1. Introduction
Geophagy among humans dates to several centuries ago, it is widely practiced in various parts of the world [
1,
2]. It has been reported in several countries in Africa such as Nigeria, South Africa, Kenya, Ghana, Cameroon, etc. [
3,
4,
5]. The first documentation of geophagic practice in Nigeria dates to the 1960s among TIV pregnant women in Benue State [
6,
7]. It is prevalent among the Yoruba, Hausa, and Igbo tribes in Nigeria [
8]. There are several reasons why people from diverse age groups, gender, status, and background practice geophagia. Some of these reasons could be cultural, as people feel it is a blessing from their ancestors and eating it will allow fertility in women [
9]. For religious reasons, people practice geophagia as a form of spiritual ritual [
10]. For example, children suck cakes with Christ impressions around the United States–Mexican border towns [
11]. Often, medical reasons prevail most, either for supplementary mineral nutrients (such as calcium (Ca), iron (Fe), and magnesium (Mg)) [
12] or detoxifying poisonous substances because of the high cationic exchange capacity of the clays [
13]. Women in Africa believe that eating earth material could reduce nausea and vomiting during pregnancy [
14]. Geophagic practice could be passed from parents to children or unintentionally by ingesting earth materials while playing on the ground or floor by hand to mouth movements [
15].
Kaolin minerals dominate the clay minerals in geophagic materials with various concentrations of major and trace elements which have health implications [
16]. Quartz occurring with kaolinite in most geophagic materials could cause dental enamel damage, abrasion of the gastrointestinal tract, and rupturing of the colon [
17]. The red colour of the geophagic soils commonly consumed is usually due to the presence of Fe [
18] which may not be bioavailable [
19]. The genesis and properties of the geophagic material determines its influence on human health. In recent times, health risks associated with trace elements present in several geophagic materials have drawn the attention of medical geologists and environmental health scientists. The impact of trace elements toxicity levels on human health depends on the type of element and its concentration in the material [
5]. For example, higher concentrations of Fe in the human body are known to cause hepatic failure and arthritis [
20,
21], whereas renal dysfunction, nausea, and diarrhea have been linked to excessive copper (Cu), cadmium (Cd), and arsenic (As) [
21]. Toxicity of lead (Pb) means it is harmful for babies in the womb and after birth because it can result in birth defects and brain damage [
8]. In addition, high levels of chromium (Cr) tend to cause kidney failure, dermatitis, and pulmonary cancer [
22,
23].
Previous studies on the health risks associated with the consumption of geophagic materials have only reported the concentrations of trace elements and its health implications relative to global averages and World Health Organisation (WHO) standards [
3,
4,
24,
25]. This approach does not examine potential non-carcinogenic and carcinogenic risks to humans [
26]. However, few studies have assessed the non-carcinogenic and carcinogenic health risks associated with trace elements in geophagic samples [
5,
8,
27,
28] through direct oral ingestion, inhalation, and dermal absorption based on the guidelines put forward by the United States Environmental Protection Agency [
29]. Lar et al. [
8] is one of the few studies on geophagic clay materials in Nigeria that assessed the potential health risks associated with trace elements present in them. They reported high risk to human health particularly pregnant women and children due to the presence of As, Cd, Pb, selenium (Se), and antimony (Sb). Okunlola and Owoyemi [
4] concluded that manganese (Mn), Cr, nickel (Ni), and cobalt (Co) concentrations were higher when compared to global occurrences in some geophagic clays from Southern Nigeria. More studies are required to assess the statuses of several other geophagic materials and report potential health risk associated with human consumption for a healthier populace. Hence, this study aimed at establishing the concentrations of selected trace elements in Cretaceous and Paleogene/Neogene geophagic kaolinitic clays from Eastern Dahomey and Niger Delta Basins, Nigeria as well as estimating the possible associated health risks to humans.
