Inhalation Bioaccessibility of Potentially Toxic Metals in Tobacco Snuff and Related Exposure Risks ()
1. Introduction
Globally, tobacco smoking, inhalation and sniffing have been reported to be the leading cause of many preventable diseases especially those affecting the heart, liver, lungs, many cancers and premature death over the course of the 20th century. C. A. Viegas [1] reported that there are different forms of tobacco in use based on their mode of ingestion: smoke (cigars and pipes) or smokeless tobacco (snuff). In Nigeria, tobacco snuff is the ground form of tobacco leaves, mixed with potash [2] [3] [4] [5].
Amidst the medicinal properties of tobacco which include anthelmintic [6], anti-nociceptive [7], haematological [8], Antibacterial [9] [10] and several negative effects associated with the consumption of tobacco-based products has been highlighted such as Coronary thrombosis [11], Infertility [12] and Cancer [13] [14] [15].
Tobacco has also been useful as pesticides [16] [17]. The plant has characteristics of being able to absorb and accumulate metals from the soil environment [18] [19]. However, Golia et al. [20] reported that the extent of the absorption and accumulation of these metals from the soil depends on the type of soil, the pH, and the chemical composition of the metal.
Snuff is a smokeless tobacco that is made of finely ground or shredded tobacco leaves. It may have different scents and flavors and may be moist or dry [21] . Moist snuff tobacco is placed in the mouth, usually between the cheek and gum or behind the upper or lower lip. Dry snuff tobacco is inhaled through the nose. Snuff tobacco contains nicotine and many harmful, cancer-causing chemicals that have been reported to cause cancers of the mouth, esophagus, pancreas, gum disease, heart disease, stroke, and other health problems.
One of the primary harm of smoking to lungs comes from the smoke itself [22]. Unlike tobacco smoke, snuff is free of tar and harmful gases such as carbon monoxide and nitrogen oxides. Since it cannot be inhaled into the lungs, there is no risk of lung cancer, bronchitis, and emphysema. It is not known whether nicotine or carbon monoxide is the major culprit responsible for cigarette-induced coronary heart disease. If it is carbon monoxide a switch to snuff would reduce the risk substantially. In conclusion, the rapid absorption of nicotine from snuff confirms its potential as an acceptable substitute for smoking. Switching from cigarettes to snuff would substantially reduce the risk of lung cancer, bronchitis, emphysema, and possibly coronary heart disease as well.
However, the presence of heavy metals in snuffs and tobacco leaves can pose a health challenge. Heavy metals are natural components of the earth’s crust that cannot be degraded or destroyed. To a small extent, they enter our bodies via food, drinking water and air. As trace elements, some heavy metals (e.g. copper, selenium, zinc) are essential to maintain the metabolism of the human body. However, at higher concentrations, they can lead to poisoning. It has been reported that exposure to Cadmium via inhalation leads to pneumonia, pulmonary edema and death [23], also IARC classified Cadmium as a carcinogen to humans. Some workers [24] [25] in their research reported that inhalation, ingestion, dermal absorption are the major routes of entry of chromium into human systemic circulation, and that it is also carcinogenic, causes nasal septum perforation, asthma, bronchitis, pneumonitis, liver disease, skin allergies, dermatitis, dermal necrosis and dermal corrosion. Zinc has been reported to be toxic on exposure to high doses with health effects as apoptosis by acting on several molecular regulators of programmed cell death, including caspases and protein from the Bel and Bax families [26]. Nickel is the major cause for most allergic skin reactions and leads to allergic contact dermatitis which is a positive dermal patch test [27] [28].
Bioaccessibility is the ability of a given dose of a substance to be absorbed into the systemic circulation [29] [30]. It acts on the principle of being a subcategory of absorption and is the fraction of an administered dose of unchanged substance that reaches the systemic circulation, which generally designated simply the quantity or fraction of the ingested dose that is absorbed. The three major routes of exposure of substances into the systemic circulation are ingestion, inhalation and dermal absorption [31] [32].
