Neuroendocrine differentiation in thymic epithelial tumors with special reference to thymic carcinoma and atypical thymoma

To determine the neuroendocrine (NE) features of thymic epithelial tumor, immunohistochemistry and electron microscopy studies were performed on eight NE tumors (thymic carcinoids) and 26 non-NE tumors (nine thymic carcinomas, five atypical thymomas, and 12 thymomas other than lymphocytic thymoma). Immunohistochemical studies were performed with antibodies against general markers for NE cells (synaptophysin, a subunit of a guanine nucleotidebinding protein, Go, and small-cell lung carcinoma cluster 1 antigen), and a broad panel of antibodies for hormonal substances. Thymic carcinoid showed synchronous diffuse immunoreactivity for the three NE markers and contained cells that were positive for a variety of hormonal products: human chorionic gonadotropin (hCG) a-subunit (eight of eight), hCG β-subunit (three of eight), adrenocorticotropic hormone (ACTH) (three of eight), calcitonin (two of eight), calcitonin gene-related peptide (two of eight), and serotonin (one of eight). Conversely, although positivity for NE markers was neither synchronous nor diffuse in non-NE tumors, seven of nine thymic carcinomas, three of five atypical thymomas (focal or dispersed distribution), and none of the five thymomas were positive for at least two of these NE markers. A small number of neoplastic cells were positive for hCGa-subunit or ACTH in three thymic carcinomas and one atypical thymoma. Ultrastructurally, dense core granules (DCG) were much more frequent in thymic carcinoid, but several DCG-like granules were identified in 12 of 13 non-NE tumors with or without immunoexpression of NE markers. The presence of focal or dispersed NE cells in thymic carcinoma and atypical thymoma may reflect multidirectional differentiation within the tumor, which, like cytological atypia, epithelial CD5 expression, and lack of immature T cell infiltration, may be another feature of this group at thymic tumors.     

34betaE12 Cytokeratin Immunodetection in the Differential Diagnosis of Small Cell Tumors of Lung

The group of small cell tumors of the lung includes fine following: (1) small cell carcinoma (SCC) of neuroendocrine (NE) origin, (2) poorly differentiated squamous carcinoma, (3) the rare basaloid (basal cell) carcinomas, and (4) malignant lymphomas, primitive neuroectodermal tumors (PNETs), and rhabdomyosarcomas. The differential diagnosis among these entities carries a heavy therapeutic impact but may be difficult in small biopsy specimens or in cytologic material, especially if necrosis or artifactual alterations are present. The use of additional techniques such as immunostaining for NE markers is not always helpful, since immunoreactive chromogranin A is detectable in only a small percentage of small cell carcinomas. It has recently been reported that in the aerodigestive tract 34betaE12 cytokeratin (CK) immunostaining selectively labels non-NE carcinomas, including squamous cell carcinoma, adenocarcinoma, and the rare basaloid carcinoma. We evaluated the role of such CK immunodetection in the differential diagnosis of small cell lung tumors in cytologic and biopsy specimens. Eighty-one lung tumors diagnosed by means of endoscopic bronchial biopsy, fine needle aspirate, or bronchial washing were collected. They included 43 small cell NE carcinomas and 38 cases used as controls (comprehensive of 2 large cell neuroendocrine carcinomas, 4 carcinoid tumors, 30 cases of non-NE lung carcinomas, 2 cases of bronchial infiltration by non-Hodgkin lymphomas). 34betaE12 CK immunoreactivity was found in 29/30 cases of non-NE carcinomas, but in only 3/43 SCCs. The latter showed positivity in only a few scattered cells. The 2 cases of bronchial infiltration by malignant lymphoma as well as the 4 cases of carcinoid tumors and the 2 cases of large cell neuroendocrine carcinomas were negative. These findings were confirmed in the surgical specimens of operatedon cases. We conclude that, in lung carcinoma biopsies showing a small cell pattern, presence of 34betaE12 CK immunoreactivity favors a non-NE carcinoma, whereas its absence supports the diagnosis of SCC. Int J Surg Pathol 8(4):317-322, 2000     

