Squamous cell carcinoma of lung
Definition
A tumour arising
from bronchial epithelium showing keratinisation or intercellular bridges.
Epidemiology
Squamous
cell carcinoma accounts for about 45% of primary lung carcinomas in men,
25% in women. More than 90% of squamous cell carcinomas of lung
occur in cigarette smokers.
Squamous cell carcinomas can be subdivided
into central and peripheral. The peripheral tumours present in older patients,
at a lower stage, with less lymph node involvement: they have variably
been reported to have a similar6
or better22
prognosis when compared to central tumours.
Radiology
Squamous cell carcinoma is the most frequent
type to cavitate. Spiral CT reveals two to four times as many cancers
as does plain chest x-ray18. CT and MRI have limited sensitivity in the imaging
of mediastinal nodes for staging. FDG-PET gives greater accuracy in assessing
both nodes5,18,23 and
distant metastases23.
Macroscopic appearances
A minority
of T1 tumours are endobronchial and exophytic: they do not have a
better prognosis than other T1N0 squamous carcinomas of lung8.
Histopathology
There is keratinisation and/or intercellular
bridges are seen.
Variants:
Immunohistochemistry
See immunohistochemistry of malignant
epithelial tumours of lung.
| |
34bE12 |
positive |
|
CK5/6 |
positive13 |
CEA |
positive |
35bH11 |
often positive |
TTF-1 |
usually negative |
CK7 |
usually negative |
Transcription factor
E2F1 |
2/1136 |
| |
|
| |
|
Cytogenetics and molecular genetics
Numerous somatic mutations are implicated
in the pathogenesis of lung cancer14. Gains in 3q are more common in squamous carcinomas
than in adenocarcinomas15,16,20. Losses on 3p have also been reported19,20,24.
The FHiT (fragile histidine triad) gene21,34
and RASSF1A26
are two genes on 3p that may be of importance
in the pathogenesis of lung cancer, particularly squamous carcinoma. Certain
deletions may be associated with metastatic potential20.
Epidermal growth factor receptor overexpression is ubiquitous in squamous
cell carcinoma25, occurs in about 65% of adenocarcinomas and large
cell carcinomas but is not a feature of small cell carcinomas.17
Ultrastructure
Differential diagnosis
Large cell carcinoma:
lacks squamous differentiation
Adenosquamous carcinoma
may be mimicked by entrapped pneumocytes.
Thymic squamous carcinoma
Squamous metaplasia with
atypia in diffuse alveolar damage.
Pseudovascular adenoid
squamous cell carcinoma closely mimics angiosarcoma but is positive
for cytokeratins and EMA, negative for CD31, CD34 and Ulex europaeus
I lectin1,2.
Prognosis
Stage I five year survival
is 70%.
Epidermoid carcinomas
are the non-small cell carcinomas of lung most prone to give rise
to isolated local recurrences7.
Basaloid carcinoma is reported to have a prognosis
inferior to that of poorly differentiated squamous cell carcinoma4,12.
pRb2/p130 is a member of the retinoblastoma
gene family; loss may correlate with poor overall survival and
is demonstrable by immunohistochemistry28.
Immunohistochemical demonstration of abnormal expression of p27(KIP1)29, loss of expression of the fragile histidine triad gene27,34, p1630
or p2133, or overexpression
of cyclin E31,32 may predict
poor survival. Nuclear, as opposed to cytoplasmic, expression of the
transcription factor Y-box binding protein (YB-1) correlates with
poor prognosis35.
References
Tumours of the Lung, Pleura, Thymus and Heart. WHO Classification
of Tumours. IARC Press 2004.
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revised 14.6.2005.
©SMUHT/PW
Bishop