Imatinib with intensive chemotherapy in AML with t(9;22)(q34.1;q11.2)/BCR::ABL1. A DATAML registry study.

Acute myeloid leukemia (AML) with t(9;22) (q34.1; q11.2)/BCR::ABL1, a distinct entity within the group of AML with defining genetic abnormalities, belong to the adverse-risk group of the 2022 ELN classification. However, there is little data on outcome since the era of tyrosine kinase inhibitors. Among 5819 AML cases included in the DATAML registry, 20 patients with de novo BCR::ABL1+AML (0.3%) were identified. Eighteen patients treated with standard induction chemotherapy were analyzed in this study. Imatinib was added to chemotherapy in 16 patients. The female-to-male ratio was 1.25 and median age was 54 years. The t(9;22) translocation was the sole chromosomal abnormality in 12 patients. Main gene mutations detected by NGS were ASXL1, RUNX1 and NPM1. Compared with patients with myeloid blast phase of chronic myeloid leukemia (CML-BP), de novo BCR::ABL1+AML had higher WBC, fewer additional chromosomal abnormalities, lower CD36 or CD7 expression and no ABL1 mutations. Seventeen patients (94.4%) achieved complete remission (CR) or CR with incomplete hematologic recovery. Twelve patients were allografted in first remission. With a median follow-up of 6.3 years, the median OS was not reached and 2-year OS was 77% (95% CI: 50-91). Four out of five patients who were not transplanted did not relapse. Comparison of BCR::ABL1+AML, CML-BP, 2017 ELN intermediate (n = 643) and adverse-risk patients (n = 863) showed that patients with BCR::ABL1+AML had a significant better outcome than intermediate and adverse-risk patients. BCR::ABL1+AML patients treated with imatinib and intensive chemotherapy should not be included in the adverse-risk group of current AML classifications.

The first case of six-way complex translocation of t(4;7;9;22;8;14) in a patient with chronic myeloid leukemia.

In chronic myeloid leukemia (CML), patients exhibit the t(9;22)(q34.1;q11.2) translocation, resulting in the formation of a Philadelphia chromosome (Ph). However, a subset of CML patients display variant complex translocations, characterized by three-way, four-way, and five-way translocations, which have been occasionally associated with a poor prognosis. This case report presents the first case of a t(9;22) variant six-way complex translocation in CML. The R banding chromosome karyotyping technique was used to obtain preliminary karyotyping results, and the multi-probe FISH technique was used to assist in the verification of chromosome results. Both FISH and PCR proved the existence of fusion genes. A 45-year-old male patient admitted to our hospital due to elevated WBC and anemia. Bone marrow smears revealed a significant proliferation of mature granulocytes, accompanied by an increase in eosinophils and basophils. Karyotype analysis indicated abnormalities in six chromosomes, including 4, 7, 8, 9, 14, and 22. Further analysis using FISH technology demonstrated the presence of the BCR::ABL1 fusion gene, as well as the mapping of the BCR (22q11), MYC (8q24), IGH (14q32), D4S163 (4q35.1), and D7S486 (7q31) genes to new chromosomes. Ultimately, the karyotype findings were described as t(4;7;9;22;8;14)(q27;q22;q34;q11;q22;q12). PCR showed that BCR::ABL1 was p210. After treatment with imatinib for 4 months, the patient achieved complete cytogenetic response (CCyR) and early molecular response (EMR). This is the first report of complex chromosomal karyotype involving six-way translocation in CML; the combination of chromosome analysis and FISH techniques is an effective strategy in determining the karyotype result.

Consensus recommendations on counselling in Phelan-McDermid syndrome, with special attention to recurrence risk and to ring chromosome 22.

