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Iron Supplementation in Athletes

DOI:10.2165/00007256-199826040-00001
Authors:
Peter Nielsen at University of Hamburg
Peter Nielsen
Detlef Nachtigall at Chiesi Farmaceutici S.p.A.
Detlef Nachtigall
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Abstract

There is still debate in the literature on whether or not endurance athletes tend to have low iron stores. In this article, we propose that endurance athletes really are at risk of becoming iron deficient due to an imbalance between absorption of dietary iron and exercise-induced iron loss. The purpose of this article is to present a critical review of the literature on iron supplementation in sport. The effect of iron deficiency on performance, its diagnosis and suggestions for treatment are also discussed. Studies of the nutritional status of athletes in various disciplines have shown that male, but not female, athletes clearly achieve the recommended dietary intake of iron (10 to 15 mg/day). This reflects the situation in the general population, with menstruating women being the main risk group for mild iron deficiency, even in developed countries. Whereas the benefit of iron supplementation in athletes with iron deficiency anaemia is well established, this is apparently not true for non-anaemic athletes who have exhausted iron stores alone (prelatent iron deficiency); most of the studies in the literature show no significant changes due to supplementation in the physical capacity of athletes with prelatent iron deficiency. However, the treatment protocols used in some of these studies do not meet the general recommendations for the optimal clinical management of iron deficiency, that is, with respect to adequate daily dosage, mode of administration and treatment period. For future studies, we recommend a prolonged treatment period (≥3 months) with standardised conditions of administration (use of a pharmaceutical iron preparation with known high bioavailability and a dosage of ferrous (Fe++) iron 100 mg/day, taken on an empty stomach). Currently, decisions regarding iron supplementation are best made on the basis of taking care of individual athletes. We believe that there are sufficient arguments to support controlled iron supplementation in all athletes with low serum ferritin levels. Firstly, the development of iron deficiency is prevented. Secondly, the nonspecific upregulation of intestinal metal ion absorption is reverted to normal, thus limiting the hyperabsorption of potentially toxic lead and cadmium even in individuals with mild iron deficiency.
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... Iron deficiency is frequent among endurance athletes with excessive training regimens [8][9][10][11][12][13][14]. The majority of studies have shown an iron deficiency in athletes from a variety of sporting disciplines [15][16][17][18] that require a high level of fitness to sustain proficient, physical, and cognitive functions. A lack of iron can strongly affect physical work capacity by reducing oxygen transport to muscles [1]. ...
... Sweat excretion from eccrine sweat glands is primarily a mechanism of thermoregulation but is also a way the body loses iron [9,27]. For instance, the daily sweat-related iron loss is estimated to be 1-2 mg per 2 h of exercise, equivalent to 1% and 3% of recommended daily intake of iron for women and men respectively [18,[28][29][30]. Iron is necessary for oxygen transport and energy metabolism among endurance athletes to maintain their exercise capacity, and to prevent increased heart rate, shortness of breath, and exhaustion during exercise. ...
