To report a case of iron overload secondary to xerocytosis, a rare disease in a teenager, diagnosed, by T2* magnetic resonance imaging. We report the case of a symptomatic patient with xerocytosis, a ferritin level of 350ng/mL and a significant cardiac iron overload. She was diagnosed by T2* magnetic resonance imaging and received chelation therapy Ektacytometric analysis confirmed the diagnosis of hereditary xerocytosis. Subsequent T2* magnetic resonance imaging demonstrated complete resolution of the iron overload in various organs, as a new echocardiography revealed a complete resolution of previous cardiac alterations. The patient remains in chelation therapy. Xerocytosis is a rare autosomal dominant genetic disorder characterized by dehydrated stomatocytosis. The patient may present with intense fatigue and iron overload. We suggest the regular use of T2* magnetic resonance imaging for the diagnosis and control of the response to iron chelation in xerocytosis, and we believe it can be used also in other hemolytic anemia requiring transfusions.
OBJETIVO: Correlacionar a localização das alterações clínicas de portadores de linfedema com as dos achados linfocintilográficos. MÉTODO: Foram avaliados 34 pacientes com linfedema dos membros inferiores atendidos no Setor de Linfologia da Disciplina de Cirurgia Vascular da Faculdade de Medicina do ABC. As linfocintilografias com imagens adquiridas em dois tempos - 20 minutos e 3 horas - foram analisadas quanto aos seguintes parâmetros: vasos linfáticos, refluxo dérmico, circulação colateral, linfonodos poplíteos e inguinais. Correlacionaram-se os resultados com a localização do edema no membro: grupo A (sem edema), grupo B (pé), grupo C (tornozelo), grupo D (perna) e grupo E (coxa). RESULTADO: A maioria das imagens linfocintilográficas apresentou anormalidades nos vasos linfáticos e linfonodos inguinais e pouca alteração em relação aos outros parâmetros. Dos 34 pacientes, 12 apresentaram linfedema unilateral clinicamente. Destes, 11 apresentaram alteração linfocintilográfica bilateral. CONCLUSÃO: A localização do linfedema ao exame físico não correspondeu, na maioria dos casos, às alterações linfocintilográficas. Em todos os grupos, as alterações linfocintilográficas ocorreram na perna e na coxa. O exame físico do membro pode estar normal e ainda assim apresentar anormalidades na linfocintilografia.
The peak frequency of Hodgkin's disease convergesmatches with women of reproductive fertility age. Currently, this disease is the fourth more diagnosed neoplasia during pregnancy. In addition, there is no consensus in the literature on how to treat pregnant women because of the risks of chemotherapy for mothers and for fetuses. We report three cases of pregnant women with Hodgkin's disease. A review of the literature was made aiming to suggest a protocol to treat these patients.
Introduction: The development of next-generation sequencing has made it feasible to interrogate the entire genome or exome (coding genome) in a single experiment. Accordingly, our knowledge of the somatic mutations that cause cancer has increased exponentially in the last years. MPNs and MDS/MPD are chronic myeloid neoplasms characterized by an increased proliferation of one or more hematopoietic cell lineages, and an increased risk of transformation to acute myeloid leukemia (AML). MPNs and MDS/MPDs are heterogenous disorders, both in clinical presentation and in prognosis. We sought to determine the genetic landscape of Ph-negative MPNs and MDS/MPD through next-generation sequencing. Methods: Paired DNA (sorted CD66b-granulocytes/skin biopsy) from 102 patients with MPNs or MDS/MPD was subjected to whole exome sequencing on a Illumina HiSeq 2000 platform using