Resistance Training Could Enhance Gut Microbiota Health

While noticeable muscle growth, like bulging biceps, is a clear advantage of weightlifting, research indicates that strength training can also be beneficial for your gut microbiota.

No singular cluster of microorganisms ensures good health, yet certain compositions are linked with enhanced medical outcomes, including a stronger immune system and healthier aging. Key players include faecalibacterium, Akkermansia, and Rose Buria Hominis, all of which generate short-chain fatty acids such as butyric acid that support the intestinal lining and combat inflammation.

While diet is undeniably significant, studies suggest that aerobic exercise—like cycling and running—can create an environment favorable for these microbial species to thrive. This may occur via improved blood flow, hormonal shifts, or metabolic by-products associated with physical activity, including lactic acid. Research on resistance training has yielded mixed results; some studies indicate significant changes, while others show negligible effects. “Current research is somewhat limited,” notes Matieu Krauss from the Norwegian Sports Science School in Oslo.

For clarity, Sven Nahnsen, from the University of Tübingen in Germany, along with his team, studied a sizable group of 150 sedentary adults who underwent an eight-week training regimen that included a variety of resistance exercises like lateral pulls, seated rows, chest presses, and leg curls.

In contrast to past research, participants utilized an “intelligent” machine that automatically adjusted weights and range of motion based on individual performance, thereby keeping a meticulous record of progress. “The data is precise as every lift is digitally documented,” shares Nahnsen.

Prior to starting, and at intervals during the program, participants submitted stool samples, which researchers analyzed for genetic and metabolic fingerprints of commonly found gut microorganisms.

Across the group, there was no average alteration in microbiome composition post-program. The outcome seemed to vary based on each individual’s training response, showing a correlation between increased intensity and microbiota changes.

High-achieving participants who reaped significant muscle strength benefits exhibited an increased percentage of faecalibacterium and Rose Buria Hominis by the program’s conclusion. “These species were more abundant in those who gained substantially more strength,” summarized Nahnsen.

The reasons why some individuals responded better to the training compared to others remain ambiguous. One might assume it relates to their effort, yet compliance levels were similar across low and high performers. An alternative explanation could be that successful participants altered their diets following their exercise routines. This lifestyle adjustment could reasonably influence both microbiota and muscle strength. However, despite attempts to account for this through dietary assessments, researchers found no substantial differences in food intake, “a factor we couldn’t completely discount,” according to Nahnsen.

Another intriguing prospect is that the microorganisms themselves may partially facilitate the improvements in strength. In high-performing individuals, changes in the microbiome may enhance the production of short-chain fatty acids, enabling muscles to better respond to the eight-week training regimen. However, Nahnsen emphasizes that this warrants further investigation.

He aspires that this research will serve as a foundation for exploring potential mechanisms. “Our goal was to establish a ‘dictionary’ of microorganisms likely affected by resistance training to assist other researchers in uncovering the mechanisms,” he stated. Strategies to promote beneficial shifts in the microbiota post-training could represent a novel approach to enhancing exercise’s health benefits and sports performance.

It’s worth noting that the trial did not include a control group of participants who remained inactive. Nevertheless, Klaus, who did not participate in the study, is optimistic about the findings. “These results reinforce the idea that exercise positively impacts gut health, regardless of the specific type, and highlight that resistance training can induce microbiome-related changes tied to specific health benefits,” he remarked. “This underscores the importance of integrating both endurance and resistance training into health promotion strategies aimed at improving microbiome health.”