Study area

Akwa Ibom state covers a total land mass of 8412 km² of Nigeria with inhabitants more than 5 million in 2016.⁴² It is located in the coastal south-south part of the country, lying between latitudes (4°32′N and 5°33′N) and longitudes (7°25′E and 8°25′E). The state has both wet and dry seasons; the wet season lasts between 8 and 9 months.⁴³ The dry season starts in the last week of November or early December and ends in early March. The state is located within the humid tropics; this attribute and its closeness to sea makes the state generally humid. On the basis of its geographical location, the climate of the state is a tropical rainy type which experiences abundant rainfall with very high temperature. The mean annual temperature of the state lies between 25°C and 29°C, while mean annual rainfall ranges from 2000 to 3000 mm. The highest humidity is observed in July; meanwhile, the minimum happens in January.⁴⁴ Annual evaporation ranges between 1500 and 1800 mm.⁴⁵ As an oil-producing state in Nigeria, the area is experiencing intensive oil-related activities. The climatic conditions in the state permits farming both at the subsistence and commercial levels. Based on the International Union of Soil Sciences World Reference Base (IUSS-WRB) Working Group⁴⁶ classifications of soil profile, the studied abattoir waste–impacted soils are in the Anthrosol (Hortic class). A study by Obasi et al⁴⁷ indicated that the animals supplying meat to the inhabitants of Akwa Ibom state for some years now are as follows: cattle, pig, goat, dog, chicken, and sheep. According to the United States Department of Agriculture⁴⁸ classifications of soil texture, the dominant soil texture in Akwa Ibom state is sandy loam. This study was undertaken in Akwa Ibom state because majority of the inhabitants depend on meat as a major source of protein; thus, a lot of animals have been slaughtered in abattoirs within the state. Consequently, a large volume of waste products has been generated and deposited indiscriminately in the area. Other author previously indicated that these wastes have the potential of elevating the metal load of the receiving environment.^25,49

The studied locations, their coordinates, and some images are shown in Table 1. Figure 1 shows the location of the studied abattoirs in Akwa Ibom state.

Table 1.

Names, coordinates, and pictures of studied abattoir soils and control.

Figure 1.

Map of Akwa Ibom state showing the studied abattoir soils and control plot.

Sampling, pretreatment, and analysis

The top layer (0-15 cm) of the studied soils was selected, and samples were collected from 3 separate points and merged together to form a composite sample for the location.⁵⁰ At each location, 15 subsamples and 5 composite samples were obtained for this study. Samples were collected between December 2015 (dry season) and May 2016 (wet season) to cover the climate of the study area. Surface soil samples were collected within the same period from a garden in Uyo local government as well and used as control. A total of 90 subsamples and 30 composite samples were obtained for this study. Soil samples were air dried for 3 days, ground, and sieved using a 2-mm mesh. One gram of the sieved soil sample was mixed with aqua regia (HCl and HNO₃ in the ratio of 3:1) and digested on a hot plate. The levels of Fe, Pb, Zn, Cu, Cr, and Ni in filtrates obtained from the digestion process were analyzed using an Agilent 710 inductively coupled plasma optical emission spectrometer (ICP-OES). The instrument was standardized following the requirements by ISO 11466 and ISO/IEC 17025.^51-53

Determination of physicochemical properties of soils

pH of studied abattoir soils and control was determined in a 1:2.5 (v/v) soil/water suspension as described by Van-Reeuwijk.⁵⁴ Organic matter (OM) content was determined by wet oxidation methods of Walkley and Black.⁵⁵ Electrical conductivity of the soil samples was determined by the photometric methods described by Rhoades et al.⁵⁶ The cation exchange capacity (CEC) of the studied soils was analyzed using photometric methods by ISO 11260.⁵⁷

Percentage recovery

Percentage recovery for trace metal was computed with equation (1) according to Uduma and Jimoh⁵⁹

(1)

In the equation, n denotes the concentration of a particular metal and the single digestion with strong acids represents the total concentration of a particular metal obtained.

Validation of techniques and results

Montana 1 (SRM 2710a) as a standard reference soil was used for the authentication of analytical techniques and results obtained. The standard reference material was digested using similar procedures applied for the studied abattoir soils. The levels of Fe, Pb, Zn, Cu, Cr, and Ni were obtained in the filtrate using Agilent 710 inductively coupled optical emission spectrometer. The results are presented in Table 2 and are consistent with those in the certified results.