2. Materials and Methods
A total of thirteen (13) geophagic kaolinitic clays comprising of six (6) Cretaceous and seven (7) Paleogene/Neogene were collected from Lakiri and Ubulu-Uku deposits within Eastern Dahomey and Niger Delta Basins, Nigeria, respectively (
Figure 1 and
Figure 2). The dominance of kaolins in the clays have been established through a separate study [
30], hence, the term ‘kaolinitic clays’ is used to define rocks rich in kaolins without particle size connotation [
31].
Fresh samples were collected at 2 m and 1 m intervals from Lakiri (LP) and Ubulu-Uku (UL) deposits within Ise (Abeokuta Group) and Ogwashi-Asaba Formations from outcrop faces dug to 60 cm (
Figure 1 and
Figure 2). Detailed geologic descriptions of the formations have been published earlier by Oyebanjo et al. [
32]. The samples were air-dried and gently pulverised to a finer homogenous grain size prior to analyses. No sieving was carried out to have the samples in the state in which they are consumed [
3].
The trace elemental concentrations of vanadium (V), Cr, zinc (Zn), Cu, Pb, Ni, and Co in the geophagic samples were determined using an Excimer laser with 193 nm resolution attached to an agilent 7700 series inductively coupled plasma mass spectrometer (Agilent Technologies, Santa Clara, CA, USA) at the Central Analytical Facilities (CAF), Stellenbosch University (SU), South Africa (SA). Certified reference Basaltic Hawaiian Volcanic Observatory (BHVO) glass and powder by United States Geological Survey (USGS) were used as standards [
33,
34]. The limit of detection (LOD) and limit of quantification (LOQ) for each element in mg kg
−1 were 0.015 and 0.20, 0.148 and 1.99, 0.011 and 0.23, 0.101 and 1.52, 0.130 and 1.56, 0.004 and 0.06, and 0.008 and 0.11 for V, Cr, Cu, Ni, Zn, Pb, and Co, respectively. The analytical procedures and processing followed those described by Adebayo et al. [
35]. Glitter software [
36], distributed by Access Macquarie Ltd., Macquarie University, New South Wales, was used for data processing. A PANalytical Axios Wavelength Dispersive X-ray Fluorescence Spectrometer (Malvern Panalytical Ltd, Malvern, United Kingdom) at CAF, SU, SA equipped with a 2.4 kW Rhodium tube was used to determine Fe concentrations (detection limit of 0.5 mg kg
−1) in fused glass disks. Theoretical alpha and measured line overlap factors to the raw intensities measured with the SuperQ PANalytical software were used to correct for matrix effects in the samples. The NIM-G (Bushveld Granite from the Council for Mineral Technology, South Africa) and BE-N (Basalt from the International Working Group) were used as standards. The analytical procedures and processing followed those described by Fitton [
37].
Pollution levels and risk evaluation due to the consumption of the geophagic kaolinitic clays were conducted using the index of geoaccumulation (Igeo), hazard index (HI), and carcinogenic risk index (CRI), respectively.
The I
geo developed by Muller [
38] was computed following the formula:
where C
n is the concentration of the trace element, B
n is the background of the element using the upper continental crust (UCC) values [
39], and the factor 1.5 was used to minimise the possible variations in B
n due to lithogenic influence. The I
geo descriptive classes for the contamination level are as follows: uncontaminated (I
geo ≤ 0), uncontaminated to moderate (0 < I
geo ≤ 1), moderate (1 < I
geo ≤ 2), moderate to heavy (2 < I
geo ≤ 3), heavy (3 < I
geo ≤ 4), heavy to extremely (4 < I
geo ≤ 5), and extremely (I
geo > 5) [
38].
