|
The purpose of this
course is to prepare healthcare workers to prevent, identify and react
to allergic reactions in their patients.
Upon completion of the course, the
learner will be able to:
|
1. |
Define what an allergy is
and some theories as to how
allergies are acquired
(environmentally,
genetically, etc.) |
| |
|
|
2. |
Describe the four types of
hypersensitivity reactions. |
| |
|
|
3. |
Describe the pathophysiology
of an allergic reaction. |
| |
|
|
4. |
Describe some signs and
symptoms of various allergic
reactions in relation to
their causes. |
| |
|
|
5. |
Describe how a diagnosis of
an allergic reaction is
made, and some treatments
and prevention techniques
for allergic reactions. |
An allergy is "an acquired, abnormal
immune response to a substance
(allergen) that does not normally
cause a reaction" (Thomas, 1997, pp.
66-67). Thus, they are not related
to exposure to infection or due to
injury (Merck, 2005). In simpler
terms, it is the body's way of
responding to some kind of foreign
substance. In normal cases where the
body reacts to a foreign body, the
body's immune system is activated
which normally protects the body
from harmful substances. When the
body reacts to a substance that is
in no way innately harmful (an
allergen), this is called an
allergic or hypersensitivity
reaction (Haith, 2005).
Allergens can be almost anything
such as pollen, dust, plants,
medications, foods, or insect venom.
Viruses or even bacteria can be
allergens as they can trigger a
reaction unrelated to their normal
viral or bacterial influence in the
body (Haith, 2005). An allergen is
defined as something that can induce
IgE-mediated and T-helper 2 cell
immune response. They are mostly low
molecular weight proteins which are
often able to be made particulates
in the air (Merck, 2007).
The terms allergy, atopy, and
hypersensitivity are often
interchanged and confused. Allergies
are categorized into four different
hypersensitivity reactions by Gell
and Coombs and atopy refers simply
to the first type (type I
hypersensitivity reactions) only
(Merck, 2005). There are many
diseases and reactions that fall
under the general classification of
allergy. These will be described
below as well as their subsequent
etiologies, pathophysiology,
treatment, and prevention.
It is thought that genetic,
environmental, and site-specific
factors contribute to the
development of allergies. Because
allergies seem to be inherited (as
evidenced by strong family
histories, association between
atopic disease and specific genetic
factors), genetics is partially
implicated in the development of the
disease.
Allergic reactions are mediated
through the T-helper 2 responses
which activate eosinophils and IgE
production. This response is a
generalized response and causes the
generalized inflammatory reaction
common with exposure to allergens.
The T-helper 1 responses are more
specific, and the body develops
antibodies to these allergens when
the T-helper 1 system is activated.
Upon exposure a second time to the
allergen, the body targets the
allergen itself specifically, and
does not cause the generalized
swelling that the T-helper 2
response does. In fact, T-helper 1
responses actually suppress the
T-helper 2 response. Early childhood
exposure to bacterial/viral
infection can shift the T-helper 2
cell responses to the more specific
T-helper 1 responses. The "hygiene
hypothesis" suggests that in more
developed countries where there are
fewer children per family, cleaner
indoor environments, and early
vaccination and antibiotic usage,
children may be deprived of the
ability to develop this natural
"shifting" towards the T-helper 1
cell response.
The site-specific response refers to
molecules in the lungs and
gastrointestinal tract that direct
T-helper 2 cells to certain tissues
which can react to allergens in
those specific areas. It is also
thought that chronic exposure to an
allergen sensitizes the patient
(Merck, 2007).
As mentioned above, there are four
different categories into which
allergic reactions lie. They are as
follows:
|
1. |
Type I (immediate
hypersensitivity) reactions.