Table 2.

Summary of measured and certified reference trace metal concentrations in Montana soil 1 (SRM 2710a).

Category of pollution of trace metals

These parameters were used to ascertain the actual source, their extent of contamination/pollution, and the pollution status of the studied locations. These pollution indices were also exploited to evaluate the contributions of both natural and anthropogenic factors on the accumulation of trace metals in the studied soils.

Contamination factor of trace metals

Contamination factor (CF) of the trace metals in studied abattoir soils was determined using equation (2) in line with Hakanson⁶¹ and Pekey et al⁶²

(2)

where CF is the contamination factor, Cm is the concentration of the metal in the studied sample, and Bm is the background value which is the average crust value of the metals shown in Table 3. The different classes of CF are shown in Table 4 below.

Table 3.

Mean physicochemical properties of the studied abattoir soils and control.

Table 4.

Different categories of CF, C_deg, $E_r^i$ , and RI as proposed by Hakanson⁶¹ and Yang et al.⁶³.

Degree of contamination

Degree of contamination (C_deg) denotes the summation of all the CFs of trace metals for a particular abattoir soil and was determined using equation (3) as reported by Hakanson⁶¹ and Mmolawa et al⁶⁴

(3)

where Cm represents the level of the metal in the studied sample and Bm is the background concentration of the metal obtained in the study (control); the different classes of C_deg are shown in Table 4.

Ecological risk factor ( $E_r^i$ ) of trace metals

The ecological risk factor of trace metals determined was determined using equation (4) according to Hakanson⁶¹

(4)

T_r is the toxic-response factor for metal and CF is the contamination factor. Toxic-response factors of metals determined are Pb (5.00), Cd (30.00), Ni (5.00), Fe (0.00), Zn (1.00), and Cu (5.00). The different classes of ecological risk factor are shown in Table 4.

Potential ecological risk index

The RI of the different abattoir soils studied was determined using equation (5) as reported by Cao et al⁶⁵ and Yang et al⁶³

(5)

where Σ $E_r^i$ indicates the summation of trace metals determined in dumpsite soils studied. Classifications of ecological risk and RIs are indicated in Table 4.

Anthropogenic fraction

The anthropogenic fraction which indicates the proportion of each metal contributed to the studied soils by human activities was determined using equation (6) by following the methods of Ghaderi et al⁶⁶

(6)

where AF is the anthropogenic portion, F1 represents the acid extractable, F2 means the reducible fraction, F3 is the oxidizable proportion, and TM means the total metal.

Lithogenic fraction

The lithogenic fraction of trace metal signifies the level of each metal contributed by the natural soil-forming process in studied soils was evaluated using equation (7) according to Ghaderi et al⁶⁶

(7)

where LF is the lithogenic fraction and AF is the anthropogenic fraction

Health risk assessment

The following health risk assessment parameters were determined: DI rate, noncarcinogenic risk, and a THI.^67,68

Daily intake of trace metals

The risk associated with human exposure to these metals in studied abattoir soils was examined to evaluate the noncancer toxicity on human beings within the study area. Daily intake was computed using the United States Environmental Protection Agency (USEPA)⁶⁹ and the National Environmental Protection Agency of China (NEPAC; 2013). The DI of soil ingested was validated using equation (8)

(8)

where C is the mean metal concentration, IngR means the ingestion rate (IR), EF denotes the exposure frequency per day per year, ED is the exposure period in a year, BW represents the body weight in kilograms, and AT signifies the average time for noncarcinogens.^69,70 Numerical values for parameters used for the computation of DI are indicated below.