The HI and CRI were used to estimate the non-carcinogenic and carcinogenic risks associated with the individual trace elements through direct oral ingestion, inhalation of particulate elements through mouth and nose, and dermal absorption of the elements on exposed skin [
24,
41,
42]. HI is the sum of hazard quotients (HQ) for each of the pathways (ingestion (HQ
ing), inhalation (HQ
inh), and dermal (HQ
derm)) whereas, CRI is the sum of the chronic daily intake (CDI, mg kg
−1 d
−1) for each of the pathways (ingestion (CDI
ing), inhalation (CDI
inh), and dermal (CDI
derm). The CDI, HI, and CRI values for the individual elements through the pathways were computed as follows:
Details of the parameters used in Equations (2)–(6) are presented in
Table 1. HI values < 1 suggest no significant risk of non-carcinogenic effects, whereas HI > 1 suggest potential risk of non-carcinogenic effects [
42,
43]. In addition, CRI values > 1 × 10
−4 is considered unacceptable with potential adverse carcinogenic risk to human health, whereas values between 1 × 10
−6 and 1 × 10
−4 are generally acceptable [
42,
44].
A T-test was used to assess the differences in the trace element concentrations between the Cretaceous and Paleogene/Neogene geophagic kaolinitic clays using IBM Statistical Package for Social Sciences (SPSS) version 25.0.
3. Results and Discussion
The results of trace element concentrations in the geophagic kaolinitic clays are presented in
Table 2. In the Cretaceous geophagic kaolinitic clays, the mean Fe, V, Cr, Co, Ni, Cu, Zn, and Pb were 15,560.22, 149.82, 143.54, 7.92, 62.42, 26.17, 39.91, and 35.16 mg kg
−1, respectively. No unique trace element concentration variations with depth was observed except for LP2 0m having the highest concentrations (except for Pb) (
Figure 3a). Mean values for Fe, V, Cr, Co, Ni, Cu, Zn, and Pb were 90,685.70, 155.08, 113.45, 3.77, 21.68, 43.80, 69.85, and 30.96 mg kg
−1, respectively in the Paleogene/Neogene geophagic kaolinitic clays. Samples from UL2 1m and 3m had higher trace element concentrations relative to others (
Figure 3b).
Based on the trace element concentrations, the order of trace elements in the Cretaceous geophagic kaolinitic clays was Fe > V > Cr > Ni > Zn > Pb > Cu > Co, whereas in the Paleogene/Neogene geophagic kaolinitic clays was Fe > V > Cr > Zn > Cu > Pb > Ni > Co (
Figure 4). Iron is the most abundant element in the geophagic kaolinitic clays which could be attributed to its abundance in the upper continental crust and the presence of hematite, goethite, and anatase minerals in them [
30,
51]. In addition, some of the Fe were present in the structure of the kaolinites [
52,
53].
Comparison between the trace elements in the Cretaceous and Paleogene/Neogene geophagic kaolinitic clays showed that the differences in the concentrations were not statistically significant (
p > 0.05) except for Fe (
Table 3 and
Figure 4). The mean concentrations of V, Cr, Co (except geophagic clays from Asaba, Ibadan, and Free State), Ni (except geophagic clays from Geita), and Cu were higher and Fe (except geophagic clays from Taraba), Zn (except geophagic clays from Ibadan and Benin), and Pb (except geophagic clays from Free State and Geita) were lower in the Cretaceous geophagic kaolinitic clays than those reported for geophagic clays from Asaba, Ekiti, Ibadan, Benin (Nigeria: [
4]), Free State (South Africa: [
49]), and Geita (Tanzania: [
50]) (
Table 2 and
Figure 4). Paleogene/Neogene geophagic kaolinitic clays have a higher average Fe, V, Cr (except geophagic materials from Geita), Cu (except geophagic clays from Geita), Zn (except geophagic clays from Taraba), and a lower average Co, Ni (except geophagic clays from Taraba and Free State), and Pb (except geophagic clays from Free State and Geita) relative to those reported from Asaba, Ekiti, Ibadan, Benin (Nigeria: [
4]), Free State (South Africa: [
49]), and Geita (Tanzania: [
50]) (
Table 2 and
Figure 4).
