic to humans (Group 2A) on the basis of limited evidence of carcinogenicity in humans and sufficient evidence in animals. Organic lead compounds were considered not to be classifiable as to their carcinogenicity to humans (Group 3) because there was inadequate evidence for carcinogenicity in humans and animals. The mechanisms of lead induced cancers in experimental systems are complex, appearing to involve oxidative stress, interaction with zinc finger proteins, induction of apoptosis, altered cell signalling pathways and interactions with cellular genetic machinery by high affinity lead-binding proteins (IARC, 2006).

14.          Flora et al. (2012) and Wani et al. (2015) reviewed the toxicity of lead. They determined that the central nervous system, erythropoietic system and the kidneys are the most affected systems but overall, all bodily systems are adversely affected by the presence of this metal.

15.          It has been estimated that systolic pressure is approximately 1 mm Hg higher for each doubling of bPb, without any clearly identifiable threshold (EFSA, 2010). In the dose response (DR) modelling for cardiovascular effects, EFSA selected a 1 % change in systolic blood pressure as a benchmark response (BMR), this was within the range that could have significant consequences for human health at a population level, an average BMDL01 of 36 µg/L bPb was calculated from two longitudinal and two cross-sectional studies (Glenn et al., 2003; Vupputuri et al., 2003; Nash et al., 2003; Glenn et al., 2006).

16.          Both reduced glomerular filtration rate (GFR) associated with exposures to average bPb levels of <200 µg/L and increased serum creatinine in subjects with blood lead levels below 100 µg/L have been observed.  EFSA (2010) selected a 10 % increase in the prevalence of chronic kidney disease as a BMR for renal effects and a BMDL10 of 15 µg/L bPb was calculated using data from a cross-sectional study conducted in the USA (Navas-Acien et al., 2009).

17.          The COT (2013) determined that neurodevelopmental effects represent the most sensitive endpoint for effects in the developing fetus whilst also being protective of the other toxicological end points in the mother. The study used for the benchmark dose modelling undertaken by EFSA (2010) is described in the following paragraph.

18.          An analysis by Lanphear et al. (2005), was used by both EFSA and JECFA for dose-response (DR) modelling of neurodevelopmental effects (EFSA, 2010; and FAO/WHO, 2011). This was a pooled analysis of data from seven prospective cohort studies concerning the quantitative relationship between performance on IQ tests and measures of bPb concentration, among children followed from infancy. The primary outcome measure was full-scale IQ, assessed at an age between four years 10 months and 10 years. This was related to four measures of bPb: concurrent bPb (the most recent measurement before IQ was assessed), maximum bPb (the highest concentration of bPb that had been measured at any time before IQ was assessed), average lifetime bPb (the mean of bPb measurements from age 6 months up to the time that IQ was assessed) and early childhood bPb (the mean of measurements between 6 and 24 months of age). After adjustment for covariates, IQ was inversely related to each of these measures of bPb (Lanphear et al., 2005).

19.          The toxicology of lead specifically in the context of pregnancy outcomes and its effects on maternal health have also been previously reviewed and the results are briefly described below:

20.          Maternal lead exposure is associated with multiple poor birth outcomes including pre-term delivery and small for gestational age (SGA) births (Chen, (2006); Jelliffe-Pawlowski et al. (2006); Taylor et al. (2015); Vigeh et al. (2011); and Zentner et al., (2006)). 

21.          It has been found that low to moderate lead exposure may also increase the risk of spontaneous abortion during early pregnancy (Hertz-Picciotto, 2000; Ou et al. 2020). Additionally, Lamadrid-Figueroa et al. (2007) determined that women in the upper tertile of the plasma/blood Pb ratio had twice the incidence rate for spontaneous abortion than those in the lower tertile (p = 0.02). Borja-Aburto et al. (1999) evaluated the risk of spontaneous abortion from low or moderate Pb exposures during their first trimester. The odds ratio for spontaneous abortion was found to be 1.8 for every 5 μg/dL increase in bPb. Conversely, however, Vigeh et al. (2011) did not find significant difference between spontaneous abortion cases and ongoing pregnancies, suggesting that in apparently healthy women, low bPb levels (mean <5 μg/dL) in early pregnancy may not be a risk factor for spontaneous abortion. Based on available data, it can be inferred that long-term lead exposure adversely affects fetal viability as well as fetal and early childhood development, as lead is reported to cross the placenta readily.