Agilent SureSelect kit. Diagnosis included primary myelofibrosis (MF; N=42), essential thrombocythemia (ET; N=28), polycythemia vera (PV; N=12), chronic myelomonocytic leukemia (CMML; N=10), systemic mastocytosis (MS; N=6), MDS/MPD-Unclassified (N=2) and post-MPN AML (N=2). Tumor coverage was 150x and germline coverage was 60x. Somatic variants calls were generated by combining the output of Somatic Sniper (Washington University), Mutect (Broad Institute) and Pindel (Washington University). The combined output of these 3 tools was further filtered by in-house criteria in order to reduce false-positive calls (minimum coverage at both tumor/germline ≥8 reads; fraction of reads supporting alternate allele ≥10% in tumor and ≤10% in germline; ratio of allele fraction tumor:germline >2; excluding mutations seen in SNP databases). All JAK2 and CALR mutations were validated through Sanger sequencing. Validation of other somatic mutations is currently underway. Analysis of driver mutations was made with the Intogen web-based software, using the Oncodrive-FM and Oncodrive-cluster algorithms (www.intogen.org). Significantly mutated genes were considered as those with a q-value of <0.10. Results: We identified a total of 309 somatic mutations in all patients, with each patient having an average of 3 somatic abnormalities, fewer than most solid tumors that have been sequenced so far. Mutations occurred in 166 genes, and 40 of these were recurrently somatically mutated in Ph-negative MPNs. By the Oncodrive-FM algorithm, the following genes were identified as the most significantly mutated driver genes in Ph-negative MPNs and MDS/MPDs (in order of significance): CALR, ASXL1, JAK2, CBL, DNMT3A, U2AF1, TET2, TP53, RUNX1, EZH2, SH2B3 and KIT. By the Oncodrive-cluster algorithm, which considers clustering of mutations at a hotspot, the following genes were significantly mutated: KIT, JAK2, SRSF2 and U2AF1. Somatic mutations were seen in genes that are mutated at a low frequency in Ph-negative MPNs, including ATRX, BCL11A, BCORL1, BIRC5, BRCC3, CSF2RB, CUX1, IRF1, KDM2B, ROS1 and SUZ12. Consistent with the clinical phenotype, 96 patients (94%) had mutations that lead to increased cellular proliferation, either through activation of the JAK-STAT pathway (e.g. JAK2, CALR) or mutations that activated directly or indirectly signaling by receptor tyrosine kinases (e.g. FLT3, KIT, CBL). Besides biological pathways regulating cell proliferation, the most commonly implicated pathways included regulation of DNA methylation (e.g. DNMT3A, TET2), mRNA splicing (e.g. U2AF1, SRSF2) and histone modifications (e.g. ASXL1, EZH2), seen in 27%, 25% and 22% of patients, respectively. Abnormalities in these 3 pathways were more often seen in MF, MDS/MPD and CMML, as compared to PV and ET (65% vs. 20%; p<0.0001). Conclusions: Our study represents one of the largest series of patients with these neoplasms evaluated by whole exome sequencing, and together with the published data helps to delineate the genomic landscape of Ph-negative MPNs and MDS/MPDs. The majority of the most frequent mutations seen in Ph-negative MPNs have already been reported. Nevertheless, there are several low frequency mutations that need to be further studied and functionally validated in vitro and in vivo for a deeper knowledge of the pathophysiology of MPNs. Besides activation of cellular proliferation, abnormalities of DNA methylation, histone modification and mRNA splicing emerge as the most important biological pathways in these disorders. Disclosures No relevant conflicts of interest to declare.
Sepsis caused by coryneform bacteria is probably underdiagnosed: diphtheroids are usually considered contaminants when obtained in blood cultures.
