1. Introduction
Eggs are an important source of many nutrients necessary for the proper development and functioning of the human organism. They are a good source of nutraceuticals used in the prevention of civilization diseases [
1,
2,
3]. The chemical composition of eggs is complex and may be influenced by various factors (breed, age of birds, housing system, and feed composition) [
4,
5,
6]. The mineral composition of eggs is important in terms of food safety, due to the fact that all elements, including essential, can become toxic or lead to deficiencies if consumed in inappropriate amounts [
7,
8,
9]. Additionally, feed and environment, and thus eggs, may be contaminated with potentially toxic elements, such as Ag, As, Be, Cd, Cr, Hg, Ni, Pb, Sb, V, and Tl [
10,
11,
12].
Reports have described the chemical composition of eggs from different breeds of hens from different housing and feeding systems, but determinations of macro- and trace element contents are limited. For example, determinations of the concentration of 11 micro- and trace elements (Ba, Cu, Fe, Mn, Ni, Pb, Rb, Se, Sr, V, and Zn) in hens eggs obtained from various poultry housing systems in Latvia were reported. Eggs from organic farms had the most variable concentration range and the highest element content, while eggs from other maintenance systems contained lower element concentrations [
13]. The content of 12 trace elements (As, Cd, Co, Cr, Cu, Mo, Mn, Ni, Se, V, Ti, and Zn) in hen eggs (Lohman type) from three maintenance systems was analyzed by Giannenas et al. [
14]. The authors concluded that trace element content in yolks were higher than trace element content in albumen. Cr concentration was higher in a courtyard, rather than organic, diet. The highest concentration of Se in yolks was found in eggs from the organic system, followed by eggs from the conventional system. Zn concentration in yolks was highest in the courtyard system, followed by yolks from the conventional system, which, in turn, was higher than yolks from the organic system. Mn concentration was lowest in yolks from the courtyard system, but Cr concentration was highest in eggs from the courtyard system. In the case of albumen, there were differences in Zn and Cr levels, which were the highest in albumen from the courtyard system. The results show measurable differences among eggs from hens maintained in different production systems.
Other reports determined the level of some trace elements (As, Co, Cu, Fe, Mn, and Se) in eggs from three different sources (commercial farm, village, and markets) in Malaysia. The greatest concentration of these metals (except Co) was found in eggs from commercial farms, compared with other sources [
15]. However, Kiczorowska et al. [
5] proved that the mineral composition of Rhode Island Red (RIR) hen eggs varied significantly, depending on the large-scale, courtyard, or organic systems. Free-range eggs showed a substantial increase in the content of macroelements K and Na (albumen and yolk) and Ca and Mg (yolk), and microelements Zn, Se, and Mn (albumen and yolk) and Fe (yolk). The authors explained this with the possibility of supplementing the diet of hens on the paddock. Additionally, researchers [
16] believe that hen type, age, and rearing environment has little effect on the chemical composition of egg content, and the observed differences in mineral content of eggs are unlikely to have significant effect on human nutrition.
It seems that the chemical composition of the feed, both the concentration of macronutrients and trace elements, may have the greatest impact on the mineral composition of eggs. A recent study [
6] has determined the level of 38 chemical elements in the egg white and yolk of Lohmann Brown (LB) hens kept in a cage system and fed with commercial feed mixture with additive of humic preparations. The authors showed the limited effect of the mineral composition of feed on the concentration of essential and nonessential elements in eggs. These relationships were significant in the case of Bi, Co, Ni, and S (feed–albumen), and Bi, Fe, K, and Sb (feed–yolk).
Despite many studies on the mineral composition of hen eggs and the influencing factors, there is no information to-date regarding the content of minerals in eggs of local breeds (e.g., Green-Legged Partridge—Polish native breed), which are increasingly kept in ecological, organic, and free-range systems [
17,
18]. Since 1991, GLP hens have been covered by a national program for the conservation of animal genetic resources, among the other 10 breeds/families of laying hens. This breed is also classified by the FAO as a global genetic resource [
19].
The aim of this study was to assess the chemical composition (macro-, micro-, trace, and ultratrace elements) in the content of GLP hens’ eggs kept in a free-range system with varied mineral nutrition.
2. Materials and Methods
2.1. Ethical Statement
The experiment on GLP hens was approved by the Second Local Ethical Committee on Animal Testing at Wroclaw University of Environmental and Life Sciences (UPWr) (No. 17/2009, 9 February 2009).
2.2. Animal Population and Experimental Design
All experiments were carried out in hen farms in Modrze (Poland). The animal material consisted of 300 GLP hens, which were divided into two experimental groups (Gr-1 and Gr-2) of 150 birds each. At the beginning of the experiment, the hens were 18 weeks of age and were kept until the peak of laying (32–33 weeks). The birds were kept in a free-range system and had free access to green, partly grassy paddocks with an area of 8 m2/head. At night, the birds stayed in henhouses equipped with feeders, drinkers, three-story perches, and nest boxes. The floor of the henhouses was covered with crushed straw and sawdust. There were 5 hens/m2 inside the henhouse, the perch length was 25 cm/hen, and there were six hens per nest. The birds had constant access to feed and water.
