Contamination of Heavy Metals (Lead, Zinc, Magnesium and Manganese) Concentrations in Human Eyes ()
1. Introduction
Contamination of the environment refers to the dispersion of chemical substances from localized sources into worldwide distribution in the environment caused by human activities [1]. Lead contamination is widespread in our environment primary due to leaded petroleum and lead—based paint causing practically every adult to have amassed some degree of lead in their system [2]. In industrial settings avoiding lead exposure of pregnant woman, children is particularly crucial [3]. Eye protection such as splash and impact resistant goggles as well as face shields is also necessary [4]. It is advised that contact lenses should not be worn when working with tetraethyl lead. Chronic exposure to metals at high enough level to cause chronic toxicity effects [5], such as hypertension in individuals exposed to lead can also occur in individuals who have no symptoms.
Low level metals exposure contributes much more towards the causation of chronic disease and impaired functioning than previously thought [6]. Essential trace elements such as zinc and copper participate in various enzymatic reactions directly related to the regulation of blood pressure, the toxicological action of several heavy metal ion such as lead can cause hypertension by effecting hormone metabolism [7]. Magnesium may be important in physiological regulation of blood pressure whereas alteration in cellular magnesium metabolism could contribute to the pathogenesis of blood pressure elevation [8]. Nutritional toxicological and genetic research over the past century has led to the recognition of the critical role micronutrients/transition metals such as (Mn, Cu and Zn) play in diverse cellular and molecular events. The characterization of various metal-binding and transport protein revealed their role in intracellular absorption, transition and storage of metals and their role in disease pathology [9].
2. Materials and Methods
2.1. Apparatus
Ashimadzu atomic absorption spectrophotometer model (AA-630-12) was used with an air-acetylene burner (slot dimensions 100 × 0.62 mm). Instrument settings were: lamp current, 10 mA; wave length, 285.2 nm; slit width, 0.2 nm. These conditions were maintained constant throughout the measurements.
2.2. Reagents
Metals stock solutions: add 200 mg of metals to a 100 ml volumetric flask. Dissolve using the minimal quantity of hydrochloric acid. Dilute to volume with deionized water.
Metals working standards: Transfer 0.5 - 5 ml of the stock solution to ten a 100 ml volumetric flask and dilute to volume with deionized water. This gives a concentrations of 10 - 100 μg Metal/ml.
2.3. Preparation of Samples
Each lens was placed into pre weight digestion tube. The sample was weighted to determine a dry weight (gram) after drying at 95˚C overnight [10]. Next day reweighted to determine dry weight (gm), then (1 ml) of concentrated nitric acid was added digest tube which was placed in waterbath at 100˚C, the sample digested for approximately 1 h until all tissues material has been dissolved, then (1 ml) perchloric acid was added until (deep brown color) with clear solution was obtain dilute each sample to mark with deionized water to 10 ml.
2.4. Statistical Analysis
The statistical analysis was carried out using two-way analysis of variance with unbalanced repeated measurements. Statistical significance between individual time points was made by using Revised Least Significant Difference (RLSD) test. The probability level for significance was 5% less.
3. Results and Discussion
As a result of human activities, lead and its compounds can be found in all parts of our environment this includes air and water [9], it is accumulative with age in bones, aorta, kidney and liver. Lead is a general protoplasmic poison that is cumulative, slow acting and subtle and produces a variety of symptoms. Essential trace elements play major roles in many metabolic pathways. There are many factors such as cultural habits, socioeconomic status environmental exposure and diet may have contribution to the trace metals in blood stream of humans and ultimately cause some disease/health impact [11]. Average concentration of lead in flutestripped cigarette is 2.4 μg/g about 6% passing into main steam smoke [12], therefore smoker and former smokers have higher blood lead levels than non-smokers. Cigarettes consumption depress the activity of enzyme 5-aminolevolinic acid dehydratase (most sensitive indicator of the lead burden to the body) in erythrocytes from 117.5 activity units in non-smoker to 88.8 in smokers of less than 20 cigarettes/ day to 74.1 in heavy smokers of more than 20 cigarettes/ day [13].
Zinc is a vital mineral in eye health. A deficiency has been linked to retinal detachment, it is a factor in metabolic functioning of several enzymes in the choriortinal complex (the vascular coating of the eye). It may also protect against light-induced damage and deficiency has been linked to molecular degeneration [14]. Copper and manganese are important for proper healing and for retarding the growth of cataracts [15].
In this study heavy metals (lead, zinc, magnesium and manganese) concentrations in human eyes. Table 1 shows their characters. All the measurements of the eyes sam-
ples subjected to statistical analysis using the independent samples RLSD-test to compare between measurements of the study groups (smoker and none-smoker), sex (males and females), life environment (outskirts and citycentre) and (patients and control) groups.
The statistic results showed that there is a significant difference (p < 0.001) in the metal levels in all the compared males and females eyes measurements as shown in Figure 1, the concentration of the four metals in eyes about 20% excess in females higher than in males. From this finding it would appear that while variation does occur in concentrations of metals in eyes with difference in sex, no definite pattern of distribution is present.
Figure 2 illustrates the variation in the concentration of metals in human eyes as a function of life environments. Statistically significant differences (p < 0.001) were observed between persons living in city centre and others who living in outskirt for concentrations of all three metals. Geographical influences are thought to be the main source of variability. The observed variations are probably a reflection of the varying levels present in foods, that are generally dependent on geochemical environment in which they are living. Environmental contamination can also be a source of metals human eyes. Figure 3 illustrates that there is a statistical relationship between the metals levels in eyes of smoker and nonsmoker groups. The concentration of metals in the smokers persons was about 50% higher than in the non-smoker persons.
Figure 1. Concentrations of metals in human eyes as a function of sexes.
Figure 2. Concentrations of metals in human eyes as a function of life environment.
Figure 3. Concentrations of metals in human eyes as a function of health case.
As shown in Figures 4-6, there was a statistical relationship between the metals levels in human eyes of patients and control groups (p < 0.01). The concentration of metals in patients eyes was about 40% lower than in the control group eyes with exception of lead for all type of disease.
Figure 4. Concentrations of metals in human eyes as a function of health cases.
Figure 5. Concentrations of metals in human eyes as a function of health cases.
Figure 6. Concentrations of metals in human eyes as a function of health cases.
4. Conclusions
Significant relation was observed between samples containing Pb, Mn, Mg and Zn mentally stress subjects.
1) Clinically high lead encephalopathy in smoker with high exposure to lead [16];
2) The neurological disorder known a manganese results from occupational exposure to manganese dust and fumes [17];
3) Significant defer in zinc and magnesium levels in workers suffering from respiratory trouble were significantly high.
Trace/toxic elements play a vital role in human health yet there is obviously a great deal of concern about the obtimum intake and the safe range of each element [18].
5. Acknowledgements
Authors wish to thank Dr. S. Z. Alasadi and Z. A. AlAshoor, Ophthalmologist Department, College of Medicine, University of Basra, for their available co-operating in collection of the samples.