22.          Hu et al. (2006) found that both maternal plasma and whole blood lead during the first trimester (but not in the second or third trimester) were significant predictors (p < 0.05) of poorer Mental Development Index (MDI) scores.  Postnatal blood lead levels in the offspring were less strongly correlated with MDI scores indicating that the adverse effect of lead exposure on neurodevelopment may be most pronounced during the first trimester.

23.          Poropat et al. (2017, from abstract) and Ikechukwu et al. (2012, from abstract) found a correlation between an increase in blood lead and the development and progression of preeclampsia. Ikechukwu et al. (2012) further state that the increases observed in lead levels were paralleled by decreases in serum calcium and phosphorus levels. Conversely, Liu et al (2019) did not find an association between the development of preeclampsia and bPb levels.

Derivation of a health-based guidance value

24.          The dose response modelling and derivation of an HBGV have been reviewed and summarised in the COT statement (2013). The COT discussed the three endpoints assessed by EFSA (cardiovascular, renal and neurodevelopmental effects) and concluded that the most relevant was neurodevelopmental effects. This is summarised in brief in the following paragraphs.

Benchmark Dose Modelling

25.          An analysis by Lanphear et al. (2005) (paragraph 28), was used by both EFSA and JECFA for dose-response (DR) modelling of neurodevelopmental effects (EFSA, 2010; and FAO/WHO, 2011). The DR modelling was previously described in a COT statement in 2013 relating to Pb in the infant diet and has been summarised in the following paragraphs (COT, 2013).

26.          Budtz-Jørgensen (2010) was commissioned by EFSA to calculate a BMDL for the association of lead with the development of intellectual function, by modelling of data from the pooled analysis by Lanphear et al. (2005). The benchmark calculations used regression models with full IQ score as the dependent variable, and adjustment for birth weight, Home Observation for Measurement of the Environment (HOME) score (The HOME Inventory is an index that reflects the quality and quantity of emotional and cognitive stimulation in the home environment (Lanphear et al., 2005)), maternal education and maternal IQ, all of which were significantly associated with IQ in the dataset. BMD and BMDL values were calculated for a 1% change in full scale IQ score (a decrease in IQ by 1 point), taking concurrent blood lead, maximum blood lead, average lifetime blood lead and early childhood blood lead as alternative exposure metrics. The dose-response models applied were logarithmic, linear, and a piecewise linear function with breakpoint at 100 µg/L.

27.          For the assessment of risk, EFSA took as a point of departure, the BMDL01 value of 12 µg/L from the piecewise linear dose-response model for concurrent blood lead. Concurrent blood lead concentration exhibited the strongest relationship with IQ, and the piecewise linear model showed a better fit to the data than the linear model. The logarithmic model generally gave an even better fit than the piecewise linear model, but the differences were small, and EFSA preferred the latter because, taking into account the mathematical properties of the logarithmic model, they considered that it provided “less uncertain estimates of the BMDL01”. Using the US EPAs Integrated Exposure and Uptake Biokinetic (IEUBK) toxicokinetic model, the blood lead BMDL01 of 12 µg/L was estimated to correspond to a dietary lead exposure in infants and children of 0.5 µg lead/kg bw/day (EFSA, 2010).

