Question 5: If a patient with an inoperable cancer is treated using a drug that reduces the rate of cell division, how might the patient’s white blood cell count change? How might the patient’s environment be modified to compensate for the effects of these changes?
Answer:
If a drug
that reduces the rate of cell division is given to a cancer patient, one would
expect a decrease in that person’s white blood cell count (Prinjha, and
Tarakhovsky, 2013).This is because not only would the cancer cells have their
rate of cell division stunted, but the immune cells would also.
A drug which
inhibits cancer cell growth and is given to a patient with an inoperable cancer
is likely to be a form of targeted therapy in regard to cancer treatment. These
drugs are more specialised in choosing cancer cells to exhibit their effects.
Older drugs find it harder to differentiate between healthy and cancerous
cells, and given that their effect usually increases depending on the rate of
cell reproduction (advantageous because cancer cells tend to rapidly
reproduce), these older drugs commonly cause much harm to fast-growing cells
such as the skin and digestive tract. However, targeted therapies still have
substantial side-effects, particularly fatigue, nausea, skin and clotting
problems as well as elevated blood pressure. These forms of drugs, however,
would have less effect upon the white blood cell count than ordinary drugs
(National Cancer Institute, 2014).
Chan, Koh
and Li (2012), state that cancerous cells are most vulnerable during mitosis
and that the use of drugs centred on cell division is therefore of high
importance to cancer treatment. They also state that drugs producing
antimitotic effects tend to be highly specific, but that the body reacts
unpredictably when exposed to them.
According to
Schmidt (2000 pp. 112-115), the production of thymidylate and dihydrofolate are
of substantial importance in the role of DNA synthesis. Given that cancer is
fundamentally a cellular error causing uncontrolled replication, the inhibition
of DNA synthesis plays a pivotal role in treating cancer. A compound called
5-fluorouridine bears strong similarity to the substrate acted upon by
thymidylate synthase, once it has been phosphorylated by a nucleoside kinase
(the only difference is that this product contains a fluorine where the natural
substrate, dUMP, contains hydrogen). However, once this end-product (called
5-fluorouridine monophosphate) binds with thymidylate synthase, the fluorine
stays bonded to the enzyme, causing it to no longer function. Since the 5-fluorouridine
monophosphate reacts with the enzyme, and the enzyme can no longer function
afterwards, it is called a “suicide substrate”. DNA necessary for cell division
can also be reduced by decreasing the reduction of dihydrofolate to
tetrahydrofolate. When N5,N10-methylene tetrahydrofolate
donates a methyl group to deoxy-UMP under the supervision of the thymidylate
synthase enzyme, thymidylate (deoxy-TMP) is formed. This reaction is
illustrated in figure 5.1.
Since the
tetrahydrofolate compound in this reaction is oxidised to dihydrofolate, the
converse of this (reduction of dihydrofolate by dihydrofolate reductase (DHFR)),
will consequently lead indirectly to thymidylate production. Thus, the
inhibition of DHFR will also reduce thymidylate production. Substrates which
are competitive inhibitors of folates are called folate antagonists, where an
antagonist is a substance that binds to a receptor, without producing the
receptor’s activity. Thus, a substance binding to a folate-receptor, may not
produce the same effect as a folate-containing substance binding to it. The
From Schmidt
(2000, p. 230), information is given about the G1 phase of cell division. This
particular phase is actually a point of non-division, in which various
biochemical reactions take place, but the cell does not actively divide. Many
animal cells can spend years in the G1 phase without dividing, which makes it
highly important in cancer treatment. If the G1 phase could be clearly
understood, then cells could be encouraged to remain within it, not dividing,
and consequently not resulting in cancer formation. An unfortunate consequence
of decreasing cell division non-specifically however, is that all cells in the
body which take in a particular drug that decreases cell division will have
their rate of replication decreased. This makes it more difficult for the body
to combat infections which are not affected by the drugs, given that the body
cells may be subjected to division-inhibition for many weeks or months before
encountering a new infection, its immune cells are likely to be lower in number
and therefore not be as capable of combating the threat.
If the
number of white blood cells that a patient has, decreases, then that person is
more susceptible to all possible infections as these cells fight them.
Among the
white blood cells or leukocytes, the form most important during consideration
of possible infections is the neutrophil. This is the type of white blood cell
most abundant in plasma, constituting roughly 54-62% of the overall number of
circulating leukocytes (Mescher 2013, p. 235). Neutrophils are relatively small
phagocytic immune cells that are produced in vast quantities every day (roughly
126 billion enter the digestive tract daily, according to Seeley, VanPutte,
Regan and Russo, 2011, p. 791), and are often the first of the immune cells to
reach infected regions in great numbers. Once at an infected site, neutrophils
are responsible for increasing immune cell activity and inflammation at this
area. This is brought about by their release of cytokines which encourage the
proliferation and differentiation of immune cells, and by chemotactic agents,
respectively (Seeley, VanPutte, Regan and Russo, 2011, p. 792).
