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Home| Immune System| Transfer Factor Story| Riovida | Healing Process| Testimonials| Forms What Is The Immune System?
The adaptation process creates immunological memories and allows even more effective protection during future encounters with these pathogens. This process of acquired immunity is the basis of vaccination.
Transfer Factor works on a similar basis of
‘borrowed immunity memory’ from two natural sources ie. cow’s colostrum
and chicken egg yolk. Immune information molecules are extracted from
these two natural sources and encapsulated as natural food supplement.
Layered Defense in Immunity
When a virus or bacteria (also known
generically as a germ) invades your body and reproduces, it normally
causes problems. Generally the germ's presence produces some side effect
that makes you sick. For example, the strep throat bacteria
(Streptococcus) releases a toxin that causes inflammation in your throat.
The polio virus releases toxins that destroy nerve cells (often leading to
paralysis). Some bacteria are benign or beneficial (for example, we all
have millions of bacteria in our intestines and they help digest food),
but many are harmful once they get into the body or the bloodstream.
1. It creates a physical barrier that
prevents bacteria and viruses from entering your body.
Both innate and adaptive immunity depend on
the ability of the immune system to distinguish between self and non-self
molecules. Transfer Factors provide information to help your body to
recognize between the self and non-self molecules. In immunology, self
molecules are those components of an organism's body that can be
distinguished from foreign substances by the immune system. Conversely,
non-self molecules are those recognized as foreign molecules. One class of
non-self molecules are called antigens (short for antibody generators) and
are defined as substances that bind to specific immune receptors and
elicit an immune response.
Components of the Immune System One of the funny things about the immune system is that it has been working inside your body your entire life but you probably know almost nothing about it. For example, you are probably aware that inside your chest you have an organ called a "heart". Who doesn't know that they have a heart? You have probably also heard about the fact that you have lungs and a liver and kidneys. But have you even heard about your thymus? There's a good chance you don't even know that you have a thymus, yet its there in your chest right next to your heart. There are many other parts of the immune system that are just as obscure, so let's start by learning about all of the parts. The most obvious part of the immune system is what you can see. For example, skin is an important part of the immune system. It acts as a primary boundary between germs and your body. Part of your skin's job is to act as a barrier in much the same way we use plastic wrap to protect food. Skin is tough and generally impermeable to bacteria and viruses. The epidermis contains special cells called Langerhans cells (mixed in with the melanocytes in the basal layer) that are an important early-warning component in the immune system. The skin also secretes antibacterial substances. These substances explain why you don't wake up in the morning with a layer of mold growing on your skin -- most bacteria and spores that land on the skin die quickly.
Your nose, mouth and eyes are also obvious
entry points for germs. Tears and mucus contain an enzyme (lysozyme) that
breaks down the cell wall of many bacteria. Saliva is also anti-bacterial.
Since the nasal passage and lungs are coated in mucus, many germs not
killed immediately are trapped in the mucus and soon swallowed. Mast cells
also line the nasal passages, throat, lungs and skin. Any bacteria or
virus that wants to gain entry to your body must first make it past these
defenses.