28.          JECFA (FAO/WHO, 2011) also used data from the Lanphear et al. (2005) analysis for dose-response modelling. Models were based on concurrent blood lead levels since they showed the highest correlation with IQ. Initially, six different models were considered – four with linear form and two sigmoidal. From these, a bilinear model (unlike the piecewise linear model used by EFSA, this did not constrain the inflexion in the dose-response relationship to be at a pre-specified blood lead concentration) was chosen to characterise the relationship of blood lead to IQ, since it provided a better fit than four of the other models, and it was considered that it would give better estimates of effect than the one other model with similar fit, when non-dietary exposures to lead were unknown or highly variable. Using this model, the chronic dietary exposure of a 20 kg child corresponding to a decrease of 1 IQ point was estimated to be 0.6 µg/kg bw/day with a 90 % confidence interval of 0.2 - 7.2 µg/kg bw/day.

29.          The differences between the EFSA and JECFA analyses are small and reflect inevitable uncertainties in the specification of the mathematical models. The COT noted that both were influenced by an apparently steep dose-response at low levels of lead exposure (blood lead levels less than 75 µg/L), which was based on few data from a single study in Rochester, USA, and may have rendered the BMDL values conservative.  In this statement, the COT has based its risk characterisation on the EFSA BMDL01, which is between the EFSA BMD01 and the lower 90 % confidence limit for the BMD01 calculated by JECFA. The EFSA BMDL01 corresponds to a dietary exposure of 0.5 µg/kg bw/day.

Exposure Assessment

Exposure from food

30.          The FSA Exposure Assessment Team has provided dietary exposure data on lead for women of childbearing age (16 – 49 years of age) (Table 1, Appendix 1). The food commodities which result in the highest exposure to lead are green vegetables, miscellaneous cereals and other vegetables with mean exposure values of 0.0088, 0.0080 and 0.0063 µg/kg bw/day and 97.5th percentile values 0.034, 0.028 of 0.019 µg/kg bw/day, respectively. The total exposures via food were calculated as 0.12 µg/kg bw/day (mean) and 0.23 µg/kg bw/day (97.5th percentile).

Exposure from drinking water

31.          Data on concentrations of lead in water had previously been provided by the Drinking Water Inspectorate (DWI) (for England and Wales), the Drinking Water Quality Regulator (DWQR) for Scotland and Northern Ireland Water. The concentration data from 2019 for lead in drinking water are given in Table 2, Appendix 1.

32.          The FSA Exposure Assessment Team has provided values for water consumption for women of child-bearing age of 8 (median) and 32 (97.5th percentile) g (ml) of water per kg bodyweight per day. Using the upper bound mean lead concentration values in drinking water (2.15, 0.48 and 1.1 for England/ Wales, Scotland and Northern Ireland respectively), the calculated exposures to lead from drinking water are shown in Table 1.

Table 1. Calculated mean and 97.5th percentile exposures for women of childbearing age to lead from drinking water, using the mean upper bound concentration values (µg/kg bw/day).

Region

N (number of women)

Median **

97.5th percentile **

England and Wales*

10967

0.00024

0.00098

Scotland

436

 0.000054

 0.00021

Northern Ireland

122

 0.00013

 0.00050

*using 99th percentile lead concentration.

** Average body weight of 70.3kg for women of childbearing age used for exposure calculation. Value provided by the FSA Exposure Assessment Team from years 1 – 11 of the rolling National Diet and Nutrition Survey, NDNS.

Exposure from the air

33.          Defra provide data on air pollution throughout the UK. An interactive map (Defra, 2020) shows that the majority of the country in 2020 had an average air concentration of <10 ng lead/m3, with major urban centres in England and Wales having concentrations of 10 – 50 ng lead/m3.

34.          The WHO estimates that the average inhalation rate for a 70 kg adult is 20 m3/day (WHO, 2000). 

35.          As a worst-case scenario, if an adult female were to be constantly exposed to an air concentration of 50 ng lead/m3 then this would result in a daily exposure to 1000 ng of lead from the air. For women with an average body weight of 70 kg, (value provided by the FSA Exposure Assessment Team from years 1 – 11 of the rolling National Diet and Nutrition Survey, NDNS) this gives an exposure of 14 ng/kg bw (0.014 µg/kg bw/day).

