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Background: Cetuximab enhances the efficacy of chemotherapy in several cancer types. This trial assessed the activity of cetuximab and chemotherapy in advanced gastric cancer. Methods: Patients with previously untreated, metastatic, gastric cancer received cetuximab 400 mg m −2 at first infusion followed by weekly infusions of 250 mg m −2 combined with FUFOX (oxaliplatin 50 mg m −2 , 5-FU 2000 mg m −2 , and DL -folinic acid 200 mg m −2 d1, 8, 15 and 22 qd36). The primary endpoint was tumour response. Results: Overall, 52 patients were enrolled. The most common grade 3/4 toxicities were diarrhoea (33%), and skin toxicity (24%). Efficacy was evaluable in 46 patients who showed a response rate of 65% (CI 95%: 50–79%) including four complete responses. Time to progression (TTP) was 7.6 months (CI 95%: 5.0–10.1 months) and overall survival (OS) was 9.5 months (CI 95%: 7.9–11.1 months). Epidermal growth factor receptor (EGFR) was detectable in 60% of tumours but showed no correlation with treatment outcome. A KRAS mutation was found in only 1 of 32 (3%) tumour samples analysed. Conclusion: Cetuximab plus FUFOX showed an interesting high response rate in metastatic gastric cancer. Cetuximab plus platinum–fluoropyrimidine chemotherapy is at present being investigated in a phase III randomised controlled trial.

Renal sinus fat (RSF) is a perivascular fat compartment located around renal arteries. In this in vitro and in vivo study we hypothesized that the hepatokine fetuin-A may impair renal function in non alcoholic fatty liver disease (NAFLD) by altering inflammatory signalling in RSF. To study effects of the crosstalk between fetuin-A, RSF and kidney, human renal sinus fat cells (RSFC) were isolated and cocultured with human endothelial cells (EC) or podocytes (PO). RSFC caused downregulation of proinflammatory and upregulation of regenerative factors in cocultured EC and PO, indicating a protective influence of RFSC. However, fetuin-A inverted these benign effects of RSFC from an anti- to a proinflammatory status. RSF was quantified by magnetic resonance imaging and liver fat content by 1 H-MR spectroscopy in 449 individuals at risk for type 2 diabetes. Impaired renal function was determined via urinary albumin/creatinine-ratio (uACR). RSF did not correlate with uACR in subjects without NAFLD (n = 212, p = 0.94), but correlated positively in subjects with NAFLD (n = 105, p = 0.0005). Estimated glomerular filtration rate (eGRF) was inversely correlated with RSF, suggesting lower eGFR for subjects with higher RSF (r = 0.24, p < 0.0001). In conclusion, our data suggest that in the presence of NAFLD elevated fetuin-A levels may impair renal function by RSF-induced proinflammatory signalling in glomerular cells.

Follicular lymphoma (FL) is characterized besides the t(14;18)(q32;q21), by recurrent chromosomal alterations and somatic mutations. In this study, we analyzed cases of FL in situ (FLIS) without manifest FL (mFL), partial involvement by FL (PFL) and paired cases of FLIS and mFL to detect possible early chromosomal imbalances, mutations, as well as DNA-methylation patterns of genomic regions of selected genes. We demonstrate that all paired FLIS and mFL cases were clonally related, based on IGH rearrangement patterns and BCL2 breakpoint sequences. FLIS and PFL had no or few secondary chromosomal imbalances detectable by array comparative genomic hybridization (FLIS 0.8 copy number alterations (CNA)/case; PFL 2.0 CNA/case; mFL 6.3 CNA/case) and a lower level of DNA methylation of genes recurrently de novo methylated in lymphomas, as compared with mFL. EZH2 Tyr641 mutations were detected in a subset of both FLIS (2/9) and PFL (1/3) cases. In conclusion, these findings provide evidence that FLIS represents a FL precursor lesion of long-lived clonal B cells carrying the t(14;18) with no or few secondary genetic changes. Our data suggest that there may be more than one distinct lesion driving the progression from FLIS to manifest lymphoma.

The simultaneous detection of multiple somatic mutations in the context of molecular diagnostics of cancer is frequently performed by means of amplicon-based targeted next-generation sequencing (NGS). However, only few studies are available comparing multicenter testing of different NGS platforms and gene panels. Therefore, seven partner sites of the German Cancer Consortium (DKTK) performed a multicenter interlaboratory trial for targeted NGS using the same formalin-fixed, paraffin-embedded (FFPE) specimen of molecularly pre-characterized tumors (n = 15; each n = 5 cases of Breast, Lung, and Colon carcinoma) and a colorectal cancer cell line DNA dilution series. Detailed information regarding pre-characterized mutations was not disclosed to the partners. Commercially available and custom-designed cancer gene panels were used for library preparation and subsequent sequencing on several devices of two NGS different platforms. For every case, centrally extracted DNA and FFPE tissue sections for local processing were delivered to each partner site to be sequenced with the commercial gene panel and local bioinformatics. For cancer-specific panel-based sequencing, only centrally extracted DNA was analyzed at seven sequencing sites. Subsequently, local data were compiled and bioinformatics was performed centrally. We were able to demonstrate that all pre-characterized mutations were re-identified correctly, irrespective of NGS platform or gene panel used. However, locally processed FFPE tissue sections disclosed that the DNA extraction method can affect the detection of mutations with a trend in favor of magnetic bead-based DNA extraction methods. In conclusion, targeted NGS is a very robust method for simultaneous detection of various mutations in FFPE tissue specimens if certain pre-analytical conditions are carefully considered.

