Noninvasive fetal RhD genotyping from maternal blood

Rhesus (Rh) D blood group incompatibility between a pregnant woman and the fetus can occasionally cause maternal alloimmunization and hemolytic disease of the fetus and of the newborn in subsequent pregnancies. RHD genotyping of fetuses carried by RhD-negative women using fetal DNA obtained invasively through amniocentesis or chorionic villus sampling is an aid to the clinical management of these cases. Technological advances allow for accurate prediction of fetal RHD genotype using cell-free fetal DNA from maternal blood, thus overcoming the invasive procedures. Presently, many laboratories worldwide provide the test as a routine service for immunized women. Mass application of RhD noninvasive prenatal diagnosis for all fetuses carried by RhD-negative women is highly desirable so that unnecessary anti-D administration is avoided. © 2010 Expert Reviews Ltd

Proteomic analysis of amniotic fluid for the diagnosis of fetal aneuploidies

Advances in technologies associated with mass spectrometry-based proteomic techniques have added a new dimension to the field of biomedical research. Most of the existing research on human gestation has focused on the application of these high-throughput methodologies in the study of amniotic fluid. In cases of fetal aneuploidies, the use of proteomic platforms has contributed to the identification of relevant protein biomarkers that could potentially change early diagnosis and treatment. The current article focuses on studies of normal amniotic fluid using proteomic technologies and describes alterations noted in the amniotic fluid proteome in the presence of fetal aneuploidies. © 2011 Expert Reviews Ltd

Early non-invasive detection of fetal y chromosome sequences in maternal plasma using multiplex PCR

Objective: Clinical indications for fetal sex determination include risk of X-linked disorders, a family history of conditions associated with ambiguous development of the external genitalia, and some fetal ultrasound findings. It is usually performed in the first trimester from fetal material obtained through CVS and is associated with an approximately 1% risk of miscarriage. Ultrasound fetal sex determination is often performed after 11 weeks of gestation. This study aims to validate a reliable method for non-invasive prenatal diagnosis of fetal gender using maternal plasma cell-free fetal DNA (cffDNA) for fetal sex assessment in the first trimester of pregnancy and test its clinical utility in the diagnosis of potentially affected pregnancies in carriers of X-linked disorders. Study design: In the validation study, blood samples from 100 pregnant women at 6-11 weeks of gestation were analysed. In the clinical study, 17 pregnancies at risk of having an affected fetus were tested. 7 ml of maternal blood in EDTA were obtained and cffDNA was extracted using a commercially available kit. DNA was enzymatically digested using a methylation sensitive endonuclease (AciI) to remove maternal unmethylated sequences of the RASSF1A gene. A multiplex PCR was performed for the simultaneous amplification of target sequences of SRY and DYS14 from chromosome Y, along with RASSF1A and ACTB sequences. Amplification of these loci indicates fetal gender, confirms the presence of cffDNA and allows assessment of digestion efficiency. Results: After establishing the appropriate experimental conditions, validation studies were successful in all 100 cases tested with no false negative or false positive results. Y chromosome-specific sequences were detected in 68 samples, and 32 cases were diagnosed as female based on the amplification of RASFF1A sequences only, in the absence of ACTB. In the clinical studies, fetal sex was correctly diagnosed in 16 pregnancies, and one case was reported as inconclusive. Conclusions: Fetal sex assessment by detecting Y chromosome sequences in maternal blood can be routinely used from the 6th week of gestation. Reliable fetal sex determination from maternal blood in the 1st trimester of gestation can avoid conventional invasive methods of prenatal diagnosis. © 2012 Elsevier Ireland Ltd

Diet of the Monk Seal (Monachus monachus) in Greek Waters

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Aberrant microRNA expression in tumor mycosis fungoides

Herein, miRNA candidates relevant to mycosis fungoides were investigated to provide data on the molecular mechanisms underlying the pathogenesis of the disease. The miRNA expression profile of skin biopsies from patients with tumor stage MF (tMF) and normal donors was compared using miRNA microarrays. Overall, 154 miRNAs were found differentially expressed between tMF and the control cohort with the majority of them being up-regulated (57 %). Among the upregulated miRNAs, miR-3177, miR-514b-3p, miR-1267, and miR-1282 were exclusively detected in 70 % of tMF. Additional upregulated miRNAs included miR-34a, miR-29a, let-7a*, and miR-210, while miR-200c* was identified among the downregulated ones. Quantitative real-time polymerase chain reaction was used to further investigate the expression profiles of miR-34a and miR-29a and validated the overexpression of miR-34a. Enrichment studies revealed that the target genes of the differentially expressed miRNAs were important in several cancer-related signaling pathways. The overlapping relationship of the target genes among tMF, Sezary syndrome, and atopic dermatitis revealed several common and disease-specific genes. Collectively, our study modulated miR-34a as a candidate oncogenic molecule and miR-29a as a putative tumor suppressor highlighting their promising potential in the molecular pathogenesis of tMF. © 2016, International Society of Oncology and BioMarkers (ISOBM)

Tumor molecular profiling of NSCLC patients using next generation sequencing

Non-small cell lung cancer (NSCLC) is the most common type of lung cancer and a tumor with a broad spectrum of targeted therapies already available or in clinical trials. Thus, molecular characterization of the tumor using next generation sequencing (NGS) technology, has become a key tool for facilitating treatment decisions and the clinical management of NSCLC patients. The performance of a custom 23 gene multiplex amplification hot spot panel, based on Ion AmpliSeq™ technology, was evaluated for the analysis of tumor DNA extracted from formalin-fixed and paraffinembedded (FFPE) tissues. Furthermore, the Ion AmpliSeq™ RNA Fusion Lung Cancer Research Panel was used for fusion RNA transcript analysis. The mutation spectrum of the tumors was determined in a cohort of 502 patients with NSCLC using the aforementioned targeted gene panels. The panel used for tumor DNA analysis in this study exhibited high rates (100%) of sensitivity, specificity and reproducibility at a mutation allelic frequency of 3%. At least one DNA mutation was detected in 374 patients (74.5%) and an RNA fusion was identified in 16 patients, (3.2%). In total, alterations in a cancer-driver gene were identified (including point mutations, gene rearrangements and MET amplifications) in 77.6% of the tumors tested. Among the NSCLC patients, 23% presented a mutation in a gene associated with approved or emerging targeted therapy. More specifically, 13.5% (68/502) presented a mutation in a gene with approved targeted therapy (EGFR, ALK, ROS1) and 9.4% (47/502) had an alteration in a gene related to emerging targeted therapies (ERBB2, BRAF, MET and RET). Furthermore, 51.6% of the patients had a mutation in a gene that could be related to an off label therapy or indicative for access to a clinical trial. Thus, the targeted NGS panel used in this study is a reliable approach for tumor molecular profiling and can be applied in personalized treatment decision making for NSCLC patients