LKB1 protein expression in neuroendocrine tumors of the lung

During a recent investigation of LKB1 gene abnormality in lung lesions, strong expression of LKB1 protein in normal neuroendocrine (NE) cells of the bronchial epithelium was found. Because LKB1 functions as a tumor suppressor gene, the question of whether alteration of LKB1 expression is related to the development of pulmonary NE tumors of various grades was investigated. LKB1 immunohistochemistry was examined in a total of 68 primary pulmonary NE tumors consisting of 30 specimens of small cell lung carcinoma (SCLC), 23 large cell neuroendocrine carcinomas (LCNEC), two atypical carcinoids, and 13 typical carcinoids. Loss or low expression (<20% immunoreactive cells) of LKB1 protein expression was more frequently observed in high-grade NE tumors (SCLC and LCNEC; 45/53, 84.9%) than in typical and atypical carcinoids (3/15; 20%). The difference in LKB1 immunoreactivity between the high-grade NE tumors and the carcinoid group was statistically significant ( P  < 0.0001). In conclusion, marked reduction of LKB1 expression in high-grade NE tumors of the lung suggests a possible role of LKB1 inactivation in its tumorigenesis. Although a few previous studies indicated rare genetic alterations of LKB1 in SCLC, further studies including analysis of other NE tumors and focusing on epigenetic abnormalities of LKB1 gene are warranted.     

Malignancy-associated X chromosome allelic losses in foregut endocrine neoplasms: further evidence from lung tumors.

Association of X chromosome allelic losses with tumor malignancy has been identified in foregut but not in midgut endocrine neoplasms. The aim of this study was to investigate the association of deletions on X chromosome with malignancy in lung neuroendocrine tumors, another family of foregut neoplasms comprising four categories with increased malignancy: typical and atypical carcinoids, large cell neuroendocrine and small cell lung carcinomas. To evaluate loss of heterozygosity, DNA extracted from nine typical carcinoids, 17 atypical carcinoids, six large cell neuroendocrine carcinomas and five small cell lung carcinomas was PCR-amplified for 18 microsatellite markers spanning the whole X chromosome. All tissue samples were formalin-fixed and paraffin-embedded. X chromosome losses were absent in typical carcinoids, whereas they were found in nine out of 17 atypical carcinoids and in five out of six large cell neuroendocrine carcinomas (involving 28 and 70% of informative loci, respectively). On the contrary, deletions on X chromosome were an extremely rare event in small cell lung carcinomas. In atypical carcinoids, the presence of losses was associated with larger tumor size, higher pT status and advanced stage. No death occurred in atypical carcinoid patients without deletions on X chromosome, whereas all atypical carcinoid patients who had died from disease showed allelic losses. In conclusion, X chromosome allelic losses, absent in benign 'typical' carcinoids, progressively increased in frequency from intermediate-grade 'atypical' carcinoids to high-grade large cell neuroendocrine carcinomas. These results extend the association of deletions on X chromosome with malignancy, already demonstrated in other foregut endocrine neoplasms, to lung neuroendocrine tumors. The absence of X chromosome allelic losses in small cell lung carcinomas underlines a striking difference from large cell neuroendocrine carcinomas, possibly linked to different pathogenetic mechanisms of these two highly aggressive neuroendocrine lung tumors.     

Expression of urokinase-type plasminogen activator, stromelysin 1, stromelysin 3, and matrilysin genes in lung carcinomas.

