A team of biomedical engineers from Duke University have shown that human muscle possesses the natural ability to fend off some of the damage caused by chronic inflammation through exercise. Their discovery was manifested when they used engineered, grown in the lab human muscle.

There are a variety of processes that take place throughout the body through exercise. It can be somewhat difficult to differentiate which cells and systems are performing what inside the body of an active human. The team can mix and match a variety of cell types and tissue components from their engineered muscle platform and in the recent study, their discovery showed the muscle cells were able to take on anti-inflammatory measures on their own.

Inflammation can be good or bad. When a person injures their body, the first response is a low level inflammation reaction that will clear out debris and help in the rebuilding of tissue. As a response in other times, the body’s immune system will overreact and begins creating an inflammatory response that leads to damage. This is often the case in some COVID-19 situations where a deadly cytokine storm occurs. Additionally, there are a variety of diseases that also bring on chronic inflammation such as sarcopenia and rheumatoid arthritis which can lead to the wasting away of muscle and weakening its capability to contract.

There are a large variety of molecules which can lead to inflammation. Interferon gamma is a molecule that is pro-inflammatory and has been linked to a variety of muscle dysfunction and wasting. Earlier research in both animals and humans has exhibited that in general, exercising can assist in mitigating some of the results of inflammation. However, it has been challenging to differentiate what particular role these cells might play and also how they can be interacting with particular offending molecules for example, interferon gamma.

It is well known that diseases that are chronically inflammatory encourage muscles to atrophy. The team set out to see if the identical thing would occur in their engineered human muscle that was grown in the lab in a Petri dish. They not only confirmed that interferon gamma mostly works via a specific signaling pathway, they also were able to show that through exercising the muscle cells they were able to directly counter the pro-inflammatory signaling pathway separate from the presence of other tissues and cell types.

The team then set out to show proof that muscle by itself is able to block the destructive effects of interferon gamma. They used an engineered muscle platform which the lab had been developing over the previous decade. They initially grew functional, contracting human skeletal muscle in the lab and then began improving their processes by adding reservoirs of stem cells and immune cells to the mix.

The team involved in the recent study, utilized the lab-grown, fully functional muscles and overwhelmed them with high levels of interferon gamma for a period of seven days in order to copy the effects caused by long lasting periods of chronic inflammation. As the team expected, the muscle lost a large amount of its strength and it also became smaller.

They then reapplied the interferon gamma, however this time they also used a pair of electrodes to simulate an exercise regime on the muscle. They discovered that this procedure just about completely prevented the results of chronic inflammation. They also demonstrated that the simulated exercise on the muscle inhibited a particular molecular pathway contained in the muscle cells. They also showed that two particular medications that are used to treat rheumatoid arthritis also blocked the same pathway which resulted in the identical anti-inflammatory effects.

When the muscle cells were exercised, the muscles specifically were directly rivaling the pro-inflammatory signal that was being induced by interferon gamma quite to the surprise of the team. The results indicate how beneficial human muscles that are grown in the lab could be in the discovery of novel mechanisms that occur in disease and ultimately finding possible treatments. There certainly are thoughts that regimes and optimal levels of exercise could be a tool in fighting chronic inflammation while at the same time deterring over stressing cells. The hope is by using the lab engineered muscle, researchers will be able to find out if their notions could be true.

To view the original scientific study click below

Exercise Mimetics and JAK Inhibition Attenuate IFN-induced Wasting in Engineered Human Skeletal Muscle

A recent study from the University of Saskatchewan (USask) has shown that stretching is more effective and superior to brisk walks for reducing blood pressure in people who have high blood pressure or could be at risk of developing high blood pressure. The team found that just 30 minutes of stretching for 5 days each week resulted in better improvements in blood pressure over a 30 minute walk for 5 days of the week.

The CDC reports that about 45% of adults in the U.S. which equates to about 108 million people have hypertension. In 2018, hypertension was either a contributing cause or a primary cause of almost half a million deaths. And according to the National Heart, Lung and Blood Institute, uncontrolled or undiagnosed hypertension can result in a variety of diseases including chronic kidney disease, cardiovascular disease, vascular dementia and eye damage.

Health care professionals will typically recommend aerobic exercise to lower blood pressure. However, earlier research has shown that stretching might lower blood pressure due to improved blood flow and reduced stiffness of arteries. Stretching is not just about stretching muscles. When you stretch you are also stretching the blood vessels that feed into muscle, including all arteries. By reducing stiffness of arteries, there is less resistance to the flow of blood. Resistance to blood flow will increase blood pressure.

The current study by USask researchers is the first to test walking against stretching in a head-to-head comparison in the identical group of participants. The team randomly assigned 40 females and males with a mean age of 61 to two groups for an eight week study period. One group participated in a whole body stretching routine for 30 minutes each day for 5 days per week. The other group participated in brisk walks for the same amount of time and frequency. Every participant had elevated blood pressure or had stage 1 hypertension at the beginning of the study.

The stretching routine consisted of 21 stretching exercises with each participant performing each stretch two times while holding each stretch for 30 seconds and with a 15 second rest period between stretches.

The participants in the walking routine were asked to monitor their pulse and increase their pace if their pulse fell short of 50-65% of the maximum heart rate for their age.

All participant’s blood pressure was measured at both the beginning and at the end of the 8-week program utilizing three different techniques – one with a sphygmomanometer while the person sat down, one using the same meter while the person was lying down, and one with an automatic ambulatory blood pressure monitor which was set to take readings in 20 minutes intervals during waking time and in 45 minute intervals during sleep.

When compared to brisk walking, stretching resulted in greater reductions in blood pressure across all three types of the measurements. The study did show that the walkers lost more body fat from their waist over the 8 week period. The two different groups did not differ in their overall levels of activity outside their 30 minute daily routines. This indicates that the group participants did not compensate by adjusting or changing their usual levels of activity.

People who walk for help in reducing their blood pressure should continue to do so, but think about adding in some sessions of stretching. People should not come away from the research thinking they should not be participating in some kind of aerobic activity such as biking, walking, etc. All these activities have positive effects on blood sugar, cholesterol levels and body fat.

While the research protocol had the participants stretching for 30 minutes each time, the team suspects people can still benefit the same from shorter routines that emphasize the larger groups of muscles in the legs, in particular the hamstrings and the quadriceps. Yoga has been shown to product similar reductions in blood pressure.

The advantage to stretching is that it can be easily incorporated into a person’s daily routine, it doesn’t put people at the mercy of the weather, it is easy on the joints, and does not require a big commitment of time.

The team is currently seeking funding to engage in a larger study that would include more participants. Their goal is to expand the scope beyond measurements of blood pressure to explore possible physiological reasons behind why stretching results in reduced blood pressure – such as changes in the body’s nervous system and arterial stiffness.

To view the original scientific study click below:
Stretching is Superior to Brisk Walking for Reducing Blood Pressure in People With High–Normal Blood Pressure or Stage I Hypertension.