A formulated synthetic lung fluid (SLF) known as Gambles solution emulates the extracellular environment of the deep lungs and this has been widely used to access inhalable toxicants in human test subjects [33]. Boisa and his colleagues [34] developed a method for the inhalation bioaccessibility test which includes most components that were previously omitted in vitro formulations. They suggested that their formulation closely approximates human respiratory tract fluid. This study will apply inhalation bioaccessibilty model developed by Boisa et al. [34] to evaluate bioavailabilty of Cd, Cr, Ni and Zn in tobacco snuff and leaves.
2. Materials and Method
2.1. Collection of Samples
The foreign and local tobacco snuffs and leaf samples were obtained and identified by the technologist at the Botany department of Rivers State University, Port Harcourt.
2.2. Experimental Procedure
The procedure of AOAC, 2000 was adopted for the determination of total metal concentration using standard ashing procedure. The method of Boisa et al. [34] was adopted the inhalation bioaccessibility test, and their recently developed in vitro stimulated epithelial lung fluid (SELF) was employed for the test.
2.3. Ashing and Ash Solution
The tobacco leaves samples were weighed and oven dried to remove moisture for easy disaggregation, the leaves were ground into fine powder. One gram of Nigeria snuff (NS), Foreign snuff (FS), Nigerian tobacco leaves (NL), and foreign tobacco leaves (FL) were weighed in triplicates into crucibles and put in Muffle furnace at 105˚C for 2 hours. Five milliliters of Concentrated HCL was added to the resulting ash and diluted with 20 mls of deionized water, and heated in a fume chamber for 10 minutes. The content was allowed to cool, filtered into a volumetric flask and made up to 100 mls with deionized water (AOAC, 2000). The ash fluid was assayed for the total concentration of Cd, Cr, Ni and Zn using Atomic Absorption Spectrophotometer (A Analyst 200 AA Spectrometer).
2.4. Preparation of Stimulated Epithelial Lung Fluid (SELF)
The method of Boisa et al. [34] was adopted: 500 mls of inorganic and organic reagents each were prepared, and combined to form 1000 ml of reagent in a 1 liter bottle which contained 260 mg bovine serum albumin, 122 mg cysteine, 100 mg dipalmitoyl choline, 376 mg glycine and 500 mg Mucin. The resulting fluid was mixed thoroughly. HCL (0.4 ml) was added to attain the desired pH of 7.4 ± 0.2.
2.5. Inhalation Bioaccessibility Extraction
The Stimulated Epithelial Lung Fluid (SELF) was heated to 37˚C ± 2˚C in a water bath before use. Triplicate set of approximately 0.3 g of test samples (tobacco leaves and snuff) were accurately weighed into a labeled centrifuge tube to which 20 ml of the prepared SELF was added. The resulting suspensions were rotated for a range of fixed times at a speed of 30 rpm for 96 hours then centrifuged at 3000 rpm for 10 minutes and the clear supernatant was transferred into fresh tubes and submitted for AAS (Perkin Elmer Analyst 200 model) analysis to determine bioaccessible concentrations of Cd, Cr, Ni and Zn.
2.6. The Percentage Inhalation Bioaccessible Fraction (%IBAF)
The percentage inhalation bioaccessible fraction (%IBAF) was calculated thus:
2.7 Risk Assessment
The risk assessment was calculated after Boisa et al. [34]
where:
DI = Daily intake
Ftb = Total or % bioaccessible concentration
TR = Tracheobronchial retention (0.75)
Smass = Inhalation rate (10 g) day−1
BW = Body weight (60 kg)
2.8. Quality Control
Reagent blank was included within the inhalation bioaccessibility extraction procedure, to determine reproducibility; all samples were extracted in triplicate. Instrumental detection limit for the element was 0.1 µg/l with the method detection limit, two orders of magnitude greater at approximately 10 µg/l. All reported data are based on the average of three replicate.
2.9. Statistical Data Analysis
Statistical analyses were performed using SPSS 21 (SPSS Inc., Chicago, IL, USA). P ≤ 0.05 was considered significant. Data are presented as Mean ± standard deviation (SD). Differences in continuous data were compared using one-way analysis of variance (ANOVA: three or more groups) followed by the post-hoc test.