Let's look at each of these components in detail. Thymus The thymus lives in your chest, between your breast bone and your heart. It is responsible for producing T-cells, and is especially important in newborn babies - without a thymus a baby's immune system collapses and the baby will die. The thymus seems to be much less important in adults - for example, you can remove it and an adult will live because other parts of the immune system can handle the load. However, the thymus is important, especially to T cell maturation. Spleen The spleen filters the blood looking for foreign cells (the spleen is also looking for old red blood cells in need of replacement). A person missing their spleen gets sick much more often than someone with a spleen. Bone marrow Bone marrow produces new blood cells, both red and white. In the case of red blood cells the cells are fully formed in the marrow and then enter the bloodstream. In the case of some white blood cells, the cells mature elsewhere. The marrow produces all blood cells from stem cells. They are called "stem cells" because they can branch off and become many different types of cells - they are precursors to different cell types. Stem cells change into actual, specific types of white blood cells. White Blood Cells You are probably aware of the fact that you have "red blood cells" and "white blood cells" in your blood. The white blood cells are probably the most important part of your immune system. And it turns out that "white blood cells" are actually a whole collection of different cells that work together to destroy bacteria and viruses. Here are all of the different types, names and classifications of white blood cells working inside your body right now:
Leukocytes
Learning all of these different names and the
function of each cell type takes a bit of effort, but you can understand
scientific articles a lot better once you get it all figured out! Here's a
quick summary to help you get all of the different cell types organized in
your brain. Leukocytes are divided into three classes:
All white blood cells start in bone marrow as stem cells. Stem cells are generic cells that can form into the many different types of leukocytes as they mature. For example, you can take a mouse, irradiate it to kill off its bone marrow's ability to produce new blood cells, and then inject stem cells into the mouse's blood stream. The stem cells will divide and differentiate into all different types of white blood cells. A "bone marrow transplant" is accomplished simply by injecting stem cells from a donor into the blood stream. The stem cells find their way, almost magically, into the marrow and make their home there. Different Roles Each of the different types of white blood cells have a special role in the immune system, and many are able to transform themselves in different ways. The following descriptions help to understand the roles of the different cells.
T Cells Helper T cells are actually quite important and interesting. They are activated by Interleukin-1, produced by macrophages. Once activated, Helper T cells produce Interleukin-2, then interferon and other chemicals. These chemicals activate B cells so that they produce antibodies. The complexity and level of interaction between neutrophils, macrophages, T cells and B cells is really quite amazing.
Because white blood cells are so important to the immune system, they are
used as a measure of immune system health. When you hear that someone has
a "strong immune system" or a "suppressed immune system", one way it was
determined was by counting different types of white blood cells in a blood
sample. A normal white blood cell count is in the range of 4,000 to 11,000
cells per microliter of blood. 1.8 to 2.0 helper T-cells per suppressor
T-cell is normal. A normal absolute neutrophil count (ANC) is in the range
of 1,500 to 8,000 cells per microliter. An article like Introduction to
Hematology can help you learn more about white blood cells in general and
the different types of white blood cells found in your body.
"There are two major types of MHC protein molecules--class I and class
II--that span the membrane of almost every cell in an organism. In humans
these molecules are encoded by several genes all clustered in the same
region on chromosome 6. Each gene has an unusual number of alleles
(alternate forms of a gene). As a result, it is very rare for two
individuals to have the same set of MHC molecules, which are collectively
called a tissue type. Antibodies Antibodies (also referred to as immunoglobulins and gammaglobulins) are produced by white blood cells. They are Y-shaped proteins that each respond to a specific antigen (bacteria, virus or toxin). Each antibody has a special section (at the tips of the two branches of the Y) that is sensitive to a specific antigen and binds to it in some way. When an antibody binds to a toxin it is called an antitoxin (if the toxin comes from some form of venom, it is called an antivenin). The binding generally disables the chemical action of the toxin. When an antibody binds to the outer coat of a virus particle or the cell wall of a bacterium it can stop their movement through cell walls. Or a large number of antibodies can bind to an invader and signal to the complement system that the invader needs to be removed. Antibodies come in five classes:
Whenever you see an abbreviation like IgE in a medical document, you now know that what they are talking about is an antibody. Natural Killer Cells
Natural Killer (NK) cells are yet another type of lethal lymphocyte. Like
cytotoxic T cells, they contain granules filled with potent chemicals.
They are called "natural" killers because they, unlike cytotoxic T cells,
do not need to recognize a specific antigen before swinging into action.
They target tumor cells and protect against a wide variety of infectious
microbes. In several immunodeficiency diseases, including AIDS, natural
killer cell function is abnormal. Natural killer cells may also contribute
to immunoregulation by secreting high levels of influential lymphokines.