36.          This assumes full absorption of all lead in particles inhaled, but this depends upon particle sizes and since some of the inhaled dose may become trapped in other parts of the nasopharynx, these inhalation values are probably an overestimate, but may contribute in a small way to ingested lead.

Exposure from soil and dust  

37.          People may be exposed to lead through swallowing dirt that contains lead.  Ingestion of contaminated soil is often as a result of “hand-to-mouth” activity and while being a more important route of exposure for toddlers and children, still presents a potential source of intake in adults, for example, from the surface of unwashed vegetables.

38.          Lead concentrations in soil are influenced both by underlying lithological lead concentrations and by anthropogenic release of lead. Lead was measured in topsoil from England from a depth of 0-15 cm as part of a DEFRA-commissioned project (Ander et al., 2011).

39.          Table 2 shows the lead exposures from soil for women of child-bearing age.  Mean and 75th percentile lead concentrations from soil in regions classified as rural, semi-urban or urban were used to assess potential exposures of adults through soil ingestion.  An ingestion rate of 50 mg soil/day was assumed based on the rate used by the Environment Agency in their Contaminated Land Exposure Assessment (CLEA) model (Environment Agency, 2009) and was based on a consensus value from studies by USEPA (1997) and Otte et al. (2001). It is a combined value for soil and dust as most of the evidence used to determine the ingestion rate does not differentiate between soil and household dust.  Furthermore, the evidence base for selecting a representative soil ingestion rate for adults is much smaller than that for children and as such USEPA (1997) cautioned that the value is highly uncertain and based on a low level of confidence.

Table 2. Median and 75th percentile exposure values for women of childbearing age to lead from soil.  Soil lead concentrations taken from the Defra-commissioned contaminants in the soils of England report (Ander et al. 2011) and an ingestion of 50 mg soil/day provided by the Environment Agency (2009).

Statistic 

Region  

Soil concentration of lead (mg/kg)  

Lead ingestion (µg/kg bw/day)* 

Mean 

Rural 

35 

0.025 

Mean 

Semi-Urban 

57 

0.041 

Mean 

Urban  

166 

0.118 

75th percentile 

Rural 

46 

0.033 

75th percentile 

 

Semi-Urban 

100 

0.071 

75th percentile 

 

Urban  

322 

0.229 

* Average body weight for women of childbearing age used for ingestion rate = 70.3 kg, value provided by the FSA Exposure Assessment Team from years 1 – 11 of the rolling National Diet and Nutrition Survey, NDNS.

40.          The data presented are representative of lead concentrations in the soil in England only. There have been no individual studies investigating the lead levels in soils of Wales, Scotland or Northern Ireland.

41.          Pica behaviour is described as the craving for and intentional ingestion of substances that are not described as food. Globally, it is thought to affect up to 28 % of pregnant women, albeit with a high degree of geographic variability (Fawcett et al, 2016). Therefore, pica presents a potential route of exposure to lead in the maternal diet. However, pica has not been considered as part of this statement due to the lack of data available for the consumption of soil as part of pica behaviour.

42.          No recent data were available for levels of lead measured in household dust in the UK.

Aggregate Exposure

43.          Aggregate exposure to lead from food, drinking water, soil and dust, and air were derived by considering a number of scenarios based on available data. Table 3 shows scenarios of aggregate exposure from the sources listed above and includes estimate of average and high exposure from these sources as indicated below.

44.          Average and high exposure for food and drinking water represents the mean and P97.5 exposure as described in paragraphs 30 – 32. Data for exposure from drinking water in England and Wales were used as this represented the highest exposure compared to Scotland and Northern Ireland. The contribution from air in all scenarios is based on average inhalation rates and the maximum concentration from a range reported for England and Wales. For exposure from soil and dust, the average and high exposure represents the mean and P75 exposure respectively for the region with the highest exposure (i.e. urban region as shown in Table 2 and paragraphs 37 -41).

Table 3. Aggregate exposure to lead from food, drinking water, soil, dust and air*.