2.3. Feed Mixture
The basal feed mixture was formulated according to the poultry nutrition standards [
20]. The hens were fed with feed mixtures based on corn meal, soybean meal, postextraction rapeseed meal, wheat (grains and bran), dicalcium phosphate, ground limestone, salt and vitamin–mineral premix, with Gr-2 birds additionally receiving mineral organic feed additives (MOFA) which was 10% of the feed mixture. The feed mixture was produced under veterinary supervision on the farm where the hens were kept. The MOFA were composed of flaxseed meal, dry microalgae, dolomite, humin, and aluminosilicate raw materials. Both mixtures were sent to the laboratory at the Department of Animal Nutrition and Feed Management of UPWr. In this laboratory, the basic parameters of feed mixture were determined (crude protein, crude fat, crude fiber, crude ash, and dry matter) [
21].
2.4. Sample Collection for Analyses
Eggs used for tests were collected at the peak of laying for five successive days from both groups. Every day, five undamaged eggs with similar weight (53–57 g) were randomly selected from each experimental groups. In the next step, the eggs were broken and the albumen and yolk were separated. Every day, five samples (n = 5) of albumen and yolk were collected from both groups, resulting in a total of 50 samples. Samples were stored for 6 days in a coldroom (+4 °C) before transport to the chemical laboratory at the Wroclaw University of Science and Technology (WUST). Additionally, approximately 0.5 kg (n = 5) samples of the feed mixtures were collected for chemical analysis at weekly intervals from the fifth week before egg collection.
2.5. Analitical Techniques
The chemical composition of the feed mixture and hen eggs was tested to determine chemical element content. Analyses were performed using inductively coupled plasma spectroscopy by ICP-OES and ICP-MS techniques. The appropriate mass of biological material (feed, 0.5 g; albumen, 1.5 g; and yolk, 1.5 g) was mineralized in Teflon bombs with 5 mL of concentrated, spectrally pure nitric acid (HNO3, from Merck) in a START D microwave digestion system (Milestone, Italy). The following analytical equipment was used: an inductively coupled plasma optical emission spectrometer with ultrasonic nebulizer (Varian VISTA-MPX ICP-OES, Melbourne, Victoria, Australia); and an inductively coupled plasma spectrometer with mass detector (ICP-MS Varian Ultra Mass-700 Instrument, Melbourne, Victoria, Australia).
In the feed mixture and egg content (albumen and yolk), the concentration of the following elements was determined by ICP-MS method: Co, Cr, Cu, Fe, I, Mn, Mo, Se, and Zn. Analysis of the remaining elements was performed by ICP-OES: macro- and microelements Ca, K, P, S, Mg, Na and Al, Ba, Si, Sr; trace elements As, B, Be, Bi, Cd, Cs, Ga, Ge, Li, Nd, Ni, Pb, Rb, Ti, V, Y, and Zr; and ultratrace elements Ag, Au, Ce, Gd, Hf, La, Lu, Nb, Pd, Pt, Ru, Sb, Sn, Ta, Te, Tl, U, W, and Yb. Mercury (Hg) content was analyzed by atomic absorption spectrometry, mercury analyzer AMA-254 (Altec Ltd., Prague, Czech Republic). Anions, such as Cl, F, Br, and radioactive elements (except U), were not determined. These elements were bonded chemically to metals, with the exception of B, I, Se, Si, and Te (non-metals), although elements such as Al, As, B, Ge, Sb, Se, and Te are classified as metalloids [
22,
23].
Analytical determinations were carried out in the Laboratory of Multielemental Analyses at WUST, accredited by the Polish Center for Accreditation and ILAC/MRA, No. AB 696. The analytical determinations were performed in accordance with PN-EN ISO 17025. The quality of analytical process was controlled with the certified reference material: whole egg powder (NIST RM 8415), corn flour (INCT-CF-3) and soya bean flour (INCT-SBF-4).
To avoid possible secondary contamination of the sample, no metal tools and laboratory equipment were used, only those made of plastic or glass.
2.6. Statistical Analysis
Analysis of the results was carried out using Statistica ver. 13.1. The data is presented as the mean and standard error of mean (SEM). The Shapiro–Wilk test was used to determine the normality of the data distribution. If the distribution was normal, a Student’s t-test for independent samples was performed. If the distribution was not normal, a Mann−Whitney U test was performed. Differences were considered significant if p < 0.05 or p < 0.01.
