PREVENTION OF MICROELEMENTS DEFICIENCY IN THE BODY OF SWIMMERS

PREVENTION OF MICROELEMENTS DEFICIENCY IN THE BODY OF SWIMMERS

Authors

  • EDUARD FEROYAN Georgian State Educational University of Physical Culture and Sports
  • LALI KOKAIA Patriarchate of Georgia saint King Tamar University
  • NINO TSAGAREISHVILI Tbilisi State Medical University
  • NINO KURDIANI Tbilisi State Medical University

DOI:

https://doi.org/10.52340/jecm.2022.08.19

Keywords:

prevention, microelements, deficiency, swimmers

Abstract

Introduction. As you know, trace elements play an important role in the life of every living cell. Deficiency of trace elements or their unbalanced ratio in food can lead to profound metabolic disorders and cause the development of a number of diseases, including "sports anemia". The content of trace elements in the blood depends on the nature of muscle activity, its volume, intensity and fitness of the body. Under the influence of systematic training, in parallel with the growth of muscles and their need for oxygen, the content of iron, copper, and manganese in the blood cells increases. At the same time, the physical performance of athletes also increases. In the practice of sports, there are very few clear recommendations for the consumption of microelements with food for athletes of various qualifications, age and gender. It is possible to say exactly how much alimentary iron (Fe), copper (Cu) and manganese (Mn) is necessary to satisfy the body's need for microelements only after studying the balance of microelements in the body of athletes, which is the most relevant today.

The purpose of this study was to study the daily balance of microelements in the body of swimmers of high qualification categories.

Research methods. The elemental profile of the organism of the examined contingent was established on the basis of urine analysis (morning, middle portion collected in a special container). The analysis was carried out by inductively coupled argon plasma mass spectrometry (ICP-MS) on a Nexion 300D + NWR213 device (PerkinElmer, USA), as well as the effectiveness of prescribed drugs was assessed by indicators of capillary blood. Hemoglobin and serum iron were determined using the appropriate standard kits, hematocrit and erythrocytes were determined using conventional methods. Statistical processing of the obtained data was carried out using Microsoft Excel XP software packages (MicosoftCorp., USA) and Statistica 6.0 (StatSoft Inc., USA).

Results. In our studies, it was found that the total loss of iron in most cases significantly exceeded the intake of iron with food. During the period of active rest, the absorption of iron from food increased. In most cases, his balance was positive. Through the correct selection of foods rich in trace elements, you can try to influence the balance of trace elements in the body.

Conclusion. Thus, the complexes we offer to a greater or lesser extent have a positive effect on a number of important indicators, and are recommended for the prevention of anemia and, also, are highly effective and, therefore, very promising products for improving physical performance.

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References

Горбачев, А.Л. Физиологическая роль микроэлементов в поддержании физической формы спортсменов. – Магадан: СВГУ, 2018; 65 с.

Евстафьева Е.В., Бояринцева Ю.А., Евстафьева И.А., Перекотий Е.В. Особенности микроэлементного и гемодинамического статуса подростков и юношей с разным уровнем двигательной активности / Российский физиологический журнал им. И.М.Сеченова. Клиническая физиология. 2017; 570-581.

Зайцева И.П., Агаджанян Н.А., Скальный А.В. Влияние профессиональной физической нагрузки различного уровня у девушек-спортсменок на содержание макро- и микроэлементов в различных биоиндикаторных средах // Теория и практика физической культуры. 2016; 6: 45.

Зайцева, И. П., Зайцев О. Н. Изучение влияния профессиональной физической нагрузки на содержание химических элементов в волосах спортсменов (борцов) / Физиология человека. 2019; 45(1): 81-87.

Оберлис Д., Харланд Б., Скальный А. Биологическая роль макро- и микроэлементов у человека и животных. /Наука, СПб. 2008, 544 с.

Радыш И.В., Скальный А.В. Введение в медицинскую элементологию. М.: РУДН, 2015. 200 с.

Скальный А.В. Физиологические аспекты применения макро- и микроэлементов в спорте. Оренбург: ИПК ГОУ ОГУ, 2005. 210 с.