We have previously shown that the extracellular-matrix-degrading enzymes, urokinase-type plasminogen activator (u-PA), stromelysin 1, stromelysin 3, and matrilysin, may play an important role in the transition from lung preneoplasia to invasive carcinoma. Using in situ hybridization and immunohistochemistry, we analyzed serial frozen sections for the expression of these enzymes in 89 lung carcinomas including 25 neuroendocrine (NE) carcinomas (10 small-cell lung carcinomas, 7 large-cell NE carcinomas, 1 atypical, and 7 typical carcinoids) and 64 non-small-cell, non-NE carcinomas (29 squamous and 7 basaloid carcinomas, 23 adenocarcinomas, and 5 large-cell carcinomas). Proteases, except matrilysin, were more often expressed in stromal than cancer cells. In non-small-cell, non-NE carcinomas, stromal co-expression of u-PA and stromelysin 3 was seen in 80 to 90% of the tumors and was highly correlated (P < 0.0001). Stromal u-PA and stromelysin 3 expression was linked to tumor size (P = 0.01 and 0.03, respectively) and lymph node involvement (P = 0.001 and 0.02, respectively). Epithelial expression of u-PA was correlated to tumor size (P = 0.04). Epithelial expression of stromelysin 3 predominated in squamous and basaloid carcinomas (P = 0.0005) and was inversely correlated to squamous differentiation (P = 0.018). Epithelial expression of matrilysin predominated in adenocarcinomas and large-cell carcinomas (P = 0.07). In NE carcinomas including small-cell lung carcinomas, stromal expression of u-PA was correlated to lymph node metastasis (P = 0.017). Epithelial expression of all enzymes were significantly less frequent in NE than in non-NE tumors. We conclude that 1) epithelial expression of matrix proteases in lung cancer is linked to cell phenotype (NE versus non-NE, squamous versus glandular) and 2) their stromal, rather than epithelial, expression influences local metastasis.     

Differential expression of neural-cadherin in pulmonary epithelial tumours

Aims:  Neural (N)-cadherin belongs to a group of transmembrane molecules with a crucial role in tissue morphogenesis and maintenance of an epithelioid phenotype and increased N-cadherin expression is implicated in tumour progression and dedifferentiation. The aim was to determine whether evaluation of N-cadherin in pulmonary tumours might assist in identifying lesions with more aggressive potential.
Methods and results:  One hundred and fifty-five pulmonary lesions were analysed for N-cadherin expression using immunohistochemistry, including neuroendocrine hyperplasia ( n  = 3), typical carcinoid ( n  = 59), atypical carcinoid ( n  = 12), small cell lung carcinoma ( n  = 11), large cell neuroendocrine carcinoma ( n  = 12), adenocarcinoma ( n  = 35) and squamous cell carcinoma ( n  = 23). Lymph node status was correlated with immunohistochemical expression. N-cadherin expression was demonstrated in all cases of neuroendocrine hyperplasia, 96% of typical carcinoids, 83% of atypical carcinoids, 63% of the small cell lung carcinomas and 32% of large cell neuroendocrine carcinomas. Over 90% of the adenocarcinomas and 100% of the squamous cell carcinomas were negative. Increased N-cadherin expression in typical carcinoids was associated with negative lymph node status ( P  < 0.001).
Discussion:  N-cadherin is differentially expressed in pulmonary tumours and is predominantly observed in neuroendocrine lung lesions with high expression in typical and atypical pulmonary carcinoids. The level of expression of N-cadherin between types of lung tumours does not appear to indicate malignant potential or aggressive behaviour.     

Abnormal p53 expression in lung neuroendocrine tumors. Diagnostic and prognostic implications.

The diagnostic and prognostic implications of p53 immunostaining have been investigated in 59 pulmonary neuroendocrine tumors, including typical carcinoids (n = 15), so-called "atypical carcinoids" (n = 22), and small cell lung carcinomas (SCLCs; n = 22). Immunocytochemistry was performed on formalin-fixed, paraffin-embedded samples using the monoclonal antibody PAb1801, which has been shown to be suitable for staining fixed and embedded tissue sections. p53 immunoreactivity was restricted to atypical carcinoids (45% of the cases being immunoreactive) and to SCLCs (which were positively stained in 59% of the cases), whereas it was consistently lacking in typical carcinoid tumors. When the group of the so-called "atypical carcinoids" was further reclassified, p53 immunostaining was strictly confined to those cases belonging to the histologically more aggressive subsets (well differentiated neuroendocrine carcinoma subsets II and III). Within the same tumor type, however, p53 immunoreactivity did not correlate with the clinical outcome of the disease and was not predictive of the length of survival. The data indicate that abnormal p53 expression (which is strictly dependent on structural abnormalities of the p53 gene) is detectable in the majority of neuroendocrine carcinomas of the lung and might represent a useful adjunct in the differential diagnosis of pulmonary neuroendocrine neoplasms, particularly in routinely fixed and embedded small bronchoscopic biopsies.     

