Composition of omega-3 and omega-6 fatty acids in freeze-dried chicken embryo eggs with different days of development

Campos, Célia Maria Teixeira de; Hamad, Antônio José Simões; Block, Jane Mara; Padilha, José Carlos Fiad; Ogliari, Paulo José; Barreira-Arellano, Daniel; Moreira, Rosana Nogueira Cavalcanti

doi:10.1590/S1516-89132004000200009

Abstracts

Fatty acids omega--3 and omega--6 composition and specially DHA were determined in freeze-dried chicken embryo eggs with pre-determined incubation periods. Fertile and embryo eggs presented palmitic (23.18 + 0.54%), stearic (7.70 + 0.28%), palmitoleic (3.00 + 0.19%), oleic (36.28 + 0.58%), linoleic (22.18 + 0.34%), linolenic (1.08 + 0.04%), arachidonic (2.04 + 0.03%), docosahexaenoic (0.91 + 0.03%), total omega-3 acids (2.26 + 0.10%) and total omega-6 acids (24.62 + 0.33%). There were no significant differences in total contents of omega-3 fatty acids (p=0.1226) between freeze-dried chicken embryo eggs with different incubation periods (3, 5, 7, 9, and 11 days) and fertile freeze-dried chicken eggs (day 0). However, there were significant differences in total medium contents of omega-6 fatty acids (p=0.0001). There was also a strong statistical evidence that quadratic model was related with expected values of DHA content (p= 0.0013).

Chicken embryo eggs; fatty acids omega-3 and omega-6; DHA

No presente trabalho, foi determinada a composição em ácidos graxos ômega-3, ômega-6 e, em especial, o DHA em ovos de galinha embrionados e liofilizados com períodos de incubação pré-estabelecidos. De acordo com os resultados obtidos, os ovos férteis e embrionados apresentaram a seguinte composição média de ácidos graxos saturados: palmítico (23,18 + 0,54%) e esteárico (7,70 + 0,28%); insaturados: palmitoléico (3,00 + 0,19%), oléico (36,28 + 0,58%), linoléico (22,18 + 0,34%), linolênico (1,08 + 0,04%), araquidônico (2,04 + 0,03%) e DHA (0,91 + 0,03%); total de ácidos ômega-3 (2,26 + 0,10%) e total ácidos ômega-6 (24,62 + 0,33%). Verifica-se que não há diferenças significativas nos teores médios totais de ácido graxos ômega-3 (p=0,1226), entre os ovos embrionados liofilizados com diferentes dias de incubação (3,5,7,9, e 11 dias) e ovos férteis liofilizados (dia 0). Porém, há diferenças significativas nos teores médios totais de ácidos graxos ômega-6 (p=0,0001). Também, há uma forte evidência estatística que o modelo quadrático está associado com os valores esperados do teor de DHA (p=0,0013).

FOOD SCIENCE AND TECHNOLOGY

Composition of w-3 and w-6 fatty acids in freeze-dried chicken embryo eggs with different days of development

Célia Maria Teixeira de CamposI, ^* * Author for correspondence ; Antônio José Simões Hamad^I; Jane Mara Block^I; José Carlos Fiad Padilha^I; Paulo José Ogliari^I; Daniel Barreira-Arellano^II; Rosana Nogueira Cavalcanti Moreira^II

^IUniversidade Federal de Santa Catarina - UFSC;CIF/CCS, CAL/CCA, ZOT/CCA, INE/CTC; Campus Universitário Trindade; celinha@ccs.ufsc.br; C. P. 476; 88010-970; Florianópolis - SC - Brazil

^IIUniversidade Estadual de Campinas - UNICAMP; FEA; Laboratório de Óleos e Gorduras; Campinas - SP - Brazil

ABSTRACT

Fatty acids w--3 and w--6 composition and specially DHA were determined in freeze-dried chicken embryo eggs with pre-determined incubation periods. Fertile and embryo eggs presented palmitic (23.18 + 0.54%), stearic (7.70 + 0.28%), palmitoleic (3.00 + 0.19%), oleic (36.28 + 0.58%), linoleic (22.18 + 0.34%), linolenic (1.08 + 0.04%), arachidonic (2.04 + 0.03%), docosahexaenoic (0.91 + 0.03%), total w-3 acids (2.26 + 0.10%) and total w-6 acids (24.62 + 0.33%). There were no significant differences in total contents of w-3 fatty acids (p=0.1226) between freeze-dried chicken embryo eggs with different incubation periods (3, 5, 7, 9, and 11 days) and fertile freeze-dried chicken eggs (day 0). However, there were significant differences in total medium contents of w-6 fatty acids (p=0.0001). There was also a strong statistical evidence that quadratic model was related with expected values of DHA content (p= 0.0013).

