Health risk implications of iron in wastewater soil-food crops grown in the vicinity of peri urban areas of the District Sargodha.

Irrigation using sewage water can be beneficial, as it can increase the productivity of crops but has negative consequences on crops, soil contamination, and human health. It contains a variety of toxins, such as chemicals and heavy metals, which damage the soil and crops. In this regard, the aim of the research was to assess the potential health hazards of iron (Fe) metal in food crops (leafy and root crops) treated with wastewater (T_1), canal water (T_2), and tube well water (T_3). Water, soil, and edible components of food crops were collected at random from three distinct locations. Fe concentration in samples was estimated using atomic absorption spectrophotometer, following wet digestion method. The Fe concentrations, ranged from 0.408 to 1.03 mg/l in water, 31.55 to 187.47 mgkg-1 in soil and 4.09 to 32.583 mgkg-1 in crop samples; which were within permissible limits of the World Health Organization (WHO). There was a positive correlation between soils and crops. The bioconcentration factor, enrichment factor (EF), daily intake of metals (DIM), health risk index (HRI), and target hazard quotient (THQ) all values were <1, except for a pollution load index >1, which indicated soil contamination, but there was no Fe toxicity in crops, no health risk, and no-carcinogenic risk for these food crops in humans. To prevent the excessive accumulation of Fe metal in the food chain, regular monitoring is needed.

Assessing the health risk of cadmium to the local population through consumption of contaminated vegetables grown in municipal solid waste-amended soil.

Pollution caused by municipal solid waste (MSW) is becoming a serious threat to the environment. Composting may be an effective way to speed up the decomposition of biodegradable components in MSW, resulting in compost that can be utilized as an organic fertilizer. The pot experiments were carried out with different soil-MSW mixtures (100:0, 75:25, 50:50, and 25:75; w/w) to determine the impact of MSW on the bioconcentration of Cd in commonly consumed plants of Sargodha. The possible health risks were evaluated by applying pollution indices, such as the pollution load index, bioconcentration factor, enrichment factor, and health risk index. The pollution load index was higher than 1 in 75% MSW-amended soil. However, the concentration of Cd was found to be below the permissible limits in all studied vegetables, with a range of 0.019-0.106 mg/kg. In the study, serum samples from different volunteers living in four sites in Sargodha were also collected and analyzed. For vegetable crops, the health risk index (HRI) was less than one. It is concluded that the concentration of Cd was increased by increasing the fraction of MSW. Although the metal contents in the soil treated with MSW were not high enough to categorize the soil as polluted, these findings show that the reuse of MSW can serve as an alternative to mineral fertilizers. However, the presence of Cd in MSW can have a direct impact on soil fertility and, if biomagnified, on crop production and human health.

Evaluation of nickel toxicity in wheat as function of diverse type of fertilizers: implications for public health.

Many studies have described the physiological, biochemical, and molecular responses to heavy metal toxicity and deficiencies individually in plants. The present study assess nickel (Ni) concentration in amended soil, plant vegetative parts, and wheat grains, grown under diverse types of fertilizers in Sargodha, Punjab, Pakistan. Different varieties of wheat were grown in pot and fields. Different treatments (municipal solid waste, poultry waste, press mud, farm yard manure) of fertilizers were applied in order to study the metal level increased in different parts (root, shoot, grain) of wheat due to fertilization. Results indicated that metal level was found highest in roots followed by shoot and grain. The highest level of nickel in root was present in V1 (2.35 mg/kg) due to T2 (2.60 mg/kg) treatment. Higher nickel levels in wheat shoot and grains were observed in V5 (2.36 mg/kg) and V8 (2.29 mg/kg), respectively, due to applied treatment T2 (2.57 mg/kg). This study concluded that treatment T9 was proven safe in view of the observed Ni concentration, while treatment T2 (municipal solid waste) resulted in higher accumulation of nickel in wheat grains which showed that municipal solid waste should be treated before their application in agriculture fields to secure the public health. This study recommended that although application of fertilizers increased the plant growth and nutritional value, it also enhanced metal accumulation in the wheat grains which could be harmful for consumers especially human being. Government should take actions to prevent metal toxicity in human food chain.

Appraisal of iron accumulation in soil, forages, and blood plasma of sheep and goats: a case study in different districts of Punjab, Pakistan.

