AMJ Vol 7 No 2 2020_200804 Final.indd Althea Medical Journal. 2020;7(2) 61 Correlation between Hemoglobin Concentration and Cardiorespiratory Fitness in Adolescent Sportsmen Billy Leoprayogo,1 Venna,2 Ignatio Rika Haryono,3 Francisca Tjhay4 1School of Medicine and Health Sciences Atma Jaya Catholic University of Indonesia, Indonesia, 2Department of Clinical Pathology School of Medicine and Health Sciences Atma Jaya Catholic University of Indonesia, Indonesia, 3Department of Physiology School of Medicine and Health Sciences Atma Jaya Catholic University of Indonesia, Indonesia, 4Department of Medicine Biology School of Medicine and Health Sciences Atma Jaya Catholic University of Indonesia, Indonesia Correspondence: Francisca Tjhay, Department of Medicine Biology, School of Medicine and Health Sciences Atma Jaya Catholic University of Indonesia, Jl. Pluit Raya No. 2, Penjaringan, Jakarta Utara, Indonesia, E-mail: francisca.tjhay@atmajaya.ac.id AMJ. 2020;7(2):61–4 Abstract Background: Sport is a physical activity that increases human body oxygen demand. Hemoglobin has a major role to fulfill the oxygen demand. The ability to fulfill this demand was also seen as cardiorespiratory fitness. Sportsmen have a high cardiorespiratory fitness due to the intensity and frequency of training. This study aimed to explore the effect of hemoglobin concentration on cardiorespiratory fitness of adolescent sportsmen. Methods: This was a cross-sectional study conducted from October–November 2019. Male badminton and basketball sportsmen aged 15–19 years old in Jakarta and Bogor were recruited (n=72). Hemoglobin concentration was measured with a digital hemoglobinometer. The VO2max was estimated with a beep test. FITNESSGRAM® Performance Standard was used for the classification of cardiorespiratory fitness. The hemoglobin concentration and cardiorespiratory fitness were then analyzed (Spearman and Kruskal-Wallis). Results: There was a correlation between hemoglobin concentration and cardiorespiratory fitness (p=0.001), although the correlation was weak (r=0.38). Kruskal-Wallis analysis showed there was a significant mean difference in hemoglobin concentration on cardiorespiratory fitness groups (p=0.005). Conclusions: The mean of the hemoglobin concentration in the Healthy Fitness Zone (HFZ) cardiorespiratory group is higher than in the Need Improvement (NI) group and the Need Improvement within Health Risk (NI-HR) group. Keywords: Adolescent sportsmen, cardiorespiratory fitness, hemoglobin concentration Introduction Sport is a form of physical activity that is planned and structured, involving various movements of many muscle groups which are done repeatedLy. Sports have a good impact on adolescent’s bodies such as increased bone density, cognitive development, and also an increase in cardiorespiratory fitness which is expressed by an increase in VO2max.1 Basketball and badminton are physical activities.2,3 Both of these exercises increase the body’s oxygen demand because it performs repeated muscle contraction in large quantities for a period of time and both sports require movement from the upper and lower extremities. Hemoglobin is needed to fulfill this need because of its role as the transporter of the oxygen from the lungs to tissues and muscles throughout the body.4 Hemoglobin also acts as a buffer that maintains the pH of the blood to remain in optimal condition for aerobic metabolism.5 Looking at the role of hemoglobin during exercise, hemoglobin concentration also affects the quality of individual cardiorespiratory fitness. The VO2max had an increase of about 1% for each increase in https://doi.org/10.15850/amj.v7n2.1847 Althea Medical Journal. 2020;7(2) 62 AMJ June 2020 Hb concentration by 0.3 g/dL.6 This shows the effect of Hb in cardiorespiratory fitness. This study aimed to explore the correlation between hemoglobin concentration and cardiorespiratory fitness, especially in adolescent sportsmen. Adolescents were targeted to improve their cardiorespiratory fitness by exercising regularly to increase and maintain their physical fitness. Methods This was a cross-sectional study conducted from October–November 2019 among male badminton and basketball players aged 15–19 years old in Jakarta and Bogor. The sampling technique was a snowball sampling until the number of respondents met the sample target. The inclusion criteria were those who were willing to take part in the study after consent and underwent the hemoglobin concentration examination. In brief, the hemoglobin concentration was measured with a digital hemoglobinometer with an azide-methemoglobin method that has been tested for the validity and reliability using within the run and between day methods. The hemoglobin concentration was then grouped into the following; low concentration with Hb <14 g/dL, normal concentration with Hb 14–17.5 g/dL, and high concentration with Hb >17.5 g/dL. Each respondent went through hemoglobin examination before conducting the beep test which was calculated using a quadratic formula model to estimate the VO2max. Cardiorespiratory fitness was then classified with the FITNESSGRAM® Performance Standard classification based on the estimated VO2max. The respondents were then group into cardiorespiratory fitness groups; healthy fitness zone (HFZ), need improvement (NI) group, and need improvement within health risk (NI–HR) group. Table 1 Distribution of Hemoglobin Concentration and Cardiorespiratory Fitness Hemoglobin Concentrationa Total Low Normal High Cardiorespiratory Fitness NI-HR 7 15 2 24 NI 4 17 3 24 HFZ - 19 5 24 Total 11 51 10 72 Note: a = Hemoglobin concentration for male adolescent; Low=Hb concentration <14 g/dL; Normal=Hb concentration =14–17.5 g/dL; High=Hb concentration >17.5 g/dL. The cardiorespiratory fitness was grouped into; NI-HR=need Improvement within health risk, NI = need improvement, HFZ=healthy fitness zone The data obtained were then processed using the SPSS