Non carcinogenic risk (hazard quotient)

A noncarcinogenic risk for individual metal expressed as hazard quotient (HQ) was evaluated using equation (10)

(9)

where HQ represents the noncancer hazard quotient and Rfd denotes the chronic reference dose of trace metal. The Rfd mg/kg day for metals determined are Fe (0.07), Pb (0.0035), Zn (0.04), Cu (0.04), Cr (0.001), and Ni (0.02).⁶¹

Total chronic hazard index of trace metals

Total chronic hazard index which is the sum of all the individual HQs was determined using equation (10)

(10)

The risk evaluation of parameters and values applied are ingestion rate (IR) (100 and 50 mg/d for children and adults, respectively^be; exposure rate (d/y) (350 d/y^c); exposure duration (y) (6 years—child^b, 30 years—adult^b); average duration for noncarcinogens (d/y) (365 d/y^d); and body weight (kg) (15 kg—child^ad, 70 kg—adult^d). a, USEPA⁶⁹; b, Grzetic and Ghariani⁷⁰; c, Wang et al⁷¹; d, USEPA⁶⁷; and e, USEPA.⁶⁹

Statistical analysis

Statistical analysis of data obtained in this research was performed using IBM SPSS Statistics 20 (IBM USA). The multivariate analyses, namely, Pearson correlation analysis, factor analysis, and cluster analysis, were performed with Duncan’s multiple range tests at 1% level of probability. Correlation analysis was performed for 10 factors, and the statistical significance was tested at 95% confidence limit. The factor analysis was performed on 10 parameters using the varimax rotation method, and values from 0.560 and above were considered significant. Cluster analysis was done using dendrograms to identify homogeneous groups of variables with common properties.

Analysis of physicochemical properties

The results for physicochemical properties of studied abattoir soils and control are presented in Table 3. pH of the studied abattoir soils varied between 5.74 and 6.69 with a mean of 6.25 ± 0.25. This pH range is lower than 6.22 to 7.44 reported by Chukwu and Anuchi,⁴⁹ consistent with 4.99 to 6.73 obtained by Ubwa et al²⁴ in abattoir soils. The mean pH value obtained in studied soils is above 4.77 reported in the control. Thus, the waste products generated within these abattoirs may have affected the pH of the studied abattoir soils, thereby making the pH of the soils more alkaline than the control. This could be the impact of higher OM and CEC of soils.^72,73

The electrical conductivity (EC) of the soils varied from 30.90 to 70.38 µS/cm with a mean value of 46.61 ± 15.01 (Table 3). This EC range is higher than 2.03 to 2.54 µS/cm obtained by Akan et al⁷⁴ but lower than 60.00 to 110.00 µS/cm reported by Chukwu and Anuchi⁴⁹ in abattoir soils. The results obtained also revealed that EC values obtained in the studied abattoir soils were higher than values in the control site. This is consistent with the results reported for EC in abattoir waste–impacted soils by Onweremadu.⁷⁵ This could be attributed to the low CEC of the control soil and variations in the rate at which OM complexes are formed.^76,77 Hence, the waste products generated in the abattoirs may have influenced the EC of the studied abattoir soils significantly.

Organic matter is an important soil property that may influence metal availability, cation exchange, and complex formation.^78,79 The OM content of the studied abattoir soils varied between 6.3% and 12.4% with a mean value of 8.3 ± 2.44%. The OM range obtained is higher than 0.7% to 7.4% by Yahaya et al²⁶ but lower than 5.6% to 24.1% obtained by Ubwa et al²⁴ in abattoir soils. Generally, OM values of studied abattoir soils were higher than values at the control. This is consistent with the result of OM content between the studied abattoir soils and control obtained by Ojo et al.⁸⁰ This could be due to the low volume of biodegradable wastes at the control site. Hence, the high amounts of biodegradable wastes in the abattoir soils may have affected the organic content of the studied soils considerably.

Cation exchange capacity of the soil has a considerable impact on the accumulation of total metal in soil.⁸¹ The CEC of studied soils ranged from 26.25 to 34.46 cmol/kg with a mean of 29.17 ± 3.28 cmol/kg (Table 3). The CEC range reported is higher than 12.54 to 16.84 cmol/kg obtained by Neboh et al⁶ in abattoir soils. The mean value of CEC obtained in the studied abattoir soils is more than 23.67 cmol/kg reported in control site. This is similar to the findings by Iwegbue et al⁸² in abattoir waste–impacted soils. This may be attributed to the high organic content of the studied abattoir soils. Thus, this study has shown that abattoir wastes have the potential of influencing the CEC of soil considerably.

