A recent study published in Neurobiology of Learning and Memory has revealed that intermittent exercise, akin to the “weekend warrior” pattern, offers lasting cognitive benefits compared to continuous exercise. The research, conducted with mice, found that short bursts of exercise sustained over weeks maintain memory-enhancing effects even after a sedentary delay. These findings shed light on how exercise impacts brain function, offering potential strategies to preserve cognitive abilities over time.
Previous studies have established that physical exercise improves cognition, aiding memory, attention, and learning. However, many of these studies focused on continuous, daily exercise routines, which are often impractical for most people. The “weekend warrior” approach—a pattern of condensed physical activity concentrated into a few days each week—has been linked to cardiovascular benefits in humans.
Yet, its cognitive implications remained unexplored. The researchers aimed to determine whether intermittent exercise could provide comparable or superior benefits to continuous exercise in enhancing memory and brain function.
The study also sought to investigate the molecular mechanisms underlying these effects. In particular, the researchers focused on genes like Acvr1c and Bdnf, which are important for hippocampus-dependent long-term memory formation. By studying mice, the team aimed to uncover how exercise schedules influence both behavioral and molecular outcomes.
To explore the effects of intermittent exercise, the researchers used 48 male mice, all 12 weeks old, housed in either exercise or sedentary cages. The exercise cages included running wheels to allow voluntary physical activity. The mice were divided into three groups based on their exercise regimen:
Half of the mice in each group experienced a seven-day sedentary delay after completing their exercise regimen, while the other half did not. To assess memory, the researchers used a subthreshold Object Location Memory (OLM) task. This test involved placing two identical objects in a chamber and later moving one object to a new location. The mice’s exploration time of the novel location was measured to calculate a discrimination index, which reflects memory performance.
Additionally, the researchers analyzed brain tissue using quantitative PCR to measure levels of Acvr1c and Bdnf in the hippocampus. These genes are known to play key roles in long-term memory and learning.
The findings revealed that both continuous and intermittent exercise enhanced memory compared to the control group. However, the benefits of intermittent exercise proved more enduring. After a seven-day sedentary delay, mice in the intermittent exercise group maintained high memory performance, whereas the cognitive benefits for the continuous exercise group diminished.
Molecular analyses provided further insights. The levels of Acvr1c and Bdnf were persistently elevated in the hippocampi of mice in the intermittent exercise group, even after a week of inactivity. In contrast, these levels dropped in the continuous exercise group after the same delay. Notably, the elevated expression of these genes correlated with better memory performance, suggesting their role in sustaining cognitive benefits.
Interestingly, the amount of running—measured as average daily distance—did not significantly influence memory outcomes. This suggests that the exercise regimen, rather than its intensity, was the critical factor in producing long-lasting cognitive effects.
While the study provides compelling evidence for the cognitive benefits of intermittent exercise, it also has some limitations. First, the research was conducted exclusively on male mice, leaving questions about whether the findings apply equally to females. Past studies have indicated similar cognitive benefits of exercise in female mice, but this specific intermittent regimen warrants further investigation.
Additionally, the study did not explore the exact duration of the cognitive benefits or whether they are cyclical during the sedentary period. Future research could examine how long these benefits persist and whether reintroducing exercise at different intervals amplifies or diminishes the effects. The underlying molecular mechanisms also remain partly unclear, particularly regarding how intermittent exercise primes genes like Acvr1c and Bdnf for prolonged activation.
“Here, we demonstrate persistent cognitive benefits following engagement in intermittent ‘weekend warrior’ exercise. Additionally, we observe molecular correlates of persistence of cognitive function where genes that we know to be critically involved in hippocampus dependent long-term memory, remain up-regulated following a sedentary delay. The persistent exercise regime of the weekend warrior protocol may be more effectively priming specific genes and/or reactivating the molecular memory window more efficiently, thus allowing for longer-lasting cognitive benefits.”
“However, it is unknown whether the benefits are cyclical throughout the 7-day delay, or if the benefits are continuous, nor is the total period that the benefits persist known. Seeing as mRNA data were taken from hippocampal samples 1-hour post-test, future work should assess protein and mRNA levels of these genes of interest during consolidation. Future studies can also investigate the role of Acvr1c and Bdnf IV in the observed cognitive benefits and their associated mechanism. Understanding the optimal parameters for persistent cognitive function and the mechanisms mediating persistent effects will allow for the possible alleviation of cognitive decline or impairments and aid in therapeutic pursuits investigating the mitigation of cognitive ailments.”
The study, “The weekend warrior effect: Consistent intermittent exercise induces persistent cognitive benefits,” was authored by Scott La Tour, Hassan Shaikh, Joy H Beardwood, Agatha S. Augustynski, Marcelo A. Wood, and Ashley A. Keiser.
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