The test for
abundance of circulating neutrophils is called the absolute neutrophil count
(ANC), and is considered the most important risk factor for both bacterial and
fungal infections, according to Johnston and Spence (eds, 2003, p. 253). The
diagnosis of neutropenia (a deficiency of neutrophils), is stated as an ANC of
less than 500 per millilitre of plasma, or expected to fall to this level
within the next 24 hours of being tested. These writers also state that risk
increases as neutrophil count decreases, and that the rate at which neutrophil
count is decreasing, as well as how long neutropenia has presented, also play a
pivotal role in contracting bacterial and fungal infections. The more rapidly
neutrophil count is falling, and the longer a person has had neutropenia, the
more likelihood there is of becoming infected, and the more severe the
infection is likely to be. Thus, it is highly important to consider
neutropenia, although B-cell and T-cell function is also compromised in cancer
treatment, usually due to chemotherapy, but further exacerbation can occur via
concomitant utilisation of steroids (Johnston and Spence, eds, 2003, p. 246).
These authors also explain that the use of catheters in immunocompromised
cancer patients poses a significant risk of subsequent infection, this is due
to the ease with which microbial colonies can form within the synthetic
catheter, possibly migrating into the host and causing infection. Therefore, it
is of the utmost importance that catheters be monitored and if possible,
sampled, in order to gauge microbial growth.
There are
many other types of immune cell that are important in the response to
infection. This first section deals with those cells which are an integral part
of the innate immune system, i.e. the branch of the immune system acts in a
non-specific manner:
Neutrophils
fall into this category but are explained in detail above.
Monocytes
are white blood cells that circulate the body and are enticed by
chemo-attractants to enter damaged tissue and differentiate into macrophages
which are important for consuming toxic substances and cells that may damage
the body, they may also stimulate B-cell and T-cell activity during infection (Seeley,
VanPutte, Regan and Russo, 2011, p. 791). Macrophages are roughly 5 times the
size of monocytes, and have additional lysozymes and mitochondria. They are
larger, longer-lasting, and are capable of engulfing larger particles than
neutrophils, though they appear at the site of infection a little later than
neutrophils. Thus, they are most used in the later stages of infection. Their
large size makes them ideal for engulfing cellular debris, and even whole
neutrophils which have died earlier on during the immune response. Macrophages
may also secrete various substances such as interferons, complement, and
prostaglandins. The roles of interferons and complement are discussed
elsewhere, but prostaglandins have a variety of actions, perhaps most
importantly of which are its function in increasing the permeability of blood
vessels (which can allow immune cells to permeate vascular and reach infected
or damaged tissue, and also in causing vasodilation, again allowing immune
cells to reach a particular site by aiding blood flow to the affected region.
This is shown by Seeley, VanPutte, Regan and Russo, 2011, pp. 789, 792.
Both
basophils (motile) and mast cells (nonmotile) are immune cells that promote
inflammation within tissues through the release of various chemicals, e.g.
leukotrienes and histamine. This inflammatory response can increase blood flow
to the area, signal other leukocytes to arrive on the scene, and encourage the
formation of either a platelet plug or clot to seal off the affected region to
further damage and/or infection. Conversely, eosinophils are motile immune
cells that enter tissues and inhibit the inflammatory response. They do this by
breaking down the substances secreted by the basophil and mast cells.
Therefore, eosinophils are produced in larger quantities during immune
reactions where a large inflammatory response occurs, such as in allergies.
Additionally, eosinophils have the ability to kill some forms of parasites (Seeley,
VanPutte, Regan and Russo, 2011, pp. 791-793).
Finally, NK
(natural killer) cells are important in the attack on cancer cells. NK cells
contain enzymes that can chemically lyse or split tumour cells, preventing the
growth spread of cancer, one of their preferred mechanisms of actions is to
chemically lyse the plasma membrane of harmful cells (Seeley, VanPutte, Regan
and Russo, 2011, p. 791-792).
The adaptive
immune system then, deals with specific and personalised threats to the body. This
branch of the immune system is capable of responding to a specific substance,
called an antigen. These antigens may be produced by the body, for example, a tumour
cell (a self-antigen), or produced by a foreign invader or microbe which has
found its way into the body and may cause harm (a foreign antigen). Within the
umbrella term of adaptive immunity, there are two main categories of immune
response; cell-mediated immunity and antibody-mediated immunity.