Key words: Chicken embryo eggs, fatty acids w-3 and w-6, DHA

RESUMO

No presente trabalho, foi determinada a composição em ácidos graxos w-3, w-6 e, em especial, o DHA em ovos de galinha embrionados e liofilizados com períodos de incubação pré-estabelecidos. De acordo com os resultados obtidos, os ovos férteis e embrionados apresentaram a seguinte composição média de ácidos graxos saturados: palmítico (23,18 + 0,54%) e esteárico (7,70 + 0,28%); insaturados: palmitoléico (3,00 + 0,19%), oléico (36,28 + 0,58%), linoléico (22,18 + 0,34%), linolênico (1,08 + 0,04%), araquidônico (2,04 + 0,03%) e DHA (0,91 + 0,03%); total de ácidos w-3 (2,26 + 0,10%) e total ácidos w-6 (24,62 + 0,33%). Verifica-se que não há diferenças significativas nos teores médios totais de ácido graxos w-3 (p=0,1226), entre os ovos embrionados liofilizados com diferentes dias de incubação (3,5,7,9, e 11 dias) e ovos férteis liofilizados (dia 0). Porém, há diferenças significativas nos teores médios totais de ácidos graxos w-6 (p=0,0001). Também, há uma forte evidência estatística que o modelo quadrático está associado com os valores esperados do teor de DHA (p=0,0013).

INTRODUCTION

Since ancient times chicken embryo eggs, fertile eggs and unfertilized eggs have been used by humans as food and also in the treatment of diseases. From the nutrition point of view, eggs have been always one of the most complete foods available for man (Thapon and Bougeois, 1994). Besides vitamins and mineral elements, eggs can provide three essencial elements for a good diet: proteins, lipids and carbohydrates (Beig and Garcia, 1986).

In recent times, cardiovascular diseases in occidental populations have increased and, consequently, caused an increase in people's interest for foods that have the capacity of preventing these pathologies. Polyunsaturated fatty acids, mainly those of w-3 family, such as docosahexaenoic (DHA), have a very important role in these diseases prevention, because of its property of decreasing the blood pressure and being a reducer of rates of blood plasma's triglycerides (Park et al., 1997). According to Connor (2000), there was a strong evidence of inverse relation between quantity of w-3 fatty acids in diet, blood and tissues, and coronary diseases and their complications. Other effects attributed to w-3 fatty acids included an increase of memory capacity, visual development, and formation of cerebral tissue (Park et al., 1997).

Nettleton (1995) reported that w-3 fatty acids family have shown therapeutic effects also in diabetes Type II. They offer a benefic potential effect because they reduced the triglycerides rates and, interrelation between glucose and lipid oxidation, which acted on prostaglandins and insulin secretion.

w-3 fatty acids, therefore, are considered benefic and researches have been trying to increase their quantity in food, specially eicosapentaenoic (EPA), or docosapentaenoic (DPA) and docosahexaenoic (DHA) (Stadelman and Pratt, 1989). Ferrier et al. (1995) mentioned that eating eggs enriched with w-3 fatty acids produced significant increase in docosahexaenoic acid (DHA) concentration and other polyunsaturated w-3 fatty acids in phospholipid fraction of human blood.

Lin et al. (1991) recommended including w-3 and w-6 in food for children. They pointed out that when only a-linolenic acid was present in diet, it could be deficient in the reserves of DHA in the brain and the retina. Health and Welfare Canada recommend to ingest w-3 fatty acids daily for all ages people, 1.1 g/day for women and 1.5 g/day a-linolenic acid for men (Ferrier et al., 1995). w-3 fatty acids are essential in human pregnancy and childhood. DHA is transferred to fetus by the placenta during pregnancy and it is present in human milk along with other w-3 fatty acids including a-linolenic (Connor, 2000).

Embryo chicken eggs could be a natural source of w-3 fatty acids, mainly of DHA, because several studies have demonstrated that embryo's fatty acids and lipids composition is completely different from original yolk, from which embryo is derived (Speake et al., 1998).

MATERIALS AND METHODS

Preparation of sample units

Chicken embryo eggs (Gallus gallus domesticus L.) were obtained from Isabrown fertile eggs, incubated at 39^oC + 0.5^oC for 0, 3, 5, 7, 9 and 11 days. The Isabrown hens were bred in intensive outdoor raise system, according to Salatin (1993). The shell of incubated eggs was removed aseptically in sterile plates and the stage of development of the embryo was verified.

