What insights does research have found that the brain talks to gut bacteria, and what does it mean f

Studies have found that the brain can have a direct dialogue with bacteria in the gut, which can bring some new enlightenment to diseases, such as diabetes or obesity by affecting people's brains. Doctors can use some techniques to make patients think that they have eaten a lot of food, which will make the brain nerves more happy, and may make the body mistakenly think that it is full, so it will not send a hunger signal.

Scientists have studied mice and found that neurons can control many things. For example, if the brain loses the ability to measure hunger and satiety, it is possible for a mouse to weigh more**. In the experiment, the weight of the elderly female mice was relatively large, and they were also particularly susceptible to type 2 diabetes.

If your nerves are particularly sensitive to a certain food and you feel full after eating a little bit, it can really help you with obesity or diabetes. Because diabetics are not allowed to eat sweets, and obese people cannot eat high-calorie foods. Of course, these two foods are more popular for people to eat, and only by giving neurons the illusion or allowing neurons to control the body can people stop wanting to eat this kind of food, without such thoughts.

Now this experiment has only been carried out to the animal stage, and no real clinical trials have been conducted, and it is not known whether it will have an effect on humans. Friends who saw the news also said that if the brain sends a signal of diarrhea, the bacteria in the intestines are very likely to carry it out, and this command makes you diarrhea immediately. And some constipation patients also hope that such a method will be launched as soon as possible, so that they will no longer be constipated and can defecate quickly.

But it may take a long time to actually apply it to real life, after all, it is still in the research stage, and it is just a research conclusion.

Nowadays, medical technology is becoming more and more developed, and people's treatment will become relatively simple and not so difficult. Maybe one day in the future, some cancers or special diseases can also be affected**.

Take a more gentle approach, adopt a more scientific method, carry out scientific nurturing, avoid accidents, all organs of the body are connected, can affect the whole body.

It has brought a good reference role and can be a good improvement for such a medical research.

Research has found that the brain can speak directly to bacteria in the gut, which could pave the way for interdisciplinary collaboration in neuroscience, immunology, and microbiology.

As far as the current level of scientific development is concerned, the human body still has a lot to uncover the veil of mystery, a recent study in the journal "Science" shows that the brain can directly talk to the bacteria in the intestine, scientists through the study of mouse models found that neurons in the hypothalamus can directly detect changes in the bacterial flora of the intestine, and regulate physiological processes such as appetite and body temperature according to the changes in the bacterial flora. It is strange to hear it suddenly, it turns out that the brain also has such a function, and it can control people's appetite just by changing the microflora. In fact, the human body is comparable to a very sophisticated instrument, and each organ works closely together, but there are some connections that we have not yet discovered.

The discovery could have a direct impact on interdisciplinary collaboration between neuroscience, immunology, and microbial science. In this study, the research team found that neurons in the hypothalamus can directly sense bacterial wall peptides, which were previously thought to be only the work of immune cells, and that neurons in the hypothalamus can directly use them as an indirect measure of food intake by sensing intestinal bacterial wall peptides, which means that intestinal bacteria can protect the gut from harm by regulating intake. Gut bacteria may be used by the brain as an indirect measure of food intake, or as a direct measure of bacterial expansion or death due to food intake.

With this research, it is extremely conducive to making a breakthrough in diabetes, and you can control your appetite by regulating the intestinal flora, and may bring new methods for brain diseases and metabolic diseases such as diabetes and obesity.

This article proposes that the brain nerve senses the intestinal microbiota, which has another idea, that is, to regulate human metabolism by influencing the intestinal microbiota. For example, the practice of interfering with the intestinal flora, which can be probiotics and the like, adjust the type of intestinal flora, and finally affect the brain. Of course, in turn, the intestinal flora can also be regulated through the brain, for example, for some patients with gastrointestinal diseases.

In fact, it is still full of attraction, and mental illness and gastrointestinal diseases are solved together.

For industries such as biology, medicine, computers, artificial intelligence, and chemicals, because this discovery can promote these industries to research and develop their economies.

For the human body, there are still many aspects that need modern science and technology, due to the progress of medical technology, these aspects are also being broken through by human beings step by step and new research, the impact on the future medical industry and even other industries is immeasurable, taking the current study as an example, the study found that the brain, can be directly talked to by intestinal bacteria to have a certain impact on the human brain, and determine what foods humans want to eat affect human final behavior. The findings of this study will also have a certain impact on many industries today.

First, there is an important breakthrough in the field of modern medicine, for a long time, there is an important blind spot in the influence of human beings on the digestive organs and the significance of digestive organs to medical research, that is, it is impossible to determine how the brain prefers which kind of food is carried out, and these studies just explain this phenomenon, thus making an important breakthrough in the research and pathological experiments of the Department of Digestive Diseases.

The second also has a certain impact on the development of the modern pharmaceutical industry, due to the role of bacteria, so the brain will be more or less biased when executing orders, and this research breakthrough can fundamentally cut off the intake of unhealthy food by human beings, so as to fundamentally change unhealthy behavior habits and the resulting bad consequences, and the intervention of drugs in it is particularly critical and important, how to study the relevant drugs, for the current human intestinal diseases have important discoveries.

Finally, in a fundamental sense, the study found that it also has a certain important role in the field of brain science, not only for digestive problems and other problems of intestinal diseases, but also for the study of the brain has an important breakthrough.