Distribution of trace metals

The concentrations of trace metals determined in the studied abattoir soils and control are shown in Table 5.

Table 5.

Mean (mg/kg) of total metals in the studied soils and control plot.

Total Fe ranged from 623.88 to 887.80 mg/kg with a mean value of 728.01 ± 92.65 mg/kg. This range is below 2569.00 to 4130.00 mg/kg obtained by Yahaya et al²⁶ but higher than 59.36 to 81.70 mg/kg obtained by Simeon and Friday ³³ in the studied soils. Pb varied between 0.55 and 0.99 mg/kg with a mean value of 0.74 ± 0.20 mg/kg. This is lower than 7.17 to 12.50 mg/kg reported by Chukwu and Anuchi⁴⁹ but higher than 0.18 to 0.83 mg/kg obtained by Ubwa et al²⁴ in abattoir waste–impacted soils. The range and mean value for total Zn is 14.92 to 24.86 mg/kg and 20.61 ± 4.56 mg/kg, respectively. The range of Zn obtained is higher than 1.302 to 5.236 mg/kg reported by Ubwa et al²⁴ but lower than 50.91 to 92.50 mg/kg obtained by Yahaya et al.²⁶ The level of total Cu in studied soils ranged between 15.66 and 19.34 mg/kg with a mean of 17.49 ± 1.40 mg/kg. The range is higher than 0.05 to 1.70 mg/kg reported by Osu and Okereke²⁵ but lower than 36.46 to 40.60 mg/kg obtained by Ojo et al.⁸⁰ The range and mean concentration of total Cr are 15.66 to 19.34 mg/kg and 17.49 ± 1.40 mg/kg, respectively. This range is lower than 4.25 to 5.86 mg/kg reported by Chukwu and Anuchi⁴⁹ but higher than 0.072 to 0.136 mg/kg obtained by Ubwa et al.²⁴ Concentrations of total Ni ranged from 8.80 to 10.39 mg/kg with a mean of 9.59 ± 0.58 mg/kg. Generally, the mean values of all the metals were higher in the studied soils than in the control plot. This could be attributed to the elevated OM and the metals being components of animal feeds.^83-86 Higher levels of these metals have also been confirmed in animal wastes.^87,88 Hence, this study has revealed that abattoir wastes have the potential of elevating the concentrations of metals in the environment.

The mean values of all the metals determined were lower than their recommended limits by FEPA²⁷ for Nigerian soil except Fe. Consequently, Fe could be considered as a pollutant in the studied soils; however, as an important element for both plants and animals including humans, the effect may not be alarming.⁸⁹ Total metals in the studied soils fluctuated from one location to the other, and this could be attributed to the discrepancy in the activities, size, and age of these abattoirs. Total metals in the studied abattoir soils is in the order Fe > Zn > Cu > Ni > Pb > Cr. This is an indication that the studied soils accumulated more of the essential elements than the toxic ones. This may be attributed to the wastes generated from these abattoirs as their feeds have high level of these essential elements.⁹⁰

Sequential extraction of metals, anthropogenic, and lithogenic fractions of metals

The results of sequential extraction of trace metals in the studied abattoir soils and control are shown in Table 6. The results revealed that Fe existed mostly in the residual (inert) fraction both in the studied soils and control. This is in agreement with the findings by Fagbote and Olanipekun⁹¹ and Osakwe.⁹² The residual fraction contributed 34.8% and 58.9% of the several fractions in abattoir soils and control, respectively. The proportions of other fractions of Fe are indicated in Table 6. The high proportion of Fe in the residual fraction is an indication of its low bioavailability. As indicated in Table 6, the human factor (anthropogenic) contributed 61.5% of Fe in the studied soils, while the natural influence supplied 38.8%. However, 61.2% of Fe was contributed by the natural source in the control soil, while anthropogenic factor contributed 38.6%. Accordingly, wastes from abattoirs might have added significant amounts of Fe to the underlying soil as reported by Osu and Okereke.²⁵ The proportion of the different fractions of Fe in both the studied soils and control followed the order RES > RED > OX > AEX.

Table 6.

Mean speciation (mg/kg), percentage composition, % recovery, anthropogenic fraction, and lithogenic fraction of trace metals in the studied abattoir soils.