The remaining content was homogenized, fronzen and freeze-dried using a BagMixer (Interscience, France), a plate freezer (Frigostrella, Brazil) and Micromodulyo Freeze Dryer (Edwards, E-C Apparatus, USA). The freeze-dried product was packed in 30g plastic flasks, sealed and labeled. Samples of the flasks were selected for analysis using random numbers (Vieira and Hoffmann, 1989).

Fatty acids composition

Fatty acids were determined by gas chromatography (AOCS - Ce 1f - 96) adapted by Abril and Barclay (1999), in which fatty acids are identified by comparison of pattern retention times and quantified by areas standardization, using a gas chromatograph (Perkin Elmer 8420) and a capillary silica column (CP-Sil-88, N° 985132, 50 m x 0,25 mm).

Statistical design

For analyzing the statistical data variance analysis with contrasts and regression analysis was applied using software Statistica for Windows version 5.1 and SAS System for Windows version 6.12.

RESULTS AND DISCUSSION

Fatty acids composition in freeze-dried chicken embryo eggs with different incubation periods could be observed at Table 1.

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Table 1 showed that fertile and embryo eggs could be sources of saturated fatty acids: palmitic (average: 23.18 + 0.54%) and stearic (average: 7.70 + 0.28%); unsaturated: palmitoleic (average: 3.00 + 0.19%), oleic (average: 36.28 + 0.58%), linoleic (average: 22.18 + 0.34%), linolenic (average: 1.08 + 0.04%), arachidonic (average: 2.04 + 0.03%) and docosahexaenoic (average: 0.91 + 0.03%). These result were similar with averages values found by Ferrier et al. (1995) for fatty acids composition in eggs used as control.

Bragagnolo and Turatti (1999) found DHA contents in "light eggs" (with reduced lipids and cholesterol and enriched with w-3 acids) around 1.5%. Compared with these results, embryo eggs produced in this work, presented contents of 0,6% lower than enriched eggs available at market.

Fig. 1 shows the contents of w-3 and w-6 fatty acids according to incubation periods in freeze-dried chicken embryo eggs. Results indicated that fertile and embryo eggs could represent a source of polyunsaturated fatty acids, including w-3 fatty acids.

Table 2 shows the variance analysis with contrasts in which there are comparisons of total medium contents of fatty acids w-3 and w-6 in fertile eggs (day 0) with those in embryo eggs (3, 5, 7, 9, and 11).

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There are no significant differences in total medium contents of w-3 fatty acids (p=0.1226), between freeze-dried chicken embryo eggs with different incubation periods (3, 5, 7, 9, and 11 days) and fertile freeze-dried chicken eggs (day 0) (Table 2). These embryo eggs presented a medium content of these acids 0.022% less than fertile eggs. However, there were significant differences in total medium contents of w-6 fatty acids (p=0.0001), between freeze-dried chicken embryo eggs with different incubation periods and freeze-dried fertile eggs. Embryo eggs presented a medium content of these acids 0.294% more than fertile eggs.

Noble and Cocchi (1990) founded that: there were changes in composition of w-6 and w-9 fatty acids during incubation process, the composition and distribution of fatty acids from triglycerides fraction in yolk and of yolk sac membrane remained unaltered and, there were expressive changes in cholesteryl ester fraction and phospholipids. Researches have shown that more than 90% of total energy required by embryo is supplied by b-oxidation of fatty acids derived from yolk lipids (Noble and Cocchi, 1990; Cherian and Sim, 1993 and Speake et al., 1998). Maldjian et al.. (1995) reported that arachidonic acid w-6 was relatively resistant to b-oxidation during the development of the chicken embryo. Cherian et al. (1997) also suggested that concentration of arachidonic acid and docosahexaenoic acid (DHA) were different during incubation. These acids presented a pattern of transference of yolk to embryo different from others and they depended on supply from yolk.

Table 3 and Fig. 2 represented regression analysis and scatter diagram of DHA content in freeze-dried chicken embryo eggs with different incubation periods. There was strong statistical evidence that quadratic model was related to expected values of DHA content (p=0.0006) and it originated the following equation:

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A probable explanation for this model was that: at the 5^th day of development, the phospholipids fractions which contained DHA were preferably removed from the yolk sack before the largest period of the embryo's growth. On the 5^th day of development the yolk sac was already complete and it surrounded the whole yolk. The yolk sack was one of the extra-embryo structures that had the function to remodel lipids structures related to the DHA contents. (Noble and Cocchi, 1990; Speake et al., 1998).