Influence of iron supplementation on fatigue, mood states and sweating profiles of healthy non-anemic athletes during a training exercise: A double-blind, randomized, placebo-controlled, parallel-group study
Article
Full-text available
  • Feb 2023
Iron is specifically important to athletes, and attention has grown to the association between sports performance and iron regulation in the daily diets of athletes. The study presents new insights into stress, mood states, fatigue, and sweating behavior among the non-anemic athletes with sweating exercise habits who consumed a routine low dose (3.6 mg/day) of iron supplementation. In this double-blind, randomized, placebo-controlled, parallel-group study, both non-anemic male (N = 51) and female (N = 42) athletes were supplemented either with a known highly bioavailable iron formulation (SunActive® Fe) or placebo during the follow-up training exercise period over four weeks at their respective designated clinical sites. The effect of oral iron consumption was examined on fatigue, stress profiles, as well as the quality of life using the profile of mood state (POMS) test or a visual analog scale (VAS) questionnaire, followed by an exercise and well-being related fatigue-sweat. Also, their monotonic association with stress biomarkers (salivary α-amylase, salivary cortisol, and salivary immunoglobulin A) were determined using spearman's rank correlation coefficient test. Repeated measure multivariate analysis of variance (group by time) revealed that the total mood disturbance (TMD) score was significantly lower (P = 0.016; F = 6.26) between placebo and iron supplementation groups over the four weeks study period among female athletes. Also, a significant reduction in tired feeling/exhaustion after the exercise (P = 0.05; F = 4.07) between the placebo and iron intake groups was noticed. A significant within-group reduction (P ≤ 0.05) was noticed in the degree of sweat among both male and female athletes after 2 and 4 weeks of iron supplementation, while athletes of the placebo intake group experienced a non-significant within-group reduction in the degree of sweat. Overall, the result indicates routine use of low dose (3.6 mg/day) iron supplementation is beneficial for non-anemic endurance athletes to improve stress, mood states, subjective fatigue, and sweating conditions.
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... The repeatability coefficient of variation (%CV) for serum 25(OH)D ranged between 1.9% (54.0 mg/mL) and 6% (11.6 ng/mL), while the %CV for ferritin ranged between 2.1% (392 ng/mL) and 3.8% (12.3 ng/mL) for human serum samples. The diagnostic threshold for serum 25(OH)D insufficiency was ≤30 ng/mL [9,29] while serum ferritin insufficiency was defined as any value ≤35 ng/mL [30]. ...
... This unexpected increase in serum ferritin across both time and sport highlights the complexity of utilizing serum ferritin as a singular marker of tissue (mainly liver) iron stores, as serum ferritin is also an acute phase inflammatory marker [48]. Thus, increases in serum ferritin, as a measure of tissue iron stores across a competitive season, may be confounded by training or competition-induced inflammation, as previously verified in athletes after endurance races [30,49]. The contributions of inflammation to increased serum ferritin levels (non-related to iron storage levels) thereby warrant further investigation using additional inflammatory markers such as hepcidin [3], C-reactive protein, and interleukin-6 [49] in future athlete studies. ...
Paradoxical Relationships between Serum 25(OH)D and Ferritin with Body Composition and Burnout: Variation by Sex and Sports Team
Article
Full-text available
  • Sep 2021
Adequate serum vitamin D and iron levels are thought to influence physical training adaptations and mood positively. The primary purpose of this prospective, observational study was to investigate relationships between serum 25-OH vitamin D/25(OH)D and serum ferritin levels with body composition and athlete burnout symptoms. Seventy-three collegiate athletes (female: n = 49; male: n = 24) from indoor (swimming, basketball) and outdoor (soccer, cross-country) sports were tested pre-season and post-season for serum 25(OH)D and serum ferritin (nutrient biomarkers) via venipuncture; body composition (total lean mass, bone mineral density/BMD, and % body fat) via dual energy X-ray absorptiometry (DXA) scans; and athlete burnout symptoms (post-season) via the athlete burnout questionnaire (ABQ). When male and female cohorts were combined, significant correlations (Pearson’s r) were noted between pre-season serum 25(OH)D versus the change (∆: post-season minus pre-season) in both BMD (r = −0.34; p = 0.0003) and % body fat (r = −0.28; p = 0.015). Serum ferritin ∆ was significantly associated with lean mass ∆ (r = −0.34; p = 0.003). For burnout symptoms, serum 25(OH)D ∆ significantly explained 20.6% of the variance for devaluation of the sport in the male cohort only. Across time, serum 25(OH)D levels decreased while serum ferritin levels increased, non-significantly, in both males and females. Relationships between nutrient biomarkers and body composition were opposite of physiological expectations.
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... All separated serum specimens were sent to the hospital laboratory within 12-hours of venipuncture. The diagnostic threshold for serum 25-OH vitamin D insufficiency was ≤30ng/mL [8,28] while serum ferritin insufficiency was defined as any value ≤35ng/mL [29]. ...