Divergent differentiation in neuroendocrine lung tumors

The classification of neuroendocrine (NE) lung tumors has been revised in the 1999 World Health Organization (WHO) classification of lung tumors, allowing sharp morphological definition of typical versus atypical carcinoids, and atypical carcinoids versus large cell neuroendocrine carcinoma (LCNEC), a newly described class of high-grade NE lung tumors which differs from small-cell lung cancer by a large-cell phenotype. Divergent differentiation accounts for the high frequency of glandular differentiation with mucin production, and ultrastructural features in carcinoids and LCNEC, and low frequency of squamous differentiation in both LCNEC and SCLC. Specific NE markers (chromogranin, synaptophysin, neural cell adhesion molecule) and epithelial markers consistently negative in neuroendocrine components (cytokeratins 1, 5, 10, 14; epidermal growth factor (EGF)-receptor, human leukocyte antigen beta 2 (HLA-beta2) microglobuline) help to recognize divergent differentiation in NE tumors. At morphological level, divergent differentiation in NE tumors is recognized in WHO classification as variants: combined SCLC and combined LCNEC. The derivation of all lung tumors from a common endodermal stem cell and adoption of amine precursor uptake and decarboxylation properties by this endodermal stem cell explains divergent differentiation in NE lung tumors and the occurrence of NE subsets in NSCLC.     

High-grade neuroendocrine carcinomas of the lung express K homology domain containing protein overexpressed in cancer but carcinoid tumors do not

K homology domain containing protein overexpressed in cancer (KOC) is a member of the insulin-like growth factor (IGF) messenger RNA-binding protein family and is expressed during embryogenesis and in certain malignancies. KOC, known as L523S and IGF messenger RNA-binding protein 3, was shown to be frequently expressed in high-grade neuroendocrine carcinomas of the lung in our immunohistochemical studies using a monoclonal antibody against human KOC. Specifically, all 10 small cell lung carcinomas (SCLCs) exhibited strong cytoplasmic staining, 9 with diffuse positivity and 1 with focal positivity. Among 14 large cell neuroendocrine carcinomas (LCNECs), 9 exhibited strong and diffuse cytoplasmic staining, and 5 cases showed focal immunoreactivity. In contrast, no KOC was detected in 21 typical and atypical carcinoids, except for one atypical carcinoid with oncocytic cells showing weak cytoplasmic staining. Although SCLCs exhibited a strong and diffuse staining pattern more frequently (90%) than LCNECs (64%), the difference did not reach statistical significance (P = .3408). Interestingly, our immunohistochemical studies demonstrated that IGF-II, reportedly regulated by KOC, was comparably expressed in SCLC, LCNEC, and typical and atypical carcinoids, irrespective of KOC expression status of the tumors. These results support the formulation that KOC may play an important role in the regulation of biologic behavior of high-grade neuroendocrine carcinomas. In addition, detection of KOC expression may be diagnostically useful in distinguishing high-grade neuroendocrine carcinomas from carcinoid tumors. Our findings of equivalent IGF-II expression in KOC-positive SCLC and LCNEC and KOC-negative carcinoid tumors suggest different regulatory mechanisms involved in the control of IGF-II expression in these tumors.     

Immunohistochemical markers of small cell carcinoma and related neuroendocrine tumours of the lung

A selected group of 263 pulmonary neuroendocrine tumours comprised 156 small cell carcinomas, five combined cell carcinomas, nine atypical carcinoid/small cell carcinomas, 32 atypical carcinoids, ten large cell/small cell carcinomas, and 51 carcinoid tumours. These were compared with a group of 109 non-small cell carcinomas, using four markers of neuroendocrine differentiation to determine differences in reactivity between the two groups and among the variants of neuroendocrine tumour. The antibodies used were neuron-specific enolase (NSE), protein gene product (PGP) 9.5, human bombesin, and the C-terminal flanking peptide of human bombesin (CTP). Most small cell carcinomas, carcinoid tumours, and atypical carcinoid variants showed immunoreactivity for both NSE and PGP 9.5 but a significant number of non-small cell carcinomas, mainly squamous cell carcinomas, were also positive (11 and 35 per cent, respectively). Bombesin was specific for neuroendocrine tumours, being demonstrable in 35 per cent carcinoids and 24 per cent small cell carcinomas, but staining was focal and often confined to scattered cells. Diffuse strongly positive immunoreactivity for CTP was seen in the majority of malignant neuroendocrine tumours, but only 12 per cent of carcinoid tumours were positive and non-small cell carcinomas were negative. CTP is therefore of potential value as a specific marker of malignant neuroendocrine tumours, particularly if the amount of biopsy material is limited and the tumour is an unusual variant, such as atypical carcinoid or large cell-small cell carcinoma.     