Introduction/Background*Epithelial ovarian cancer is nowadays recognized to encompass five major disease entities with High Grade Serous Ovarian Carcinoma representing the most common histologic type. The majority of these cancers originate from fallopian tube precursor lesions including serous tubal intraepithelial carcinomas (STIC), serous tubal intraepithelial lesions (STIL), epithelia with a p53 signature and secretory cell outgrowths (SCOUT). Accordingly it has been suggested that removal of the fallopian tubes, even in women at baseline risk for ovarian cancer may reduce the incidence of this deadly disease. On the other hand risk-reducing salpingo-oophorectomy remains the gold standard for primary prevention of ovarian carcinoma in women at increased risk. Here we aim to investigate the frequency of such precursor lesions in a consecutive series of women undergoing surgery for benign pelvic diseases or primary risk-reduction.MethodologyPatients in which uterine adnexa were removed during elective gynecologic procedures (=opportunistic salpingectomy, oSE) and women undergoing risk-reducing surgery (=prophylactic salpingectomy, pSE) were identified. Serially sectioning and extensively sampling of the fimbriated end (SEE-FIM protocol) was applied in all cases, additional routine p53 and Ki-67 immunohistochemistry was performed in pSE specimens. Histopathologic findings and clinical data were collected.Result(s)*A total of 457 cases treated at the Tuebingen University Women’s hospital between 1.3.2019-31.1.2020 was available for further research. 399 patients underwent oSE (87,31%) and 58 surgeries (12,69%) were performed for primary prevention. Median patient age was 49 years (30-83) in the oSE-group and 46 years (29-63) in the pSE-group. After oSE precursor lesion were identified in 8 patients (2,01%) including STIC (n=1), STIL (n=1), SCOUT (n=4) and p53-signature (n=2). In patients with increased risk for ovarian cancer 6 lesions (10,34%) were detected (STIC:n=1; p53-signature:n=5).Conclusion*We were able to demonstrate a relevant number of ovarian carcinoma precursor lesions in a walk-in series of opportunistic and prophylactic salpingectomies. In concordance with published data a higher number of precursor lesions was found after pSE. Further studies will now investigate the impact of specialized pathology review and additional immunohistochemistry (p53/Ki-67) in oSE specimens.

The vast increase of technical, diagnostic, and treatment possibilities and deepened understanding of molecular biology has revolutionized diagnosis and treatment of cancer and thus has great impact on pathology. Different professionals are responsible for proper evaluation of the results and their translating into an accurate diagnosis and appropriate treatment. Next to expertise, a close interaction between clinical molecular biologists, pathologists, and oncologists is required; it is crucial that these professionals speak “the same language.” Key to this is communication skills and creating possibilities for collaboration in a meaningful context. Here, we present an interprofessional, educational workshop model and we describe the parameters that contribute to effective learning by specialists.

The molecular examination of pathologically altered cells and tissues at the DNA, RNA, and protein level has revolutionised research and diagnostics in pathology. However, the inherent heterogeneity of primary tissues with an admixture of various reactive cell populations can affect the outcome and interpretation of molecular studies. Recently, microdissection of tissue sections and cytological preparations has been used increasingly for the isolation of homogeneous, morphologically identified cell populations, thus overcoming the obstacle of tissue complexity. In conjunction with sensitive analytical techniques, such as the polymerase chain reaction, microdissection allows precise in vivo examination of cell populations, such as carcinoma in situ or the malignant cells of Hodgkin's disease, which are otherwise inaccessible for conventional molecular studies. However, most microdissection techniques are very time consuming and require a high degree of manual dexterity, which limits their practical use. Laser capture microdissection (LCM), a novel technique developed at the National Cancer Institute, is an important advance in terms of speed, ease of use, and versatility of microdissection. LCM is based on the adherence of visually selected cells to a thermoplastic membrane, which overlies the dehydrated tissue section and is focally melted by triggering of a low energy infrared laser pulse. The melted membrane forms a composite with the selected tissue area, which can be removed by simple lifting of the membrane. LCM can be applied to a wide range of cell and tissue preparations including paraffin wax embedded material. The use of immunohistochemical stains allows the selection of cells according to phenotypic and functional characteristics. Depending on the starting material, DNA, good quality mRNA, and proteins can be extracted successfully from captured tissue fragments, down to the single cell level. In combination with techniques like expression library construction, cDNA array hybridisation and differential display, LCM will allow the establishment of “genetic fingerprints”of specific pathological lesions, especially malignant neoplasms. In addition to the identification of new diagnostic and prognostic markers, this approach could help in establishing individualised treatments tailored to the molecular profile of a tumour. This review provides an overview of the technique of LCM, summarises current applications and new methodical approaches, and tries to give a perspective on future developments. In addition, LCM is compared with other recently developed laser microdissection techniques.