... This unexpected increase in serum ferritin across both time and sport highlights the complexity of utilizing serum ferritin as a singular marker of tissue (mainly liver) iron stores, as serum ferritin is also an acute phase inflammatory marker [43]. Thus, increases in serum ferritin, as a measure of tissue iron stores across a competitive season, may be confounded by training or competition-induced inflammation as previously verified in athletes after endurance races [29,44]. The contributions of inflammation to increased serum ferritin levels (non-related to iron storage levels) thereby warrants further investigation using additional inflammatory markers such as hepcidin [3], C-reactive protein and interleukin-6 [44] in future athlete studies. ...
Changes in Nutrient Biomarkers, Body Composition, and Burnout Symptoms in Collegiate Athletes across a Season
Preprint
Full-text available
  • May 2021
Adequate serum vitamin D and iron levels are thought to positively influence physical training adaptations and mood. The purpose of this prospective, observational, study was to investigate relationships between serum 25-OH vitamin D and serum ferritin levels with body composition and athlete burnout symptoms. Seventy-three collegiate athletes (49 female) from 7 indoor and outdoor sports were tested pre-season and post-season for: nutrient biomarkers (serum 25-OH vitamin D and serum ferritin) via venipuncture; body composition (total lean mass, bone mineral densi-ty/BMD, and % body fat) via dual energy x-ray absorptiometry (DXA) scans; and athlete burnout symptoms (post-season) via the athlete burnout questionnaire (ABQ). When male and female co-horts were combined, significant relationships were noted between pre-season serum 25-OH vit-amin D versus the change (∆: post-season minus pre-season) in both BMD (r=-0.34;p=0.0003) and % body fat (r=-0.28;p=0.015). Serum ferritin ∆ was significantly associated with lean mass ∆ (r=-0.34;p=0.003). For burnout symptoms, serum 25-OH vitamin D ∆ significantly explained 20.6% of the variance for devaluation of sport in the male cohort only. Across time, serum 25-OH vitamin D levels increased while serum ferritin levels decreased, non-significantly, in both males and fe-males. Relationships between nutrient biomarkers and body composition were opposite of physio-logical expectations.
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... Thus, parameters such as maximum oxygen consumption (VO 2 max), maximum aerobic speed (MAS), ventilatory and lactic thresholds, perception of exertion, hemoglobin concentration or the profile of certain leukocyte elements are important determinants to athletic performance [2,3,4] . In the scientific literature, there are many studies which provide information on the normative values of the above-mentioned parameters and therefore require corrections of these when athletes are subjected to exhausting training or which promote the alteration of these biological indicators [5,6,7] . This aspect is particularly frequent in female athletes in view of the particular female physiology that sets in from the age of reproduction [8,9,10] . ...
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... In eumenorrheic females, menstrual bleeding largely contributes to iron losses (Arens, 1945;Hallberg and Nilsson, 1964), with ∼1 mg of iron lost per day during menstrual bleeding (Hallberg et al., 1966). In active females, an additional 3-4 mg/day of iron may be required to replenish exercise-related iron losses (e.g., hemolysis, hematuria, gastrointestinal bleeding, sweating, and dermal losses) (Nielsen and Nachtigall, 1998). The iron demands of exercise, in addition to daily iron losses and menstruation, may result in a negative iron balance, which if not compensated for by either dietary means and/or iron supplementation, increases the risk of iron deficiency with or without anemia in active premenopausal females. ...
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Article
Full-text available
  • Jul 2022
Iron metabolism research in the past decade has identified menstrual blood loss as a key contributor to the prevalence of iron deficiency in premenopausal females. The reproductive hormones estrogen and progesterone influence iron regulation and contribute to variations in iron parameters throughout the menstrual cycle. Despite the high prevalence of iron deficiency in premenopausal females, scant research has investigated female-specific causes and treatments for iron deficiency. In this review, we provide a comprehensive discussion of factors that influence iron status in active premenopausal females, with a focus on the menstrual cycle. We also outline several practical guidelines for monitoring, diagnosing, and treating iron deficiency in premenopausal females. Finally, we highlight several areas for further research to enhance the understanding of iron metabolism in this at-risk population.
