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THE
PROCESS OF AN
ALLERGIC REACTION
 SEE
A MOVIE ABOUT THE ALLERGIC RESPONSE:
All allergic diseases including asthma, rhinitis,
sinusitis, and anaphylaxis are the result of the mobilization of
the immune system in response to a foreign substance in the body.
In order to first develop allergies, the body must
be exposed to something in the environment that prompts it to initiate
an immune response. These foreign substances, called allergens,
can be something we have swallowed, something we have inhaled, something
we have touched, or something injected into us like a needle or
an insect sting.
When an allergen enters our body, a person with an
inherited predisposition to this allergen will begin to develop
a specific type of antibody called immunoglobin E (IgE). An antibody
is a protein produced by our immune system, which circulate in the
bloodstream and help to remove any substances or organisms, such
as bacteria or viruses, which has invaded our body. The IgE antibody
is one of five different classes of antibody made by our immune
system. The other four are: IgM, IgG, IgD, and IgA. IgE antibodies
originally evolved to give the body a way of protecting itself from
parasites. However, it is also specifically targeted at allergens.
Although everyone makes IgE, people whom are prone
to allergic reactions make much larger quantities. Inheritance has
a major influence on allergies. Inheritance determines whether or
not a person makes IgE in response to everyday substances. Although
it is unlikely that there's a single gene behind allergies in all
allergic individuals, you are still more likely to have allergies
if other members of your family have them. Researchers say that
if you have 1 sibling with allergies, you have a 33% chance of having
them. If you have 1 parent that is allergic, you have a 50% chance,
and if you have 2 parents with allergies, you have a 75-80% chance
of being allergic. Other influences such as viral infections, smoking,
and hormones can also determine whether one develops allergies.
All immunoglobins including IgE are made
by B-lymphocytes, a specific type of white blood cell. The B-lymphocyte's
antibody production is regulated by Helper T-lymphocytes, another
type of white blood cell. In addition, macrophages, cells that ingest
pieces of foreign substances, assist T-lymphocytes to prompt B-lymphocytes
to make more IgE.
When an allergic individual is exposed
to a sensitizing allergen, the body makes a specific IgE, one
that is able to recognize only that allergen. (see above chart)
Millions of mast cells and basophils
are all over the body.
Mast cells reside in tissues in the
body, and basophils are in the blood stream. Both mast cells and
basophils have over 100,000 receptors that are specific for the
IgE antibody. When an allergen (antigen) enters the immune system,
the antigen binds to these IgE receptors on the surface of the
cells. When the allergic individual is reexposed to the same allergen
that initiated the response, the IgE is able to bind to that allergen.
When two IgE antibodies next to each other bind to the antigen,
this interaction "wiggles" the membrane and causes the degranulation
of the mast cell or basophil. Degranulation means the breaking
down of the mast cell or basophil.
As degranulation occurs, it causes
the mast cell or basophil to release a series of chemicals that
orchestrate the allergic reaction. Within every mast cell or basophil
are 500 to 1500 granules containing more than thirty different
allergy-causing chemicals. The best known chemical that is released
is histamine. Histamine causes itching if released in the skin,
wheezing if released in the lung, and contributes to a loss of
blood pressure if released throughout the body.
Leukotrienes are also released, and
they act similar to histamines. Cytokines are also released, and
one of the cytokines released by the basophil is interleukin-4,
which is believed to be responsible for telling the body to make
more IgE. (See Allergic Rhinitis for effects of allergy causing
chemicals on the body). The intensity of this immune response
is one of the many reasons that antihistamines alone do not work
for most allergic disease.
The phases of an immune response
Once the mast cells and/or basophils
have released their chemicals, the allergic reaction occurs rather
quickly. This part of the reaction is called the immediate
reaction. However, some people also experience what is called
a late phase reaction. The tissues in which mast cells
have released their chemicals may become hot, tender, red and
swollen for several hours. The mast cells create this reaction
by releasing chemicals, called chemotactic factors, that then
attract many other inflammatory cells to the site. These cells
include: eosinophils, neutrophils, and lymphocytes. Once they've
arrived, each one of these cells contributes to the late phase
of the allergic response. Eosinophils generate chemicals similar
to those made by mast cells, as well as release more generally
toxic substances that irritate the body. Neutrophils release a
number of chemicals including enzymes, which degrade proteins,
and in turn cause further tissue damage.
The immediate and late phase reactions
together combine to form a severe allergic response.
In skin reactions, the immediate phase
consists of a pale central area surrounded by redness and swelling.
This response reaches its peak at about 15 minutes and goes away
after about 90 minutes. However, the immediate response can also
merge with the late phase that can last up to 24 hours.
In the nose, the immediate response
consists of sneezing, itching, and the production of nasal secretions.
The late phase response is associated with swelling, constant
blockge of the nasal passages, and continuous mucus production.
In the lung, the immediate response
begins within minutes or even seconds after exposure to an allergen.
This includes shortness of breath, wheezing, and coughing. This
disappears after an hour or so. Three to four hours later, the
late phase reaction begins. It is also characterized by shortness
of breath and coughing, and can last up to 24 hours.
If the allergic response sounds very
confusing, you're right!!! That is why it is so difficult to treat
allergies with a single medication. The immune response is an
endless cycle that constantly produces IgE antibodies and other
chemicals, and therefore causes continuing allergic symptoms.
At this time, we cannot cure allergies, we can only hope to contain
them. Due to the complexity of the allergic cascade multiple drugs
are often needed to control symptoms. Alternatives including allergy
desensitization shots which reduce the overall reactivity of the
immune system may be explored with your doctor.
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