Anti-fatigue effect of Amarkand on endurance exercise capacity in rats

Fatigue is a complex metabolic state. It has been demonstrated that strenuous exercise leads to increased production of reactive oxygen species which is assistive in dilating blood vessels so as to increase blood flow and supply of oxygen and glucose. However, prolonged state of muscular activity may lower the cellular function by affecting its integrity thereby considered responsible for muscular fatigue during exercise [25]. It is therefore therapeutically attractive to increase intake of antioxidants, which may reduce fatigue and improve endurance as well as performance during exhaustive exercise [26]. Polyphenolic content of selected extracts of Amarkand species are given in Table 1. EO extract showed highest flavonoid and proanthocnidin content, which is accordance with the earlier study that includes high polyphenolic content of EO [12]. While, DBT showed presence of high phenolic content. Overall this data indicates that all the studied plants are rich source of polyphenols.

FST is the most common method frequently used for the evaluation of anti-fatigue properties of test compounds. It can describe the gradual decrease in the force capacity of muscle or the endpoint of a sustained activity, and it can be measured as a reduction in muscular force or exhaustion due to contractile function [1]. To standardize the workload and reduce the swimming time, weights at specific body weight percentages were added to the tail of the animal [27]. Lower and medium doses of DBB extract and EOM treatment groups showed significant increase in swimming time to exhaustion as compared to negative control group was evident after 2 weeks (Fig. 1). Data presented herein indicate that DBB prolongs the swimming time of rats and improved endurance exercise capacity, this activity can be attributed flavonoid and proanthocynidin content in them.

Serum urea nitrogen is the product of energy metabolism. Protein and amino acids undergo stronger catabolic metabolism when the body cannot drive energy from sugar and fats [28]. A delicate balance exists between digestion of proteins and removal of urea from the body. It was reported that SUN is a sensitive parameter to evaluate the competence of human to tolerate physical load. Thus reduced SUN reflects reduced protein metabolism followed by enhanced endurance [29]. Thus, there is direct correlation between serum urea nitrogen in vivo and exercise tolerance. As shown in Table 2, after swimming, content of SUN in EO treated groups were significantly lower (19.46 ± 0.884 mg/dl), followed by DBB treated group as compared to negative control group (26.43 ± 4.928) and other Amarkand extracts treated groups. These results suggest that EO treatment reduces decaying of nitrogenous substances in the body and increased capacity to recover from fatigue.

Creatine in the form of phosphocreatine provides a quick energy source for the cells during exercise. Creatine is often taken as an energy-enhancing, fatigue-reducing supplement [30]. In the Table 2, DBB and EO at 300 mg/kg treated groups have shown significant increase in creatine content as compared to negative control group (p < 0.001), which indicate that EO and DBB treatments may boost energy level and increase resistance to muscular fatigue. Similarly, hemoglobin concentration below normal levels results in impaired oxygen delivery to the tissues and negatively affects endurance exercise capacity [22]. EO and DBB treated groups have shown significant increase in hemoglobin concentration, which is 14.13 ± 0.771 gm% (p < 0.01), 13.75 ± 0.187 gm% (p < 0.05), respectively as compared to negative control group, improving their efficacy to recover from fatigue.

Lactate dehydrogenase (LDH) and Creatine Kinase (CK) levels in serum are key indicators of fatigue. Increased levels of LDH and decrease in CK considered as an indication of cellular necrosis and tissue damage [31]. Conversion of pyruvate to lactate is the main energy source required for intense exercise in a short time under anaerobic condition [2]. Lactate drops the intracellular pH by accumulating within the myocyte, excess lactic acid however, inhibits the contractile activity as well as glycolysis in muscle tissue [32]. Therefore, LDH level is an important marker for the degree of fatigue and workload intensity. After swimming, lactate dehydrogenase levels in DBB treated groups for all the three doses were significantly higher (p < 0.001) than negative control groups and compared to other studied treated groups (Fig. 2).

On the contrary, exercise bouts leads to increase serum CK levels which gradually go back to basal level. Serum CK level is a marker of the functional status of muscle tissue, which also indicate cellular necrosis and acute or chronic muscular injuries. Significant decrease (p < 0.001) in CK level was also observed in EL and DBB treated groups in comparison with negative control group (Fig. 2). Venuprasad et al. [21] indicated lowering of CK levels in O. sanctum extract treated rats. This was attributed with the antifatigue activity of these extracts. These results indicate the beneficial effect of EL in fatigue by accelerated clearing lactate from cells as well as efficient energy utilization with potential scavenging of free radicals.

Glycogen content is an integral determining factor in fatigue. Glycogen is a polysaccharide structure, which represents main storage form of glucose; it functions as the secondary long-term energy storage and forms an energy reserve that can be quickly mobilized to meet a sudden need of glucose [32]. Many studies have observed significant depletion of glycogen in both liver and muscles during exhaustive exercise, which is responsible for the fatigue [3]. After swimming, the concentration of liver glycogen of EO and EL treatment groups were significantly higher than that of negative control group (p <0.05). Carbohydrate-protein supplement is most beneficial during short recovery periods by enhancing the storage of muscle glycogen [33], and it was reported that EO tubers are promoted as a carbohydrate supplement [14]; it is a source of fibres, proteins and contribute greatly towards meeting human nutritional requirements [34]. Muscle glycogen is the major fuel used during sustained exercise. Depletion of glycogen results in reduction in the rate of ATP regeneration and impaired contractile activity of the muscle [35]. DBB (p <0.01) followed by EL (p <0.05) treatment groups showed significant increase in muscle glycogen than that of the negative control group (Fig. 3). As previous studies showed that D. bulbifera have antihyperglycemic, antidyslipidemic effect by lowering glycemic index, it provides more sustained form of energy and better protection from obesity and diabetes [15]. Our data indicates that administrations of EO, EL and DBB extracts significantly increases glycogen reserves in liver as well as muscle or at least minimize its utilization.

Lipid peroxidation is an indicator of oxidative damage. It has been implicated in a variety of diseased state and responsible for increasing inflammation [36]. Metabolite produced during the lipid peroxidation process can be used as the method to attribute oxidized injury. Malondialdehyde (MDA) is a product of both lipid peroxidation and of prostaglandin biosynthesis. Thus its evaluation indicates oxidative damage to cell membrane lipids [37]. The content of MDA in liver tissue for DBBM and EOM treated groups were significantly lower than that of the control group (p <0.001). Similarly, EO treatment effectively lowers the MDA content in muscle tissues (p <0.001) Fig. 4. This study has revealed a significant effect on lipid peroxidation by EO and DBB treatment in rats which suggests its protective effect. It was described earlier by Pessoa et al., [38], that as a natural antioxidant, some components of DBB upregulate antioxidant enzyme activities by reducing lipid peroxidation as DBB also have analgesic and anti inflammatory potential [16].

In summary, our data suggested that methanol extracts of DBB, EO and EL has highest polyphenolic content. Presence of polyphenols may suggest their involvement in the anti-fatigue effects in rats. Further, DBB, EL and EO treatment extend the swimming time to exhaustion by activating the energy metabolism by increasing or maintaining the content of glycogen in liver and muscle. They help eliminate the accumulated products like SUN, lactic acid and decrease the CK activity as well as inhibit lipid peroxidation in liver and muscle tissues. They also maintain the Cr and Hb content, which may facilitate recovery from fatigue.