Iron deficiency is prevalent among endurance athletes, particularly females. Low iron may compromise oxygen delivery and physical performance. Vegetarianism, desire for convenience, and perceived health risks associated with red meat contribute to low bioavailable iron intakes. The purpose of this study was to examine if lean beef supplementation would maintain iron status, improve body composition and increase performance of distance runners after 8 weeks. Twenty-eight (14 female) Division-I cross-country runners were stratified by iron status, use of iron supplements, and gender, and randomized into a control (n = 14) and intervention group. All participants maintained their typical diet and consumed a daily multivitamin, while the intervention group consumed 9 ounces of lean beef weekly. Dietary intake (total iron, heme-iron, protein, zinc), body composition, VO 2max, and iron status (hemoglobin, hematocrit, serum iron, serum ferritin, total iron binding capacity [TIBC]) were measured at baseline and post-intervention. The intervention group had greater intakes of total and heme-iron. There were no group differences in amino acids, protein, or calories. Both groups had a significant body fat increase and lean mass decease over time. There was a significant VO 2max increase over time in both groups. There were no group differences due to the intervention in serum ferritin, hemoglobin, serum iron, and TIBC. There was a significant difference in hematocrit between groups as a result of the intervention. In conclusion, increasing bioavailable iron from red meat may have effects on body composition and maintenance of blood iron markers; however, its direct impact on performance among endurance athletes is unclear.
Iron is a trace mineral that plays essential roles in the human system. Two thirds of the iron inside the body is found within hemoglobin, an iron-containing protein found in red blood cells that carries oxygen [
Health professionals have suggested based on previous research findings that athletes, especially females and distance runners, are at risk of developing iron deficiency [
Additional iron intake in a dietary form may be of importance to the endurance athlete to prevent iron depletion with consequences of thus, decreased performance. To increase the amount of bioavailable iron in the diet, prepackaged lean beef would be a convenient option for this population. The justified need for this study is to examine the iron status, body composition and performance of male and female collegiate distance runners, to increase the research knowledge on the most effective supplementation for this population. The specific aim of this study is to examine whether supplementation with a lean beef stick will result in maintenance of iron status, improvement in body composition and increase in performance compared to a multivitamin supplement alone. It was hypothesized that supplementation with increased amounts of lean beef would maintain the iron status, and improve the body composition and performance of collegiate distance runners over an 8-week period.
Twenty-eight (14 males and 14 females) NCAA Division I cross country runners from South Dakota State University, who were 18 - 24 years of age, volunteered to participate. Participant characteristics are listed in
The participants were stratified according to their baseline iron status, current use of iron supplements, and gender, and then randomized into the control or intervention group. All participants continued to exercise per their regular training regimen throughout the 8-week intervention period. The participants randomized to the intervention group were instructed to maintain their typical diet and consume 9 one-ounce servings (255.15 grams per week) of the lean beef supplement per week, along with the supplied daily multivitamin supplement. The control participants were instructed to maintain their typical diet and consume only the daily multivitamin. The provided multivitamin supplement (Equate® Complete Multivitamin/Multimineral Dietary Supplement) contained 18 mg of iron in the form of ferrous fumarate. The provided lean beef supplement (Silver Creek Specialty Meats®, Oshkosh, WI) contained 6% of the RDA for iron. The multivitamin was distributed to all subjects at baseline while the beef supplements were distributed bi-weekly throughout the study duration. Participants were required to complete a weekly calendar to annotate their beef supplement consumption and multivitamin compliance throughout the week. All documentation and collection was monitored by study personnel.
All participants were required to complete a 3-day diet history at baseline and again after the 8-week intervenetion. Participants were instructed to record two regular weekdays and one weekend day. The food records were entered into nutritional analysis software titled Food Processor for Windows, 2006 (Database version 10.2, ESHA Research, Salem, OR). Intakes of calories, carbohydrates, protein, total fat, vitamin C, calcium, zinc, heme and non-heme iron were evaluated, along with other key vitamins and minerals. Heme iron was calculated as 40% of the total iron content in the meat products consumed [
A blood sample was required of all participants at baseline and immediately after the 8-week intervention period. Participants were instructed to refrain from exercise and fast for at least 12 hours prior to their scheduled blood draw. Sampling was performed by qualified personnel using sterile techniques. Duplicate samples of approximately 15 mL of blood were obtained from the antecubital vein via vena puncture. The samples were stored in a freezer (−40˚C) until analysis. The biochemical indicators of iron status assessed included serum ferritin, hemoglobin, hematocrit, serum iron, and total iron binding capacity (TIBC). C-reactive protein levels were measured to indicate the presence of inflammation. For the purpose of this study, serum ferritin levels < 15 µg/L indicated iron deficiency. Iron deficiency anemia was classified by hemoglobin < 12 g/dL for women and < 13 g/dL
for men [1,4]. Additional indicators were also used to evaluate iron status: low serum concentrations (<60 μg/ dL), high TIBC (>400 μg/dL), and low transferrin saturation (<16%).