This paper focuses on genetic counselling in Phelan-McDermid syndrome (PMS), a rare neurodevelopmental disorder caused by a deletion 22q13.3 or a pathogenic variant in SHANK3. It is one of a series of papers written by the European PMS consortium as a consensus guideline. We reviewed the available literature based on pre-set questions to formulate recommendations on counselling, diagnostic work-up and surveillance for tumours related to ring chromosome 22. All recommendations were approved by the consortium, which consists of professionals and patient representatives, using a voting procedure. PMS can only rarely be diagnosed based solely on clinical features and requires confirmation via genetic testing. In most cases, the family will be referred to a clinical geneticist for counselling after the genetic diagnosis has been made. Family members will be investigated and, if indicated, the chance of recurrence discussed with them. Most individuals with PMS have a de novo deletion or a pathogenic variant of SHANK3. The 22q13.3 deletion can be a simple deletion, a ring chromosome 22, or the result of a parental balanced chromosomal anomaly, influencing the risk of recurrence. Individuals with a ring chromosome 22 have an increased risk of NF2-related schwannomatosis (formerly neurofibromatosis type 2) and atypical teratoid rhabdoid tumours, which are associated with the tumour-suppressor genes NF2 and SMARCB1, respectively, and both genes are located on chromosome 22. The prevalence of PMS due to a ring chromosome 22 is estimated to be 10-20%. The risk of developing a tumour in an individual with a ring chromosome 22 can be calculated as 2-4%. However, those individuals who do develop tumours often have multiple. We recommend referring all individuals with PMS and their parents to a clinical geneticist or a comparably experienced medical specialist for genetic counselling, further genetic testing, follow-up and discussion of prenatal diagnostic testing in subsequent pregnancies. We also recommend karyotyping to diagnose or exclude a ring chromosome 22 in individuals with a deletion 22q13.3 detected by molecular tests. If a ring chromosome 22 is found, we recommend discussing personalised follow-up for NF2-related tumours and specifically cerebral imaging between the age of 14 and 16 years.

State of the Science for Kidney Disorders in Phelan-McDermid Syndrome: UPK3A, FBLN1, WNT7B, and CELSR1 as Candidate Genes.

Phelan-McDermid syndrome (PMS) is a neurodevelopmental disorder caused by chromosomal rearrangements affecting the 22q13.3 region or by SHANK3 pathogenic variants. The scientific literature suggests that up to 40% of individuals with PMS have kidney disorders, yet little research has been conducted on the renal system to assess candidate genes attributed to these disorders. Therefore, we first conducted a systematic review of the literature to identify kidney disorders in PMS and then pooled the data to create a cohort of individuals to identify candidate genes for renal disorders in PMS. We found 7 types of renal disorders reported: renal cysts, renal hypoplasia or agenesis, hydronephrosis, vesicoureteral reflux, kidney dysplasia, horseshoe kidneys, and pyelectasis. Association analysis from the pooled data from 152 individuals with PMS across 22 articles identified three genomic regions spanning chromosomal bands 22q13.31, 22q13.32, and 22q13.33, significantly associated with kidney disorders. We propose UPK3A, FBLN1, WNT7B, and CELSR1, located from 4.5 Mb to 5.5 Mb from the telomere, as candidate genes. Our findings support the hypothesis that genes included in this region may play a role in the pathogenesis of kidney disorders in PMS.

Whole-genome sequencing analysis of an atypical teratoid/rhabdoid tumor in a patient with Phelan-McDermid syndrome: a case report and systematic review.

Atypical teratoid/rhabdoid tumor (AT/RT) is a rare pediatric brain tumor with abnormalities in SMARCB1 located in 22q11.2. We report a case of AT/RT associated with Phelan-McDermid syndrome (PMS) characterized by congenital developmental disorder, mental retardation, and ring chromosome 22 with 22q13.3-qter depletion, for which we performed whole-genome sequencing (WGS). A 4-year-old girl with a developmental disability was referred to our hospital due to dysphoria. Brain magnetic resonance imaging showed a 5-cm well-demarcated mass that extended bilaterally in the frontal lobes. G-banding was performed preoperatively due to a history of developmental retardation. Ring chromosome 22 and deletion of 22q13.3-qter were observed, and she was diagnosed with PMS. She underwent gross total resection of the tumor, and the pathological diagnosis was AT/RT. WGS showed somatic SMARCB1 mutation (p.R201X) and somatic loss of the entire chromosome 22 in the tumor, but not in the blood sample. WGS confirmed previously unreported BRCA2 mutations, 6q loss, and 14q acquisition during tumor progression, but no other significant findings associated with tumor progression. The present case is discussed with reference to a systematic review of previous reports of AT/RT associated with PMS. PMS patients with ring chromosome 22 should be carefully followed up for AT/RT occurrence.