Introduction: Mutations that activate the RAS-RAF-MEK-ERK pathway have long been known to occur in patients with solid tumors and hematological malignancies. The most common mutations occur in the Ras family of GTPases (HRAS, NRAS, KRAS) and the Raf family of serine-threonine kinases (ARAF, BRAF, CRAF). In myeloid malignancies, RAS mutations have mainly been described in patients with acute myeloid leukemia, chronic myelomonocytic leukemia (CMML) and myelodysplastic syndrome. There are few studies describing the incidence of mutations of the RAS-RAF-MEK-ERK pathway in patients with MPNs other than CMML. Objective: To describe the incidence, clinical features and prognostic impact of Ras and Raf mutations in patients with Ph-negative MPNs and MPN/MDS-U Methods: Paired DNA (sorted CD66b-granulocytes/skin biopsy) from patients with MPNs or MPN/MDS was subjected to whole exome sequencing on a Illumina HiSeq 2000 platform using Agilent SureSelect kit (see our abstract “Whole Exome Sequencing of Myeloproliferative Neoplasms and Myelodysplastic/Myeloproliferative Disorders”). Tumor coverage was 150x and germline coverage was 60x. Somatic variants calls were generated by combining the output of Somatic Sniper (Washington University), Mutect (Broad Institute) and Pindel (Washington University), followed by in-house filters to reduce false positive calls. Statistical calculations were done in Stata, v11.0. Results: We found clonal activating mutations of the RAS-RAF-MEK-ERK pathway in 8 patients (6.7% of cases). Diagnosis included primary myelofibrosis (PMF; N=5), MDS/MPD-U (N=2) and essential thrombocythemia (ET; N=1). Their clinical features are summarized in Table 1 (three of these patients [UPIs #11, #13, #99] are also described in the abstract “Genomic Profile of Patients with Triple Negative (JAK2, CALR and MPL) Essential Thrombocythemia and Primary Myelofibrosis”). There were 7 NRAS mutations and 1 BRAF mutation. In 5 cases the variant allele fraction (VAF) of reads in the tumor sample indicated that the mutation was present in a subclone at the time of sequencing. We next compared the clinical features of these 8 patients with 79 patients (MF=43, ET=35, MDS/MPD=1) who did not harbor these mutations. Patients with NRAS/BRAF mutations had lower hemoglobin (8.3 vs. 11.8 g/dL, p=0.001), higher white blood cell counts (28.37 vs. 7.7 x109/L, p=0.008) and had higher lactate dehydrogenase (1041 vs. 685 IU/L, p=0.02). They also had worse overall survival compared to unmutated cases (Hazard ratio [HR]=11.57; p=0.001). Most patients with NRAS/BRAF mutations had a high number of concomitant driver mutatons (median 5 vs. 1; p<0.0001). When the number of driver mutations was analyzed together with NRAS/BRAF mutations in a Cox model, NRAS/BRAF mutations were no longer independent predictors of survival (HR=1.48; p=0.61). Conclusions: Activating mutations of the RAS-RAF-MEK-ERK pathway occur in 6-7% of patients with Ph-negative MPNs, and they tend to co-occur with a high number of concomitant driver mutations. In most cases the mutation was present in a subclone, suggesting that they are late occurring. Patients with NRAS/BRAF mutations had a trend for worse outcome, but that was mainly dependent on the total number of driver mutations. The activity of MEK and BRAF inhibitors needs to be explored in patients with Ph-negative MPNs who harbor activating mutations of the RAS-RAF-MEK-ERK pathway. Table 1. Clinical features of patients with NRAS/BRAF mutations UPI Diagnosis Mutation VAF Concomitant driver genes and Chromosomal abnormalities Outcomes 7 MF NRAS p.G12S 47% ASXL1, CALR, STAG2, U2AF1 Died from disease progression 11 MF NRAS p.G12R 5% ASXL1, CBL, CUX1 (double mutant), EZH2 Died from disease progression 13 MF NRAS p.G12D 48% ASXL1, DNMT3A, ETV6 (double mutant) JARID2, U2AF1 Died from disease progression 18 MF NRAS p.G13D 25% JAK2, Del(5q) Underwent allogeneic transplantation; disease relapsed day+80; alive 29 MDS/MPD-U BRAF p.D594G 25% JAK2, Del(5q) Transformed to AML; entered CR with induction chemotherapy; underwent allogeneic transplantation; disease relapsed day+35; alive 99 ET NRAS p.G12D 43% ASXL1, CSF3R, STAG2 Alive 109 MF NRAS p.Q61R 19% CALR, DNMT3A, ZRSR2 Alive 122 MDS/MPD-U NRAS p.G12S 7% ASXL1, EZH2 (double mutant), PTPN11, TET2 (double mutant) Transformed to AML; underwent allogeneic transplantation; died on day+58 Disclosures No relevant conflicts of interest to declare.
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