Phagocytic responses of peritoneal macrophages and neutrophils are different in rats following prolonged exercise

OBJECTIVE: To analyze the effects of exhausting long-duration physical exercise (swimming) sessions of different durations and intensities on the number and phagocytic capacity of macrophages and neutrophils in sedentary rats. INTRODUCTION: Exercise intensity, duration and frequency are important factors in determining immune response to physical effort. Thus, the effects of exhausting long-duration exercise are unclear. METHODS: Wistar rats were divided into two groups: an untreated group (macrophage study) and oyster glycogen-treated rats (neutrophil study). In each group, the animals were subdivided into five groups (10 rats per group): unexercised controls, an unadapted low-intensity exercise group, an unadapted moderate-intensity exercise group, a preadapted low-intensity exercise group and a preadapted moderate-intensity exercise group. All exercises were performed to exhaustion, and preadaptation consisted of 5, 15, 30 and 45 min sessions. RESULTS: Macrophage study: the number of peritoneal macrophages significantly decreased (9.22 ± 1.78 x 10(6)) after unadapted exercise but increased (21.50 ± 0.63 x 10(6)) after preadapted low-intensity exercise, with no changes in the moderate-intensity exercise group. Phagocytic capacity, however, increased by more than 80 percent in all exercise groups (low/moderate, unadapted/preadapted). Neutrophil study: the number of peritoneal neutrophils significantly decreased after unadapted (29.20 ± 3.34 x 10(6)) and preadapted (50.00 ± 3.53 x 10(6)) low-intensity exercise but increased after unadapted (127.60 ± 5.14 x 10(6)) and preadapted (221.80 ± 14.85 x 10(6)) moderate exercise. Neutrophil phagocytic capacity decreased by 63 percent after unadapted moderate exercise but increased by 90 percent after corresponding preadapted sessions, with no changes in the low-intensity exercise groups. CONCLUSION: Neutrophils and macrophages of sedentary rats respond differently to exercise-induced stress. Adaptation sessions reduce exercise-induced stress on the immune system.

A simple quantitative in vitro macrophage migration assay.

An in vitro macrophage chemotaxis model using mouse peritoneal non-elicited resident macrophage cells and chemotaxins containing mediators of non-specific elicitors such as oyster glycogen or sodium caseinate has been described. Macrophage cells accumulation in mouse peritoneal cavity was maximum at 48 hr after injecting (i.p.) oyster glycogen (2.5%) or sodium caseinate (12%), 0.5 ml/mouse. Chemotaxins containing mediators were prepared from these mice by peritoneal lavage and termed as routine 'diluted' cocktail and 'concentrated (3 times)' cocktail. Chemotaxis assays were carried out in a modified Boyden chamber using a 48-well microchemotaxis assembly. In vitro results showed higher macrophage chemotaxis response against the 'concentrated' cocktails as compared to routine 'diluted' cocktail. Macrophages exhibited cell density dependent increase in the responsiveness to chemoattractant and macrophage cell density of 4 x 10(6) per ml concentration in the upperwell was found to be optimum. Macrophage responsiveness was seen better with sodium caseinate cocktail as compared to oyster glycogen in vitro as well as in vivo. DMSO (Dimethyl Sulphoxide) solvent (0.25% conc.) did not interfere with normal macrophage chemotaxis. Both CO2 incubator (5% CO2 in air) and BOD incubator with humidified chamber favoured chemotaxis. In vitro test system described can be used as a model to study the effect of anti-inflammatory compounds directly on the macrophage chemotaxis.