Adenocarcinoma is the most common type of lung cancer found in non-smokers and is usually seen as a peripheral lesion in the lungs. In past several years many genetic and environmental factors has been identified as a causative factor for lung cancer. Individual susceptibility, active smoking, radon exposure, exposure to high pollution levels, asbestos exposure, occupational or environmental exposure to particular agents or carcinogens contribute to the development of adenocarcinoma of the lung. Hydrocarbons cause damage to the DNA and form DNA adducts. Benzo-A-pyrine has effects on inducing p53 mutations and affects molecular signaling pathways such as AKT. Genes involved in the pathogenesis of adenocarcinoma of the lung include EGFR, HER2, KRAS, ALK, and BRAF. On gross pathology, peripheral multifocal lesions are characteristic findings in patients with adenocarcinoma of the lung. On microscopic histopathological analysis, nuclear atypia, eccentrically placed nuclei, abundant cytoplasm, and conspicuous nucleoli are characteristic findings of adenocarcinoma of the lung.
Pathogenesis
Adenocarcinoma is the most common type of lung cancer found in non-smokers and is usually seen as a peripheral lesion in the lungs, as compared to centrally located tumors such as small cell lung cancer and squamous cell lung cancer.[1][2]
Another theory for pathogenesis of lung cancer is the accumulation of molecular abnormalities beyond a certain threshold point, rather than the sequence of alterations.
Atypical adenomatous hyperplasia (AAH) is the only sequence of morphologic change identified leading to the development of invasive adenocarcinoma of the lung.
Pathogenesis of lung cancer is thought to be result of both due to stepwise, sequence-specific and multistage molecular pathogenesis and due to accumulation and combination of genetic and epigeneticabnormalities.
The airway field of injury can be seen in smokers with or without lung cancer and is highly relevant for the identification of markers for minimally invasive and early detection of lung cancer.
It has been suggested that in this adjacent field of tumor, there is closer molecular genealogy between lung cancers and airways that are in closest proximity to the tumors compared with airways that are more distant from the tumors.
The progression of the molecular airway field of injury to preneoplasia and lung malignancy is still not clear.
Focal amplifications of 14q13·3 are also frequent in adenocarcinoma of the lung, region coding for NKX2–1 (TTF1), a transcription factor crucial for development of the lung, thyroid, and brain.
Mutation in MGA, coding for a Max-interacting protein, which functions as a transcriptional repressor capable of blocking MYC-dependent transformation.[17]
Some of the other recurrent somatic copy number alterations in lung adenocarcinoma include:
mTOR JAK-STAT DNA repair Cell cycle regulation Epigenetic deregulation
Environment
Although genetics play a significant role in the pathogenesis of lung cancer, it is thought that exposure to environmental risk factors plays an equally important role in the development of lung cancer.
The length of time an individual smokes, as well as the amount, significantly increases the person's chance of developing lung cancer.
Among individuals who stopped smoking, the risk of lung cancer steadily decreases as lungtissue repairs itself and as contaminant particles are eliminated from the lungs. Nonetheless, it is thought that the risk of lung cancer among persons with a history of smoking (even when stopped) is always higher than those who never smoked.
Radon is a colorless and odorless gas generated by the breakdown of radioactiveradium (decay product of uranium) found in the Earth's crust. The radiation decay products ionize genetic material, causing mutations that sometimes turn cancerous.
Radon exposure is the second major cause of lung cancer following smoking.
The mechanism of lung damage following radon exposure is not thought to be due to the radon gas itself, but due to the short-lived alpha decay products that cause cellular damage and DNAmutations.
Asbestos
Asbestos exposure is associated with many lung diseases, including lung cancer.[25]
Tiny asbestos fibers are released into the air are breathed into the lungs. The fibers become lodged in the lungs and are stuck for an indefinite amount of time. They can eventually lead to scarring and inflammation.
Viruses
Viruses are known to be associated with the development of lung cancer in animals and humans which include:[26][27][28][29][30][31]
HIV has also been thought to increase the risk of developing lung cancer. Although the mechanism is unknown, HIV is thought to be associated with a state of chronic lunginflammation that may potentiate cellular damage and DNA mutations.
Infection and Inflammation
There may be a correlation between general inflammation of lung tissue and the development of lung cancers.[31]
Neutrophils are released in response to bacterial infection and are considered to be the initial responders during inflammation.
AAH lesions are small and usually incidental histological findings; however, they may be detected grossly, especially if they are 0.5 cm or larger.
AAH is characterized by an alveolar structure lined by rounded, cuboidal, or low columnar cells.
The postulated progression of AAH to adenocarcinoma with bronchioloalveolar features, apparent from the increasingly atypical morphology, is supported by morphometric, cyto-fluorometric, and molecular studies.
On gross pathology, peripheral multifocal lesions are characteristic findings in patients with adenocarcinoma of the lung.[32]
Single or multiple solid firm yellow-white nodule or mass which may invade into the pleura and cause pleural retraction / puckering.
Adenocarcinoma usually does not form a cavitary lesion.
Adenocarcinoma may present as a diffuse pleural thickening resembling malignant mesothelioma.
