1. INTRODUCTION
Radioactivity is present in all moments of our daily life. The radiation that exists in nature without human intervention is called natural radioactivity and it is present in the ground, in the air, etc. The radioactivity generated by human intervention is called artificial radioactivity1-5. Its applications have increased in the last few years. Therefore, it is necessary a periodical environmental control to monitor human activities such as the analysis of different types of food in order to guarantee their quality6-13.
The pulp of the araucaria’s seed is suitable for human consumption, it can be ingested naturally, roasted or boiled, the peel is used in medical infusions for the treatment of muscle tension of varicose vein. In addition, the araucaria’s resin is used for the treatment of respiratory infections and the leaves to treat scrofula, fatigue, and anemia14-19. The commercialized volume of Araucaria nuts reached over 10 thousand tons of Araucaria nuts from August 1994 to June 2002 by the Parana City Supply Centers (CEASA, in Portuguese) from Curitiba, Maringá, Londrina, Foz do Iguaçu and Cascavel, which corresponds to an approximated average of 1300 ton per year20.
The research often focuses on the nutritional content, chemistry characterization and some physicochemical properties of the Araucaria nuts6,7. However, due to its wide distribution and high amount of consumption, there is a concerning risk of exposure to natural radioactivity from the Araucaria nuts. This study aims to determine the activity of 232Th, 238U, 40K, and 137Cs and to perform a multi-element analysis of the seed of Parana pine tree (Araucaria Angustifolia), commonly known as Pinhão (Araucaria nut)15,21.
2. MATERIALS AND METHODS
2.1. Preparation of samples
The samples were acquired in the city of Londrina (Parana, Brazil) between May and July of 2014. Among 8 batches were bought in different commercial centers and informal stores found around the city. During the purchase of Araucaria nuts, their origin and time of harvest were consulted, however, some traders could not specify this information.
The Araucaria nuts were roasted on a hot plate between 100°C and 150°C, simulating cooking procedures for human consumption. Later, their pulp and peel were separated, grounded manually in a mortar and stored in neutral plastic containers of 300mL of volume. At the end, 16 containers were used for the seed’s pulp and 8 containers for the seed’s peel which were sealed for 40 days in order to achieve the secular balance for the upcoming analysis.
For the X-ray fluorescence analysis, the pulp was dehydrated, sieved and pressed into tablets to achieve homogeneous samples. A binding agent (0.250 g of boric acid - H3BO3) was used for every 1000 g of seed powder. Two 2.5 mm thick tablets were prepared for each batch by applying 9 tons of uniaxial pressure over the mix for 2 minutes. In addition, the powder samples were also measured for elementary identification of the composition, putting 1 gram of Araucaria pulp powder and the peels over a chemplex (samples holder).
2.2. Gamma-ray spectrometry
A high-resolution gamma-ray spectrometer system setup was a HPGe (hyper-pure germanium) detector, manufactured by CANBERRA (model GC6020) with a relative efficiency of 60% and the shield elaborated by ORTEC model HPLBS1 designed for environmental applications. This setup was used to measure the radionuclides of interest.
All spectra were collected during a 24-hour period, preceded by the acquisition of the background spectrum produced by natural radiation for the calculation of the activity and committed effective doses.
2.3. Energy dispersive X-ray fluorescence spectrometry (EDXRF)
A commercial equipment of X-ray fluorescence by dispersive energy (EDXRF) manufactured by Shimadzu (model EDX-720) with an Rh target (X-rays source) was used for the qualitative elemental analysis of the Araucaria nuts. A solid-state detector was used with the following experimental set up parameters: 10 mm collimator, 100 s of measurement time, 50 kV of voltage and 487 - 604 μA of current.
EDXRF analysis was performed for the elemental identification of the composition of the araucaria seeds and control of contamination with heavy metals. Because of the lack of certified material, it was not possible to quantify elements.
2.4. Estimation of the consumption per capita
Information and analysis about Araucaria nuts consumption per capita was not found in the literature. Due to this fact, the value was estimated through the quantity of Araucaria nuts commercialized among the different supply centers from Parana State and the Brazilian Institute of Geography and Statistics (IGBE, in Portuguese) shown in Table 1.
District or city | Quantity (ton) | Population | Consumption per capita |
Curitiba | 511.04 | 1751907 | 0.292 |
Cascavel | 106.1 | 286205 | 0.371 |
Foz do Iguaçu | 30.25 | 256088 | 0.118 |
Londrina | 14.68 | 357077 | 0.041 |
Maringá | 14.68 | 357077 | 0.012 |
Average | 0.167 |
The official figures might contain considerable discrepancy because of the informal or clandestine sales in rural areas, and because not all the Araucaria nuts sold, is consumed(21).
3. RESULTS AND DISCUSSIONS
3.1. Quantitative results
Figure 1 presents gamma spectrum pulps of araucaria, obtained with a 24 hours measure time. Peaks of interest from radionuclides are indicated. Because it is the most abundant in nature, the peak belonging 40K is the most intense in comparations with others peaks.
Using the spectra obtained in gamma spectrometry, the Bq / kg activities of 226Ra, 228Ra, 40K, and 137Cs in the araucaria seed and bark samples were calculated.
Due to the different ways of consumption of Araucaria seeds the activities are calculated per kg in nature.
The radioactivity of the desired radionuclides for each sample is presented in Table 2. This table organizes the average activity of 226Ra, 228Ra, 40K, and 137Cs from 16 pulp samples and 8 Araucaria nuts samples in nature per kilogram.