Minerals are essential for ruminants affecting significantly the production of grazing livestock. Iron level in forages, soil, and blood plasma of the small ruminants (goat and sheep) was investigated in three districts of Punjab. Atomic absorption spectrophotometer was used to determine the concentration of iron in collected samples. The results revealed that the mean Fe concentrations in soil of districts Sargodha, Mianwali, and Bhakhar were significantly varied and ranged from 21.85 to 23.78, 28.45 to 31.2, and 18.079 to 24.33 mg/kg, respectively. The Fe level in soil of Mianwali significantly varied and was higher than Sargodha and Bhakkar. The mean Fe concentration in forages which were used for feeding purpose were significantly varied and found between 10.95-14.49, 23.63-25.65, and 6.616-9.45 mg/kg for Sargodha, Mianwali, and Bhakhar, respectively. The mean Fe concentrations in blood plasma of goat which consumed the contaminated forages were 8.5026-11.763 mg/L in district Sargodha, 19.77-20.19 mg/L in Mianwali, and 5.508-5.858mg/L in Bhakkar. In blood plasma of sheep, the residual levels of Fe in districts Sargodha, Mianwali, and Bhakhar were ranged from 9.987 to 12.455, 15.8 to 19.785, and 3.425 to 6.383 mg/L, respectively. This study provides the data of metals effected by different sites and also their mobility from low to higher trophic level which enables us to study the iron toxicity in different trophic levels, and we recommend different safe limits and treatment in case of low and high metal profile.

Bioaccumulation of cadmium in different genotypes of wheat crops irrigated with different sources of water in agricultural regions.

The study was carried out to evaluate the health risks associated with accumulation of cadmium in the different genotypes of wheat, grown in agricultural regions of Punjab, Pakistan. Five genotypes irrigated with three varied water sources were selected randomly from each region. Among all sources of water, types of soil, and grain samples, the cadmium (Cd) quantities were found (2.24-2.82 mg/L, 1.75-4.16 mg/kg, 0.86-1.90, respectively), exceeding the maximum permissible limits (0.01 mg/L, 1.1 mg/kg, 0.2 mg/kg, respectively) described by FAO/WHO. The pollution load index (PLI) exhibited by all of the samples was higher than 1.00, the permissible limit; however, other factors including bioaccumulation, translocation, bio-concentration, daily intake, and enrichment values of Cd were less than 1.00. Moreover, the health risk index for cadmium in all types of wheat grain samples was less than 1.00. The study concluded that the continuous use of wastewater resources may lead to the accumulation of cadmium in the vital body organs that may cause severe health hazards.

Level and speciation of nickel in some forages in relation to spatial and temporal fluctuations.

The present experimental work was conducted at different sites of district Bhakkar, a semiarid region of Pakistan, to assess whether the goats are suffering nickel deficiency or toxicity and what are the possible seasonal effects on the availability and translocation of nickel in food chain. A total of 27 forage and 320 goats according to four physiological stages [does (she goat), bucks (he goat), wether (castrated), juvenile (6 month)] were recruited for this study. To fulfill this objective, soil, forage, blood plasma, urine, and feces samples were collected in 4 seasons of the year at 2 sites and were analyzed by atomic absorption spectrophotometer for nickel concentration. Different indices BCF, EF, and PLI were also studied to check the metal transfer. The results showed that sites had significant (P < 0.05) effect on nickel concentration in soil, forage, and goats. On the other hand, season and site x season had nonsignificant (P > 0.05) effects on nickel level in soil and goats. The soil (0.68-0.71 mg kg-1), forage (3.41-3.70 mg/kg), and blood (0.21-0.28 mg/l) level was lower than the permissible limits, while feces (0.57-1.34 mg/kg) and urine (0.35-1.32 mg/l) had enough concentration of nickel. Sources showed significant (P < 0.05) effects on Ni level in all stages of goats. All stages of goats except Wether (castrated) showed low level of nickel in blood. Most fluctuations in nickel concentration were observed in (S1) summer (low) and spring (S4) (high) season as a whole, while overall site 2 had high level of nickel than site 1. Thus, nickel showed deficiency in soil, forage, as well as in all stages of goats except wether goats. Nickel containing mineral mixtures are essential for does (she goat), bucks (he goat), and juveniles (6 months old), so application of Ni containing fertilizers to the soil and forage of that region and supplementation of Ni mineral mixture for grazing ruminants should be done.

Comprehensive study based on mtDNA signature (nad1) providing insights on Echinococcus granulosus s.s. genotypes from Pakistan and potential role of buffalo-dog cycle.

