Subsequent sections elaborate and discuss the results and the potential health implications of recorded concentrations of metals. Data presented below are helpful in determining research directions, creating strategies in soil remediation, soil quality monitoring programs for vegetable quality monitoring, creation of in situ detection tools for metals specific for vegetables and crops, and among other related techniques helpful for reducing health risks.
3.1. Concentration of Metals in Soil
The soil samples recorded concentrations of Cr (854–2465.86), Cu (1711.27–17,712.23), Fe (759,560.17–1,083,607.03), Mn (25,596.87–60,549.73), Ni (536.43–3216.47), Pb (393.27–1291.13), and Zn (2291.37–6160.83) mg kg
−1. All the metal concentrations in the soil, except for Cd, from the six municipalities exceeded the soil quality standards (SQS). There are very limited related studies in the area; however, results are comparable to the work of Marges et al. [
7], Senoro et al. [
69], and Sanchez et al. [
70]. The work of Marges et al. and Sanchez et al. in 2009 and 2015 at the Calancan Bay of Marinduque published in March 2011 and January 2018, respectively, showed no recorded Cd concentration in soil. The non-detection of Cd in soil in this study has been attributed to the soil acidity and uptake of some plants [
71]. The study of Usman [
71] specifically mentioned that plants remediate Cd by phytoextraction and it accumulates in the shoot. Phytoremediation activities in Marinduque were recorded during the period of 2006–2017 [
25,
26,
27,
28,
29,
30]. Other studies in Vietnam [
72], Malaysia [
73], and Indonesia [
74] where there were mining activities recorded an elevated concentration of Cr in soil with no record of Cd concentration.
It shows that Fe and Mn had the highest concentration of metals in soil across the six municipalities. The high concentration of Fe in the soil can be attributed to the mine tailings from the previous milling of sulfide ores, i.e., copper and zinc, which may have high levels of pyrite (iron sulfide) [
75,
76]. Likewise, continuous subsurface flow of metals within the island are associated to the two abandoned open mine pits that are located at the higher elevation of the island province [
3]. Metal concentration varies spatially as illustrated in
Appendix A.
Table 2 shows the mean concentrations of metals in the soil samples highlighting the SQS [
45,
77]. The trend of metal concentrations across the island province is shown in
Table 3.
3.2. Evaluation of Metal Pollution in Soil
In order to obtain the status of soil pollution from each municipality, the values of
and
were calculated using the Nemerow pollution index (NPI). The NPI illustrates the degree of probable pollution a metal contributes, and/or how several metals probably pollute a target environmental medium. As illustrated in
Figure 2, all mean
values of soil from each municipality were greater than five except for Cd which was not detected. This implies that the soil from all municipalities belongs to Class V with severe pollution level (
Table 1) and is quite alarming [
78]. Heavy metal pollution of soil is a serious environmental hazard, particularly in locations where soils intended for agricultural practices are adjacent to sources of pollution such as mining [
44].
As illustrated in
Figure 3a, the
values in all soil from each municipality ranged from 61.35 to 1055.83, which are greater than three indicating that all soil samples were under Class V with severe pollution level (
Table 1). The
of soil in all municipalities had the following order: BV > S > M > T > G > B. In
Figure 3b, the higher pERI was found in the soil of Boac and Mogpog in comparison with Buenavista, Gasan, Sta. Cruz, and Torrijos. More specifically, in Mogpog, the single ecological risk index (
) of Cu was greater than 1200, (
= 1968.03), indicating a higher contribution of Cu to RI. The RI of soil in Boac, Buenavista, and Mogpog exceeded 1200; hence, there is very high pollution risk. On the other hand, the RIs of Gasan, Sta. Cruz, and Torrijos were between 600 and 1200 indicating a high pollution risk too. The high pollution risk of the soil due to metal pollution can adversely impact plant growth [
79], microbial diversity [
80], biota [
81], and humans whose exposure includes incidental ingestion, inhalation, and dermal contact [
82].
3.3. Concentration of Metals in Vegetables
Firstly, it must be emphasized that metals such as Fe and Zn are essential micronutrients for human health and other living organisms. The degree of concentrations of metals in vegetables presented below are useful in making strategies, epidemiological studies, further research on edible agricultural yields, and creating more tools for vegetable quality monitoring to protect human health. It will also aid comprehensive soil and vegetable quality monitoring.