3. Results and Discussion
3.1. Total Heavy Metal Concentration
The mean total concentration and standard deviation of Cd, Cr, Ni, and Zn in foreign Snuff were 12.6 ± 1.7 µg/g, 24.1 ± 2.6 µg/g, 69 ± 9 µg/g and 172 ± 18 µg/g respectively, in foreign Leaves were 14.9 ± 0.6 µg/g, 37.0 ± 2.5 µg/g, 56 ± 4 µg/g and 183 ± 10 µg/g, respectively (Table 1). The mean total concentration and
Table 1. Total Heavy mean concentration of research samples.
Values are mean ± standard deviation. FS: Foreign Snuff; FL: Foreign Tobacco Leaves; NS: Nigerian Stuff; NL: Nigerian Tobacco Leaves; n: Sample Size; vs: Versus.
standard deviation of Cd, Cr, Ni, and Zn in Nigeria Snuff were 9.7 ± 1.0 µg/g, 33.3 ± 1.7 µg/g, 41 ± 4 µg/g and 153 ± 12 µg/g respectively, in Nigeria leaves, were 10.7 ± 0.6 µg/g, 37.0 ± 2.5 µg/g, 41 ± 7 µg/g and 167 ± 5 µg/g respectively (Table 1). The concentration range of Cd observed in this study is similar those reported for tobacco in USA and Greece [35] [20], but above those previously reported for tobacco in Nigeria, Ghana and Turkey [18] [36] [37] [38] (Table 2). The concentration range of Cr observed in this study is above those previously reported for tobacco in UK, and Nigeria [37] [39] (Table 2). The concentration range of Ni observed in this work is above those previously reported for tobacco and its products [20] [30] - [36] but within range reported by Iskander et al. [40] (Table 2). The concentration range reported for Zn in this work is consistent with the range reported by Adamu et al. [35] for tobacco leaves in United States. Comparing the concentrations, indicate significant difference was observed between foreign leaves, Nigerian snuff, and Nigerian leaves for cadmium concentration, (p = 0.00, F = 12.00). For Cr significant difference was observed between Foreign snuff, and each of foreign leaves, Nigerian Snuff, and Nigerian leaves (p = 0.00, F = 20.08). For Ni significant difference was observed between foreign Snuff, and each of Nigerian Snuff, and Nigerian leaves (p = 0.00, F = 13.50). For Zn significant difference was observed in all research samples was (p = 0.103, F = 2.873). The concentration variance noticed between the different matrices studied may be due site—specific characteristics of soils on which they were cultivated, their bioaccumulation capacity, and additives included during processing to the snuff.
3.2. Bioaccessible Concentrations and Percent Bioaccessibility
Bioaccessible concentrations of Cd in snuff and leaves ranged between 5.8 - 7.3 ug/g and 3.1 - 5.6 ug/g, respectively. For Cr in snuff and leaves ranged between
Table 2. Comparison of this study’s total concentrations of with other published data.
0.8 - 2.7 ug/g and 2.0 - 14.0 ug/g, respectively. For Ni in snuff and leaves ranged between 13.0 - 15.0 ug/g and 13.0 - 20.0 ug/g, respectively. For Zn in snuff and leaves ranged between 13.0 - 19.0 ug/g and 19.0 - 20.0 ug/g, respectively (Table 3). Significant difference in bioaccessible concentrations exist between the different matrices for Cd, Cr, Ni and Zn in SELF (Table 3). Cadmium can get into systemic circulation via inhalation [41]. Table 4 shows an order of increasing percentage inhalation bioaccessibility for FS, FL, NS and NL as Cadmium > Nickel > Zinc > Chromium. The % bioaccessibility range for Cd, Cr, Ni and Zn were 20.8 - 59.8, 3.3 - 8.1, 21.7 - 48.8 and 7.6 - 12.0, respectively (Table 4).
The high percent inhalation bioaccessibility range observed in this study for Cd (20.8% - 59.8%) is consistent with the range (58.7% - 67.7%) reported for total suspended particulate matter (TSP) by Hu et al., (2012) [41]. The low percent inhalation bioacessibility range (3.3% - 8.3%) observed for Cr in this study is consistent with the range (8.2% - 18.2%) reported by Hu et al. [41] for TSP. Also the moderate percent inhalation bioaccessibility range observed for Ni in this study (21.7% - 48.8%) is consistent with the range (11.2% - 23.5%) reported for
Table 3. Mean bioaccessible concentration of research samples.