Pakistan has long been considered neglected endemic region for Echinococcus granulosus. Limited surveillance studies have failed to epidemiologically draw complete picture on geographical presence and etiological agents of cystic echinococcosis. Amidst such lacunae, current study explored main transmission routes of this disease through molecular characterization of hydatid cyst isolates obtained from sheep (n = 35), goats (n = 26), cattle (n = 30) and buffalo (n = 30) from the four provinces of Pakistan. Two strains of E. granulosus sensu stricto, G1/G3, and their haplotypes were observed to be cycling in sympatry in the domestic ungulate populations. G3 genotype had higher prevalence (66.94%) in the hosts compared to G1 genotype (33.06%) which was not surprising, considering the large buffalo population in Pakistan. Haplotypic analysis revealed presence of 9 different haplotypes configured in a double clustered network with two centrally positioned haplotypes referred to as G3 (PKH1) and G1 (PKH6). Population demographics and genetic variability indices suggested expanding parasitic population in multiple host spectrum. Elucidating local transmission patterns of E. granulosus sensu stricto, buffalo-dog cycle emerged as one of the dominant causes of G3 dispersal in contrary to other global studies. Adaptability of G3 to environmental conditions of Pakistan and high affinity for buffaloes emphasize on heterogeneous nature of this strain in contrast to G1. However, more studies involving larger datasets and mitochondrial sequences could confirm this hypothetically formulated inference.

Health risk assessment through determining bioaccumulation of iron in forages grown in soil irrigated with city effluent.

The irrigation with sewage water can be useful if it has no negative effects on food crop yield, soil pollution, and health of humans. However, it includes various types of contaminants like heavy metals that pollute the soil and crops. In this regard, the aim of this study was to evaluate the possible health risks of heavy metals in forages. Forages both of summer and winter were grown with different water treatments (sewage water and tap water) in Department of Botany, University of Sargodha. The concentration of iron (Fe) in water, soil, and plant samples was determined. The Fe values in tap and sewage water were observed as 0.090 and 0.115 mg/L, respectively. The highest mean concentration of Fe was 9.608 mg/kg in the soil where Trifolium alexandrinum is grown, and the lowest mean concentration was 0.154 mg/kg which occurred in the soil where Trifolium resupinatum is grown in winter. The maximum mean concentration of Fe in the root samples of plants was observed as 2.483 mg/kg in Pennisetum typhoideum, and the minimum mean concentration occurred as 0.390 mg/kg in Zea mays grown in summer. The maximum bioconcentration factor value of Fe was observed for T. resupinatum (5.259) grown in winter. The maximum pollution load index value of Fe was observed for T. alexandrinum (0.1688). The maximum value of daily intake of metals was observed as 0.0731 in Medicago sativa, and the maximum health risk index value was determined as 0.1091 in P. typhoideum.

A study on the transfer of iron in soil-plant-animal continuum under semi-arid environmental conditions in Sargodha, Pakistan.

The present investigation on the iron (Fe) transfer from soil to plant and in turn to animal (cows), as a function of sampling periods was conducted at the Livestock Experimental Station Sargodha, Pakistan which falls under semi-arid conditions. Although the iron transfer from soil to forage increased consistently, the forage Fe content decreased progressively with increase in sampling period. Highest Fe transfer from forage to cow blood plasma was observed during October and lowest during January. The transfer of Fe from forage to animal milk was maximum during the months of October and January and minimum during December. The transfer of Fe to plasma and milk was found to be dependent variably on the growth stage of forage in this investigation. Based on the findings of the present study, it is evident that mineral supplementation with higher Fe availability is urgently warranted to the animals particularly during the months of December and January to enhance plasma Fe in the cows being reared at that livestock farm during the entire grazing period. Thus, obligatory supplementation of Fe to the ruminants is highly recommended. Since the processes involved in iron management system in humans, animals, and plants are basically similar, appropriate elemental management must be provided to the living organisms, otherwise deficient or excessive levels of iron may deteriorate the developing cells of the organisms.

A study on the transfer of cadmium from soil to pasture under semi-arid conditions in Sargodha, Pakistan.

The study was conducted on the cadmium (Cd) transfer from soil to pasture at Khizerabad Livestock Farm, District Sargodha (falling under semi-arid conditions), Pakistan. The concentrations of Cd in the soil and forage ranged from 2.80 to 6.74 mg/kg and 1.14 to 4.20 mg/kg, respectively, in different sampling periods. The higher values of Cd in pasture suggested the possible risk of entering Cd into higher food chain as these concentrations of Cd can potentially be transported from soil to different animals rearing on the farm pastures, and they should be taken into account in risk assessment of chemical toxicity. Providing region-specific mineral mixture having highly bioavailable forms of other trace elements to the ruminants like Zn, Fe, and Mn, which are known to antagonize Cd, would help in overcoming the Cd toxicity. There is an urgent need of permanent monitoring of cadmium content in the feed used in animal nutrition at livestock farm.