Скальная М.Г., Скальный А.В. Микроэлементы: биологическая роль и значение для медицинской практики. Сообщение 1. Медь // Вопросы биологической, медицинской и фармацевтической химии. 2015; 1:15.

Степанова Е.М., Луговая Е.А. Адаптивные и дизадаптивные перестройки элементной системы организма у спортсменов высокой квалификации/ Человек. Спорт. Медицина. 2020; 20(2):29–37. DOI: 10.14529/hsm200204.

Троегубова Н.А., Рылова Н.В., Самойлов А.С. Микронутриенты в питании спортсменов // Практическая медицина. 2014; 1:46.

Фероян Э., Пучковская С, Немсадзе М, Джаши Т. Применение железосодержащих препаратов в игровых видах спорта. /სამეცნიერო კონფერენციის მასალები. თბილისი. 2006: 46-48.

Bailey R.L., West Jr K.P., Black R.E. The epidemiology of global micronutrient deficiencies // Annals of Nutrition and Metabolism. 2015; 66(2):22.

Doker S., Hazar M., Ulsu M., Okan I. Kafkas E., Bozgelmez I. Influence of training frequency on serum concentrations of some essential trace elements and electrolytes in male swimmers // Biol. Trace Element Res. 2014; 158(1):15-21.

Karakukcu C., Polat Y., Torun Y. A., Pac A. K. The effects of acute and regular exercise on calcium, phosphorus and trace elements in yang amateur boxers. // Clinical laboratory. 2013; 59(5-6): 557-562.

Koehler K., Braun H., Achtzehn S. et al. Iron status in elite young athletes: gender-dependent influences of diet and exercise // European Journal of Applied Physiology. 2012. 112(2):513.

Latunde-Dada G.O. Iron metabolism in athletes - achieving a gold standard // European Journal of Haematology. 2013; 90(1):10.

McClung J.P., Gaffney-Stomberg E., Lee J.J. Female athletes: A population at risk of vitamin and mineral deficiencies affecting health and performance // J. TraceElem. Med. Biol. 2014; 28(4):388.

Pasricha S.R., Low M., Thompson J. et al. Iron supplementation benefits physical performance in women of reproductive age: a systematic review and meta-analysis //J. nutrition. 2014; 144(6): 906.

Speich M., Pineau A., Ballereau F. Minerals, trace elements and related biological variables in athletes and during physical activity // Clin. Chim. Acta. 2001; 312(1–2):1.

Uriu-Adams J., Keen C. L. Copper, oxidative stress, and human health. // Mol. Aspects Med. 2005; 26(4-5): 268-298.

Volpe S.L., Nguyen H. Vitamins, Minerals, and Sport Performance // Ed. Maughan R.J. The Encyclopedia of Sports Medicine: An IOC Medical Commission Publ. John Wiley & Sons Ltd, Chichester, UK. 2013. V.19.

Wang L., Zhang J., Wang J. et al. Effects of high-intensity training and resumed training on macro element and microelement of elite basketball athletes//Biol. Trace Element Res. 2012; 149(2):148-154.

Williams M. H. Dietary supplements and sports performance minerals. // Internat. J. Sport Nutrition. 2005 Jun; 11(2): 43-49.

Zhao J., Fan B., Wu Z. et al. Serum zinc is associated with plasma leptin and Cu–Zn SOD in elite male basketball athletes // J. Trace Elements in Medicine and Biology. 2015; 30:49.

Zheng W., Monnot A. D. Regulation of brain iron and copper homeostasis by brain barrier systems: implication in neurodegenerative diseases // Pharmacology Therapeutics. 2011: 2:177-188.

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Published

2022-12-07

How to Cite

FEROYAN, E., KOKAIA, L., TSAGAREISHVILI, N., & KURDIANI, N. (2022). PREVENTION OF MICROELEMENTS DEFICIENCY IN THE BODY OF SWIMMERS. Experimental and Clinical Medicine Georgia, (8). https://doi.org/10.52340/jecm.2022.08.19

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