RESUMO
Running for an extended period of time can cause severe stress on the body, subsequently damaging skeletal muscle and resulting in changes in blood components. However, few reports have examined vital responses during and after running. This study analyzed inflammatory responses during and after running and changes in stress responses as determined by serial changes in blood components. Venous blood was obtained before starting, 6 h after starting, 12 h after starting, and immediately after finishing 24 h of continuous running. Samples were analyzed for high-sensitivity C-reactive protein (hsCRP), pentraxin 3 (ptx3), white blood cells (WBC), myoglobin, creatine kinase (CK), and hormones. Diet and physical activity were standardized 24 h before and after running. Subjects comprised 16 men who agreed to participate in experimental running on November 8 and 9, 2008, at Tokyo Gakugei University. Mean running distance was 151.32 +/- 32.1 km (range, 83.6-210.0 km) in 24 h. A significant increase in hsCRP was seen from 12 h after starting to completion. Compared to hsCRP, ptx3 gradually increased from before starting to after completion, showing a significant difference between pre and post-run ptx3 levels. WBC count increased significantly until 6 h after starting. Neutrophils in leukocytosis increased significantly during the first 6 h. Eosinophils decreased significantly over the course of the 24 h. Cortisol increased, and testosterone decreased significantly from 6 h after starting. Dehydroepiandrosterone sulfate (DHEA-S), myoglobin, and CK increased over the course of the 24 h. Reactive oxygen metabolites (d-ROMs) changed within the normal range though there was a significant decrease, and biological anti-oxidant potential (BAP) stabilized. Active natural killer cells decreased significantly after 24 h running. Biopyrrin (BPn) increased significantly. Changes in stress oxide were small both during and after running, and adaptation for antioxidation was good. DHEAS, a biomarker of aging, was found to increase over the course of the 24 h, suggesting that controlling decreases in DHEA-S may be possible using exercise, particularly in males. The key finding was that DHEA S levels tended to increase with continuous aerobic exercise.