Scenarios

Aggregate exposure (μg/kg bw/day)

Average exposure from all sourcesa

0.25

High exposure from all sourcesb

0.49

High exposure from food and mean exposure from all other sourcesc

0.36

High exposure from drinking water and mean from other sourcesd

0.26

High exposure from soil and dust and mean from other sourcese

0.36

a This scenario represents a summation of average exposure from food, water and soil and a value for air*.

b Exposure is based on summation of P97.5 estimates for food and water, P75 for dust and soil and a value for air*.

c Exposure is based on summation of P97.5 estimates for food and the averages for water, dust and soil and a value for air*

d Exposure is based on summation of P97.5 estimates for drinking water and the averages for food, dust and soil and a value for air*

e Exposure is based on summation of P75 estimate for soil and dust and averages for food, water and a value for air*.

*The contribution from air in all scenarios is based on average inhalation rates and the maximum concentration identified for England and Wales as shown in paragraphs 33 - 34.

Risk characterisation

45.          Potential risks from maternal exposures to lead were characterised by margins of exposure (MOEs), calculated as the ratio of the BMDL of 0.5 µg/kg bw/day to estimated exposures from diet, soil and air. As the BMDL was for a small effect (a one-point difference in IQ), derived from pooled analysis of multiple cohort studies of exposures in infants and children, and is likely to be conservative (see paragraph 26-27), EFSA therefore concluded that a margin of exposure of 10 or greater should be sufficient to ensure that there was no appreciable risk of a clinically significant effect on IQ. At lower MOEs, but greater than 1.0, the risk is likely to be low, but not such that it could be dismissed as of no potential concern. (EFSA, 2010)

46.          In 2013, the COT further concluded that an MOE of >1 can be taken to imply that at most, any risk is likely to be small. MOEs <1 do not necessarily indicate a problem, but scientific uncertainties (e.g. because of potential inaccuracies in the assessment of exposures, failure to control completely for confounding factors, and the possibility that the samples of children studied have been unrepresentative simply by chance) mean that a material risk cannot be ruled out. This applies particularly when MOEs are substantially <1 (COT, 2013).

Food

47.          Using the dietary value of 0.5 µg/kg bw/day, corresponding to the calculated BMDL01 for neurodevelopmental toxicity from EFSA (2010, updated 2013), the MOEs for women of childbearing age from the highest-lead-containing food groups in the total diet study are given in Table 3.

Table 3. Calculated MOEs for lead in the food groups with the highest measured mean lead concentrations (upper bound) for the total diet in women aged 16 to 49 years of age.

Commodity

Mean lead exposure (µg/kg bw/day)*

MOE for 0.5 µg/kg bw/day

Green vegetables

0.0088

57

Misc. cereals

0.0080

63

Other vegetables

0.0063

79

Total in all food

0.12

4.2

The calculated exposures were compared to the dietary intake value of 0.5 µg/kg b.w. per day which corresponds to the blood BMDL01 of 0.5 µg/kg bw/day for developmental neurotoxicity.

* Average body weight for women of childbearing age used for exposure = 70.3 kg, value provided by the FSA Exposure Assessment Team from years 1 – 11 of the rolling National Diet and Nutrition Survey, NDNS.

Table 4. MOEs for lead in the dietary commodities with the highest measured 97.5th percentile lead concentrations (upper bound) and for the total diet in women aged 16 to 49 years of age.

Commodity

97.5th percentile lead exposure (µg/kg bw/day)*

MOE for 0.5 µg/kg bw/day

Green vegetables

0.034

15

Misc. cereals

0.023

22

Other vegetables

0.019

26

Total in all food

0.23

2.2

The calculated exposures were compared to the dietary intake value of 0.5 µg/kg b.w. per day which corresponds to the blood BMDL01 of 0.5 µg/kg bw/day for developmental neurotoxicity.

*Average body weight for women of childbearing age used for exposure = 70.3 kg, value provided by the FSA Exposure Assessment Team from years 1 – 11 of the rolling National Diet and Nutrition Survey, NDNS.