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Ergogenic Aids and the Female Athlete
Chapter
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Female athletes tend to choose their supplements for different reasons than their male counterparts. Collegiate female athletes report taking supplements “for their health,” to make up for an inadequate diet, or to have more energy. Multivitamins, herbal substances, protein supplements, amino acids, creatine, fat burners/weight-loss products, caffeine, iron, and calcium are the most frequently used products reported by female athletes. Many female athletes are unclear on when to use a protein supplement, how to use it, and different sources of protein (animal vs. plant-based). This chapter addresses protein supplementation, amino acid supplementation, and creatine. In this chapter we also address the reported performance benefits, if any, of Echinacea, ginseng, caffeine, energy drinks, pre-workouts, and iron. The chapter concludes with a discussion on contamination of supplements and banned substances for competition. Competitive athletes should be aware of the banned substance list for their governing body and that over the counter (OTC) nutritional supplement products are not currently regulated by the food and drug administration (FDA). This lack of regulation may lead to supplements that are contaminated with banned substances.
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Iron Deficiency in Athletes: A Narrative Review
Article
  • Jan 2022
Iron deficiency is a concern for athletes due to potential for performance impairments attributed to lower iron status with, or without, accompanying anemia. Despite the high interest in the topic for endurance athletes and medical providers who care for this population, the evaluation and management of athletes with iron deficiency is still evolving, particularly in relation to iron deficiency non-anemia (IDNA). This narrative review presents causes of iron deficiency in the athlete, clinical presentation, differential diagnoses, diagnostic evaluation, and proposed strategies for treatment. This article is protected by copyright. All rights reserved.
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Cardiorespiratory, hematological and physical performance responses of anemic subjects to iron treatment
Article
Full-text available
  • Oct 1975
Twenty-nine adult iron-deficient anemis subjects (13 men and 16 women) with hemoglobin levels of 4.0 to 12.0 g/100 ml blood were divided into either an iron treatment or placebo group. Hematological, cardiorespiratory and performance data were collected before, during, and after treatment and compared with data from a control group of subjects (4 men and 6 women) from the same socioeconomic population. Hemoglobin levels for the iron treatment group improved from 7.7 to 12.4 g for the women and from 7.1 to 14.0 g for the men. Values for the control group were 13.9 g and 14.3 g for the women and men, respectively. The placebo group showed virtually no change over the 80-day period (8.1-8.4 g for women and 7.7-7.4 g for men). Peak exercise heart rates (5 min, 40-cm step test) were significantly reduced after treatment from 155 to 113 for the iron treatment men and 152 to 123 for the women compared with the placebo group which showed no changes. Values for the control group were 119 and 142 for the men and women, respectively. In response to the exercise test, no difference in oxygen consumption was found between the iron treatment and placebo group although 15% more O2 was delivered per pulse in the iron treatment group. Blood lactates were significantly highein the placebo than iron treatment group both at rest, 1.18 versus 0.64 mmole/liter, and 1 min after exercise, 5.30 versus 2.68 mmoles/liter. No changes in handgrip or shoulder adductor strength were observed following treatment. These results clearly support the concept that performance requiring high oxygen delivery is significantly affected by hemoglobin levels.
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Dietary iron deficiency and sports anaemia
Article
Full-text available
  • Aug 1992
In order to determine whether dietary inadequacies can explain the sub-optimal iron status widely documented in endurance-trained athletes, the food intake records of Fe-deficient and Fe-replete distance runners and non-exercising controls of both sexes were analysed. In all the male study groups the mean dietary Fe intake met the recommended dietary allowances (RDA; > 10 mg/d (US) Food and Nutrition Board, 1989). However, both female athletes and controls failed to meet the RDA with regard to Fe (< 15 mg/d) and folate (< 200 micrograms/d). There was no difference in the total Fe intakes of Fe-deficient and Fe-replete athletes and the controls of each sex. However, Fe-deficient male runners, but not female runners, consumed significantly less haem-Fe (P = 0.048) than their comparative groups. This suggests that the habitual consumption of Fe-poor diets is a factor in the aetiology of athletes' Fe deficiency.