Pb existed primarily in reducible fraction in studied soils and control. This is consistent with the findings by Ajiboso et al⁹³ and Umoren et al.⁹⁴ The reducible fraction contributed 39.7% and 35.3% of the total fractions in the studied soils and control, respectively. The proportions of acid extractable, reducible, and oxidizable fractions are shown in Table 6. Reports have shown that the existence of metal in residual fraction symbolizes anthropogenic addition of the element to the studied environment.^95,96 This is confirmed by the high 79.3% and 61.9% anthropogenic factors of Pb in the studied soils and control site, respectively. The high anthropogenic factor reported is consistent with findings by Ghaderi et al⁶⁶ in a contaminated environment. The reported high anthropogenic factor of Pb in the control site could be attributed to atmospheric deposition.^97,98 The proportion of the fractions of Pb in the studied soils and control followed the order RED > AEX > OX > RES and RED > AEX = RES > OX, respectively.

Zn existed mainly in the oxidizable fraction in the studied soils; this is similar to the reports by Ajiboso et al⁹³ and Olubunmi and Olorunsola.⁹⁹ Thus, Zn might not be available for plants as it is strongly adsorbed to the OM.^100,101 However, at the control site, the residual fraction contributed 57.2% of the total fractions. This reveals the negative impact of high organic abattoir wastes on the bioavailability of Zn in soil. The anthropogenic factor contributed 76.7% of Zn in the studied soils and 36.7% in the control. However, the natural factor contributed a low 23.3% of Zn in the studied soils, whereas a high 63.3% of Zn at the control site was contributed by the natural factor. The trends for the several fractions of Zn in the studied soils and control site are OX > RED > AEX > RES and RES >> RED > AEX > OX, respectively.

Cu also existed principally in the oxidizable fraction which is in agreement with the results by Svendsen et al¹⁰² and Ebong et al.¹⁰³ This could be the consequence of the high tendency of OM in forming stable complexes with organic substances in soil.^104,105 Nevertheless, Cu existed mostly in the residual fraction in the control site. The oxidizable fraction contributed 39.6% of Cu in the studied soils, while the other fractions contributed a total of 60.4%. However, the residual fraction contributed 54.7% of the total fractions in the control site, while the acid extractable, reducible, and oxidizable fractions contributed 45.3%. The anthropogenic factor contributed 76% of Cu in the studied soils, while the natural factor supplied 24%. However, the anthropogenic influence added 42% of Cu in the control site, while lithogenic factor contributed 58%. The proportion of Cu in the different fractions in the studied soils and control varied as follows: OX > RED > RES > AEX and RES > OX > AEX > RED, respectively.

Cr occurred largely in the inert (residual) fraction in the studied abattoir soils and control (Table 6). This is in agreement with the reports by the literature.^71,106,107 Consequently, a greater portion of the metal is bound to clay minerals and is unavailable for plant uptake in the study area.¹⁰⁸ The residual fraction contributed 36.8% and 60.0% of the total fraction of Cr in the studied abattoir soils and control, respectively. The other fractions contributed 63.2% and 40% of the fraction of Cr in the studied soils and control, respectively. The anthropogenic factor contributed 57.1% and 36.4% of Cr in the studied soils and control, while the natural factor added 42.9% and 63.6% to the studied soils and control, respectively. The trend of Cr in the different fractions in the studied soils is RES > OX > RED > AEX but RES < OX < RED = AEX in the control site.

The results of speciation studies revealed that Ni occurred mainly in the oxidizable fraction in the studied soils. This is in agreement with the report by Łukowski¹⁰⁹ and Osakwe.¹¹⁰ However, most of Ni in the control site was in the residual fraction; hence, the proportion of acid extractable fraction was relatively lower than in the studied soils (Table 6). The results indicated that 78.1% and 37.6% of Ni was contributed by the anthropogenic factor in the studied soils and control. Nevertheless, 21.9% and 62.4% of Ni in the studied soils and control originated from the natural forming processes, respectively. The variations of Ni in the different fractions in the studied soils followed the order OX > RED > AEX > RES. But a different trend was observed for the different fractions in the control site as follows: RES >> RED > AEX > OX.