These reactions are local or
systemic anaphylactic inflammatory
responses which are IgE-mediated and
underlie all atopic diseases
(Thomas, 1997). Antigen binds to IgE
(bound to tissue mast cells and
blood basophils), trigger the
release of mediators (histamine,
chemotactic factors, etc.), and
synthesize other mediators
(prostaglandins, leukotrienes,
platelet-activating factor,
interleukins). These mediators cause
the common symptoms of an atopic
reaction by causing vasodilation,
capillary permeability, mucus
production, smooth muscle spasm,
eosinophil and T-infiltration into
tissue as well as other inflammatory
cells. Atopic disease most commonly
affects the nose, eyes, skin, and
lungs. Disorders that fall into this
category can include atopic
dermatitis, contact dermatitis,
urticaria, angioedema, latex
allergy, asthma, allergic
bronchopulmonary aspergillosis,
hypersensitivity pneumonitis, and
allergic reactions to venomous
stings (bees, ants, etc.) (Merck,
2005; Merck 2007). The anaphylactic
reactions occur when the allergen
reaches the bloodstream and causes a
massive release of chemical
mediators (Thomas, 1997). |
|
|
|
|
2. |
Type II (cytotoxic) reactions.
Type II reactions involve more
specific immune response in which
antigen-antibody complexes activate
cytotoxic T cells or macrophages and
complement which cause cell and
tissue damage. In this case, the
body is sensitized to an allergen
and the body produces an antibody to
the specific antigen. Then the
antibody binds to cellular or tissue
antigens or to a hapten (which is a
small molecule which can cause an
immune response only when attached
to a larger protein-like carrier.
The carrier does not elicit a
response by itself, only when the
hapten is coupled to it) coupled to
a cell or tissue. This leads to the
tissue damage described above
(Merck, 2005). Generally larger
molecules tend to elicit an immune
response in the body. Reaction to
these hapten-carrier products are
the same as for antigens in that the
body that generate antibodies to the
material. Upon recognition of the
complex a second time, an immune
response occurs (Wikipedia, 2008).
These reactions are mediated by IgG
and IgM and are the ones that cause
transfusion reactions and many of
the drug reactions. Due to the
release of complement, blood cells
are destroyed (Thomas, 1997).
Disorders that involve type II
reactions include transfusion
reaction, graft rejection (in organ
transplantation), Coombs'-positive
hemolytic anemia, Hashimoto
thyroiditis, etc. (Merck, 2005;
Thomas 1997). |
|
|
|
|
3. |
Type III (immune complex)
reactions. In these reactions,
IgG or IgM antibodies attach to
antigen, causing circulating
antigen-antibody complexes. These
complexes become deposited in
vessels or tissue (including
glomeruli) and adhere to the walls
and cause an acute inflammation
reaction. They can activate the
complement system, bind to and
activate immune cells, resulting in
the release of inflammatory
mediators. How much antigen is
present in relation to how much
antibody is present factors into how
severe the reaction is (i.e. a more
balanced proportion allows for more
systemic reactions as larger
complexes are formed). Some type III
reactions include serum sickness,
systemic lupus erythematosus,
rheumatoid arthritis,
cryoglobulinemia, hypersensitivity
pneumonitis, among others (Merck,
2005; Thomas 1997). |
|
|
|
|
4. |
Type IV (cell mediated or delayed
hypersensitivity) reactions. These
reactions are mediated by T-cells
(instead of antibodies) and there
are four subtypes depending on the
types of T-cells that are involved.
|
a. |
T-helper 1 cells. |
|
|
|
|
b. |
T-helper 2 cells. |
|
|
|
|
c. |
Cytotoxic T-cells. |
|
|
|
|
d. |
Interleukin-8-secreting
T-cells. |
These cells are sensitized after an
initial contact with an antigen.