Average activity (Bq/kg) | ||||
Powdered Samples | 226 Ra | 228 Ra | 40 K | 137 Cs |
Pulp | 0.93 ± 0.05 | 0.62 ± 0.02 | 498 ± 1 | 0.65 ± 0.04 |
Peel | 5.8 ± 0.4 | 3.9 ± 0.2 | 730 ± 6 | 2.4 ± 0.4 |
The radionuclides analyzed presented higher levels of activity in the Araucaria nuts peel. In all 8 batches of pulp of Araucaria nuts purchased, the presence of 137Cs was registered, but just in the batch number 6 was registered the presence of 137Cs in the peel.
In Figure 2 it is observed that all batches shown an activity of 137Cs and 228Ra, but the activity of 226Ra is similar in all samples. The 137Cs is absorbed by the tree roots due to similar properties that own the K24-26, the activities of 37Cs in all samples are below the concentration level of 600 Bq/kg for the sum of activities of 134Cs and 137Cs respectively.
Has been calculated the effective dosage committed by ingestion (DEC) with the average of 226Ra and 228Ra and average Commercialized Araucaria nuts among the different supply centers of Parana of araucaria nuts. Using the following expression for the calculated (DEC) (27-29).
Where C is the consumption per capita in Kg/years, A is the activity of radionuclide Bq/kg and e(g) Is the effective dose compromised per unit in Sv/Bq.
The Table 3 shows the effective dosage committed by ingestion (Dec) with the UNSEAR reference value.
Committed effective doses (µSv/year) | ||||||
---|---|---|---|---|---|---|
Age (years) | Araucaria nuts consumption | Reference values (UNSCEAR) | ||||
226 Ra | 228 Ra | Sum | 226 Ra | 228 Ra | Sum | |
2 a 7 | 0.96 | 0.58 | 1.54 | 7.5 | 31 | 38.5 |
7 a 12 | 0.8 | 0.39 | 119 | 12.0 | 40.0 | 52.0 |
>17 | 0.28 | 0.07 | 0.35 | 6.3 | 11 | 17.3 |
Average | 0.68 | 0.35 | 1.03 | 8.1 | 21 | 29.1 |
According to the average values of effective doses per radionuclide, it was verified that the 228Ra present on the effective committed dose of 0.35 µSv/year, which is two orders of magnitude lower than the reference values of UNSCEAR, 21 µSv/year. For 226Ra, the average effective dose weighted was 0.68 µSv/year, approximately 13 times lower than the one of reference of 8.1 µSv/year. The differences obtained for the doses and the reference values are expected since the calculations in the current research refer only to the dose of the Araucaria nuts consumption, while the reference values contain other daily diet food.
Furthermore, the DEC for 40K was not calculated since the dose of this radionuclide is controlled by the organism through homeostatic control. The annual equivalent doses for tissues from 40K are 165 and 185 µSv/year for adults and children, respectively. The effective dose is 170 µSv29,30.
3.2. Qualitative results by EDXRF
Figure 3 shows typical spectra of X Ray Fluorescence spectra on the Araucaria pulp and shield powdered. In all the pulp powder samples was detected the presence of P, S, K, Ca, Fe, Rb, Zn and Cu. However, in the pulp tablets, the frequency of Zn and Cu detection was lower than the frequency in the pulp.
In the Table 4 shows element intensity of major elements present in the araucaria measurements with X-ray fluorescence and standard deviation in the Araucaria nuts powdered tablet, pulp and peel. No significant difference between powder and tablet peaks intensity was observed, except for the increased presence of Zn in the powdered pulp.
Intensity | |||
Element | Peel | Pulp Powder Tablet | Pulp powder |
K | 1.865±0.081 | 3.417±0.635 | 3529±0.626 |
S | 0.039±0.001 | 0.073±0.003 | 0.074±0.003 |
Fe | 0.879±0.014 | 0.83±0.054 | 0.43±0.02 |
Cu | 0.612±0.014 | 0.663±0.024 | 0.707±0.019 |
P | 0.27±0.011 | 0.051±0.005 | 0.0495±0.005 |
Ca | 0.34±0.014 | - | - |
Mn | 0.29±0.013 | - | - |
Rb | - | 3.940±0.106 | 3.714±0.061 |
Zn | - | - | 0.587±0.014 |
In all the pulp powder samples was detected the presence of P, S, K, Ca, Fe, Rb, Zn and Cu. However, in the pulp tablets, the frequency of Zn and Cu detection was lower than the frequency in the pulp.
P, K, Rb, Fe, S, Ca, Cu and Zn were detected both in the pulp and the peels. Sr and Mn were observed only in the peels. No trace of Sr was detected in the pulp and the peel is consumed as a medicinal tea. As the Sr is not soluble in water and as the consumption is not frequent, this practice does not generate a risk.
The Cu is a transition non-ferrous metal abundant on earth, however, our interaction with this element is not daily. It is present in almost all types of food and in the air. Considered a micronutrient, Cu is only dangerous at high concentration and long periods of exposition, in which cases, it can cause damage to the liver and the kidney. It was not yet confirmed if Cu is a carcinogenic element31,32.
4. CONCLUSIONS
Araucaria nuts are not consumed in high amounts by the population, they are a typical food but not popular in Brazil.
The values of Dec calculated by gamma spectrometry show that the consumption of araucaria nuts are in acceptable values of 226Ra and 228Ra, in addition to verifying that the levels of activity of 137Cs and 46K are in the range accepted by UNSCEAR33.