3. Results
3.1. Feed Mixture
The results relating to the feed mixtures are presented in
Table 1.
Table 2 shows the percentage of macro- and microelements in both feed mixtures. Their chemical composition (macro-, micro-, trace, and ultratrace elements) is presented in
Table 3 and
Table 4.
The total macro- and microelement content was 53,466.0 mg/kg in Gr-1 and 57,411.8 mg/kg in Gr-2 (∆ = 7.38%). In contrast, trace and ultratrace element content was 23.32 and 26.68 mg/kg, respectively (∆ = 12.59%).
Among 56 elements, significant differences were observed for macro- and microelements. In Gr-2 feed mixture, the level of Al, Ba, Ca, K, P, S, and Si was significantly higher (p < 0.05 or p < 0.01). Ca and K were the most abundant in the feed mixtures, whereas Ba and I levels were the lowest. Among the trace and ultratrace elements, higher levels in Gr-2 feed mixture of the following elements were determined: Co, Cr, Li, Nb, Ni, Ru, Sn, and Zr, and lower levels of Cs, Pd and Te. Among trace and ultratrace elements, Cr, Rb, and Ti were the most abundant in the feed mixtures, while Au, Pt, Ta, and Tl were below 0.02 mg/kg.
3.2. Egg Albumen
Table 5 and
Table 6 summarize the results of the albumen analyses. Among the examined elements in the group of macro- and microelements, significant differences were observed for Ba, and higher levels were found in Gr-2. Na and S were the most abundant in albumen, and Ba and Mn the least.
Among the trace and ultratrace elements, there were significantly higher concentrations of the following elements in Gr-2: Au, Co, Cr, Mo, Nb, Ru, and Se, and lower levels of only As in Gr-1. The most abundant trace and ultratrace elements in the albumen were (in descending order) Rb, Ti, and Zr, while the least—below 0.001 mg/kg—was Cd, Cs, Gd, Hf, Hg, Ta, U, and W.
The total macro- and microelement content was 5735.8 mg/kg in Gr-1 and 5777.1 mg/kg in Gr-2 (∆ = 0.72%), while trace and ultratrace element content was 3.046 and 3.372 mg/kg, respectively (∆ = 10.70%).
3.3. Egg Yolk
Table 7 and
Table 8 summarize the results of the yolk analyses. Among 15 macro- and microelements, no significant differences were found between Gr-1 and Gr-2. The higher level of Ca, P, and S was detected in the yolk, and the lower of Ba, Mn, and Sr.
Among the studied trace and ultratrace elements, large variations occurred between the groups of elements: Co, Cr, Ni, Se, Sn, and Y (more in Gr-2), and Au, Hf, Hg, Nb, Nd, and Rb (less in Gr-2). The most abundant trace elements in the yolk were Rb, Se, and Cr, while those below 0.002 mg/kg were Cd, Cs, Gd, Ta, Tl, Yb, U, and W.
The total macro- and microelement content was 11732.4 mg/kg in Gr-1 and 11952.2 mg/kg in Gr-2 (∆ = 1.87%). In contrast, trace and ultratrace elements were 2.760 and 2.977 mg/kg, respectively (∆ = 7.86%).
4. Discussion
Feed mixture from Gr-2 contained the addition of MOFA, with a slightly higher (by 7.42%) weight of minerals (macro-, micro-, trace, and ultratrace elements) compared with Gr-1. This was explained by the increase in dry mater and crude ash in the Gr-2 feed mixture. The diet used in the feeding of GLP hens differed in the content of 18 chemical elements (among 56 assessed) due to the effect of the addition of MOFA. This additive contains flaxseed, microalgae, dolomite, humin, and aluminosilicate raw materials, rich in many elements, such as Al, Ba, Ca, Co, Cr, Fe, Ni, P, Si, Sr, and Ti [
12,
24,
25,
26,
27,
28]. These differences generally did not affect the mineral composition of the egg albumen and yolk; only in the case of increased content of Co and Cr in Gr-2 feed mixture, where a significant increase in these elements was found in the egg albumen and yolk of Gr-2. Similarly, an increase in Ba, Nb, Ni, Ru, and Sn in the hens’ diet caused an increase in the egg albumen (Ba, Nb, Ru) and yolk (Ni and Sn).
Previous reports [
12] have used HKW and HBF preparations in LB hen nutrition (ad libitum administration). The dietary humin preparations only significantly increased Se and decreased Mo concentration in the albumen, and increased Fe and Se concentrations in the yolk. These additives did not influence Cr, Co, Cu, I, Mn, or Zn concentrations in the eggs. These results only partially resemble those obtained in our study; for instance, they confirmed only the increase in Fe concentration in the yolk and the lack of influence of Cu and Zn content in the albumen and yolk [
12]. Other studies [
29] have shown that the addition of Fe to the diet of laying hens, also in the organic form, does not increase its concentration in egg yolk. In contrast, I, added in organic form (yeast) to the feed of hens, significantly increased its concentration in the egg yolk [
30].