When the antigens present in the
body a second time, they are
activated and damage tissue directly
through the release of cytokines or
toxins. The cytokines activate
eosinophils, monocytes, macrophages,
neutrophils, and killer cells. Type
IV reactions include contact
dermatitis, hypersensitivity
pneumonitis, allograft rejection,
and drug hypersensitivity reactions
(Merck, 2005). In contact
dermatitis, allergens combine
proteins in the skin and alter their
normal self-antigens so that foreign
antigens are created. Skin testing
for allergic reactions is performed
on the basis of type IV delayed
hypersensitivity reactions in which
the allergen is introduced into the
skin (see below) (Thomas, 1997). |
White blood cells produce antibodies
to antigens when they are exposed to
them. This process is called
“sensitization." These antibodies
detect and destroy these antigens
when the body is exposed to them a
second time. The antibody associated
with allergic reactions is called
IgE (Haith, 2005).
There are two phases of an allergic
reaction, an acute response and a
late phase response. The acute phase
occurs immediately after exposure to
an antigen and will subside or
progress into a late phase reaction
which prolongs the symptoms of the
response and can cause tissue damage
(Wikipedia, 2008). After the acute
response subsides, a late phase
response may occur as leukocytes (neutrophils,
lymphocytes, eosinophils, and
macrophages) migrate back to the
initial site, causing a reaction two
to 24 hours after the initial one
(Wikipedia, 2008).
Histamine is the major culprit in
the mediation of an allergic
reaction. An allergen will bind to
IgE (an antibody) which causes
histamine release from mast cells.
Mast cells are widely distributed
throughout the body, but are in
highest concentration in the skin,
lungs, and in the gastrointestinal
tract (Merck, 2007).
Histamine causes: 1) erythema (due
to vasodilation), 2) increased
capillary permeability (edema which
results in swelling/wheals), 3)
vasodilation (via neuronal reflex
mechanisms causing flare), and 4)
will stimulate sensory nerves (which
causes itching). Smooth muscle
contraction in the airways causes
bronchoconstriction and increased
gastrointestinal motility as well as
secretions into the lungs and via
salivary glands in the mouth. If a
systemic reaction occurs, peripheral
pooling is a result secondary to
arterial dilation. This can lead to
hypotension and shock (Merck, 2007).
In the early stages of an allergic
reaction (specifically type I
hypersensitivity) to an allergen
that is encountered for the first
time, a response occurs in the
T-helper 2 cells (a type of T-cell
that produces cytokines and
interleukin 4). These cells also
stimulate B cells to produce IgE in
response to interaction with
interleukin 4. IgE then binds to the
FcεRI receptor on mast cells and
basophils which further exacerbate
the immune response. Once these
cells are coated with IgE, they are
then sensitized to the allergen
(Wikipedia, 2008). When future
exposure to the allergen occurs, the
allergen then binds to the IgE
molecules on the mast cell or
basophil. When more than one IgE-
FcεRI receptor complex interacts
with an allergen molecule, it
activates the sensitized cell. Once
they are activated, the cells
degranulate and release histamine
and other mediators (cytokines,
interleukins, leukotrienes, and
prostaglandins) from their granules,
causing vasodilation, mucus
production, nerve stimulation, and
smooth muscle contraction
(Wikipedia, 2008).
See: Degranulation Process in an
Allergic Reaction
Degranulation Process in an Allergic
Reaction
Each type of IgE is specific for
only one type of allergen. This
explains why some people are
allergic to one allergen (example:
dog dander-as they only have the IgE
antibodies specific to that
allergen), and others are allergic
to other things (as they may have
other types of IgE antibodies
circulating in their bloodstream) (AAAAI,
2007).
Signs and symptoms of an allergic
reaction can vary depending on the
body type involved and type of
reaction (Haith, 2005). Common
symptoms of an allergic reaction
include runny nose (rhinorrhea),
stuffy nose, sneezing, itching,
headache, watery eyes, wheezing, and
dyspnea. Signs of an allergic
reaction may include blistering,
weeping of the skin, rash, hives,
welts, swelling of the face (or
eyes, lips, tongue, or throat),
edema of the airways, sinus pain,
wheezing, red eyes (conjunctival
hyperemia), swelling of the face,
and skin lichenification. If a
patient has stridor, inability to
breathe, wheezing, hypotension,
becomes unconscious, or confused,
they may be exhibiting signs of
anaphylactic shock which is caused
by extensive vasodilation. A person
in shock may be pale or red, sweaty
or dry, confused, anxious or
unconscious (Merck, 2007; Haith,
2005). The symptoms can vary being
system-wide or localized to a
particular site depending on the
individual, allergen, and mode of
introduction (Wikipedia, 2008).