Farkas et al. (1996) have shown that there was a preferential exit of phospholipids that contained DHA from the yolk to the membrane of this structure.There were also evidences, that inside the yolk sac membrane, DHA was changed from the phospholipids fractions of the yolk to lipoproteins triglicerides fractions that became part of the embryo's circulation (Farkas et al., 1996; Cherian et al., 1997; Speake et al., 1998).

Results allowed to deduce that chicken embryo development among 0 and 11 days of incubation didn't change the medium totals contents of w-3 acids, but they changed the medium totals contents of w-6 acids. Starting from 5^th day of incubation, DHA was preferably removed from the yolk before the largest period of the embryo's growth, for being associated to the growth and the development of the tissues and organs of the nervous system. And so, fertile and embryo eggs could be useful in human diet as sources of long chain w-3 (DHA) w-6 (arachidonic acid) fatty acids.

Received: July 29, 2002

Revised: October 09, 2002

Accepted: March 21, 2003

Abril, R. and Barclay, B. (1999), Fatty acid analysis of poultry eggs as methyl esters. OmegaTech. Bolder, Co. Método OT-GCPE, Rev. 3.1 24/03/99.
AOCS (1996), Official methods and recommended practices of de American Oil Chemists' Society. 4^th ed. American Oil Chemists' Society, Champaign II.
Bragagnolo, N. and Turatti, J. M. (1999), Evaluation of "light" eggs in Brazil. Paper presented at VIII European Symposium on the Quality of Eggs and Eggs Products, Bologna, Itália. Associazione Italiana di Avicoltura Scientifica, Instituto di Zootecnia, 2, 177-181.
Beig, D. and Garcia, F. C. M. (1986), O embrião de galinha. Campo Grande : UFMS/ Imprensa Universitária
Cherian,G. and Sim, J. S. (1993), Net transfer and incorporation of yolk n-3 fatty acids into developing chick embryos. Poultry Science, 72, 98-105.
Cherian, G.; Gopalakrishnan, N.; Akiba, Y. and Sim, J. S. (1997), Effect of maternal dietary n-3 fatty acids on the accretion of long-chain polyunsaturated fatty acids in the tissues of developing chick embryo. Biology of Neonate, 72, 165-174.
Connor, W. E. (2000), Importance of n-3 fatty acids in health and disease. American Journal of Clinical Nutrition, 71, 171S-175S. Suppl.
Farkas, K.; Noble, R. C.; Speake, B. K (1996), Development changes in the levels of molecular species of triacylglicerol that contain docosahexaenoic acid in adipose tissue of chick embryo. Comparative Biochemistry and Physiology B-Biochemistry and Molecular Biology, 115, 1-6.
Ferrier, L. K.; Caston, L. J.; Leeson, S.; Squires, J.; Weaver, B. J. and Holub, B.J. (1995), a-linolenic acid - and docosahexaenoic acid - enriched eggs from hens fed flaxseed: influence on blood lipids and platelet phospholipid fatty acids in human. The American Journal of Clinical Nutrition, 62, 81-86.
Lin, D. S.; Connor, W. E. and Anderson, G. J. (1991), The incorporation of n-3 and n-6 essential fatty acids into chicken embryo from eggs yolks having vastly different fatty acid compositions. Pediatric Research, 29, 601-605.
Maldjian, A.; Falkas, K.; Noble, R. C.; Cocchi, M. and Speake, B. K. (1995), The transfer of docosahexaenoic acid from the yolk to the tissues of chicken embryo. Biochimica et Biophysica Acta, 1258, 81-99.
Nettleton, J. A. (1995), Omega-3 fatty acids and health. Chapman and Hall, New York.
Noble, R. C. and Cocchi, M. (1990), Lipid metabolism and the neonatal chicken. Prog. Lipid Res., 29, 107-140.
Park, Y. K; Koo, M. H. and Carvalho, P. O. (1997), Recentes Progressos dos Alimentos Funcionais. Bol. SBCTA, 31
Salatin, J. (1993), Pastured poultry profits. Polyface Swoope, Virginia.
Speake, B. K.; Murray, A. M. B. and Noble, R. C. (1998), Transport and transformations of yolk lipids during development of avian embryo. Prog. Lipid Res., 37, 1-32.
Stadelman, W. J. and Pratt, D. E. (1989), Factors influencing composition the hen's egg. World's Poultry Science Journal, 45, 247-261.
Thapon, J. L. and Bourgeois C. M. (1994), L'oeuf et les ovoproduits. Lavoisier -Technique et Documentation, Paris.
Vieira, S. and Hoffmann, R. (1989), Estatísitica experimental. São Paulo : Atlas

