Mij
Senior Member (Voting Rights)
Researchers at the School of Medicine have shown how exercise changes the body at a molecular level and have identified blood markers of fitness.
A flurry of change
Snyder’s team set out to better understand the molecular shifts that underlie changes in physical fitness. The gold standard of medical fitness assessments is a peak VO2 test, which measures a person’s peak oxygen consumption during intense exercise and uses the score as a proxy for aerobic fitness. But Snyder and his team wanted more detail — specifically, about the ways in which exercise initiates change at the molecular level.
They performed VO2 testing for 36 individuals, including Snyder, on a treadmill. Participants, both male and female, had an average body mass index of 29 kilograms/meter squared, and their age range was from 40 to 75 years old. Before the treadmill test, the researchers drew a baseline blood sample. Participants then donned an oxygen-measuring mask and ran at a slight incline until they reached peak oxygen consumption, at which point they stopped and got off the treadmill. The researchers took blood samples from participants 2 minutes, 15 minutes, 30 minutes and 60 minutes after they had reached their peaks.
“All of these measurements allow us to describe a choreography of molecular events that occur after physical exercise,” Snyder said. “We know that exercise causes an array of physiological responses, such as inflammation, metabolism and hormone fluctuation, but these measurements allowed us to characterize those changes in unprecedented detail.”
It turns out that in the first two minutes post-exercise, the body experiences an intense flurry of molecular activity. In most participants, molecular markers of inflammation, tissue healing and oxidative stress, a natural byproduct of metabolism, spiked sharply shortly after hopping off the treadmill, as their bodies began to recover. Molecular markers of metabolism varied, Snyder said. At 2 minutes, blood samples revealed evidence that the body was metabolizing certain amino acids for energy, but it switched to metabolizing glucose, a type of sugar, around 15 minutes. “The body breaks down glycogen as part of its exercise recovery response, so that’s why we see that spike a little later,” Snyder said. Glycogen is a form of stored glucose.
As part of the study, Snyder also compared the molecular response in individuals who were insulin resistant, meaning they’re unable to process glucose properly, with the response in individuals who could process glucose normally. “The main difference we see is that insulin resistant individuals have a dampened immune response post-exercise,” he said.
LINK
A flurry of change
Snyder’s team set out to better understand the molecular shifts that underlie changes in physical fitness. The gold standard of medical fitness assessments is a peak VO2 test, which measures a person’s peak oxygen consumption during intense exercise and uses the score as a proxy for aerobic fitness. But Snyder and his team wanted more detail — specifically, about the ways in which exercise initiates change at the molecular level.
They performed VO2 testing for 36 individuals, including Snyder, on a treadmill. Participants, both male and female, had an average body mass index of 29 kilograms/meter squared, and their age range was from 40 to 75 years old. Before the treadmill test, the researchers drew a baseline blood sample. Participants then donned an oxygen-measuring mask and ran at a slight incline until they reached peak oxygen consumption, at which point they stopped and got off the treadmill. The researchers took blood samples from participants 2 minutes, 15 minutes, 30 minutes and 60 minutes after they had reached their peaks.
“All of these measurements allow us to describe a choreography of molecular events that occur after physical exercise,” Snyder said. “We know that exercise causes an array of physiological responses, such as inflammation, metabolism and hormone fluctuation, but these measurements allowed us to characterize those changes in unprecedented detail.”
It turns out that in the first two minutes post-exercise, the body experiences an intense flurry of molecular activity. In most participants, molecular markers of inflammation, tissue healing and oxidative stress, a natural byproduct of metabolism, spiked sharply shortly after hopping off the treadmill, as their bodies began to recover. Molecular markers of metabolism varied, Snyder said. At 2 minutes, blood samples revealed evidence that the body was metabolizing certain amino acids for energy, but it switched to metabolizing glucose, a type of sugar, around 15 minutes. “The body breaks down glycogen as part of its exercise recovery response, so that’s why we see that spike a little later,” Snyder said. Glycogen is a form of stored glucose.
As part of the study, Snyder also compared the molecular response in individuals who were insulin resistant, meaning they’re unable to process glucose properly, with the response in individuals who could process glucose normally. “The main difference we see is that insulin resistant individuals have a dampened immune response post-exercise,” he said.
LINK