|
Type
of Allergic C |
Body
System Involved |
Symptoms of Reaction |
 |
|
|
|
Allergic rhinitis (hay fever) |
Allergens touch the mucous membranes of the nose |
Congestion, itching, runny nose, itchy, watery
eyes, sinusitis, and otitis media. |
|
Allergic conjunctivitis |
Allergens touch the lining of the eyes. |
Red
eyes, itchy eyes, swollen eyes. |
|
Atopic dermatitis (eczema) |
Allergen exposure to the skin. |
Itching, reddening, flaking/peeling skin. |
|
Urticaria (hives) |
Allergen exposure to the skin. |
Itchy, red bumps. |
|
Asthma |
Allergen exposure to the lining of the lungs. |
Coughing, chest tightness, shortness of breath,
wheezing. |
|
Anaphylaxis |
Allergen exposure to certain stimuli which makes
its way into the bloodstream and causes a rapid,
severe reaction. |
Swelling, flushing, tingling, rash,
lightheadedness, shortness of breath, severe
sneezing, anxiety, abdominal cramping, vomiting,
diarrhea, loss of consciousness, and shock. |
|
(AAAAI,
2007) |
The most reliable diagnosis of an
allergy is obtained through the
patient's history (Haith, 2005;
Merck, 2007). Triggering factors,
frequency of allergic reaction,
duration, situations around attacks
(where attacks occur and what
activities are being done), family
history of similar allergic
reactions, etc. are all important to
obtain when diagnosing an allergy.
For patients who have asthma,
whether they began having asthma
attacks after the age of 30 or not
helps to determine whether or not
their asthma is secondary to
allergy, as childhood asthma is
usually secondary to allergy, and
adult-onset asthma usually is not
(Merck, 2007).
There are some tests that are rather
nonspecific that might suggest
allergy and can include CBC (to
detect the presence of eosinophilia),
sputum cultures (to examine for
leukocytes, eosinophils), or serum
IgE level (elevated in atopic
disorders). Although these levels
are increased in allergic disorders,
they are nonspecific and do not rule
out other causes for elevation
(Merck, 2007; Wikipedia, 2008).
A more specific allergy test for
allergic responses is skin testing.
Skin testing is done by introducing
a very small amount of a specific
antigen into the skin and watching
for a reaction. A test is considered
positive if a wheal and a flare
reaction occurs (wheal diameter 3 to
5 mm greater than that of the
control after 15 to 20 minutes). The
most common antigens used are those
for pollens, molds, dust, animal
dander, insect venoms, foods, and
certain antibiotics. Depending on
the environment in which the patient
lives and based on possible allergic
reactions in the past determines
which antigens are used. There are
two methods for performing skin
tests, percutaneous (where the
antigen is placed on the skin and
the skin is pricked slightly), and
intradermal (where the antigen is
injected into the dermis). Although
the intradermal test is more
sensitive, it is less specific and
is often done to confirm allergic
reactions after a positive skin
prick test is positive. In
conditions such as dermatographism
(where the skin wheals and flares
after simple stroking or scratching
of the skin), false positive results
can occur (Merck, 2007; Wikipedia,
2008).
Radioallergosorbent testing (RAST)
testing is done when skin testing
cannot be performed accurately or
when otherwise contraindicated. It
detects the presence of
allergen-specific serum IgE in the
serum and is quantified by measuring
the amount of antibody present in
serum (Merck, 2007; Haith, 2005;
Wikipedia, 2008).