Values are mean ± standard deviation. FS: Foreign Snuff; FL: Foreign Tobacco Leaves; NS: Nigerian Stuff; NL: Nigerian Tobacco Leaves; n: Samplesize.
Table 4. Percentage inhalation bioaccessibility of research samples.
FS: Foreign Snuff; FL: Foreign Tobacco Leaves; NS: Nigerian Stuff; NL: Nigerian Tobacco Leaves.
total suspended particulate matter (TSP) by Hu et al. [41]. But the low percent inhalation bioacessibility range (7.6% - 12.5%) observed for Zn in this study is not consistent with the range (54.3% - 75.3%) reported by Hu et al. [41] for TSP.
3.3. Risk Assessment
The daily intake risk assessment analysis based on an intake of 10 g of snuff per day is shown in Table 5. For Cd, the daily intake dose derived in this study ranged between 1.2 - 1.6 µg/kgbw/day for total concentrations and ranged between 0.7 - 0.9 µg/kgbw/day for bioaccessible concentration. Both daily intake doses estimated for total and bioaccessible concentrations in this study for Cd are above WHO tolerable daily intake dose (0.5 µg/kgbw/day) [42] [43] [44] for food items.
The daily intake dose derived for Cr in this study ranged between 3.0 - 4.2 µg/kgbw/day for total and 0.1 - 0.3 µg/kgbw/day for bioaccessible concentrations. The estimated dose range employing total concentrations are above WHO tolerable daily intake dose (2.3 µg/kgbw/day) [42] [43] [44] for food items. However, the daily intake dose estimated for the bioaccessible concentration was below the WHO tolerable daily intake dose (2.3 µg/kgbw/day).
For Nickel, the daily intake dose derived in this study ranged between 5.1 - 8.7 µg/kgbw/day for total and 0.2 - 1.3 µg/kgbw/day for bioaccessible concentrations. Both intake doses estimated for Ni using total and bioaccessible concentrations of snuff are below WHO tolerable daily intake dose (23 µgkg/bw/day) [42] [43] [44].
The daily intake doses for zinc derived in this study ranged between 19.1 - 21.5 µg/kgbw/day for total and 1.6 - 2.4 µg/kgbw/day for bioaccessible concentrations. The daily intake dose estimated using total concentration of snuff was above WHO tolerable daily intake dose (11.6 µg/kgbw/day) for food items. Conversely, the daily intake dose estimated for the bioaccessible concentration was below the WHO tolerable daily intake dose (11.6 µg/kgbw/day) [42] [43] [44].
FS Total: Foreign snuff risk assessment based on total heavy metal concentration; NS Total: Nigerian snuff risk assessment based on total heavy metal concentration; BAF: Bioaccessible fraction risk assessment for foreign and Nigerian snuff; WHO: World Health Organization.
4. Conclusions
The idea that consumption of snuff is less likely to cause harm to human prompted this study. The concentrations of Cd and Ni recorded from the tobacco snuff and leave samples in this study are consistent with those previously published for cigarettes. All the potentially toxic metals studied here indicated varying dissolutions in the synthetic lung fluid (SELF), with Cd, Cr, Ni, and Zn indicating inhalation bioaccessibility ranges of 20.8% - 59.8%, 3.3% - 8.3%, 21.7% - 48.8% and 7.6% - 12.5%, respectively.
The total and bioaccessible concentrations of Cd, Cr, Ni, and Zn were employed for the estimation of daily intake doses with an assumption that adult human subjects will snuff about an average of 10 g/day. With the total content of Cd, Cr and Zn in the snuff adult human subjects are projected to indicate daily intake doses above WHO tolerable daily intake doses. For more conservative estimations using bioaceesible concentrations, only Cd indicated daily intake dose above that recommended by WHO for food. Based on the data generated from this study, the risk analysis based on bioaccessible concentration suggests lower health risk than analysis based on total heavy metal concentration; hence the assumption that snuff is a safe alternative to tobacco smoking may be erroneous.
Acknowledgements
The authors wish to acknowledge Julie Cookey for the funds applied to this research work.