Controversial issues and new discoveries in lung neuroendocrine tumors

Lung neuroendocrine (NE) tumors consist of four histologic subtypes, which are usually classified based on a three-tiered prognostic scheme. They are typical carcinoid (TC) as low-grade malignant tumors, atypical carcinoid (AD) as intermediate-grade malignant tumors, and large cell NE carcinoma (LCNEC) and small cell lung carcinoma (SCLC), both of which are high-grade malignant tumors. This three-tiered classification is based solely on histologic grounds and is a source of controversy especially when dealing with borderline or “gray zone” categories (TC vs. AC, AC vs. LCNEC, LCNEC and SCLC). In this review, controversial issues regarding the histologic classification will be discussed, and an innovative grading system that incorporates Ki-67 labeling index will be described. In addition, the recently discovered molecular alterations involved in TC/AC, as well as pathways involved in high-grade NE carcinomas, will be discussed in order to elucidate the differences in pathogenesis and biology between carcinoid tumors and high-grade NE carcinomas.     

Apoptosis-related factors p53, Bcl2, and Bax in neuroendocrine lung tumors.

Neuroendocrine (NE) lung tumors comprise four classes of progressive aggressiveness for which proliferation and apoptosis rates could both contribute to their distinctive behavior. As p53 mutations may favor escape from apoptosis through changes in Bcl2-Bax expression balance, which are survival and apoptotic genes, respectively, we studied 121 NE lung tumors (16 typical carcinoids (TC), 5 atypical carcinoids (AC), 29 large-cell NE carcinomas (LCNECs), and 71 small-cell lung carcinomas (SCLCs) using immunohistochemistry. We quantified apoptosis by terminal-deoxynucleotidyl-transferase-mediated deoxyuridine triphosphate nick end labeling (TUNEL) in 31 of these cases. There was a significant increase of p53 mutant immunophenotype (defined as immunoreactivity with at least two antibodies for at least 20% of tumor cells) between atypical/typical carcinoids group and the LCNEC/SCLC group (P = 0.0003). There was an inverse correlation (P < 0.0001) between the scores of Bax and Bcl2 expression in individual tumors and a significant inversion of the Bcl2. Bax ratio between low-grade (typical and atypical carcinoids) and high-grade (LCNECs and SCLCs) tumors with a predominant Bax expression in the first group and predominant Bcl2 expression in the second. Whereas carcinoids had variable apoptotic indexes, LCNECs had high indexes (1.3 to 6.8%), Bcl2 overexpression, Bax down-regulation, and Bcl2.Bax ratio > 1 correlated with lower apoptotic index in both LCNEC and the pool of LCNECs and SCLCs (P < 0.05) and a lower survival rate in the group of atypical and typical carcinoids and LCNECs (P < 0.002). The highest levels of Bcl2 expression and Bcl2.Bax ratios were associated with p53 mutant immunophenotype (P = 0.02). Our results suggest that aggressiveness in NE lung tumors could be linked, in addition to proliferation, to apoptosis-related factors.     

