Mesothelioma
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Mesothelioma is a form of cancer that is almost always caused by previous exposure to asbestos. In this disease, malignant cells develop in the mesothelium, a protective lining that covers most of the body's internal organs. Its most common site is the pleura (outer lining of the lungs and chest cavity), but it may also occur in the peritoneum (the lining of the abdominal cavity) or the pericardium (a sac that surrounds the heart). |
Most people who develop mesothelioma have worked on
jobs where they inhaled asbestos particles, or have
been exposed to asbestos dust and fibre in other ways,
such as by washing the clothes of a family member who
worked with asbestos, or by home renovation using
asbestos cement products. Unlike lung cancer, there is
no association between mesothelioma and smoking
Signs and symptoms of Mesothelioma
Symptoms of mesothelioma
may not appear until 20 to 50 years after exposure to
asbestos. Shortness of breath, cough, and pain in the
chest due to an accumulation of fluid in the pleural
space are often symptoms of pleural mesothelioma.
Symptoms of peritoneal mesothelioma include weight
loss and cachexia, abdominal swelling and pain due to
ascites (a buildup of fluid in the abdominal cavity).
Other symptoms of peritoneal mesothelioma may include
bowel obstruction, blood clotting abnormalities,
anemia, and fever. If the cancer has spread beyond the
mesothelium to other parts of the body, symptoms may
include pain, trouble swallowing, or swelling of the
neck or face.
These symptoms may be caused by mesothelioma or by
other, less serious conditions.
Mesothelioma that affects the pleura can cause these
signs and symptoms:
* chest wall pain
* pleural effusion, or fluid surrounding the lung
* shortness of breath
* wheezing, hoarseness, or cough
In severe cases, the person may have many tumor
masses. The individual may develop a pneumothorax, or
collapse of the lung. The disease may metastasize, or
spread, to other parts of the body.
Tumors that affect the abdominal cavity often do not
cause symptoms until they are at a late stage.
Symptoms include:
* abdominal pain
* ascites, or an abnormal buildup of fluid in the
abdomen
* a mass in the abdomen
* problems with bowel function
* weight loss
In severe cases of the disease, the following signs
and symptoms may be present:
* blood clots in the veins, which may cause
thrombophlebitis
* disseminated intravascular coagulation, a disorder
causing severe bleeding in many body organs
* jaundice, or yellowing of the eyes and skin
* low blood sugar level
* pleural effusion
* pulmonary emboli, or blood clots in the arteries of
the lungs
* severe ascites
A mesothelioma does not usually spread to the bone,
brain, or adrenal glands. Pleural tumors are usually
found only on one side of the lungs.
Diagnosis Mesothelioma
Diagnosing mesothelioma is often difficult, because the symptoms are similar to those of a number of other conditions. Diagnosis begins with a review of the patient's medical history. A history of exposure to asbestos may increase clinical suspicion for mesothelioma. A physical examination is performed, followed by chest X-ray and often lung function tests. The X-ray may reveal pleural thickening commonly seen after asbestos exposure and increases suspicion of mesothelioma. A CT (or CAT) scan or an MRI is usually performed. If a large amount of fluid is present, abnormal cells may be detected by cytology if this fluid is aspirated with a syringe. For pleural fluid this is done by a pleural tap or chest drain, in ascites with an paracentesis or ascitic drain and in a pericardial effusion with pericardiocentesis. While absence of malignant cells on cytology does not completely exclude mesothelioma, it makes it much more unlikely, especially if an alternative diagnosis can be made (e.g. tuberculosis, heart failure).
If cytology is
positive or a plaque is regarded as suspicious, a
biopsy is needed to confirm a diagnosis of
mesothelioma. A doctor removes a sample of tissue
for examination under a microscope by a
pathologist. A biopsy may be done in different
ways, depending on where the abnormal area is
located. If the cancer is in the chest, the doctor
may perform a thoracoscopy. In this procedure, the
doctor makes a small cut through the chest wall
and puts a thin, lighted tube called a
thoracoscope into the chest between two ribs.
Thoracoscopy allows the doctor to look inside the
chest and obtain tissue samples.
If the cancer is in the abdomen, the doctor may
perform a laparoscopy. To obtain tissue for
examination, the doctor makes a small opening in
the abdomen and inserts a special instrument into
the abdominal cavity. If these procedures do not
yield enough tissue, more extensive diagnostic
surgery may be necessary.
Screening Mesothelioma
There is no universally agreed protocol for screening people who have been exposed to asbestos. However some research indicates that the serum osteopontin level might be useful in screening asbestos-exposed people for mesothelioma. The level of soluble mesothelin-related protein is elevated in the serum of about 75% of patients at diagnosis and it has been suggested that it may be useful for screening.
Staging Mesothelioma
Once the diagnosis is confirmed, the doctor may need to assess the stage to help plan treatment.
Mesothelioma is described as localized if the cancer is found only on the membrane surface where it originated. It is classified as advanced if it has spread beyond the original membrane surface to other parts of the body, such as the lymph nodes, lungs, chest wall, or abdominal organs.