The elements present in the geophagic kaolinitic clays consumed determine the nutritional value. The recommended dietary intake (RDI) contributions for Cr, Cu, Zn, and Fe are presented in
Table 4 for the various age groups. The average contributions for Cr, Cu, Zn, and Fe were 0.34 and 0.43, 0.13 and 0.08, 0.21 and 0.12, and 272.06 and 46.68 mg/30 g, respectively for Cretaceous and Paleogene/Neogene geophagic kaolinitic clays (
Table 4). The contributions from Cr and Fe were more than the RDI, whereas Cu and Zn were less than the RDI for all the various groups [
54] (
Table 4). This suggests that the consumption of the geophagic kaolinitic clays will not contribute to the nutrient demands for Cu and Zu of the geophagic individual.
3.1. Pollution and Risk Assessment
The average I
geo values (
Table 2) for the individual trace elements in the Cretaceous and Paleogene/Neogene geophagic kaolinitic clays were generally below zero for V, Cr (except for Cretaceous geophagic kaolinitic clays), Co, Ni, Cu, Zn, and Fe (except for Paleogene/Neogene geophagic kaolinitic clays) indicating no contamination. However, the average I
geo values above zero for Fe (except for Cretaceous geophagic kaolinitic clays), Pb, and Cr (except Paleogene/Neogene geophagic kaolinitic clays) for Cretaceous and Paleogene/Neogene geophagic kaolinitic clays, respectively, indicates moderate contamination levels (
Figure 5). The order of the average I
geo values follow Pb > Cr > V > Ni > Cu > Zn > Co > Fe and Fe > Pb > Cu > V > Cr > Ni > Zn > Co for Cretaceous and Paleogene/Neogene geophagic kaolinitic clays, respectively. Apart from the earlier reasons stated for occurrence of Fe in the geophagic kaolinitic clays, the Paleogene/Neogene geophagic kaolinitic clays have higher Fe concentrations relative to the Cretaceous geophagic kaolinitic clays because of the leaching of Fe from the overlying ferricitic layer above the profiles (
Figure 1) [
53,
55]. Lead can occur naturally in kaolinitic clays by inheritance from parent material through weathering, whereas anthropogenic sources for Pb are from mining and industrial activities. Atmospheric Pb deposition from the burning of leaded gasoline is very likely to account for the Pb in the kaolinitic clays [
56].
3.1.1. Non-Carcinogenic Risk
The hazard index (HI) values for the trace elements in the Cretaceous and Paleogene/Neogene geophagic kaolinitic clays through ingestion, inhaling, and dermal contact with children and adults are presented in
Table 5. The HQ through the three pathways did not exceed 1 for children (except HQ ingestion in children) and adults.
This result showed that health risk associated with the consumption of the geophagic kaolinitic clays are higher through ingestion for children. The HQ
ing of Cr and Fe accounted for 56.44% and 26.73%, and 20.99% and 72.30% of total HQ
ing for children exposed to the Cretaceous and Paleogene/Neogene geophagic kaolinitic clays, respectively. From the total non-carcinogenic HI, children are in higher risk relative to adults with HI > 1 as stipulated by USEPA [
57] (
Table 5 and
Figure 6a) when they consume the geophagic kaolinitic clays. This observation is like previous reports from other studies in Australia [
58], Malaysia [
59], South China [
42], and Iran [
26]. The consumption of the Paleogene/Neogene geophagic kaolinitic clays is riskier for the children than Cretaceous geophagic kaolinitic clays (
Figure 6a). This can be attributed to the variations in the physiological parameters between the children and adult population [
42,
47].
The HI values of the trace elements were in the following increasing order: Cr > Fe > Pb > Ni > Cu > Co > Zn and Fe > Cr > Pb > Cu > Ni > Zn > Co for both children and adults consuming the Cretaceous and Paleogene/Neogene geophagic kaolinitic clays, respectively. It is obvious that Cr and Fe are the most hazardous elements that pose non-carcinogenic risk. This is consistent with the previous observation in this study, that Cr and Fe were present in the geophagic kaolinitic clays above the RDI. The utilisable fraction of trace elements by children and adults consuming the geophagic material will be dependent on their bioavailability and absorption in the gastrointestinal tract [
5]. Excessive dosages of Fe can cause vomiting and diarrhea at low overdosage and could eventually lead to systemic toxicity at high overdosage [
54]. The toxicity level of hexavalent chromium (IV) (Cr
6+) is higher relative to trivalent chromium (Cr
3+). In addition, Cr
6+ is believed to become reduced into Cr
3+ in the human body [
26,
60]. Evidence for the carcinogenicity of Cr
3+ in humans is lacking, but it could cause skin rashes [
54].