Provocative testing is done by
exposing the patient directly to the
allergen source in order to document
reaction for various reasons. Food
allergies and some other allergens
are not easily measured with skin
testing due to lack of antigen
availability in that form and are
more accurately documented in this
way (Merck, 2007; Haith, 2005).
Medical attention is recommended in
all cases of allergic reactions
except those that are very minor and
localized. If the symptoms progress
over days, a physician should be
notified. Of course, sudden and
severe reactions require immediate
emergency care. If any of the
following occur, a medical
professional should be notified as
the reaction could progress towards
anaphylactic shock
(Haith, 2005):
|
1. |
Sudden and severe symptoms. |
| |
|
|
2. |
Exposure to an allergen that
has previously caused sudden
or severe reaction. |
| |
|
|
3. |
Swelling of the lips,
tongue, throat, or face. |
| |
|
|
4. |
Wheezing, chest tightness,
stridor, trouble breathing,
etc. |
| |
|
|
5. |
Nausea or vomiting,
confusion, unconsciousness. |
|
|
|
|
6. |
Widespread rash. |
The treatment of allergic reactions
begins with avoidance of triggering
stimuli and then medical treatment
after exposure to an allergen.
Removal of certain items that can
collect allergen material (soft
pillows, stuffed animals, etc.),
frequent washing/cleaning to remove
allergens from the environment (and
use of HEPA filters) and removal of
irritants such as perfumes, smoke,
odors, etc. can all help to avoid
allergic reaction. Severe reactions
should not be attempted to be cared
for at home (Merck, 2007; Haith,
2005).
There are several medications that
are used to block the action of
allergenic mediators (called
antagonistic drugs) to prevent the
activation of cells and to prevent
them from degranulating. Included in
these are antihistamines,
corticosteroids, epinephrine,
theophylline, and cromolyn sodium.
Anti-leukotrienes are also used.
Anti-cholinergics, decongestants,
mast cell stabilizers, and others
may help to prevent the movement of
eosinophils in response to
allergens. These only treat the
acute phases of an allergic
reaction, and are not for the
chronic treatment of allergy
(Wikipedia, 2008).
Antihistamines are used to block
histamine receptors in the body.
Histamine-1 (H1) blockers are widely
used for allergic disorders,
histamine-2 (H2) blockers are most
effective the in gastrointestinal
tract for acid suppression and are
not usually used in the treatment of
atopic disorders. H1 blockers are
most effective in the treatment of
atopic disorders and are less
effective in treating
bronchoconstriction (in asthma) and
vasodilation. Antihistamines can be
used intranasally and ocularly as
well. The most common side effect
from oral antihistamines is
drowsiness (Merck, 2007; Haith,
2005).
Mast cell stabilizers can be used to
block the release of mediators from
mast cells and their subsequent
effects. These are usually used when
antihistamines and corticosteroids
are not available or are
contraindicated (Merck, 2007).
Antiinflammatories are used to treat
symptoms of allergic reaction due to
swelling. NSAIDs are not effective
enough to do this, and thus,
corticosteroids are the drugs of
choice. Corticosteroids reverse the
effect of systemic mediators. Nasal
corticosteroids are most often
prescribed and have few side effects
as compared to corticosteroids taken
orally or via injection (Merck,
2007; Haith, 2005).
Leukotriene modifiers are used in
the treatment of asthma and seasonal
allergic rhinitis to prevent the
side effects from leukotriene
production by the body (Merck,
2007).
Anti-IgE antibody is used for more
severe cases of asthma that do not
respond to other treatments and may
also be helpful in cases of rhinitis
that are refractory to other
treatments (Merck, 2007).
Decongestants can be given to reduce
sinus drainage and relieve nasal
congestion and swelling, and sinus
pain (Haith, 2005).