Generally, the results in Table 6 indicate very high values for the percentage recovery of metals determined. This is an indication of a high level of accuracy in analytical techniques and reliability of results obtained. The result has also shown that waste products from abattoirs could affect the availability and toxicity of metals in soil. Hence, the indiscriminate dumping of abattoir wastes in the environment should be discouraged to avoid the attendants’ consequences along the food chain.

Pollution status of trace metals and the studied abattoir soils

The average crustal values of these elements in Table 3 were used as the background levels for the metals. The results of the CF of metals in the studied soils are shown in Table 7. The CF values of Fe ranged from 1.66 to 2.33; thus, it belongs to the moderate contamination class. The CF of Pb varied between the moderate and considerable contamination classes with a CF range of 2.62 to 4.71. The CF for Zn also varied between the moderate and considerable contamination classes. However; the CF for Cu, Cr, and Ni varied as follows: 1.71 to 2.11, 1.46 to 2.46, and 1.56 to 1.84, respectively. Consequently, Cu, Cr, and Ni belong to the moderate contamination class.

Table 7.

Results for metal contamination and ecological risk indices in soils.

The degree of contamination of studied abattoir soils ranged from 11.59 in Mbak II to 16.12 at Uyo Village Road. The degree of contamination of all the abattoir soils studied except Uyo Village Road belongs to the moderate degree of contamination class. However, the C_deg for Uyo Village Road with a value of 16.12 belongs to the considerable degree of contamination class.⁶¹

The ecological risk factor $(E_r^i)$ for metals determined in soils are indicated in Table 7. Fe as an essential element for all biological systems has not been assigned a toxic-response factor; hence, no ecological risk factor has been assigned to the element. The ecological risk factor for Pb varied from 13.19 to 23.55, thus belongs to the low ecological risk class as indicated in Table 4.⁶³ The ecological risk factor for Zn, Cu, Cr, and Ni ranged as follows: 1.98 to 3.30, 8.55 to 10.55, 2.92 to 4.92, and 7.80 to 9.20, respectively. Consequently, they belong to the low-risk class.⁶³ Nevertheless, the accumulation of these metals in the studied abattoir soils should be monitored due to the toxic and relentless nature of metals.

The results of the RI used to assess the possible risk associated with metals determined in the studied abattoir soils are shown in Table 7.¹¹¹ Table 7 indicates that RI varies from 35.95 in Ntak Inyang to 49.65 in Uyo Village. Consequently, the RIs of the studied abattoir soils were in the low ecological risk class according to Yang et al.⁶³ Generally, the results obtained for the ecological risk index have shown that the level of metals determined has not reached their nuisance level. However, with the incessant dumping of abattoir wastes, serious health problems may be experienced in the studied locations. Hence, proper waste management methods should be adopted by the authority concern.

Multivariate analysis of trace metals

Pearson correlation analysis, principal component analysis (PCA), and hierarchical cluster analysis were employed for the identification of relationships among parameters determined and the factors responsible for their presence in studied abattoir soils.

The interrelationship among trace metals and other properties in the studied abattoir soils was evaluated with correlation analysis. Table 8 indicates that Fe correlated positively and significantly with Pb, EC, OM, and CEC at 99% confidence limit, but with Zn at P < .02. Fe also exhibited a positive relationship with Cr but at P < .05. Fe correlated positively but insignificantly with Cu, Ni, and pH at P < .05. Pb correlated positively and significantly with EC, OM, and CEC at P < .01, but with Zn at 95% confidence limit. Pb showed a very weak positive relationship with Cu, Cr, and Ni but a weak negative one with pH at P < .05. Zn correlated positively and significantly with Cr at 99% confidence limit but with Cu, Ni, and CEC at 98% confidence limit. Zn also correlated positively and significantly with Ni but at P < .05. Zn showed a positive but insignificant associated with pH, EC, and OM at 95% confidence limit. Cu correlated positively and significantly with Cr and Ni at P < .01 but a weak positive relationship with pH, EC, OM, and CEC at P < .05. Cr correlated positively and significantly with Ni at P < .01 but insignificantly with pH, EC, OM, and CEC at 95% confidence limit. Ni showed a positive but insignificant relationship with pH, OM, and CEC but a weak negative correlation with EC at P < .05. This shows the common properties and source among the parameters with significant positive relationships.^112,113

Table 8.