3.1.2. Carcinogenic Risk
The carcinogenic risk associated with the Cr, Ni, and Pb in the Cretaceous and Paleogene/Neogene geophagic kaolinitic clays are presented in
Table 5. CRI values from ingestion (CRI
ing) and inhalation (CRI
inh) for children and adults in Cretaceous geophagic kaolinitic clays were 7.40 × 10
−5 and 4.49 × 10
−7 and 4.23 × 10
−5 and 5.14 × 10
−7, respectively. In the Paleogene/Neogene geophagic kaolinitic clays, the CRI
ing and CRI
inh were 5.85 × 10
−6 and 3.54 × 10
−7 for children, and 3.35 × 10
−5 and 4.04 × 10
−7 for adults, respectively. The CRI
ing contributed about 99.40% and 98.80% to the total CRI (TCRI) values relative to CRI
inh contributing about 0.6% and 1.19% for children and adults, respectively. The TCRI for children and adults were 7.45 × 10
−5 and 4.28 × 10
−5 for Cretaceous geophagic kaolinitic clays and 5.89 × 10
−5 and 3.39 × 10
−5 for Paleogene/Neogene geophagic kaolinitic clays, respectively. The children have higher TCRI values relative to the adults (
Figure 6b) which further suggests higher susceptibility of children to potential risk associated to the trace elements present in the geophagic kaolinitic clays. Risk level ranges from previous study are as follows: very low (<10
−6), low (10
−6–10
−5), medium (10
−5–10
−4), high (10
−4–10
−3), and very high (>10
−3) [
47,
61]. This suggests low to medium carcinogenic risk to the children and adult health consuming the geophagic kaolinitic clays. However, the TCRI values obtained are within the tolerable CRI, i.e., 10
−6 < CRI < 10
−4 [
43,
48].
4. Conclusions
The potential health risks due to selected trace elements in Cretaceous and Paleogene/Neogene geophagic kaolinitic clays within Eastern Dahomey and Niger Delta Basins, Nigeria have been assessed. The average trace elements concentrations in the Cretaceous and Paleogene/Neogene geophagic kaolinitic clays were 15,560.22 and 90,685.70, 149.82 and 155.08, 143.54 and 113.45, 7.92 and 3.7, 62.42 and 21.68, 26.17 and 43.80, 39.91 and 69.85, 35.16 and 30.96 ppm, for Fe, V, Cr, Co, Ni, Cu, Zn, and Pb, respectively. No significant statistical differences were observed between their concentrations except for Fe. This was attributed to the leaching of Fe down to the underlying Paleogene/Neogene geophagic kaolinitic clays from the overlying ferricretic layer. The average nutritional values for Cu and Zn were lower than RDI, whereas Cr and Fe were higher relative to the RDI in the Cretaceous and Paleogene/Neogene geophagic kaolinitic clays. The contamination levels for the trace elements were generally low except for Cr, Pb, and Fe with moderate contaminations. The Paleogene/Neogene geophagic kaolinitic clays (average HI = 2.21) pose higher non-carcinogenic risk to children relative to the Cretaceous geophagic kaolinitic clays (average HI = 1.10), particularly due to Cr and Fe (through ingestion). The carcinogenic risk to children and adults consuming the geophagic kaolinitic clays is low and generally within the tolerable limit (10−6 < CRI < 10−4). The study therefore recommends the processing of the geophagic kaolinitic clays by reducing the trace elements to acceptable levels prior to ingestion to minimise the potential human health risk particularly to children.