Pathophysiology Mesothelioma
The mesothelium consists of a single layer of flattened to cuboidal cells forming the epithelial lining of the serous cavities of the body including the peritoneal, pericardial and pleural cavities. Deposition of asbestos fibres in the parenchyma of the lung may result in the penetration of the visceral pleura from where the fibre can then be carried to the pleural surface, thus leading to the development of malignant mesothelial plaques. The processes leading to the development of peritoneal mesothelioma remain unresolved, although it has been proposed that asbestos fibres from the lung are transported to the abdomen and associated organs via the lymphatic system. Additionally, asbestos fibres may be deposited in the gut after ingestion of sputum contaminated with asbestos fibres.
Pleural contamination with asbestos or other
mineral fibres has been shown to cause cancer.
Long thin asbestos fibers (blue asbestos,
amphibole fibers) are more potent carcinogens than
"feathery fibers" (chrysotile or white asbestos
fibers). However, there is now evidence that
smaller particles may be more dangerous than the
larger fibers. They remain suspended in the air
where they can be inhaled, and may penetrate more
easily and deeper into the lungs. "We probably
will find out a lot more about the health aspects
of asbestos from [the World Trade Center attack],
unfortunately," said Dr. Alan Fein, chief of
pulmonary and critical-care medicine at North
Shore-Long Island Jewish Health System. Dr. Fein
has treated several patients for "World Trade
Center syndrome" or respiratory ailments from
brief exposures of only a day or two near the
collapsed buildings.
Mesothelioma development in rats has been
demonstrated following intra-pleural inoculation
of phosphorylated chrysotile fibres. It has been
suggested that in humans, transport of fibres to
the pleura is critical to the pathogenesis of
mesothelioma. This is supported by the observed
recruitment of significant numbers of macrophages
and other cells of the immune system to localised
lesions of accumulated asbestos fibres in the
pleural and peritoneal cavities of rats. These
lesions continued to attract and accumulate
macrophages as the disease progressed, and
cellular changes within the lesion culminated in a
morphologically malignant tumour.
Experimental evidence suggests that asbestos acts
as a complete carcinogen with the development of
mesothelioma occurring in sequential stages of
initiation and promotion. The molecular mechanisms
underlying the malignant transformation of normal
mesothelial cells by asbestos fibres remain
unclear despite the demonstration of its oncogenic
capabilities. However, complete in vitro
transformation of normal human mesothelial cells
to malignant phenotype following exposure to
asbestos fibres has not yet been achieved. In
general, asbestos fibres are thought to act
through direct physical interactions with the
cells of the mesothelium in conjunction with
indirect effects following interaction with
inflammatory cells such as macrophages.
Analysis of the interactions between asbestos
fibres and DNA has shown that phagocytosed fibres
are able to make contact with chromosomes, often
adhering to the chromatin fibres or becoming
entangled within the chromosome. This contact
between the asbestos fibre and the chromosomes or
structural proteins of the spindle apparatus can
induce complex abnormalities. The most common
abnormality is monosomy of chromosome 22. Other
frequent abnormalities include structural
rearrangement of 1p, 3p, 9p and 6q chromosome
arms.
Common gene abnormalities in mesothelioma cell
lines include deletion of the tumor suppressor
genes:
* Neurofibromatosis type 2 at 22q12
* P16INK4A
* P14ARF
Asbestos has also been shown to mediate the entry
of foreign DNA into target cells. Incorporation of
this foreign DNA may lead to mutations and
oncogenesis by several possible mechanisms:
* Inactivation of tumor suppressor genes
* Activation of oncogenes
* Activation of proto-oncogenes due to
incorporation of foreign DNA containing a promoter
region
* Activation of DNA repair enzymes, which may be
prone to error
* Activation of telomerase
* Prevention of apoptosis
Asbestos fibres have been shown to alter the
function and secretory properties of macrophages,
ultimately creating conditions which favour the
development of mesothelioma. Following asbestos
phagocytosis, macrophages generate increased
amounts of hydroxyl radicals, which are normal
by-products of cellular anaerobic metabolism.
However, these free radicals are also known
clastogenic and membrane-active agents thought to
promote asbestos carcinogenicity. These oxidants
can participate in the oncogenic process by
directly and indirectly interacting with DNA,
modifying membrane-associated cellular events,
including oncogene activation and perturbation of
cellular antioxidant defences.
Asbestos also may possess immunosuppressive
properties. For example, chrysotile fibres have
been shown to depress the in vitro proliferation
of phytohemagglutinin-stimulated peripheral blood
lymphocytes, suppress natural killer cell lysis
and significantly reduce lymphokine-activated
killer cell viability and recovery. Furthermore,
genetic alterations in asbestos-activated
macrophages may result in the release of potent
mesothelial cell mitogens such as platelet-derived
growth factor (PDGF) and transforming growth
factor-β (TGF-β) which in turn, may induce the
chronic stimulation and proliferation of
mesothelial cells after injury by asbestos fibres.
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