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Effect of an iron supplement on body iron status and aerobic capacity of young training women
Article
Full-text available
Serum iron deficiency has a high incidence in female athletes. We investigated the effects of a daily oral iron supplement, (160 mg) administered during an intensive 7-week physical training programme, on body iron status, and the maximal aerobic capacity (VO2max) of 13 women (group A) compared to 15 who took a placebo (group B). The subjects were 19 years old. Blood samples were obtained before training began and on days 1, 7, 21 and 42 of training. They were analysed for packed cell volume (PVC) and for haemoglobin (Hb), 2,3-diphosphoglycerate (2,3-DPG), haptoglobin, iron and ferritin concentrations. The VO2max was measured on days 0, 21 and 42 of training. Following 21 days of training Hb, PCV and ferritin were significantly higher (P less than or equal to 0.01) in group A compared to group B. Over the training period Hb rose by 9.3% and 2.4% in groups A and B, respectively. At the end of training 66% of group B exhibited ferritin concentrations below 10 ng.ml-1, while none of group A had such low values. Mean VO2max of group A had increased by 7.5% following 21 days of training (P less than or equal to 0.01) and by 15.3% after 42 days. No appreciable increase in VO2max had occurred in group B by day 21 (significantly lower than VO2max of group A; P less than or equal to 0.05), however by day 42 it had increased by 14.3% (P less than or equal to 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)
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Sports Anemia
Article
It is apparent that exercise can influence erythropoiesis and red cell survival in a variety of fascinating ways. A number of mechanisms have been reviewed that could lead to mild changes in the Hb or red cell mean corpuscular volume. In addition, athletes may be at high-risk to develop decreased iron stores. Nevertheless, iron deficiency anemia is uncommon and the ritual of routine iron supplementation is not recommended. Clearly, most of the mechanisms discussed lead to only subtle changes in the overall red cell numbers and indices. Yet there is a small subset of athletes who will have red cell changes that can only be attributable to participation in sports. The diagnosis of sports anemia, however, remains one of exclusion.
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Iron Supplementation and Running Performance in Female Cross-Country Runners
Article
  • Nov 1991
The purpose of this study was to determine the effects of two weeks of high dosage iron supplementation on various blood iron indices and metabolic parameters in non-anemic, iron-depleted competitive female cross-country runners. The subjects were highly trained members of the Colorado State University cross-country team and were completing 40 to 50 miles of training weekly. A pretest, post-test single-blind crossover design was employed. Upon collection of baseline exercise blood and metabolic data, five subjects were randomly assigned to iron supplementation (650 mg ferrous sulfate; 130 mg elemental iron) and five subjects to placebo treatment. At two weeks the treatments were reversed. Exercise blood and metabolic data were collected at two-week intervals. Dietary iron intake was assessed using a three-day dietary survey. Dietary analysis revealed deficiencies in vitamin B-6, iron, magnesium, and zinc according to USRDA standards. Baseline blood samples revealed no deficiencies in iron storage or transport proteins. Two weeks of iron supplementation resulted in no significant increases in blood iron indices. Metabolic parameters related to running performance were also unchanged after iron supplementation. High dosage, short-term iron supplementation appears to have no effect on blood or metabolic parameters in iron-depleted but non-anemic female cross-country runners.
