EGFR gene deregulation mechanisms in lung adenocarcinoma: A molecular review

For the last two decades, evolution in molecular biology has expanded our knowledge in decoding a broad spectrum of genomic imbalances that progressively lead normal cells to a neoplastic state and finally to complete malignant transformation. Concerning oncogenes and signaling transduction pathways mediated by them, identification of specific gene alterations remains a critical process for handling patients by applying targeted therapeutic regimens. The epidermal growth factor receptor (EGFR) signaling pathway plays a crucial role in regulating cell proliferation, differentiation and apoptosis in normal cells. EGFR mutations and amplification represent the gene's main deregulation mechanisms in cancers of different histo-genetic origin. Furthermore, intra-cancer molecular heterogeneity due to clonal rise and expansion mainly explains the variable resistance to novel anti-EGFR monoclonal antibody (mAb), and also tyrosine kinase inhibitors (TKIs). According to recently published 2015 WHO new classification, lung cancer is the leading cause of death related to cancer and its incidence is still on the increase worldwide. The majority of patients suffering from lung cancer are diagnosed with epithelial tumors (adenocarcinoma predominantly and squamous cell carcinoma represent ∼85% of all pathologically defined lung cancer cases). In those patients, EGFR-activating somatic mutations in exons 18/19/20/21 modify patients’ sensitivity (i.e. exon 21 L858R, exon 19 LREA deletion) or resistance (ie exon 20 T790 M and/or insertion) to TKI mediated targeted therapeutic strategies. Additionally, the role of specific micro-RNAs that affect EGFR regulation is under investigation. In the current review, we focused on EGFR gene/protein structural and functional aspects and the corresponding alterations that occur mainly in lung adenocarcinoma to critically modify its molecular landscape. © 2016 Elsevier Gmb

The long-term outcomes of cardiac implantable electronic devices implanted via the femoral route

BACKGROUND: Conventional superior access for cardiac implantable electronic devices (CIEDs) is not always possible and femoral CIEDs (F-CIED) are an alternative option when leadless systems are not suitable. The long-term outcomes and extraction experiences with F-CIEDs, in particular complex F-CIED (ICD/CRT devices), remain poorly understood. METHODS: Patients referred for F-CIEDs implantation between 2002 and 2019 at two tertiary centers were included. Early complications were defined as ≤30 days following implant and late complications >30 days. RESULTS: Thirty-one patients (66% male; age 56 ± 20 years; 35% [11] patients with congenital heart disease) were implanted with F-CIEDs (10 ICD/CRT and 21 pacemakers). Early complications were observed in 6.5% of patients: two lead displacements. Late complications at 6.8 ± 4.4 years occurred in 29.0% of patients. This was higher with complex F-CIED compared to simple F-CIED (60.0% vs. 14.3%, p = .02). Late complications were predominantly generator site related (n = 8, 25.8%) including seven infections/erosions and one generator migration. Eight femoral generators and 14 leads (median duration in situ seven [range 6-11] years) were extracted without complication. CONCLUSIONS: Procedural success with F-CIEDs is high with clinically acceptable early complication rates. There is a notable risk of late complications, particularly involving the generator site of complex devices following repeat femoral procedures. Extraction of chronic F-CIED in experienced centers is feasible and safe

Chromosome 7 multiplication in EGFR-positive lung carcinomas based on tissue microarray analysis

Background/Aim: Epidermal growth factor receptor (EGFR) over-activation is observed in significant proportions of non-small cell lung carcinomas (NSCLC). Our aim was to investigate the role of chromosome 7 multiplication with regard to its influence in EGFR expression, combined or not with gene amplification. Materials and Methods: Using tissue microarray technology, fifty (n=50) primary NSCLCs were cored and re-embedded into the final recipient block. Immunohistochemistry (IHC) and also chromogenic in situ hybridization (CISH) were performed. Results: EGFR expression at any level was detected in 40/50 (80%) cores. Over-expression was observed in 23/40 (57.5%) cases. Gene amplification was identified in 11/50 (22%) cases whereas chromosome 7 polysomy in 8/50 (16%) cases. Pure chromosome 7 multiplication alone led to low or moderate levels of expression. Overall EGFR expression was correlated with gene (p=0.001) and interestingly with chromosome 7 centromere numerical imbalances (p=0.004). Conclusion: EGFR expression is associated not only with amplification, but also with chromosome 7 centromere multiple copies. Chromosome 7 multiplication -due to centromere region amplification or true polysomy- is critical for applying monoclonal antibody targeted therapeutic strategies excluding the pure non-amplified cases