Treatment by immunotherapy is based
on the theory of hyposensitization/desensitization
via injection of the allergen to the
patient. This does not treat the
symptoms of an allergic reaction,
but alters the immune response to
prevent further reactions by
increasing IgG production which in
turn blocks excessive IgE
production. This form of treatment
is indicated when the patient cannot
avoid allergen exposure and medical
treatment is not otherwise
available. This is done by giving an
injection of the allergen monthly.
The dose of the allergen is
increased until a maximum tolerated
concentration is reached, meanwhile
observing the patient to ensure no
serious reaction takes place. This
maximum dose is then given every 4
to 6 weeks year round. This can be
done for most allergens including
pollen, dust, mold, and insect
venom. It can be done for animal
dander in those who cannot avoid
exposure and for certain antibiotics
such as penicillin. Food
desensitization is not performed
(Merck, 2007; Haith, 2005;
Wikipedia, 2008). A second type of
immunotherapy is performed in which
monoclonal anti-IgE antibodies are
injected into the bloodstream which
bind to free IgE and destroys them.
(It does not affect IgE that are
already bound to the FcεRI
receptor-if it did, it would signal
a response instead.) Sublingual
immunotherapy is a third form which
is orally administered and uses oral
immune tolerance to antigens such as
foods and resident bacteria. Oral
tolerance refers to specific
suppression of cellular and/or
humoral immune reactivity to an
antigen by administration of the
antigen orally (Wikipedia, 2008).
In the event that a patient has an
anaphylactic reaction, evaluation in
the emergency department is
performed on the basis of
stabilizing the patient by
monitoring blood pressure,
respiratory sufficiency, history of
what possibly caused the reaction,
and an IV line is often placed in
case of further/continued emergency.
Epinephrine is given in anaphylaxis
and works by dilating the
bronchioles (bronchodilator) and
constricts blood vessels (to
increase blood pressure) (Haith,
2005).
Primary prevention of allergic
reaction centers around avoidance of
known triggers. Desensitization or
immune therapy can help to prevent
future allergic attacks, especially
for those that cannot be readily
avoided. For patients who are
allergic to IV dye, they should
avoid exposure if at all possible.
When it is not possible,
administration of prednisone and
diphenhydramine before the procedure
may help to prevent complications
from IV dye administration (Merck,
2007). For those patients who have
anaphylactic reactions to certain
triggers, carrying a prefilled
epinephrine syringe to be injected
at the time of exposure may prevent
reaction and the need for
hospitalization (Merck, 2007; Haith,
2005).
Some of the most common allergens
are listed below. Some people have
cross reactions to items that are
similar in protein structure. For
instance, children can be allergic
to birch pollen and have the same
reaction with eating apples because
the protein construction in each is
similar. It is important to know
associated allergic classes as to
potentially prevent other reactions
from occurring. This scenario is
common with medication allergies,
and the most common classes of
medication allergies are listed
below as well (ACENTA, 2003;
Geimeier, 2007, and More, 2009):
Common Airborne allergens:
|
1. |
Dust mites. |
| |
|
|
2. |
Pollen. |
| |
|
|
3. |
Molds. |
| |
|
|
4. |
Pet dander. |
| |
|
|
5. |
Cockroaches. |
Common Food Allergens:
|
1. |
Cow's milk (protein). |
| |
|
|
2. |
Eggs. |
| |
|
|
3. |
Seafood/shellfish (can be
associated with allergy to
iodine or IV contrast dye). |
| |
|
|
4. |
Peanuts/tree nuts
(associated with allergies
to legumes, grass, wheat,
corn). |
| |
|
|
5. |
Soy. |
| |
|
|
6. |
Wheat. |
Other Common Allergens:
|
1. |
Insect stings. |
| |
|
|
2. |
Chemicals (detergents,
perfumes, etc.) |
| |
|
|
3. |
Grass (can be associated
with allergy to potato,
melon, tomato, watermelon,
orange, cherry, peanut) |
| |
|
|
4. |
Latex (can be associated
with allergy to avocado,
potato, banana, tomato,
chestnut, kiwi fruit, herbs,
carrot). |
| |
|
|
5. |
Medications. |
| |
| |