*

Author for correspondence

Publication Dates

Publication in this collection
06 July 2004
Date of issue
June 2004

History

Reviewed
09 Oct 2002
Received
29 July 2002
Accepted
21 Mar 2002

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Abril, R. and Barclay, B. (1999), Fatty acid analysis of poultry eggs as methyl esters. OmegaTech. Bolder, Co. Método OT-GCPE, Rev. 3.1 24/03/99.

[2] AOCS (1996), Official methods and recommended practices of de American Oil Chemists' Society. 4^th ed. American Oil Chemists' Society, Champaign II.

[3] Bragagnolo, N. and Turatti, J. M. (1999), Evaluation of "light" eggs in Brazil. Paper presented at VIII European Symposium on the Quality of Eggs and Eggs Products, Bologna, Itália. Associazione Italiana di Avicoltura Scientifica, Instituto di Zootecnia, 2, 177-181.

[4] Beig, D. and Garcia, F. C. M. (1986), O embrião de galinha. Campo Grande : UFMS/ Imprensa Universitária

[5] Cherian,G. and Sim, J. S. (1993), Net transfer and incorporation of yolk n-3 fatty acids into developing chick embryos. Poultry Science, 72, 98-105.

[6] Cherian, G.; Gopalakrishnan, N.; Akiba, Y. and Sim, J. S. (1997), Effect of maternal dietary n-3 fatty acids on the accretion of long-chain polyunsaturated fatty acids in the tissues of developing chick embryo. Biology of Neonate, 72, 165-174.

[7] Connor, W. E. (2000), Importance of n-3 fatty acids in health and disease. American Journal of Clinical Nutrition, 71, 171S-175S. Suppl.

[8] Farkas, K.; Noble, R. C.; Speake, B. K (1996), Development changes in the levels of molecular species of triacylglicerol that contain docosahexaenoic acid in adipose tissue of chick embryo. Comparative Biochemistry and Physiology B-Biochemistry and Molecular Biology, 115, 1-6.

[9] Ferrier, L. K.; Caston, L. J.; Leeson, S.; Squires, J.; Weaver, B. J. and Holub, B.J. (1995), a-linolenic acid - and docosahexaenoic acid - enriched eggs from hens fed flaxseed: influence on blood lipids and platelet phospholipid fatty acids in human. The American Journal of Clinical Nutrition, 62, 81-86.

[10] Lin, D. S.; Connor, W. E. and Anderson, G. J. (1991), The incorporation of n-3 and n-6 essential fatty acids into chicken embryo from eggs yolks having vastly different fatty acid compositions. Pediatric Research, 29, 601-605.

[11] Maldjian, A.; Falkas, K.; Noble, R. C.; Cocchi, M. and Speake, B. K. (1995), The transfer of docosahexaenoic acid from the yolk to the tissues of chicken embryo. Biochimica et Biophysica Acta, 1258, 81-99.

[12] Nettleton, J. A. (1995), Omega-3 fatty acids and health. Chapman and Hall, New York.

[13] Noble, R. C. and Cocchi, M. (1990), Lipid metabolism and the neonatal chicken. Prog. Lipid Res., 29, 107-140.

[14] Park, Y. K; Koo, M. H. and Carvalho, P. O. (1997), Recentes Progressos dos Alimentos Funcionais. Bol. SBCTA, 31

[15] Salatin, J. (1993), Pastured poultry profits. Polyface Swoope, Virginia.

[16] Speake, B. K.; Murray, A. M. B. and Noble, R. C. (1998), Transport and transformations of yolk lipids during development of avian embryo. Prog. Lipid Res., 37, 1-32.

[17] Stadelman, W. J. and Pratt, D. E. (1989), Factors influencing composition the hen's egg. World's Poultry Science Journal, 45, 247-261.

[18] Thapon, J. L. and Bourgeois C. M. (1994), L'oeuf et les ovoproduits. Lavoisier -Technique et Documentation, Paris.

[19] Vieira, S. and Hoffmann, R. (1989), Estatísitica experimental. São Paulo : Atlas

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Composition of omega-3 and omega-6 fatty acids in freeze-dried chicken embryo eggs with different days of development

Abstracts

Publication Dates

History