Body composition was measured via air displacement plethysmography (ADP; Bod Pod Life Measurement Instruments, Concord, CA) using the procedure recommended by the manufacturer.
Subjects performed a VO2max test using the Parvo Medics TrueOne Metabolic System (Sandy, Utah) at baseline and after the 8-week study duration to measure peak oxygen consumption. Participants were instructed to warm up for 5 - 10 minutes at his or her desired pace. The set starting speed varied between participants and was based on current fitness level and 5-kilometer race pace. All females began at 7.0, 7.5, or 8.0 mph and all males began at 8.5, 9.0, or 9.5 mph. The grade of the treadmill (Woodway, Waukesha, WI) remained constant at 1% for the test’s entirety, and the speed was increased 0.5 mph every minute until the subject reached volitional exhaustion. Heart rate and oxygen consumption (VO2) were monitored throughout the test. The VO2max, or maximum amount of oxygen consumed during the test, was recorded for each participant. All participants were advised to perform the baseline and post VO2max test at a similar time of day.
Statistical analysis was performed using statistical software (JMP®7, SAS Institute, Cary, NC, USA). Descriptive statistics were represented by mean ± standard error (SEM). A two-way analysis of variance with time (baseline vs post) and group (control vs intervention) was used to determine the main effect of supplementation on all variables measured. A Tukey post-hoc test was used to identify significant differences when a significant F-ratio was obtained. The level of significance for analyses was set at p < 0.05.
Twenty-eight athletes (intervention = 14, control = 14) from the cross country team completed the 8-week study. The intervention group had greater intakes of total iron and heme-iron due to the consumption of weekly beef supplements (
There was no significant weight change over time, although the body fat percentage in both groups increased significantly (p = 0.034). The percentage of lean mass in both groups deceased significantly over time (p = 0.034). When evaluated by gender, there was a significant difference in weight at baseline between groups of females, with the control females weighing more than the intervention (p = 0.022). No significant change was seen between female groups over time in body fat or lean mass percentage. Among the males there was also a significant difference in weight between groups at baseline, with the intervention males weighing more compared to the control subjects (p = 0.037). The body composition of both male groups, measured as body fat and lean mass percentage was not affected as a result of time.
There was a significant increase in VO2max from baseline to post in all subjects. When evaluated by gender, VO2max increased significantly as an effect of time in both groups of females (p = 0.0008). The VO2max was of near significant increase over time in the male participants (p = 0.058) (
There were no group differences due to the intervention in serum ferritin, hemoglobin, serum iron, and TIBC. There was a group × time significance in hematocrit (p = 0.051). There was a significant decrease due to time in hemoglobin concentration (p = 0.0001) and serum iron
(p = 0.018) (
When the results were evaluated by gender, the females experienced more changes than the males. There was a significant group × time difference between control and intervention female subjects in hematocrit that was not present in the males (p = 0.055). There was a group × time near significance in female TIBC (p = 0.058). The male findings revealed no change in serum ferritin, hematocrit, serum iron, or TIBC in group, time, or group x time effects. There was a significant decrease due to time in hemoglobin (p = 0.029) (
Athletes, particularly females and those involved in endurance sports have an increased tendency to develop iron depletion and deficiency. If untreated and without prevention, iron depletion can eventually develop into anemia, which severely influences training capacity. Even a mild decrease in tissue iron stores appears not only to reduce maximum oxygen uptake and aerobic efficiency, but also lessen endurance capacity [7,8,11]. The body’s demand for iron is elevated in athletes due to the increased turnover and losses through foot strike hemolysis, sweat, and gastrointestinal bleeding [4,12,13]. Continual trauma caused by foot strike is the main source of hemolysis and iron loss during the action of running [
The primary purpose of this study was to determine the effects of lean beef supplementation on the iron status, body composition and performance of male and female collegiate distance runners, in order to increase the research knowledge on the most effective supplementation for this population. At both baseline and post-intervenetion none of the subjects were iron deficient or anemic. Serum ferritin was used to assess iron deficiency, as it is often the parameter most examined for the evaluation of iron status [10,17,21]. In the present study, iron deficiency was defined as a serum ferritin concentration of <15 ug/dl, and anemia was defined as a hemoglobin concentration of <12 g/dl for women and <13 g/dl for men [1,4].