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Development of Runner's Anemia during a 20-Day Road Race: Effect of Iron Supplements
Article
  • Jul 1991
Intense training for long-distance running has been associated with reduced hemoglobin (Hb) levels and low iron stores. Whether iron supplementation helps prevent this “runner's anemia” remains controversial. To determine the relationship between iron status and the early stage of reduced Hb levels in male runners, we examined hematologic variables in 15 healthy men (ages 25 to 47 yrs) who ran twice their regular training distance in 20 days during a 500-km road race. Nine of the runners took iron-containing tablets which provided an average of 36 mg/d of iron, while the other six did not take iron supplements. Only one of the 15 subjects had a low Hb concentration (< 14 g/dl) before the race. After 10 days (285 km), low Hb levels (p < 0.001) were found in 12/15; six of these runners took iron supplements. However, following a 2-day rest period and five more days of running, only 5/15 and 7/15, respectively, had low Hb levels. Serum iron, ferritin, total iron binding capacity, and percent transferrin saturation values remained within normal limits and did not change significantly. Reticulocyte counts progressively increased, becoming 8-fold higher than at baseline (p < 0.001), irrespective of the use of iron supplements. “Runner's anemia” developed in 11/15 (73%) of the subjects, independently of their iron status and iron intake. The reductions in Hb were accompanied by parallel decreases in RBC count and hematocrit, and by a significant reticulocytosis. It was concluded that the development of low Hb levels in these runners was acute in origin, partly reversible with rest, not prevented by iron supplementation, and therefore probably due to a functional hemodilution.
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Effects of training and iron supplementation on iron status of cross-country skiers
Article
  • Jan 1991
We have studied the effects of iron treatment on iron deficient cross-country skiers. Kind and duration of their daily training were also considered. Forty-eight athletes were divided in three balanced groups: Group A received 160 mg ferritinic iron/die, Group B received the same amount of iron and 1 gr of ascorbic acid and Group C was untreated. Blood samples were taken at the start, after two months and four months of supplementation. Hematological and iron status parameters were determined. Average training duration was 80 min a day. Running was the most frequent method of training but also roll and country skiing were commonly used. At the initial sample low serum ferritin values were found in all the three groups (Group A = 23.3 micrograms/l, Group B = 20.9 micrograms/l and Group C = 23.5 micrograms/l). After iron treatment serum ferritin increased in Groups A and B (+67.8% and +63.6% respectively) but was slightly reduced in Group C. Serum iron was unchanged and total iron binding capacity decreased following ferritin increase. Ascorbic acid failed to increase iron absorption in Group B. A significant reduction of haptoglobin (-14% and -9% in Group A and B respectively) was also documented. We conclude that cross-country skiers extensively use running in their training and it may be one of the cause of their poor iron status. Ferritinic iron treatment seems to be effective in replacing iron stores in cross-country skiers who underwent heavy training.
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Iron repletion decreases maximal exercise lactate concentration in female athletes with minimal iron-deficiency anemia
Article
We studied the effect of 2 weeks of iron therapy on exercise performance and exercise-induced lactate production in trained women athletes: six control subjects with normal parameters of iron status and nine with mild iron-deficiency anemia defined by low Fe/TIBC, ferritin, and minimally decreased Hgb values. Iron therapy improved the abnormal measures of iron status and low Hgb in the second group to normal. Exercise performance in a progressive work-exercise protocol on a bicycle ergometer to exhaustion was unchanged after iron therapy in both groups; however, blood lactate levels at maximum exercise in the iron-deficient group decreased significantly from 10.3 +/- 0.6 mmol/L before therapy to 8.42 +/- 0.7 after therapy (p less than 0.03). The control subjects did not significantly alter lactate levels after maximal exercise on iron compared to placebo: 8.3 +/- 0.8 mmol/L vs. 8.5 +/- 0.7. Although there was not a significant difference in maximum exercise performance after iron therapy, these data support animal experiments implying that iron may play a role in oxidative metabolism and that minimal decreases in Hgb may impair arterial oxygen content enough to affect aerobic metabolism. In addition, these findings may have important implications for competitive women athletes in whom mild iron deficiency may go unnoticed.
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