Carcinomas of the lung with neuroendocrine differentiation

While there are examples of each of the histologic types of bronchogenic carcinoma in which ectopic hormone production has been demonstrated, three groups of lung cancers manifest this type of differentiation with great regularity. These are the carcinoid, atypical carcinoid, and the small cell carcinoma, which have been called neuroendocrine carcinomas of the lung. The carcinoids are neoplasms with a heterogeneous array of histologic appearances that share relatively uniform nuclear features, the absence of both tumor necrosis and mitotic figures, and a good prognosis. Neuroendocrine differentiation is demonstrable with such regularity in carcinoids that the diagnosis is not considered tenable in the absence of at least one of the following features: argyrophilia, the demonstration of neuron-specific-enolase or neuropeptides by immunohistochemistry or other techniques, or the demonstration of numerous dense-core membrane-bound granules, usually 150 to 250 nm in diameter, by electron microscopy. The atypical carcinoids (well or moderately differentiated neuroendocrine carcinomas) share the neuroendocrine differentiation of the carcinoids and many of their histologic features, but are distinguished by the presence of tumor necrosis, more anaplastic large cell nuclei with numerous mitotic figures, and a distinctly worse prognosis. They are a heterogeneous lot with some similarities to carcinoids, small cell carcinomas, and large cell or adenocarcinomas. The demonstration of at least one of the neuroendocrine features listed above is considered necessary for this diagnosis. Small cell carcinoma is also a heterogeneous group of neoplasma primarily distinguished by their finely granular chromatin pattern which correlates with a much worse prognosis but a higher likelihood of response to chemotherapy and radiotherapy. Many small cell carcinomas share the neuroendocrine differentiation of the carcinoids or atypical carcinoids, but some do not and the demonstration of these features is not a requisite for inclusion in the small group. The morphologic demonstration of neuroendocrine differentiation may be more difficult in small cell carcinomas, but they more frequently produce clinically important amounts of ectopic neuropeptides. While the term neuroendocrine carcinoma of the lung includes several quite different entities and does not by itself convey histogenetic or prognostic implications, the demonstration of neuroendocrine differentiation in pulmonary neoplasms is an important procedure when combined with the recognition of other cytologic and histologic features.     

Differential distribution of the neuron-associated class III beta-tubulin in neuroendocrine lung tumors

OBJECTIVE: To study the immunoreactivity profile of the neuron-associated class III beta-tubulin isotype (beta III) in epithelial lung tumors. DESIGN: One hundred four formalin-fixed, paraffin-embedded primary and metastatic lung cancer specimens were immunostained with an anti-beta III mouse monoclonal antibody (TuJ1) and an anti-beta III affinity-purified rabbit antiserum. Paraffin sections from fetal, infantile, and adult nonneoplastic lung tissues were also examined. RESULTS: In the fetal airway epithelium, beta III staining is detected transiently in rare Kulchitsky-like cells from lung tissues corresponding to the pseudoglandular and canalicular but not the saccular or alveolar stages of development. beta III is absent in healthy, hyperplastic, metaplastic, and dysplastic airway epithelium of the adult lung. In contrast, beta III is highly expressed in small cell lung cancer, large cell neuroendocrine carcinoma, and in some non-small cell lung cancers, particularly adenocarcinomas. There is no correlation between expression of beta III and generic neuroendocrine markers, such as chromogranin A and/or synaptophysin, in pulmonary adenocarcinomas. Also, focal beta III staining is present in primary and metastatic adenocarcinomas (to the lung) originating in the colon, prostate, and ovary. beta III is expressed to a much lesser extent in atypical carcinoids and is rarely detectable in typical carcinoids and squamous cell carcinomas of the lung. The distribution of beta III in small cell lung cancer and adenocarcinoma metastases to regional lymph nodes and brain approaches 100% of tumor cells, which is substantially greater than in the primary tumors. CONCLUSIONS: In the context of neuroendocrine lung tumors, beta III immunoreactivity is a molecular signature of high-grade malignant neoplasms (small cell lung cancer and large cell neuroendocrine carcinoma) although its importance in atypical carcinoids must be evaluated further. In addition, beta III may be a useful diagnostic marker in distinguishing between small cell lung cancers and certain non-small cell lung cancers (poorly differentiated squamous cell carcinomas), especially in small biopsy specimens. To our knowledge, beta III is the only tumor biomarker that exhibits a substantially more widespread distribution in poorly differentiated than in better differentiated pulmonary neuroendocrine tumors. However, the significance of beta III phenotypes in non-small cell lung cancer, particularly adenocarcinoma, with respect to neuroendocrine differentiation and prognostic value, requires further evaluation.     