The importance of the brain-gut axis in maintaining homeostasis has long been recognized. However, the emergence of the microbiota, one of the key regulators of gut-brain function, has led to the construction of a balanced model of the microbiome-gut-brain axis, and the importance of the microbiome-gut-brain axis (MGBA) has been gradually recognized.

For example, compounds released by the microbial community circulate through the gut-brain axis to regulate physiological functions such as the host's immune response, metabolism, and brain function. However, it is still unknown whether neurons in the brain can directly sense the components of bacteria, and whether bacteria can regulate physiological processes by regulating neurons.

Using brain imaging techniques, scientists initially observed that NOD2 receptors in mice were expressed by neurons in different regions of the brain, particularly in miceHypothalamusRegion. The hypothalamus is the higher center of the cerebral cortex that regulates visceral activity, and it regulates visceral activity by linking it with other physiological activitiesBody temperatureIngestionWater balanceBlood sugarwithReproductionand other important physiological functions. They then found that when these neurons came into contact with bacterial wall peptides in the gut, the neurons' electrical activity was inhibited.

The symbiotic bacteria affect the contraction rhythm of the hydra itself, and their nerve cells can activate pacemaker cells through immune receptors, and release specific molecules such as bacterial peptides to regulate the symbiotic bacteria, so as to achieve a dialogue with each other. Such conversations are likewise found in worms and mice.

Later research found that bacteria and the brain communicate through the immune system, which is the most basic way of communication in animals. As cnidarians evolved from posterior animals to chordates, and then to fish, the communication between bacteria and organisms changed like never before with the birth of central systems such as the brain and vertebrae.

The intestinal tract is known as the "second brain", and in recent years, the research on the "gut-brain axis" has become more and more in-depth. The gut microbiota has been found to regulate host physiological processes by releasing compounds in the bloodstream, including immunity, metabolism, and brain function. However, it has not been proven whether brain neurons can directly sense bacterial components, and whether bacteria can directly regulate host physiological processes by regulating neurons.

The recent publication of a study that has attracted a lot of attention about the direct dialogue between the brain and intestinal bacteria, and this finding has led to a variety of speculations, which is very surprising that the brain can bypass the body's various neural processing centers to directly give instructions to the intestinal bacteria, so what is the significance of this discovery?

Sometimes we think about losing weight in our minds, maybe the appetite for food during that time is not very good, or it may be relatively slow to digest food, etc., these behaviors are not easy to explain before, but if it is based on the fact that the brain can talk directly to the intestinal bacteria,Then we may be able to propose an explanation that the brain can control the digestive function of the gutAnd it can even give orders directly to the bacteria in the intestines. Sometimes, the digestive function of the human body is abnormal, and various changes in bacteria may also make people feel inexplicable emotional changes or other changes recentlyIt is also possible that the changes in bacteria are directly fed back to the nerves in the brainThis phenomenon can be said to be the best theoretical basis for explaining this series of problems.

At present, most of the ** intestinal drugs we have developed are directly from the intestines, such as some intestinal probiotics or anti-inflammatory drugs for a certain type of bacteria. But this theory has changed our thinking, and it may be possible to control the bacteria in the gut by sending corresponding signals to the bacteria in the gutThis changes the colony environment of the intestines, which not only does not impair the function of the stomach itselfIt can also make the body recover more naturally. Similarly, for the brain, there may be a drug that can change some of the brain's problems by increasing the rate of certain aspects of intestinal coloniesIt may indirectly change mood, insomnia and anorexia.

This study can be said to provide a strong basis for subsequent research on the brain and intestinesThe follow-up relationship between what kind of colonies affect the brain, and how the brain talks to intestinal bacteria, etc., are all difficult problems that we need to overcomeThese problems are inseparable from this research, so the findings of this study are very important.

Hopefully, our science can go one step further and solve the relevant problems as soon as possible!

It has been revealed that hypothalamic neurons can directly sense changes in intestinal bacterial activity and adjust appetite and body temperature accordingly. These findings suggest that there is a direct dialogue between the gut microbiota and the brain, which re-emphasizes the importance of the brain-gut axis and may lead to new approaches to brain diseases and metabolic diseases such as diabetes and obesity.

It affects human obesity, enteritis, autoimmune diseases, response to cancer drugs, and even affects human lifespan. A growing body of evidence reveals the degree of interdependence between humans and these gut microbiotas, and also highlights the importance of the brain-gut axis.

It can better control neurons, and can control the information of the brain, and can also directly achieve dialogue with this bacterium through information transmission, whether it can be used to treat diseases in this way, and whether it can be applied to the medical process? In this way, it is possible to directly ** the disease.

It is of great significance to better understand the condition of the body for medical research, promote medical progress, and better understand the specific conditions of the brain and intestines.

Bacteria in the gut can control appetite, emotions, mind, and even emotions in the human brain, and once there is a problem in the gut, it may not only trigger depression but also Alzheimer's disease.

It may have a direct dialogue with the human body, it may also have a dialogue with some body movements, it may also freely control the human body, and it may also develop more of the brain, which may make the brain work better, these secrets have not been proven.

The human body secretes 1 2 liters of saliva every day, the human brain is still 80% water, teeth are the only body parts that can repair themselves, stress and fear can lead to the secretion of earwax, these are the secrets of the human body that need to be understood.