Tag: cardiac output

Categories : Cardiovascular Disease ExerciseTags :

Swimming Beats Running for Strengthening the Heart, Study Finds

On By ModernMedia
Photo by Kampus Production

By Maria Fernanda Ziegler  |  Agência FAPESP – A study conducted on an animal model by researchers at the Federal University of São Paulo (UNIFESP) in Brazil demonstrated that swimming is more effective than running in promoting healthy heart growth and improving the strength with which the heart muscle (myocardium) contracts.

“Swimming and running are two excellent ways to improve cardiorespiratory health and protect the heart muscle, but we wanted to know if one could be even more beneficial than the other. We found that, although both increase respiratory capacity, swimming goes a step further by combining functional and molecular adaptations that make the heart stronger and more efficient,” says Andrey Jorge Serra, a professor at UNIFESP and coordinator of the study supported by FAPESP

The study, published in the journal Scientific Reports, demonstrates that swimming promotes greater modulation of microRNAs that control various heart adaptations, such as cardiac cell growth, the formation of new blood vessels (angiogenesis), protection against cell death, and the regulation of contractility and responses to oxidative stress, compared to running training.

MicroRNAs are molecules that regulate the expression of messenger RNAs, which are responsible for protein synthesis.

“Although several studies had already examined the expression of microRNAs regulated by aerobic training in general, little was known about expression patterns when swimming and running were compared in the same experimental setting. Therefore, this study reveals that there’s a distinction in cardiovascular effects between these two modalities,” says Serra.

In the study, the mice underwent an eight-week training protocol consisting of daily 60-minute sessions five days a week. The rats were divided into three groups: one that did not train, one that only ran, and one that only swam. Since running and swimming are very different forms of exercise, the comparison between the training regimens was not based on the speed the animals reached but rather on the relative intensity of the effort, as measured by maximum oxygen consumption (VO₂ max) – an indicator that assesses the body’s ability to capture, transport, and utilize oxygen during physical activity.

According to the results, running and swimming improved physical fitness similarly: between the first and last training sessions, VO₂ max increased by more than 5%. However, only swimming promoted significant structural changes in the heart, such as increases in cardiac and left ventricular mass. Running did not show relevant differences compared to the sedentary animals.

“People’s choice of sport depends largely on personal preference, aptitude, and enjoyment. But our results show that swimming may have a special impact in situations involving myocardial recovery, cardiac rehabilitation, and above all, scientific research. This is also relevant because studies on aerobic exercise often use running and swimming interchangeably, and we now know that the effects aren’t the same,” Serra explains.

Before and after the training period, the researchers administered a series of tests to evaluate various aspects of cardiac health, including cardiorespiratory capacity, fitness, and the structure and function of the heart and myocardium.

The study also analyzed the gene expression and protein pathways involved in physiological cardiac hypertrophy and the mechanisms involved in identifying regulatory microRNAs.

“Although we don’t yet know why this change occurs at the molecular level, of the microRNA, we were able to delve deeply into and investigate the molecular pathways that control physiological hypertrophy,” the researcher adds.

The article “Swimming is superior to running in inducing physiological cardiac hypertrophy and enhancing myocardial performance” can be read at nature.com/articles/s41598-026-36818-2.

Source: FAPESP

Categories : Medical Research & TechnologyTags :

The Vagus Nerve also Plays a ‘Fight or Flight’ Role for the Heart

On By ModernMedia
Photo by Stephen Andrews

Researchers have reported in Circulation that the vagus nerve, known for its parasympathetic role in ‘resting and digesting’, also has an important role in exercise, helping the heart pump blood.

Exercise science currently holds that the ‘fight or flight’ (sympathetic) nervous system is active during exercise, helping the heart beat harder, and the ‘rest and digest’ (parasympathetic) nervous system is lowered or inactive. However, University of Auckland physiology Associate Professor Rohit Ramchandra says that this current understanding is based on indirect estimates and a number of assumptions which this new study has proven to be wrong.

“Our study finds the activity in these ‘rest and digest’ vagal nerves actually increases during exercise,” Dr Ramchandra says. “Our group has used ‘tour de force’ electrical recording techniques to directly monitor vagal nerve activity in exercising sheep and has found the activity in these vagal nerves going to the heart increases during exercise.

”For the heart to sustain a high level of pumping, it needs a greater blood flow during exercise to fuel the increased work it is doing: our data indicate that the increase in vagal activity does just this.”

During exercise, there is a four to five-fold increase in the amount of blood pumped out by the heart per minute, requiring increased cardiac output. This is modulated by autonomic nerves that travel from the brain, including the sympathetic and parasympathetic vagal nerves.

The vagal nerve connects the brain to the heart, and other internal organs including the gut, regulating the ‘rest and digest’ parasympathetic nervous system responses. The new research finds the parasympathetic and sympathetic nervous systems work together in exercise to help increase cardiac output. The researchers also investigated the role of mediators released by the cardiac vagal nerve.

“The cardiac vagus nerve releases multiple mediators, and previous research has focused on a neurotransmitter, acetylcholine, which has no impact on our ability to exercise,” says Dr Ramchandra. “Our study focused on a different mediator, vasoactive intestinal peptide (VIP) and it shows that the vagus nerve releases this peptide during exercise, which helps the coronary vessels dilate allowing more blood to pump through the heart.”

The first and co-corresponding author Dr Julia Shanks says, “Vasoactive intestinal peptide was first found in the gut and it does help in digestion, but what we now know is that it is also important in exercise.”

The trial was conducted in sheep, because of their similarity to humans in many important respects including cardiac anatomy and physiology. They are also well-established as an animal model to assist with finding ways to combat heart disease that translate to humans.

These fundamental findings could have applications in diseases, including heart failure, where people cannot tolerate exercise.

“This inability to carry out simple tasks involving exertion means that quality of life is severely compromised in these patients,” Dr Ramchandra says. “One potential reason why exercise tolerance is reduced is that the diseased heart simply does not receive enough blood. Our follow-up study will try to see whether we can use this important role of cardiac vagal nerves to improve exercise tolerance in heart failure.”

There is a lot of interest in trying to ‘hack’ or improve vagal tone as a means to reduce anxiety. Investigating this was outside the scope of the current study.

Dr Ramchandra says we do know that the vagus mediates the slowing down of heart rate and if we have high vagal activity, then our hearts should beat slower.

“Whether this is the same as relaxation, I am not sure, but we can say that regular exercise can improve vagal activity and has beneficial effects.”

Source: University of Auckland