48.          Neither the mean nor the 97.5th percentile consumption MOEs for the foods with the highest measure of lead, nor for the total amount of lead in food as a whole as reported by the NDNS, has a value of 1 or lower, indicating that any risk of toxicity from lead in food is likely to be small.

Drinking water

49. The MOEs for lead in drinking water are shown in Table 5.

Table 5. MOEs for lead in drinking water using the concentration data provided by the water regulators for England and Wales, Scotland and Northern Ireland and consumption data provided by the FSA Exposure Assessment Team.

Region

97.5th percentile lead exposure (µg/kg bw/day) **

MOE for 0.5 µg/kg bw/day

England and Wales *

 0.00098

 510

Scotland

 0.00021

 2400

Northern Ireland

 0.00050

1000

The calculated exposures were compared to the dietary intake value of 0.5 µg/kg b.w. per day which corresponds to the blood BMDL01 of 0.5 µg/kg bw/day for developmental neurotoxicity MOEs rounded to 2 s.f.

*Using 99th percentile lead concentration.

**Average body weight for women of childbearing age used for exposure = 70.3 kg, value provided by the FSA Exposure Assessment Team from years 1 – 11 of the rolling National Diet and Nutrition Survey, NDNS.

50.          The MOEs for intake of lead from drinking water from the four countries of the United Kingdom are all greater than 10; indicating that there is no appreciable risk of a clinically significant effect on IQ.

Air

51.          The inhaled exposure level would have minimal impact upon total lead exposure. Relative to the BMDL01 corresponding dietary intake value derived by EFSA, a conservative intake from air gives an MOE of 36 for developmental neurotoxicity.

Soil and Dust

52.          The MOEs for exposures from lead in soil are shown in Table 6 and Table 7.

Table 6. MOEs for lead in soil from regions in England using the mean concentrations of lead. Soil lead concentration data are taken from Defra (Ander et al. 2011) and a soil ingestion rate from the Environment Agency (2009).

Region

Mean lead exposure

(µg/kg bw/day) *

MOE for 0.5  µg/kg bw/day 

Rural

0.025

20

Semi-Urban

0.041

12

Urban

0.118

4

The calculated exposures were compared to the dietary intake value of 0.5 µg/kg b.w. per day which corresponds to the blood BMDL01 of 0.5 µg/kg bw/day for developmental neurotoxicity.

* Average body weight for women of childbearing age used for ingestion rate = 70.3 kg, value provided by the FSA Exposure Assessment Team from years 1 – 11 of the rolling National Diet and Nutrition Survey, NDNS.

Table 7. MOEs for lead in soil from regions in England using the highest measured (75th percentile) lead concentrations. Soil lead concentration data taken from Defra (Ander et al. 2011) and a soil ingestion rate from the Environment Agency (2009).

Region

75th Percentile lead exposure (µg/kg bw/day) *

MOE for 0.5  µg/kg bw/day 

Rural

0.033

15

Semi-Urban

0.071

7

Urban

0.229

2

The calculated exposures were compared to the dietary intake value of 0.5 µg/kg bw/day which corresponds to the blood BMDL01 of 0.5 µg/kg bw/day for developmental neurotoxicity.

* Average body weight for women of childbearing age used for ingestion rate = 70.3 kg, value provided by the FSA Exposure Assessment Team from years 1 – 11 of the rolling National Diet and Nutrition Survey, NDNS).

53.          The MOEs for soil ingestion from regions across England are all greater than 1, therefore, any risk of toxicity from lead in soil is likely to be small. Furthermore, the soil ingestion rate could be an overestimate, particularly as it is a combined value for soil and dust. The ingestion rate is also highly uncertain as it is based upon a small and variable evidence base. Consequently, the actual soil ingestion rate and lead exposure through this route could be much lower.

Aggregate Characterisation

54.          A combined exposure assessment, considering exposure to lead from all sources, relative to the BMDL01 of 0.5 µg/kg bw/day, gives a MOE range of 1-2 depending on the individual contribution to the total of each source (food, drinking water, soil/dust). In a scenario where there are high exposures to lead from all sources (food, drinking water, soil/dust) the MOE is 1, conversely, in a scenario where there are average levels of exposure to each source, the MOE is 2.  In all aggregate scenarios, any risk of toxicity from lead is likely to be small.