Antibody-mediated immunity is brought about by the production of antibodies
(these are released by cells that result from the differentiation of B-cells)
that bind with antigens to form antigen-antibody complexes that inhibit the
actions of harmful cells. On the other hand, cell-mediated immunity arises from
the activity of T-cells, which can destroy whole cells instead of inhibiting
vital components. This is highly useful for infections from viruses, which essentially
‘hijack’ the biochemical reactions of a cell for their own needs (Seeley,
VanPutte, Regan and Russo, 2011, p. 794-806).
The adaptive
immune system almost entirely consists of B-cells and T-cells to combat
infection:
B-cells can
be stimulated by antigens on the cell surface membrane of a pathogen and
differentiate to produce either a plasma cell or memory B-cell. The plasma cell
in this scenario would produce antibodies complementary in shape to the harmful
antigen which would inhibit the effectiveness of the pathogen and signal for
its lytic destruction by neutrophils, eosinophils, macrophages or monocytes.
The memory B-cells formed by differentiated of B-cells can promote a rapid and
lasting immune reaction to a specific form of pathogen. If this pathogen were
to enter the body, memory B-cells would mass-produce antibodies that would
inhibit its actions. (Seeley, VanPutte, Regan and Russo, 2011, pp.791, 803).
There are
many types of T-cells; delayed hypersensitivity T-cells promote inflammation through
the release of cytokines, helper T-cells stimulate the activity of effector
T-cells and B-cells, Suppressor T-cells do the opposite, inhibiting the action
of both T-cells (effector forms) and B-cells, and lastly, memory T-cells are
similar to memory B-cells in their ability to maintain a lasting immunity
towards a particular antigen that has been previously encountered. (Seeley,
VanPutte, Regan and Russo, 2011, p. 791).
Finally,
dendritic cells activate both B-cells and T-cells after recognition of a harmful
antigen (Seeley, VanPutte, Regan and Russo, 2011, p. 791).
Another area
of concern is the mucous membrane throughout the digestive tract. This membrane
can become inflamed and mouth, stomach and other ulcers can result from the use
of both chemotherapy and radiotherapy (depending on where the latter is
targeted to), these ulcers and general damage to the mucous membrane can
facilitate the harbouring of pathogens which can infect the body (Johnston and
Spence, eds, 2003, p. 253). Further to this, though beyond the scope of this
essay, is the effect of the underlying cause or simultaneous condition with
regard to cancer. Chronic lung or liver diseases as well as AIDS, can
independently compromise immune function, which would only be worsened by cancer
treatment.
Care must be
taken to ensure proper health of skin, teeth and the general oral cavity.
Healthy skin and mucous membranes in the oral cavity produce secretions that
prevent bacterial infection. For example, skin secretes oils and has an acidic
pH due to the actions of sebaceous and sweat glands. Saliva in the oral cavity
contains many antimicrobial agents, including the protein lysozyme, which
destroys the cells walls of bacteria. These are some examples of nonspecific
barriers (methods that provide a broad-spectrum of defence not limited to a
single pathogen at a time). See Houghton Mifflin Harcourt (2014). Broken skin,
infected gums and rotting teeth can all harbour bacteria that can lead to an
infection the immunocompromised patient. Antibiotics may be taken to control
overall and in particular, digestive bacteria, lest these should turn
pathological.
According to
Pack (2001, pp. 210-212), there are three types of barrier preventing
infections to the body. These are the nonspecific barriers, the nonspecific
defences, and the specific defences of the body. Many of the nonspecific
barriers have already been covered, these are; skin, sweat, proteins such as
lysozyme, cilia, digestive juices, and commensals (symbiotic organisms exist in
and on the human body that can compete against harmful microbes). These
barriers prevent the inward movement of harmful substances and microbes into
the body.
The
nonspecific defences are responsible for nonspecific removal and destruction of
threats that have found their way into the body. Examples include phagocytes
(white blood cells that engulf and digest pathogens, neutrophils, eosinophils,
macrophages and monocytes are included in this category). Natural killer cells,
are also on the list, as well as interferons and a defensive chemical called
“complement”. Interferons are released by cells that are infected by viruses,
and help the immune system recognise when a viral infection has occurred. Interferon
is also aptly named for its ability to interfere with the production of viruses
(Seeley, VanPutte, Regan and Russo, 2011, p. 789). Complement is a compound
formed by roughly 20 proteins bonded together which attracts phagocytic immune
cells to the site of an infection, as well as lysing cells by its own actions
(Pack, 2001, p. 211).
The immune
system forms the specific defence system against foreign microbes (Pack, 2001,
p. 213). Some of the nonspecific defences such as natural killer cells and
phagocytes are used for specific defence, particularly when an antigen has become
part of an antigen-antibody complex and immune cells are signalled to engulf
it.