program. Data distribution was tested by the Kolmogorov-Smirnov. When data were not normally distributed, the Spearman correlation test was performed and continued with the Kruskal-Wallis hypothesis test. Results In total, there were 77 male sportsmen recruited, consisting of basketball players and badminton players. Due to rejection in the Hb concentration examination, 5 subjects were excluded, thus, only 72 sportsmen were included for further analysis. The average hemoglobin concentration of these sportsmen was 15.9±1.6 g/dL (range 12.5– 18.7 g/dL). There were 11 sportsmen who had low Hb concentrations, which fall in the cardiorespiratory group of NI–HR (n=7), NI (n=4), but none in the HFZ group. The distribution of hemoglobin concentration among the cardiorespiratory fitness group was shown in Table 1. A correlation test between hemoglobin concentration and cardiorespiratory fitness had shown a value of r=0.38 (p=0.001), suggesting a positive mild correlation between hemoglobin concentration and cardiorespiratory fitness. Table 2 Mean of Hemoglobin Concentration and Cardiorespiratory in Fitness Group Cardiorespiratory Fitness Mean Hb concentration (g/dl) NI-HR 15.3 NI 15.7 HFZ 16.7 Note: NI-HR= need improvement within health risk; NI= need improvement; HFZ= healthy fitness zone Althea Medical Journal. 2020;7(2) 63 There was a different mean of hemoglobin concentration on cardiorespiratory fitness groups (Kruskal-Wallis test, p=0.005). A post hoc analysis was used after the Kruskal-Wallis test to know which group have different mean hemoglobin concentration. It showed a value of p=0.02 for HFZ and NI group, p=0.001 for HFZ and NI-HR group, and p=0.40 for NI and NI-HR group (p<0.05). These results indicated that the HFZ had a significant difference of mean hemoglobin concentration with both NI and NI-HR groups, but between the NI and NI- HR group, no statistical difference was found. The mean hemoglobin concentration of each cardiorespiratory fitness group was shown in Table 2. Discussion Sport is a physical activity which increases the oxygen demand of the human body. There are physiological changes that occur during exercise such as a 1.5 to 2 times increased heart rate than at rest and an increase in respiratory rate from about 16 times/minute up to 60–80 times/minute.7 This physiological change is an attempt that our body does to meet the increase in oxygen consumption that occurs from about 250 ml/minute at rest to 3000–5000 ml/minute when exercising.8 The oxygen needed by the body to meet the increased demand when doing exercise is delivered by hemoglobin. This study has shown that the average hemoglobin concentration is higher in sportsmen with higher cardiorespiratory fitness. Blood composition changes during and after exercise, and there is an effect of exercise on red blood cells oxygen supply ability. Plasma volume is decreased and hematocrit is increased during exercise. The increase of hematocrit occurs relatively due to the blood plasma volume loss. Blood plasma exits the blood vessels into the extracellular space due to a difference in osmotic pressure caused by muscle metabolites and increased capillary hydrostatic pressure.9 Interestingly, another study on the effect of blood donation on cardiorespiratory fitness observed the changes in cardiorespiratory fitness of respondents before and after 450 ml blood donation. Respondents conducted blood tests and beep tests on the first day continued with blood donation on the second day. Second blood test and second beep test on the third day. The study showed that the decline in cardiorespiratory fitness 24 hours after blood donation were generally not visible. However, the group with good cardiorespiratory fitness experienced a significant decline after blood donation.10 The parameter of blood that affects cardiorespiratory fitness is the oxygen- carrying capacity of the blood which is the role of hemoglobin. The recovery of blood volume after 24 hours of blood donation reaches a volume that was almost similar to the beginning, but the hemoglobin concentration was not returned to the initial concentration due to hemodilution. This study showed the same results as there were differences in hemoglobin concentration on the HFZ group with other groups as the HFZ group have better cardiorespiratory fitness than the other groups. The relationship of hemoglobin concentration with cardiorespiratory fitness has shown that VO2max has the strongest relationship with oxygen-carrying capacity from the blood. The parameters that play a major role in the carrying capacity of oxygen are hemoglobin concentration, blood volume, and also the total mass of hemoglobin. The parameter which has the strongest relationship to the oxygen-carrying capacity is the total mass of hemoglobin,11 suggestings that the correlation in this study is weak. Future research is needed to elucidate the cardiorespiratory fitness and their factors that might improve the quality of physical fitness in adolescent sportsmen. There are factors affecting hemoglobin concentration in the blood.12 This study has managed to control these factors which include sportsmen smoking behavior, previous hematological disorders, history of iron supplementation therapy, and history of living in high-altitude places, however, this study has no data of sportsmen’s regular diet to evaluate daily iron intake.13,14 The recommended intake for iron is 10.8–18.4 mg/day.15 Iron intake highly affects hemoglobin concentration, which may cause false positive on the low hemoglobin concentration in the NI–HR group. In conclusion, there is a positive correlation between hemoglobin concentration and cardiorespiratory fitness in sportsmen aged 15–19 years old in this study, especially those in the Healthy Fitness Zone. The hemoglobin concentration varies among sportsmen, which the majority of them within the normal range. 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