Conclusions

55.          Lead is a heavy metal pollutant that is ubiquitous in the environment and is thus present in the diet of the general population, including women of childbearing age. Levels have, nonetheless, fallen since the phasing out of lead in petrol, plumbing and paints.

56.          Lead in pregnant women can cause increased blood pressure and may be associated with preeclampsia and premature birth.

57.          Lead accumulates in the body, so adverse effects can occur from long term dietary exposures at levels below those which cause acute toxicity. Neurotoxicity has been identified at lower levels of exposure, and the developing brain appears to be more vulnerable than the mature brain. It has not been possible to demonstrate a threshold level of exposure below which the neurodevelopmental effects of lead do not occur.

58.          EFSA (2010, updated 2013) derived BMDLs for neurodevelopment, renal function and systolic blood pressure and provided values as both µg/ml in blood and the corresponding dietary intake values in µg/kg bw/day. The COT determined that the most relevant endpoint was the BMDL01 for neurodevelopmental toxicity as this value is the most sensitive whilst also being protective of the other endpoints in the mother.  

59.          Exposure of women of childbearing age to lead, in food at the mean and 97.5th percentile of consumption of commodities with the highest concentrations and from soil and dust give MOEs exceeding 1, for effects of developmental neurotoxicity relative to the dietary intake value of 0.5 µg/kg bw/day corresponding to the BMDL01. These MOEs indicate, that any risk of toxicity from lead in food is likely to be small.

60.          There is no appreciable risk of a significant effect on IQ in children following maternal exposure to lead in air in the UK.

61.          The calculated MOEs for soil exposure indicate that in semi-urban and urban areas in the 75th percentile of measured lead levels, there is a low risk to human health, however, this is based upon ingestion rates of high uncertainty.

62.          Toxicity will depend on total exposure to lead from all sources, it is therefore important to consider this to determine an overall likely level of risk.  A circumstance in which there are high levels of exposure to lead from food, drinking water and soil/ dust would result in a MOE of 1.  A circumstance in which there are average levels of exposure to lead from food, drinking water and soil/ dust would result in an MOE of 2.  Therefore, a combined aggregate exposure would be expected to give a MOE range of 1-2 depending on the individual contribution of each source.  These MOE values indicate that an aggregate risk of toxicity from lead in relation to the maternal diet and other potential sources of maternal exposure is likely to be small.

Secretariat

September 2022

Abbreviations

AGA

Adequate for gestational age

ALA

D-aminolaevulinic acid

ALAD

D-aminolaevulinic acid dehydratase

ATSRD

Agency for Toxic Substances and Disease Registry

BMD

Benchmark Dose

BMDL01

Benchmark Dose Lower Limit for 1% change in effect

BPb

Blood lead

CI

Confidence interval

CLEA

Contaminated Land Exposure Assessment 

COT

Committee on Toxicity

DNA

Deoxyribonucleic acid

DWI

Drinking Water Inspectorate

DWQR

Drinking Water Quality Regulator

EFSA

European Food Safety Authority

FSA

Food Standards Agency

IQ

Intelligence Quotient

JECFA

Joint FAO/WHO Committee on Food Additives

kPa

KiloPascals

L

Litre

MDI

Mental development index

mmHg

Millimetres of mercury

MOE

Margin of exposure

NDNS

National diet and nutrition survey

OR

Odds ratio

Pb

Lead

SBP

Systolic blood pressure

SD

Standard deviation

SGA

Small for gestational age

µg

Microgram

Search terms

The references cited in this discussion paper are of publications found in PubMed searches and references therein, using the following search terms:

Pb And       

Maternal health

 

Pb And

Pre-conception

 

Pb And

Conception

 

Pb And

Post-partum

 

Pb And

Toxicity

 

Pb And

Mechanism

 

Pb And

ADME

 