The female subjects experienced a near significant change (p = 0.055) in hematocrit levels as a result of the intervention, where the control females decreased 3.8% in volume and the intervention subjects increased by 14.8% from baseline. The female intervention group revealed a baseline hematocrit level of 35.1 ± 1.4, which is just below the defined normal levels ranging between 36% - 46% [
The documentation completed by each individual and collected by study personnel reported compliance with the intake of the provided vitamin/mineral supplement daily. Compliance with the beef supplementation within the intervention group was positively indicated by an increase in protein, total iron, Fe mg/1000kcals, hemeiron and red meat average intake from baseline to post when compared to the control. This finding is vital for the understanding of potential dietary supplementation
with this at-risk population. The convenience of additional iron intake in the form of lean beef supplementation reveals the present method used may be effective in the prevention of iron depletion through maintenance of iron stores during a training period. There was no significant difference between groups as an effect of the intervention in calorie, protein, or amino acid intakes, which is noteworthy because both groups in this study had fairly high levels of protein intake, reported between 1.4 - 1.7 g/kg. An athlete who consumes calorie and protein amounts within the recommended range throughout an intense training duration is less likely to experience a change in measures of iron status, body composition or performance [4,10,24-27]. The reported significant difference in calcium intake seen in the control group was due to a decrease in the group’s dairy consumption at the post-intervention data collection. Calcium inhibits the absorption of both heme and non-heme iron, and may have the capability to alter serum ferritin concentrations, although only at specific doses of 300 to 600 mg [
When both genders were combined the findings revealed no significant weight change between groups over time, although there was a significant increase in body fat along with a decrease in lean mass. The results of Freidmann et al. [
The performance of both groups experienced a significant increase over time. However, the reported results can be attested as an effect of training, in which both groups increased consistently. Because these athletes were well trained prior to baseline data collection and intervention, their iron status, body composition and performance measures may lack significant change as an effect of the dietary supplementation. The metabolism of iron and protein, composition of adipose and lean mass tissue, as well as maximal oxygen consumption are well-established in this population due to its long-term consistency and maintenance with a regular training schedule [10,27]. This provides reason for an introduction of the present form of a lean beef supplementation at the beginning of a training regime, with the intention of preventing low-iron intakes.
Even though significant differences between groups as an effect of the intervention were not seen, the trends that did occur in the areas of measurement do follow results of current literature. This lack of significance could be due to sample size. It was calculated a sample size of 57 may be needed to be confident in determining differences in iron status. This study was unique in that the measurement of supplementation effects on endurance athletes was completed on individuals during a competitive season, where the athletes involved underwent a common training and competition schedule and lived a similar lifestyle. The subjects were well nourished based on baseline diet histories and well trained prior to baseline data collection. The differences between the results of this study and other studies may be related to the inconsistencies in training status, intensity and duration among subjects in other studies.
In conclusion, endurance athletes, especially women have a tendency to develop low iron stores and iron deficiency. The determination of iron status is difficult to accurately report due to the interaction of various hematological markers with the body’s response to physical activity. Increasing bioavailable iron from red meat may assist in the maintenance of iron stores; however, its direct impact on performance among endurance athletes with a normal iron status is unclear. The change in body composition of this population over the course of a competitive season with the supplementation of lean beef may result in an enhancement in lean mass, although this component requires additional research. The results of this study reveal the willingness of athletes to consume this form of dietary supplementation as part of their training and competition routine. The prevention of iron depletion and deficiency should be emphasized and athletes should be monitored regularly to avoid a potential decrease in health status and performance outcomes.
The funding for this research was provided by the South Dakota Beef Council and the South Dakota Agricultural Experiment Station.