Lymph System
The lymph system is most familiar to people because doctors and mothers
often check for "swollen lymph nodes" in the neck. It turns out that the
lymph nodes are just one part of a system that extends throughout your
body in much the same way your blood vessels do. The main difference
between the blood flowing in the circulatory system and the lymph flowing
in the lymph system is that blood is pressurized by the heart, while the
lymph system is passive. There is no "lymph pump" like there is a "blood
pump" (the heart). Instead, fluids ooze into the lymph system and get
pushed by normal body and muscle motion to the lymph nodes. This is very
much like the water and sewer systems in a community. Water is actively
pressurized, while sewage is passive and flows by gravity. Complement System The complement system, like antibodies, is a series of proteins. There are millions of different antibodies in your blood stream, each sensitive to a specific antigen. There are only a handful of proteins in the complement system, and they are floating freely in your blood. Complements are manufactured in the liver. The complement proteins are activated by and work with (complement) the antibodies, hence the name. They cause lysing (bursting) of cells and signal to phagocytes that a cell needs to be removed. Hormones
There are several hormones generated by
components of the immune system. These hormones are known generally as
lymphokines. It is also known that certain hormones in the body suppress
the immune system. Steroids and corticosteroids (components of adrenaline)
suppress the immune system. Tumor Necrosis Factor Tumor Necrosis Factor (TNF) is also produced by macrophages. It is able to kill tumor cells, and it also promotes the creation of new blood vessels so it is important to healing.
Disorders of human immunity Immunodeficiencies
Immunodeficiencies occur when one or more of
the components of the immune system are inactive. The ability of the
immune system to respond to pathogens is diminished in both the young and
the elderly, with immune responses beginning to decline at around 50 years
of age due to immunosenescence. In developed countries, obesity,
alcoholism, and illegal drug abuse are common causes of poor immune
function. However, malnutrition is the most common cause of
immunodeficiency in developing countries. Diets lacking sufficient protein
are associated with impaired cell-mediated immunity, complement activity,
phagocyte function, IgA antibody concentrations, and cytokine production.
Deficiency of single nutrients such as iron; copper; zinc; selenium;
vitamins A, C, E, and B6; and folic acid (vitamin B9) also reduces immune
responses. Additionally, the loss of the thymus at an early age through
genetic mutation or surgical removal results in severe immunodeficiency
and a high susceptibility to infection.
Hypersensitivity
Allergies are another form of immune system
error. For some reason, in people with allergies, the immune system
strongly reacts to an allergen that should be ignored. The allergen might
be a certain food, or a certain type of pollen, or a certain type of
animal fur. For example, a person allergic to a certain pollen will get a
runny nose, watery eyes, sneezing, etc. This reaction is caused primarily
by mast cells in the nasal passages. In reaction to the pollen the mast
cells release histamine. Histamine has the effect of causing inflammation,
which allows fluid to flow from blood vessels. Histamine also causes
itching. To eliminate these symptoms the drug of choice is, of course, an
antihistamine. Physiological regulation
Hormones can act as immunomodulators,
altering the sensitivity of the immune system. For example, female sex
hormones are known immunostimulators of both adaptive and innate immune
responses. Some autoimmune diseases such as lupus erythematosus strike
women preferentially, and their onset often coincides with puberty. By
contrast, male sex hormones such as testosterone seem to be
immunosuppressive. Other hormones appear to regulate the immune system as
well, most notably prolactin, growth hormone and vitamin D. It is
conjectured that a progressive decline in hormone levels with age is
partially responsible for weakened immune responses in aging individuals.