Combined neoplasia of the lung: description of a case of adenocarcinoma mixed with typical carcinoid]

OBJECTIVE: To report about a lung tumor that was a combination of typical carcinoid and adenocarcinoma. RESULTS AND CONCLUSIONS: The patient, a 71-year-old male, presented with a 2.5-cm pulmonary nodule that, microscopically, was a combination of an adenocarcinoma (tubular with clear cell features and bronchioloalveolar) and a typical carcinoid. Immunohistochemically, both components were positive for cytokeratin, but only the carcinoid component was positive for chromogranin and synaptophysin. In the range of neuroendocrine tumors of the lung, a combination with other histological types of carcinoma (squamous, adeno, large cell and pleomorphic) can be found with both small cell carcinoma and large cell neuroendocrine carcinoma, but is very rare with typical and atypical carcinoids.     

What can we learn from the errors in the frozen section diagnosis of pulmonary carcinoid tumors? An evidence-based approach

The intraoperative diagnosis of pulmonary neuroendocrine tumors can be difficult. Frozen section diagnosis was requested on 87 neuroendocrine tumors including 58 typical carcinoids, 8 atypical carcinoids, 18 large cell neuroendocrine carcinomas, and 3 small cell carcinomas from 2405 patients that underwent frozen section diagnosis at Cedars-Sinai Medical Center from 2002 to 2007. The deferral and error rate for carcinoid tumors was 4.13% and 7.5%, respectively, and resulted in 4 unnecessary lobectomies and 2 second thoracotomies. The most common errors included misdiagnoses as lymphoma, squamous carcinoma or metastasis from breast carcinoma. Thirty one pathologic features were evaluated in the 66 carcinoid tumors and 10 frozen sections each of lymphoma, squamous cell carcinoma, and metastatic breast carcinoma. Seven pathologic features were significant by chi square test at P > .05. Positive likelihood ratios identified 11 pathologic features that were useful for the diagnosis of carcinoid tumor from other neoplasms. The applicability of the 11 pathologic features was tested with a group of pathologists, resulting in significant improvement in diagnostic accuracy as measured by pre and posttests. The value of evidence-based pathology and Bayesian statistics to evaluate complex differential diagnoses in pathology is discussed.     

The unusual spectrum of neuroendocrine lung neoplasms

Neoplasms of the lungs showing neuroendocrine differentiation are classified histologically into the following groups: (1) carcinoid, (2) atypical carcinoid (well-differentiated neuroendocrine carcinoma and malignant carcinoid, (3) small cell neuroendocrine carcinoma (small cell undifferentiated carcinoma and oat cell carcinoma), and (4) large cell neuroendocrine carcinoma (atypical endocrine tumor of the lung and intermediate neuroendocrine carcinoma). Nine examples of neuroendocrine lung carcinomas are discussed that have unusual histologic features that make it difficult to assign them to one of the above groups, have unusual immunohistochemical features, have unusual ultrastructural features, or exhibit a biologic behavior different from what one would have predicted from their morphologic appearance. The findings in these nine cases suggest that the present classification of neuroendocrine lung neoplasms may be too precise and that these neoplasms, like other nonneuroendocrine pulmonary tumors, exhibit a wider morphologic and biologic spectrum than previously appreciated.     

CGH-Befunde bei neuroendokrinen Tumoren der Lunge

According to the 1999 World Health Organisation classification of lung tumors, the classification of neuroendocrine (NE) tumors is solely based on light-microscopic features. Typical and atypical carcinoid tumors are distinguished from large cell (LCNEC) and small cell neuroendocrine carcinomas (SCLC). We used comparative genomic hybridization (CGH) on 50 samples to investigate the cytogenetic relationships between NE tumors. On average, carcinoid tumors showed markedly fewer chromosomal imbalances (1.8/case, 23 cases) than LCNEC (13.3/case, 17 cases) or SCLC (17/case, 10 cases). The frequency of amplicons increased accordingly. Typical carcinoid tumors exhibited significant defects on chromosomes 11 and 13 only. Interestingly, only the frequency of losses on chromosome arm 11q was very similar for all three tumor entities (about 30%). In conclusion, the CGH results support the classification of typical carcinoid tumors as a separate entity in clear distinction from the NE carcinomas.