The mean concentrations (mg kg
−1) of metals in the vegetable samples collected from Marinduque are shown in
Figure 4a–h with a red horizontal line representing the maximum permissible limits (MPL) set by World Health Organization, Food and Agriculture Organization and International Food Standards [
82]. Metal concentrations in vegetables are represented by Y-coordinates and illustrated by vertical bars. The MPL (mg kg
−1) for Cd, Cr, Cu, Fe, Mn, Ni, Pb and Zn concentrations illustrated in
Figure 4a–h are 0.1, 2.3, 40, 425, 11, 10, 0.2 and 50, respectively [
63,
67,
82,
83,
84,
85]. The string bean samples had concentrations (mg kg
−1) of Cd (0.004–4.581), Cr (0.0005–6.968), Cu (48.34–68.50), Fe (48.40–68.58), Mn (16.72–35.75), Ni (0.001–13.978), Pb (0.012–5.986), and Zn (155.98–275.50). Metal concentrations in sweet potato tops ranged from 0.004 to 4.531 Cd, 0.0005–9.323 Cr, 11.13–24.99 Cu, 70.84–625.35 Fe, 28.21–52.84 Mn, 0.001–11.022 Ni, 0.012–6.581 Pb, and 107.73–157.99 Zn. The bitter melon samples had concentrations of Cd (0.004–4.541), Cr (0.0005–6.9625), Cu (7.95–16.44), Fe (37.70–47.76), Mn (11.26–37.54), Ni (0.001–7.811), Pb (0.01–5.74), and Zn (138.54–190.24). Metal concentrations in eggplant range from 0.004 to 4.675 Cd, 0.0005–6.9128 Cr, 10.433–17.822 Cu, 3.20–39.57 Fe, 1.86–23.94 Mn, 0.001–6.494 Ni, 0.012–6.533 Pb, and 0.001–157.630 Zn. It was recorded that Zn concentration in all types of vegetables across the island province exceeded the MPL except for the eggplant collected from Boac. The Fe in sweet potato tops collected from Gasan municipality exceeded the MPL. Additionally, the concentration of Mn in all types of vegetables, except for the eggplant collected from Mogpog, exceeded the MPL. Likewise, Cd and Cr concentrations in most types of vegetables from Buenavista and Gasan exceeded the MPL. It was also recorded that concentration of Pb in most types of vegetables from Buenavista, Gasan, and Sta. Cruz exceeded the MPL. Only the string beans from Buenavista and Gasan and the sweet potato tops from Gasan exceeded the MPL for Ni. The spatial distribution map of metal concentrations in soil and vegetables is illustrated in
Appendix A to further visualize the potential distribution of metal concentrations across the island province.
It is useful to note that the leafy vegetable (sweet potato tops) had accumulated the highest metal concentrations. Similar findings have been reported by Luo et al. [
86], indicating that leafy vegetables accumulate metals more than non-leafy vegetables. The distribution trend of metal concentration in vegetables is shown in
Table 4. It shows that Zn had the highest concentration, among target metals in all vegetables across the six municipalities.
3.4. Potential Human Health Risk of Metals by Ingestion
The EDI of metals through consumption/oral intake of vegetables by the population in Marinduque is presented in
Table 5. The eggplant contributed most to the population EDI given that it has the highest
among the vegetables tested. It was followed by sweet potato tops then string beans and lastly bitter melon as illustrated in
Figure 5. The metals of concern in vegetables were Cd, Cr, Fe, Mn, Pb, Zn, and Cu. The EDI of individual metals as a result of vegetable consumption was in the order of Zn > Fe > Mn > Cu > Ni > Cr > Pb > Cd. Bar plots are illustrated in
Figure 5 and
Figure 6 to visualize the concentration of metals in each vegetable type and the potential contribution of specific vegetables to the HHI of each municipality.
The TCR associated with exposure to heavy metals such as Cr, Cd, Ni, and Pb from vegetable consumption was calculated using EDI data (
Table 5), CSF [
63,
78,
79], and TCR data shown in
Table 6.
The computed EDI ranges for various vegetables were – Cd, – Cr, – Fe, – Mn, – Ni, – Pb, – Zn, and – Cu.
The THQ and HHI values were used to interpret the metals’ possible health hazards. The computed potential HHI of metals present in vegetables is shown in
Table 7 which evaluated the cumulative effect of ingesting a variety of potentially harmful metals from several vegetables [
63]. Ingestion of the vegetable samples recorded to have THQ values ranged from
to
Cd,
–
Cr,
–
Fe,
–
Mn,
–
Ni,
–
Pb,
–
Zn, and
–
Cu. All of the HHI values were less than 1, hence, there is a potential low non-carcinogenic human health risk to the human population from vegetable consumption [
87]. Further, it was found that the highest HHI values in vegetables were in Buenavista and Gasan. It is being emphasized that THQ and HHI were significantly affected by the EDI and R
fD values. These values are estimated values with uncertainty.
