Iron's significance in human health and diseases has been extensively examined in recent reviews, leading to the consensus that iron insufficiency is a worldwide issue requiring immediate attention. Fe-enriched eggs are significant for delivering this essential trace mineral to humans. This study aimed to assess the effects of adding premix minerals on the physical and chemical quality of eggs and the yolk's iron levels. 1,680 Lohman brown laying hens, aged 31 weeks (body weight: 1.70±0.11 kg, egg production average: 81.2 %), were divided into two groups (n = 840) and fed different diets for six weeks. The diets included a basal diet (CON) and a diet enriched with a 2.5 g / kg food premix mineral (PM-Fe). The findings indicated that there was no impact on the physical and chemical quality of the eggs. However, compared to the control diet, the addition of premix significantly enhanced the iron level in the yolk after 42 days (p<0.05). To summarize, adding 2.5 g per kg of premix mineral (which contains 12.6 g per kg of iron premix) can result in a 23.4% rise in iron content in the diet and a 15.7% increase in iron content in the egg yolk.

AOAC, 2005. Official Methods of Analysis of the Association of Official Analytical Chemists 20th ed. Assoc. off. Anal. Chem. Washington, D.C

Bai, S., S. Cao, X. Ma, X. Li, X. Liao, L. Zhang, M. Zhang, R. Zhang, S. Hou, X. Luo and L. Lu. 2021. Organic iron absorption and expression of related transporters in the small intestine of broilers. Poult. Sci. 100, p.101182.

Buckiuniene, V., M. A. Grashorn, R. Gruzauskas, V. Kliseviciute, A. Raceviciute-Stupeliene, G. Svirmickas, S. Bliznikas, A. Miezeliene and G. Alencikiene. 2016. Effect of organic and inorganic iron in the diet on yolk iron content, fatty acids profile, malondialdehyde concentration, and sensory quality of chicken eggs. European Poultry Science/Archiv für Geflügelkunde. 80.

Choi, I., C. Jung, H. Seog, H. Choi. 2004. Purification of phosvitin from egg yolk and determination of its physicochemical properties. Food Sci. Biotechnol. 13, 434–437.

Fuqua, B.K., C. D. Vulpe, G. Anderson. 2012. Intestinal iron absorption. J. Trace Elem. Med. Biol., 26:115–119

Graham, R. M., A. C. Chua, K. W. Carter, R. D. Delima, D. Johnstone, C. E. Herbison. 2010 Hepatic iron loading in mice increases cholesterol biosynthesis. Hepatology. 52, 462–471.

Grotto, H. Z. W. 2008. Metabolismo do ferro: Uma revisão sobre os principais mecanismos envolvidos em sua homeostase. Revista Brasileira de Hematologia e Hemoterapia. 30, 390 – 397.

Grzeszczak, K., S. Kwiatkowski, and D. Kosik-Bogacka. 2020. The role of fe, zn, and cu in pregnancy. Biomolecules. 10, 1–33.

Henry, P. R., and E. R. Miller. 1995. Iron bioavailability. In: Bioavailability of Nutrients for Animals. Elsevier. p. 169–199.

Indonesian Ministry of Health. 2018. Laporan Nasional Riskesdas 2018. Jakarta.

Korish, M. A., and Y. A. Attia. 2020. Evaluation of heavy metal content in feed, litter, meat, meat products, liver, and table eggs of chickens. Animals. 10.

Kundu D, A. Roy, T. Mandal, U. Bandyopadhyay, E. Ghosh, and D. Ray. 2013. Relation of iron stores to oxidative stress in type 2 diabetes. Niger J Clin Pract. 16, 100–103.

Lesnierowski, G., and J. Stangierski. 2018. What’s new in chicken egg research and technology for human health promotion? - A review. Trends Food Sci. Technol. 71, 46–51.

Márquez-Ibarra, A., M. Huerta, S. Villalpando-Hernández, M. Ríos-Silva, M. I. Díaz-Reval, H. Cruzblanca, E. Mancilla, and X. Trujillo. 2016. The effects of dietary iron and capsaicin on hemoglobin, blood glucose, insulin tolerance, cholesterol, and triglycerides, in healthy and diabetic Wistar rats. PloS one. 11, e0152625.

Mezzaroba, L., D. F. Alfieri, A. N. Colado Simão, and E. M. Vissoci Reiche. 2019. The role of zinc, copper, manganese and iron in neurodegenerative diseases. Neurotoxicology. 74, 230-241.

Paik, I., H. Lee, and S. Park. 2009. Effects of organic iron supplementation on the performance and iron content in the egg yolk of laying hens. J. Poult. Sci. 46, 198–202.

Park, S. W., H. Namkung, H. J. Ahn, and I. K. Paik. 2004. Production of iron enriched eggs of Laying Hens. Asian-Australas J. Anim. Sci. 17, 1725–1728.

Rajpathak, S.N., J. P. Crandall, J. Wylie-Rosett, G. C. Kabat, T. E. Rohan, F. B. Hu. 2009. The role of iron in type 2 diabetes in humans. Biochem Biophys Acta. 1790, 671–681.

Sanlier, N., and D. Üstün. 2021. Egg consumption and health effects: A narrative review. J. Food. Sci. 86, 4250–4261.

Sarlak, S., A. S. Tabeidian, M. Toghyani, A. D. F. Shahraki, M. Goli, and M. Habibian. 2021. Effects of replacing inorganic with organic iron on performance, egg quality, serum and egg yolk lipids, antioxidant status, and iron accumulation in eggs of laying hens. Biol. Trace Elem. Res. 199, 1986–1999.

Siró, I., E. Kápolna, B. Kápolna, and A. Lugasi. 2008. Functional food. Product development, marketing and consumer acceptance—A review. Appetite. 51, 456–467.

SNI. 2021. How to test for metal content in solid waste, sediment and soil test samples by acid deconstruction method using an Atomic Absorption Spectrometer (AAS) or an Inductively Coupled Plasma Optical Emission Spectrometric (ICP-OES). Badan Standardisasi Nasional. Jakarta.

Soppi, E. T. 2018. Iron deficiency without anemia - a clinical challenge. Clin. Case Rep. 6, 1082–1086.

Whittaker, P., and R. F. Chanderbhan. 2001. Effect of increasing iron supplementation on blood lipids in rats. Br. J. Nutr. 86, 587–592.

WHO. 2019. Anemia in women and children. Geneva.

Xie, C., H. A. M. Elwan, S. S. Elnesr, X. Y. Dong, and X. T. Zou. 2019. Effect of iron glycine chelate supplementation on egg quality and egg iron enrichment in laying hens. Poult. Sci. 98, 7101–7109.

Zhao, D., C. Zhang, J. Ma, J. Li, Z. Li, and C. Huo. 2022. Risk factors for iron deficiency and iron deficiency anemia in pregnant women from plateau region and their impact on pregnancy outcome. Am. J. Transl. Res. 14, 4146-4153.