Microscopic Pathology
On microscopic histopathological analysis, nuclear atypia, eccentrically placed nuclei, abundant cytoplasm, and conspicuous nucleoli are characteristic findings of adenocarcinoma of the lung.
Atypical adenomatous hyperplasia (AAH): is the precursor of peripheral adenocarcinomas. It consists of well demarcated columnar or cuboidal cells with the following features:[33][34]
Well differentiated (low grade) : Normal appearance
Poorly differentiated (high grade): Abnormal glandular appearance with a positive mucin stain
Histological Subtypes
The IASLC/ATS/ERS lung adenocarcinoma histologic classification system was proposed in the Journal of Thoracic Oncology in 2011.[35]
According to this new classification, tumor size ≤3 cm with pure lepidic pattern, but without lymphatic, vascular, pleural invasion or tumor necrosis was defined as adenocarcinoma in situ (AIS).
If tumor size ≤3 cm with a lepidic predominant pattern and contained ≤5 mm stromal invasion it was defined as minimally invasive adenocarcinoma (MIA).
If tumor had >5 mm stromal invasion it was defined as an invasive adenocarcinoma.
Sometimes the glandular cells and lumina may contain mucin.
Papillary adenocarcinoma
The papillary pattern is composed of glandular tumour cells growing along fibrovascular cores.
Papillae, necrosis, surrounding invasion, cuboidal to columnar epithelial lining, mucinous or non-mucinous.
Lung adenocarcinomas with papillary growth show 2 types of papillary architecture:
True papillary type: Papillae containing a layered glandular epithelium surrounded by fibrovascular core.
Micropapillary type: The papillary tufts lack a central fibrovascular core and extensively shed within alveolar spaces.
Micropapillary adenocarcinoma:
The papillary tufts lack a central fibrovascular core and extensively shed within alveolar spaces.
Micropapillary growth has been associated with an aggressive clinical course compared with traditional papillary adenocarcinoma.
Micropapillary adenocarcinoma (MPA) may be often diagnosed at a high stage in nonsmokers, with intralobar satellites.
Micropapillary adenocarcinoma frequently metastasizes to the contralateral lung, mediastinal lymph nodes, bone, and adrenal glands, with high mortality.
Solid adenocarcinoma
Cohesive cell cluster in a nest-like pattern without acinar polarity are the hallmark of the solid growth pattern.
Solid adenocarcinoma consists of sheets of tumor cells with abundant cytoplasm and mostly vesicular nuclei with several conspicuous nucleoli.
No acinar, papillary, or lepidic patterns are seen and there was no suggestion of mucin in tumor cell cytoplasm
Invasive mucinous adenocarcinomaMicrograph of mucinous adenocarcinoma of the lung, H&E stain. Source: Libre pathology
Mixed invasive mucinous: Invasive mucinous adenocarcinoma demonstrates areas with lepidic, acinar, and papillary patterns.
Fibrotic focus that contains invasive tumor with a desmoplastic stroma.
The tumor consists of columnar cells filled with abundant mucin in the apical cytoplasm and shows small, basally oriented nuclei.
Nonmucinous adenocarcinoma
Colloid adenocarcinoma:
This tumor consists of abundant pools of mucin growing within and distending airspaces.
Well differentiated mucinous glandular epithelium along the surface of fibrous septa and within the pools of mucin.
Tumor cells may be very inconspicuous.
The surface of the fibrous wall may be lined by well-differentiated cuboidal or columnar mucinous epithelium.
Fetal adenocarcinoma:
Fetal adenocarcinoma consists of malignant glandular cells growing in tubules and papillary structures with endometrioid morphology.
Some tumor cells have prominent clear cytoplasm, and squamoid morules are present
Enteric adenocarcinoma:
Consists of an adenocarcinoma that morphologically resembles colonic adenocarcinoma with back-to-back angulated acinar structures.
The tumor cells are cuboidal to columnar with nuclear pseudostratification.
This subpleural adenocarcinoma tumor consists primarily of lepidic growth with a small (0.5 cm) central area of invasion.
It may present as the lepidic pattern and/or acinar invasion.
Mucinous (MIA):
Mucinous MIA consists of a tumor showing lepidic growth and a small (0.5 cm) area of invasion.
The tumor cells consist of mucinous columnar cells and pale cytoplasm resembling goblet cells growing mostly in a lepidic pattern along the surface of alveolar walls.
The tumor invades the areas of stromal fibrosis in an acinar pattern.
Low grade differentiation.
Preinvasive lesions
Atypical adenomatous hyperplasia (AAH): Consists of atypical pneumocytes proliferating along alveolar walls.
Non invasive.
The slightly atypical pneumocytes are cuboidal and show gaps between the cells.
Nuclei are hyperchromatic and may present with nuclear enlargement and multinucleation.
Adenocarcinoma in situ (AIS)
Nonmucinous (AIS): Tumor grows purely with a lepidic pattern.
No foci of invasion or scarring is seen.
It shows atypical pneumocytes proliferating along the thickened, but preserved, alveolar walls.
Mucinous AIS: Consists of a nodular proliferation of mucinous columnar cells growing in a purely lepidic pattern.
Although there is a small central scar, no stromal or vascular invasion is seen.
The tumor cells consist of cuboidal to columnar cells with abundant apical mucin and small, basally oriented nuclei.
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