Correlation matrix between metals and physicochemical properties of the studied abattoir soils.

Principal component analysis was used to identify the actual sources of parameters determined in the studied abattoir soils according to Wu and Kuo.¹¹⁴ Table 9 shows 3 key factors with eigen values greater than 1 with a 96.4% of the total variance. Factor one (F1) contributed 57.5% of the total variance with strong positive loadings on Fe, CEC, OM, Zn, EC, Pb, Cr, and Cu (Table 10). This signifies the negative impact of the natural and anthropogenic factors on the soil quality.¹¹⁵ The second factor (F2) contributed 27.1% of the total variance with significant positive loadings on Cr, Ni, and Cu (Table 10). This signifies explicitly the anthropogenic impact of abattoir wastes on the studied soils.¹¹⁶ The third factor (F3) contributed 11.9% of the overall variance with a strong positive loading on soil pH only (Table 10). This signifies the negative impact of organic substances from abattoirs on the soil environment.¹¹⁷

Table 9.

Total variance explained for parameters determined in the studied soils.

Table 10.

Total variance explained.

The pair-wise relationships among parameters determined in the studied abattoir soils are illustrated in Figure 2. Figure 2 indicates 2 main clusters as follows: the one linking Pb, Cr, Ni, Zn, and Cu together and the second one that links Fe alone. Consequently, the presence of abattoir wastes might have impacted significantly on Pb, Cr, Ni, Zn, and Cu concentrations in the studied soils. However, substantial amounts of Fe in the studied soils might have been contributed from a source different from the other metals.

Figure 2.

Hierarchical clusters with the trace metals determined in the studied abattoir soils.

Human health risk appraisal

The effect of metal toxicity on human could be explained by assessing the DI rate of metals in waste-impacted soil. Daily intake rate, HQ, and THI of each metal are presented in Table 11. The results obtained revealed that the DI rate for all the metals in the studied soils was below their recommended oral Rfds by the USEPA.¹¹⁸ The general trend for the DI rate of these metals is Fe > Zn > Cu > Ni > Pb > Cr. Fe recorded the highest DI rate for both the children and adults, whereas the lowest rate was recorded by Cr. This is consistent with the report by Ebong et al¹⁰³ for Fe in Lemna dumpsite soil. The high DI recorded by Fe may not be harmful because the metal is vital for life, but its availability should be monitored to avoid toxicity along food chain.^119,120 Although Cr, Pb, and Ni show low DI rates, it should not be neglected because they are highly hazardous even at a very low concentration and are capable of being transferred into edible plants or leached into groundwater.

Table 11.

Results (×1/10²) for noncarcinogenic risk for each trace metal and exposure pathway.

The results for HQ for the metals determined in the studied abattoir soils are shown in Table 10. The HQ for each of the metal is less than 1; thus, these metals may not be hazardous to both the children and adults. The HQ values for trace metals in children is in the order Fe > Cu > Ni > Pb > Zn > Cr, while for the adults is in the order Fe > Ni > Cu > Pb > Cr > Zn. Accordingly, Fe recorded the highest HQ value for both the children and adults. The lowest HQ values for the children and adults were recorded by Cr and Zn, respectively. Consequently, the potential risk of Fe toxicity is high in both the children and adults, but children were more vulnerable than the adults. Although the THI value is less than 1, there is a tendency of these people being exposed to noncarcinogenic health problems which are directly proportional to the THI value.¹²¹

The THI of oral exposure to abattoir waste–impacted soils by Fe, Pb, Zn, Cu, Cr, and Ni in human is shown in Table 10. The mean THI values of trace metals for the children and adults are 88.347E−2 and 47.991E−2, respectively. The mean THI value for the children was much higher than that for the adults. Consequently, children within the studied locations are more vulnerable to health hazard than the adults. Figures 3A and B indicate that HQ of Fe in children and adults contributed 90% and 89%, respectively, to the total hazard index. The THI values for both the children and adults are less than 1, thus may not result in a serious health risk. Cu, Cr, Ni, Pb, and Zn contributed a total of 10% and 11% to the entire total hazard index for the children and adults, respectively.

Figure 3.

Average hazard quotient for children (A) and adults (B).