Conversely, some hormones are regulated by the immune system, notably
thyroid hormone activity. How Antibiotics Work
Sometimes your immune system is not able to
activate itself quickly enough to outpace the reproductive rate of a
certain bacteria, or the bacteria is producing a toxin so quickly that it
will cause permanent damage before the immune system can eliminate the
bacteria. In these cases it would be nice to help the immune system by
killing the offending bacteria directly. Vaccinations
There are many diseases that, if you catch
them once, you will never catch again. Measles is a good example, as is
chicken pox. What happens with these diseases is that they make it into
your body and start reproducing. The immune system gears up to eliminate
them. In your body you already have B cells that can recognize the virus
and produce antibodies for it. However, there are only a few of these
cells for each antibody. Once a particular disease is recognized by these
few specific B cells, the B cells turn into plasma cells, clone themselves
and start pumping out antibodies. This process takes time, but the disease
runs it course and is eventually eliminated. However, while it is being
eliminated, other B cells for the disease clone themselves but do not
generate antibodies. This second set of B cells remains in your body for
years, so if the disease reappears your body is able to eliminate it
immediately before it can do anything to you. Immunological memory When B cells and T cells are activated and begin to replicate, some of their offspring will become long-lived memory cells. Throughout the lifetime of an animal, these memory cells will remember each specific pathogen encountered and can mount a strong response if the pathogen is detected again. This is "adaptive" because it occurs during the lifetime of an individual as an adaptation to infection with that pathogen and prepares the immune system for future challenges. Immunological memory can either be in the form of passive short-term memory or active long-term memory. Passive memory Passive immunity is usually short-term, lasting between a few days and several months. Newborn infants have no prior exposure to microbes and are particularly vulnerable to infection. Several layers of passive protection are provided by the mother. During pregnancy, a particular type of antibody, called IgG, is transported from mother to baby directly across the placenta, so human babies have high levels of antibodies even at birth, with the same range of antigen specificities as their mother. Breast milk also contains antibodies that are transferred to the gut of the infant and protect against bacterial infections until the newborn can synthesize its own antibodies. This is passive immunity because the fetus does not actually make any memory cells or antibodies, it only borrows them. In medicine, protective passive immunity can also be transferred artificially from one individual to another via antibody-rich serum or oral supplements like Transfer Factor.
Active memory and immunization
Long-term active memory is acquired following infection by activation of B
and T cells. Active immunity can also be generated artificially, through
vaccination. The principle behind vaccination (also called immunization)
is to introduce an antigen from a pathogen in order to stimulate the
immune system and develop specific immunity against that particular
pathogen without causing disease associated with that organism. This
deliberate induction of an immune response is successful because it
exploits the natural specificity of the immune system, as well as its
inducibility. With infectious disease remaining one of the leading causes
of death in the human population, vaccination represents the most
effective manipulation of the immune system mankind has developed. Borrowed Immunity Memory Transfer Factors are natural supplements made up of tiny immune information molecules that acts as ‘borrowed immunity memory’ from cow’s colostrum & chicken egg yolk which help to strengthen, educates to recognize, respond & remember and regulate (balance) your immune system.
Home| Immune System| Transfer Factor Story| Riovida | Healing Process| Testimonials| Forms | Chinese
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Inside your
body there is an amazing protection mechanism called the immune system. An
immune system is a collection of mechanisms within an organism that
protects against disease by identifying and killing pathogens and tumor
cells. It detects a wide variety of agents, from viruses to parasitic
worms, and needs to distinguish them from the organism's own healthy cells
and tissues in order to function properly. As part of this more complex
immune response, the human system adapts over time to recognize particular
pathogens more efficiently.
When you get a cut, all sorts of
bacteria and viruses enter your body through the break in the skin. When
you get a splinter you also have the sliver of wood as a foreign object
inside your body. Your immune system responds and eliminates the invaders
while the skin heals itself and seals the puncture. In rare cases the
immune system misses something and the cut gets infected. It gets inflamed
and will often fill with pus. Inflammation and pus are both side-effects
of the immune system doing its job. 
Thymus 
Another
important role of the immune system is to identify and eliminate tumors.
The transformed cells of tumors express antigens that are not found
on normal cells. To the immune system, these antigens appear foreign, and
their presence causes immune cells to attack the transformed tumor cells.
The antigens expressed by tumors have several sources; some are derived
from oncogenic viruses like human papillomavirus, which causes cervical
cancer, while others are the organism's own proteins that occur at low
levels in normal cells but reach high levels in tumor cells. One example
is an enzyme called tyrosinase that, when expressed at high levels,
transforms certain skin cells (e.g. melanocytes) into tumors called
melanomas. A third possible source of tumor antigens are proteins normally
important for regulating cell growth and survival, that commonly mutate
into cancer inducing molecules called oncogenes. 