It was reported [
31] that the diet of laying hens can be supplemented with soybean meal enriched with Cr, Cu, Fe and Zn. The results showed that the use of enriched soybean meal in the diet of laying hens (Hy-Line Brown) influenced the transfer of microelements to eggs, particularly at high doses. Eggs were biofortified with Cu, Fe and Zn and, to a lesser extent, with Cr. On the basis of these results, it can be concluded that the transfer of trace elements to eggs was not linearly dependent on the dose of biologically bound microelements in the diet. This proves a specific mineral independence of eggs, indicating the genetic determinants of their chemical composition.
The literature describes the physicochemical quality parameters of GLP eggs. It is known that egg albumen and yolk from these hens have a favorable amino acid composition, fatty acid profile, and higher vitamin content, mainly A and E, compared with farmed eggs [
32,
33,
34,
35]. However, there is no data on the mineral composition of these eggs, especially since these birds are kept only in an extensive system, having free access to soil and vegetation of the enclosures, allowing them to eat insects and worms [
4,
36]. Only Szablewski et al. [
37] provided the content of nine macro- and microelements (Ca, Cu, Fe, Mg, Mn, Na, K, Se, and Zn) in GLP eggs from hens maintained in an organic system. The results were difficult to compare, as the authors provided the content of elements for the whole egg, i.e., protein and yolk combined. In general, the mean values of these elements were similar (except for Zn) to the results of the tests of eggs of other hen breeds (Sussex, RIR).
Our own research showed that the content of the main minerals and trace elements differs significantly from the standard values provided, for example by Rehault-Godbert [
3]. Hence, the egg albumen of GLP had much higher levels of Ca, I, Na, but less K, Mn, P, Se, and Zn. The values of Cu, Fe, and Mg were similar. In the egg yolk of these hens, there was approximately twice as much Cu, Fe, Mg, Mn, P, and Zn, slightly more (by 10–20%) Ca, Na, and K, and less I and Se compared with the standard values [
3].
The obtained results in the field of trace elements can be compared those by Giannenas et al. [
14], who specified 12 trace elements in eggs from hens kept in the different systems. Similarly in the egg albumen of GLP, there was much more As, Co, Cr, Mo, V, and Se, and less Mn, Ni, and Zn compared with the results of the cited authors. The concentrations of Cd, Cu, and Tl were similar. Co, Cr, V, and Zn concentrations in the yolk were higher, but As, Mo, and Tl were lower compared with our results (mean values of Gr-1 and Gr-2). The results of determined Cd, Cu, Mn, Ni, and Se concentrations were similar [
14].
The obtained results can be compared with those of the tests (38 elements) carried out on the eggs of LB battery-raised hens fed with a standard feed mixture [
6]. In the case of GLP in the egg albumen, the concentration of Ca, Cu, Fe, and Na was much higher among macro- and microelements, while Al and K was lower. Among the trace elements in the egg albumen of GLP there were at least double Cr, Mo, V, Sn, Ti, and Zr, and lower levels of Bi and Ni. In the case of the yolk, higher concentrations of Ca, Mn, P, Si, and Sr, and two- or three-times higher concentrations of Bi, Co, and Li were observed, with much lower concentrations of Ag, As, Be, Ni, Tl, Sb, and W [
6]. These differences probably stem from genetic differences and the system of maintenance. GLP hens had free access to the enclosures and could supplement their diet by eating soil, grass, insects, etc. Furthermore, in the egg albumen and yolk of Gr-2, the mass of the analyzed elements was slightly higher than in Gr-1 (by 0.90% and 1.88%, respectively). The lack of testing of the water content of these edible elements of the egg made it impossible to explain this phenomenon.
In general, it seems that the eggs of GLP are characterized by higher content of many essential elements (macro- and microelements), while the concentrations of toxic elements (including heavy metals/metalloids) did not differ from the values given in previous reports [
38,
39,
40]. This is of particular importance in the context of consumer health and safety. Especially that toxic metals enter the human organism mainly through the respiratory and digestive tracts. The circulation of these metals in ecosystems is primarily related to the food chains of plants, animals, and humans [
41,
42]. This is due to the fact that heavy metals from soil, along with water, are taken up by plants and accumulate in their tissues (mainly roots and leaves), which are then eaten by animals and humans [
43,
44]. It should also be remembered that the amount of absorbed metal depends on its form, pH in the digestive tract, the speed of its passage through the digestive system, and the presence of other substances that may modify its absorption. However, the interpretation of the results is complicated due to the complex relationships between chemical elements (synergistic, antagonistic, and agonistic), which makes it difficult to interpret the results objectively, even with the appropriate statistical analysis performed [
40,
45,
46].