VIRUSES

Scientists generally believe that viruses do not live. Many claims that these are just organic structures that interact with living organisms. They say that they are "creatures on the edge of life", but they are not really meaningful creatures. This is because they say that they have no cell structure, do not have their own metabolism and can only regenerate within the cell structure. In addition, we do not do this with cell division.

There are many viruses on this planet. It is estimated that the earth contains 1031 viruses or ten viruses with 31 zeros. Technically (in the case of winks) it is between billions and billions (although it is enough to say Baijiu). Basically, many and there are also different types. There are about 5,000 different viral genotypes per 200 litres of water (about 50 gallons or the content of a typical hot water tank). The virus is the coldest and most difficult to live on this planet, and the virus is found in boiling hot springs. There are high viruses in the atmosphere and the deepest wells on earth. They live in the mountains and most profound in the sea. And sometimes they even move into space.

You are part of the life of this planet. You cannot avoid them. Unlike bacteria, viruses have neither nuclei nor cell walls. They are a minimal lifespan that is matched to the simplicity of the design. There are many types, but in general, viruses are strands of DNA or RNA that are surrounded by mathematically elegant polyhedral, called capsids, whose shape is virus-specific. In a so-called "envelope virus", the capsid is surrounded by one or more protein envelopes. Because of this simplified structure, they are no less alive than bacteria, for example. They are unique life forms (but that is not the reason to discriminate against them).

They are very similar to seeds (or spores): they only grow if they find the right soil. And like seeds, they continuously monitor the outside world, even when they are floating. The surface of the protein envelope of the virus is littered with receptors, which are certain types of sensory organs that bypass the virus. Viruses use these elegant senses to analyze their surroundings and find the best cells. Like Dr Ryan, a doctor and researcher commented that the virus has a certain sensation that can be divided between rudimentary smells and tactile sensations. There is a method for the detection of the chemical composition of the cell surface. This gives the virus the best able to recognize the correct cell surface [to find its own host cell]. Recognize them through 3D recognition of surface chemistry. Viruses sense the environment, assess their nature, find the most easily reproducible cellular organisms in them, and then stimulate the organisms in which they exist to spread very new viruses to highly developed ones. The host has the ability. And they can survive very well.

You can analyze the type of immune response against them and change yourself to bypass them - or change the host's immune response itself. They can be derived from useful definitions of terms. That is, it analyzes the inputs and creates new behaviour based on what determines the meaning of those inputs. Viruses can be classified in several ways: size or shape, presence or absence of encapsulated capsules (but not all), DNA or RNA-based (and single or double-stranded, positive or negative meaning), protein structure and how you type duplicate it. DNA viruses are reasonably reliable because infections are a kind of copy-checking mechanism" that cannot be found in RNA viruses. This means that if the DNA virus makes more of itself in the host cell, it uses a biofeedback loop to ensure that its copy is reasonably accurate. In contrast, RNA viruses cannot. As a rule, a large number of copies are made that differ from the original. Some of these copy differences are deliberately triggered by the RNA virus and improve its genetic variation and thus the viability of the host. For this reason, permanent vaccines against DNA viruses are often designed, but the production of vaccines against RNA viruses is complicated, if not impossible. This also makes it very difficult to treat RNA “viruses with drugs. They start making synthetic drug solutions as soon as they are found, like bacteria. For example, hepatitis C virus mutation rates have been shown to accelerate in response to interferon and ribavirin therapy in the same way that bacterial changes occur in the presence of antibiotics. RNA virus infections such as West Nile and Japanese encephalitis are fundamentally different from DNA virus infections. We exist in a period of swiftly growing global landscape and the local environment. Viruses with RNA as a genetic material can quickly adapt to these different conditions and take advantage of them. Therefore, it is not surprising that RNA viruses cause some recent prominent examples of newly emerging or re-emerging infections. - Stuart Nicol and other DNA viruses produce billions of microorganisms, while RNA viruses produce billions of similar viruses, but they are not the same virus. It's like a swarm of bees - all similar, but all different. In fact, it is much more accurate to consider an RNA infection as being caused by a group of viruses. The most similar is “that the human immune system is activated or dies first when using drugs that it can recognize. This allows others to multiply freely without being checked, and actually increase very quickly (some viruses generate a new generation every minute), but subtly for each newly created virus and make the necessary changes.

There is also evidence that both DNA and RNA viruses such as bacteria exchange information because they are not affected by the medical or immune systems. Similar viruses actively share the gene structure and cause infections that are very difficult to treat. For example, influenza viruses (and intentionally) regularly (and intentionally) use completely new genes to restore their genetic structure and make them invisible to the human immune system. And collect these new gene sequences from Asian pigs and birds. For this reason, a new flu vaccine is needed every year.

Viruses transmitted by ticks or mosquitoes use compounds in the saliva of arthropods to penetrate new hosts. Salivary compounds reduce the host's specific immune response, provide them with arthropods, and often numb the site of the bite. If the immune response is reduced in this area, the virus can enter new hosts where there is little resistance. Once in the virus, it reaches the draining lymph node closest to the site of the bite and is transported through the lymph to the spleen. So, they begin to change the host's immune function and decrease the ability of immune cells to recognize and kill invading microorganisms. In this case, the virus begins to spread throughout the body, usually on immune cells, macrophages or monocytes. For example, this is common with the encephalitis virus. It then travels through the lymph to the barrier between the brain and the rest of the body, releasing connections that make the boundary more porous, get into the mind and find brain neurons, cells that it really likes. Other viruses occur through inhalation (influenza), sex (HIV) or through eating (enterovirus). As soon as they are in the body, they ride on their personal cells (usually immune cells, these cells move everywhere) and actively search for their favourite places. This is the case with HIV, which considers T4 lymphocytes as complete host cells, the Epstein-Barr virus, which has an affinity for human B cells, or the Japanese encephalitis virus, which prefers monocytes.

Excerpt From: Medicrone, Ester. “Herbal Antivirals: Natural Remedies for Emerging and Resistant Viral Infections.” iBooks. 2020