It can be seen from
Table 6 that the TCR of Ni due to vegetable consumption in Buenavista (
), Gasan (
), and Sta. Cruz (
) exceeded the maximum threshold value of
[
66,
67,
83,
84]. This indicates potential risk of developing cancer if the population has a daily intake of vegetables shown in
Table 5. The corresponding TCR of Cr in Buenavista (
) and Gasan (
) is also higher than the maximum threshold value. It was observed that ingestion of Cr and Ni in vegetables may pose a cancer risk to the population of Marinduque. This recorded result is similar to the findings of Gebeyehu et al. [
63]. Chronic exposure to high amounts of Cr causes malignancies of the gastrointestinal tract, respiratory and central nervous systems [
74,
76]. However, it is considered that the ingested dose of vegetable with elevated concentration of metals is not always equal to the absorbed metal concentration dose as a fraction could potentially be excreted from the body [
88]. Hence, regular excretion is important. Additionally, it is noted that the TCR was based on EDI shown in
Table 5, CSF, body weight, and 365 days a year of exposure frequency. Therefore, these variables significantly affect the potential to acquire carcinogens and the likelihood of cancer risk during a lifetime exposure. These elevated metal concentrations in the vegetables that posed HHR to the population were associated to the existence of two abandoned open mine pits which are located at the higher elevation of Marinduque [
69]. Groundwater flow [
21] through porous media, and runoff overflow in the island province potentially caused the elevated concentration of metals in soil that the vegetables may have absorbed from the soil. Given the above information, it is advised to exercise a 75% temporary consumption reduction of bitter melon, eggplant, string beans, and sweet potato tops produced in the municipalities of Buenavista and Gasan. This is to avoid Cr and Ni TCR. Therefore, the proposed monthly average consumption of bitter melon, eggplant, string beans, and sweet potato tops is 6.9, 7.8, 7.4, and 14 g person
−1, respectively. This is to reduce exposure and the probability of cancer occurrence by vegetable ingestion. The TCR at 75% reduction is shown in
Table 7. The TCR of Ni in Buenavista and Gasan still exceeds the threshold value despite a 75% consumption reduction. Hence, a comprehensive study covering quality of other vegetables produced in the island will be helpful to identify the location and types of vegetables that must be consumed by the public without posing TCR.
Based on the calculated TCR estimation, a 75% reduction of vegetable consumption would leave Ni alone as concern in the municipalities of Buenavista and Gasan. The TCR of Ni in Buenavista and Gasan at 75% reduction of vegetables consumption is 1.52 × 10
−4 and 2.13 × 10
−4, respectively. The recommended 75% consumption reduction is temporary as mentioned above. This recommendation, apart from being temporary, is only for bitter melon, eggplant, string beans, and sweet potato tops produced specifically from the municipalities of Buenavista and Gasan. Hence, the effects of the 75% reduction (referred above) do not violate the “food security (FS)” goal defined by the United Nations’ Committee on World Food Security. The FS definition states that “all people, at all times, have physical social, and economic access to sufficient, safe, and nutritious food that meets their food preferences and dietary needs for an active and healthy life.” The vegetables produced by the above-mentioned municipalities were not safe based on the detected metal concentrations that were beyond the maximum permissible limit [
62,
66,
82,
83,
84].
3.5. Relationships of Metals in Soil and Vegetables
Pearson correlation analysis was carried out to determine the degree of interrelation and association of the metals in soil and vegetables [
89]. As shown in
Table 8, the correlation coefficients of Ni-Cr, Zn-Pb, and Cu-Zn were 0.917, 0.940, and 0.921 (
p < 0.01), respectively. The value of (
p < 0.01) expresses statistical significance of the relationship and association of metals in soil and vegetables.
HCA was further used to determine the affinity and behavior of metal in the soil across the province.
Figure 7 shows the dendrogram results generated by HCA for metals. The following two primary clusters were identified: (1) Cr-Ni-Cd-Pb-Zn-Cu-Mn and (2) Fe. It produced results that were similar to those of the Pearson correlation analysis.
As shown in
Table 9, the correlation coefficients of Cr-Cd, Mn-Fe, Ni-Fe, Ni-Mn, Pb-Cd, and Pb-Cr were 0.986, 0.629, 0.605, 0.852, 0.977, and 0.977 (
p < 0.01), respectively. These positive significant correlations between these various metals in soil and vegetables demonstrated that they commonly interact, cooperate with each other to promote potential uptake of vegetables from soil, and are a common source of pollution [
41,
74,
75].
Furthermore, spatial correlation technique was employed to analyze further the relationship of metal concentrations in vegetables that were collected in proximity to where the soil samples originated.
Table 10 elaborates the generated Moran’s Index that measures the spatial autocorrelation of soil and vegetables. This table illustrates that the concentration of Cr, Ni, Pb, and Zn in the soil is spatially correlated with concentration in vegetables. In addition, though Cd was not detected in soil, the Cd concentration in vegetables shows that it is spatially correlated to nearby environmental media having a Moran’s I and
p-value of 0.668301 and 0.004269, respectively. This is attributed to the groundwater [
21,
65] and runoff quality [
65].