On page 254
(Johnston and Spence, eds, 2003), the authors make known the vices of surgical
removal of the human spleen, which can take place occasionally as part of cancer
treatment. They state that the spleen is necessary for removal of opsonized
pathogens (those bound by antibodies in the preparation of phagocytosis) and
erythrocytes which have been infected with parasites. Surgical removal of the
spleen also reduces the body’s ability to develop immune reactions to
previously unencountered antigens. According to Pack (2001, pp. 204-209), the
spleen is the largest organ in the lymphatic system. It contains two distinct
regions; the white pulp and the red pulp. The white pulp contains many
lymphocytes (T cells and B cells), as well as reticular fibres, whereas the red
pulp contains many venous sinuses that act as a reservoir of red blood cells.
The spleen has several main functions; filtering the blood of pathogens and debris
from dead and aged cells, the destruction of old erythrocytes and subsequent
recycling of organelles and nutrients, acting as a reserve for blood, and
providing a site of T cell and B proliferation (T cells reproduce before
returning to attack non-self cells and B cells produce antibodies and plasma
cells which go on to inactivate harmful antigens. Thus, its removal can have
dangerous consequences.
The above
effects combined produce a patient who is highly susceptible to infection. They
mention several bacteria whose infections are more commonly and severely
present in immunocompromised patients, there are; Streptococcus pnuemoniae, Capnocytophaga canimorsus and Babesia microti (a bacterium that
presents with malaria-like symptoms such as fever, chills, sweating, and head
and body aches information that is elaborated upon by the Centers for Disease
Control and Prevention, 2014a).
Wigglesworth
(2003) gives a lot of information on the use of environment changes for
immunosuppressed patients. If such patients are currently residing in a
hospital then they can be separated from the main hospital population and wads,
usually by keeping them in a single room. Hygiene is of particular importance
to ensure that no pathogens are transferred from care workers to the patient.
Hand-washing is a must in this scenario.
According to
the University of Utah Health Care (2003), proper hand-washing is the most
important action in the prevention of infectious diseases. The amount of
visitors that a person meets during the day and the foods that they eat must be
monitored to ensure there is little risk of infection. Certain foods are
considered high-risk when it comes to patients with a weakened immune system,
extra care must be taken to avoid these foods. Soft cheeses and anything made
with raw eggs are a hazard for such patients. Therefore, mayonnaise was also be
avoided.
Additionally,
the use of vaccinations before a person is likely to become immunocompromised
can decrease the likelihood of infection. This has been proposed as a strategy
for persons likely to exhibit lower immune function for a number of different
reasons including cancer and HIV (Tolan, et al, 2013).
The Centers
for Disease Control and Prevention recommend that any sign of fever in patients
receiving chemotherapy be treated as an emergency, even if it is the only
symptom (Centers for Disease Control and Prevention, 2014b). Further safety
precautions can be taken to reduce the chance of infection can be taken. One
can avoid sharing any personal items, such as cups or utensils or anything that
requires insertion into the mouth, e.g. toothbrushes. Daily washing should be
done with unscented lotions. Lotions which are scented can damage or dry the
skin, allowing pathogens to colonise or pass through this layer. Meat and eggs
must be cooked thoroughly, raw fruit and vegetables must be washed carefully,
gloves should be worn around pets and for gardening, and care must be taken to
avoid damaging the gums during tooth-brushing (thus a soft toothbrush is highly
recommended), see Centers for Disease Control and Prevention, 2014c. This same
source provides ample knowledge of the warning signs of infection in order to
warn immunocompromised patients. Some of the more noticeable signs are; a fever
of >38oC for over one hour, sore throat, burning or other pain
upon urination, shortness of breath, diarrhoea, vomiting and increased
urination.
Finally, the
Centers for Disease Control and Prevention also note that white blood cell
usually drops to its lowest value as a result of chemotherapy around 7 to 12
days after the chemotherapy dose has finished, and from this point the low
count can last for around a week before increasing again. This lowest point is
when most vigilance is required in protecting oneself from infection, as the
immune system will be most weakened and unable to respond adequately (Centers
for Disease Control and Prevention, 2014d).
Question 5 References:
Centres for
Disease Control and Prevention, 2014a. Babesiosis
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Centres for
Disease Control and Prevention, 2014b.Emergency
Room Personnel, [online] Available at: < http://www.cdc.gov/cancer/preventinfections/pdf/er_personnel_poster.pdf
> [Accessed 13 April 2015].
Centres for
Disease Control and Prevention, 2014c. How can I prevent an infection? [online] Available at: < http://www.cdc.gov/cancer/preventinfections/pdf/neutropenia.pdf
> [Accessed 13 April
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Centres for
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Chan, K.S.,
Koh, C.G., and Li, H.Y., 2012. Mitosis-targeted
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Houghton
Mifflin Harcourt 2014. Nonspecific
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Johnston,
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National
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Schmidt, F.,
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