|
|
a. |
Penicillin (and associated
antibiotics, the "-cillins"). |
| |
|
|
b. |
Cephalosporins (also
associated with allergy to
penicillin derivatives). |
| |
|
|
c. |
Sulfonamides. |
| |
|
|
d. |
Non-steroidal
anti-inflammatory drugs (NSAIDs). |
| |
|
|
e. |
IV contrast dye. |
| |
|
|
f. |
Local anesthetics (often the
preservatives in the
preparations are the source
of the reaction to these
medications). |
| |
|
|
g. |
General anesthesia. |
| |
|
|
h. |
Anti-seizure medications. |
| |
|
|
| |
|
Other Common Cross Reactions:
|
1. |
Birch: Apple, carrot,
cherry, pear, peach, plum,
fennel, walnut, potato,
spinach, wheat, buckwheat,
peanut, honey, celery, kiwi
fruit, hazelnut, anise,
fennel, coriander, cumin. |
| |
|
|
2. |
Mugwort Sage: Celery,
carrot, spices, melon,
watermelon, apple,
chamomile, hazelnut, anise,
fennel, coriander, cumin. |
| |
|
|
3. |
Ragweed: Melon, chamomile,
honey, banana, sunflower
seeds |
| |
|
|
4. |
Plantains: Melon |
Nurses in the hospital setting can
help identify existing allergies by
taking a history from patients
regarding past reactions to
medications, foods, or environmental
factors. Accurate documentation of
these previous reactions may help to
prevent an inadvertent reaction
while the patient is in the hospital
setting, during a potentially
vulnerable time. Accurate
assessments of patients in the
hospital may help the nurse to
identify an allergic reaction a
patient may be having to something
introduced within the hospital. In
this instance, it is important for
the nurse to accurately document the
findings and notify the appropriate
personnel to initiate/prescribe
treatment for the reaction, if
necessary. An anaphylactic reaction
within the hospital setting may
require advanced cardiac support
skills and would require the nurse
to accurately assess the situation
and initiate appropriate care. Any
allergies discovered in the hospital
setting should be explained to the
patient along with how to avoid such
triggering factors and potential
reactions in the future. Knowledge
of the different classes of
medications and potential cross
reactions helps the nurse to educate
the patient to identify not only the
particular medication/allergen to
avoid, but also class(es) of
medications/allergens to which a
patient may have similar reactions.
Nurses who work in the community
setting can be instrumental working
with patients with allergies by
educating them about particular
signs and symptoms of an allergic
reaction and when a reaction is
serious enough to warrant emergency
intervention. Teaching can be
undertaken for patients with known
allergies regarding usage of
medications for mild allergic
reactions and severe reactions
including how to use epinephrine
injectional systems for patients who
have potential or known anaphylactic
reactions to certain triggers. Often
hyposensitization shots are
administered by nurses in the
community setting. It is important
to monitor response to all
therapies, and this can be done by
the nurse directly while the patient
is in his/her care, or by taking a
verbal history from the patient. If
a response is noted, the nurse may
need to notify the patient's
physician about the reaction, and
may administer care to the patient,
depending on the severity and type
of reaction. The nurse can help the
patient identify triggering factors
by encouraging them to keep a log of
reactions and all potential
triggers. Once the triggers are
known, nurses can help patients
learn ways to avoid these triggering
factors and potential further
reaction.
Allergic reactions are usual
responses to any number of various
potential triggers and can become
very serious and life threatening.
Careful notice of reaction to which
triggers, when, and under which
circumstances can help a patient to
identify their specific triggering
factors. Skin testing can also be of
help in identifying triggering
factors. Once the factors are
identified, they can more readily be
avoided, and if not able to be
avoided, medical therapy can be
utilized to prevent future reaction.
Of course, in the event of any major
reaction, emergency medical
attention should always be sought
for the patient.
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