Pb And

Toxicokinetics

 

Pb And

Absorption

 

Pb And

Distribution

 

Pb And

Metabolism

 

Pb And

Excretion

 

Pb And

Biomarker

 

Pb And

Exposure

 

Pb And

Pre-eclampsia

 

Pb And

Pica

Pb And

Abortion

 

Pica And

Pregnancy

 

Soil And

Pregnancy

 

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Appendix 1

Lead exposure from food in women of childbearing age

Table 1. Estimated exposure (in µg/kg bw/day) to lead from foods consumed by women of childbearing age (16-49 years) using data from the total diet study food groups (Bates et al., 2014, 2016; Roberts et al., 2018). 

Food Groups

Mean Exposure to lead LB to UB (µg/kg bw/day)*

97.5th Percentile Exposure to lead LB to UB (µg/kg bw/day) *

Bread

0.0061

0.015

Miscellaneous Cereals

0.0080

0.023

Carcase meat

0-0.0014

0-0.0065

Offal

0.00057

0.011

Meat products

0.0022

0.010

Poultry

0.0015

0.0055

Fish and seafood

0.0015

0.0071

Fats and oils

0-0.00034

0-0.0010

Eggs

0-0.00052

0-0.0025

Sugars and confectionaries

0.0020

0.0081

Green vegetables

0.0088

0.034

Potatoes

0-0.0045

0-0.013

Other vegetables

0.0063

0.019

Canned vegetables

0.0027

0.013

Fresh fruit

0-0.0047

0- 0.018

Fruit products

0.0041

0.024

Non-alcoholic beverages

0-0.039

0-0.091

Milk

0-0.0037

0-0.014

Dairy products

0.0023

0.0087

Nuts and seeds

0-0.00013

0-0.0011

Alcoholic drinks

0.0053

0.037

Meat substitutes

0.00020

0.0027

Snacks

0.00055

0.0025

Desserts

0.00062

0.0039

Condiments

0.0045

0.016

Tap water

0-0.0048

0-0.021

Bottled water

0-0.0013

0-0.0093

Total

0.057-0.12

0.12-0.23

*Values have been rounded to two significant figures. LB=lower bound; UB=upper bound, average body weight for women of childbearing age used for exposure = 70.3 kg, value provided by the FSA Exposure Assessment Team from years 1 – 11 of the rolling National Diet and Nutrition Survey, NDNS.

Lead exposures from water in women of childbearing age

Table 2. Concentration of lead in tap water sampled in the nations of the United Kingdom in 2019 (µg/l).

Region

N

LB mean

LB SD

UB mean

UB SD

England and Wales*

10967

0.38

0.38

2.15

1.9

Scotland

436

0.34

1.2

0.48

1.2

Northern Ireland

122

0.24

0.79

1.1

0.75

*99th percentile concentration.

LB = lower bound: values below the limit of detection assumed to be zero.

UB = upper bound: values below the limit of detection assumed to be the same as the limit of detection.

References

Bates, B.; Lennox, A.; Prentice, A.; Bates, C.; Page, P.; Nicholson, S.; Swan, G. (2014) National Diet and Nutrition Survey Results from Years 1, 2, 3 and 4 (combined) of the Rolling Programme (2008/2009 – 2011/2012) Available at:  Main heading (publishing.service.gov.uk)

Bates, B.; Cox, L.; Nicholson, S.; Page, P.; Prentice, A.; Steer, T.; Swan, G. (2016) National Diet and Nutrition Survey Results from Years 5 and 6 (combined) of the Rolling Programme (2012/2013 – 2013/2014) Available at: Main heading (publishing.service.gov.uk)

Roberts, C.; Steer, T.; Maplethorpe, N.; Cox, L.; Meadows, S.; Page, P.; Nicholson, S.; Swan, G. (2018) National Diet and Nutrition Survey Results from Years 7 and 8 (combined) of the Rolling Programme (2014/2015 – 2015/2016) Available at: National Diet and Nutrition Survey (publishing.service.gov.uk)