A rare case of atypical chronic myeloid leukemia associated with t(8;22)(p11.2;q11.2)/ BCR-FGFR1 rearrangement: A case report and literature review.

Myeloid/lymphoid neoplasm with t(8;22)(p11.2;q11.2)/BCR-FGFR1 is an extremely rare diagnosis, with few reported cases to date. In contrast to other FGFR1-partner rearrangements that are associated with chronic eosinophilic leukemia, acute myeloid leukemia, and/or lymphoblastic lymphoma, patients with BCR-FGFR1 have a myeloproliferative disorder that closely resembles chronic myeloid leukemia (CML). The current report describes a rare case of a 61 year old man with an atypical CML phenotype associated with t(8;22)(p11.2;q11.2)/BCR-FGFR1. A literature review is presented to enhance the awareness of this rare diagnostic entity.

A case of a patient characterized by t(8;22)(p11;q11) and BCR/FGFR1 fusion gene, who was successfully treated with haploidentical hematopoietic stem cell transplantation.

Objective: The 8p11 myeloproliferative syndrome [EMS] is a rare myeloproliferative disorder which usually develops rapidly with chromosomal translocation of the fibroblast growth factor receptor 1 gene. The gene has 15 fusion partners, including the breakpoint cluster region (BCR) gene on chromosome 22. Of all the tests available, chromosome karyotype determination is the most important for the diagnosis of EMS. Here, we describe one case of a patient characterized by marked increase of white blood cells and thrombocytopenia and diagnosed as EMS with t(8;22)(p11;q11) by chromosome karyotype.Methods: 28-year-old man was referred to our hospital. He had a onemonth history of intermittent coughing and a small amount of expectoration after catching a cold. As an outpatient, his complete blood count showed: WBC was 130.04 × 109/L with 80.20% granulocytes.Hematologic investigations, bone marrow analysis and genomic DNA sequencing studies were performed.Results: Despite additional chromosomal abnormalities,the patient progressed rapidly with a B blast cell clone in one month. After diagnosis inthree months, the patient underwent the haplo-identical BMT of his brother, followed up for three years, and had a high rate of survival.Conclusions: Our report provides a definite conceptual framework for a better understanding of the characteristics of The 8p11 myeloproliferative syndrome [EMS].

A child with cat-eye syndrome and oculo-auriculo-vertebral spectrum phenotype: A discussion around molecular cytogenetic findings.

Cat eye syndrome (CES) is a rare chromosomal disorder that may be evident at birth. A small supernumerary chromosome is present, frequently has 2 centromeres, is bisatellited, and represents an inv dup(22)(q11) in those affected. It's known that the 22q11 region is associated with disorders involving higher and lower gene dosages. Conditions such as CES, 22q11 microduplication syndrome (Dup22q11) and oculoauriculovertebral spectrum phenotype (OAVS) may share genes belonging to this same region, which is known to have a predisposition to chromosomal rearrangements. The conditions, besides being related to chromosome 22, also share similar phenotypes. Here we have added a molecular evaluation update and results found of the first patient described with CES and OAVS phenotype, trying to explain the potential mechanism involved in the occurrence of this association.

Recurrent loss of chromosome 22 and SMARCB1 deletion in extra-axial chordoma: A clinicopathological and molecular analysis.

Extra-axial chordoma is a rare neoplasm of extra-axial skeleton and soft tissue that shares identical histomorphologic and immunophenotypic features with midline chordoma. While genetic changes in conventional chordoma have been well-studied, the genomic alterations of extra-axial chordoma have not been reported. It is well known that conventional chordoma is a tumor with predominantly non-random copy number alterations and low mutational burden. Herein we describe the clinicopathologic and genomic characteristics of six cases of extra-axial chordoma, with genome-wide high-resolution single nucleotide polymorphism array, fluorescence in situ hybridization and targeted next-generation sequencing (NGS) analysis. The patients presented at a mean age of 33 years (range: 21-54) with a female to male ratio of 5:1. Four cases were histologically conventional type, presented with bone lesions and three of them had local recurrence. Two cases were poorly differentiated chordomas, presented with intra-articular soft tissue masses and both developed distant metastases. All cases showed brachyury positivity and the two poorly differentiated chordomas showed in addition loss of INI-1 expression by immunohistochemical analysis. Three of four extra-axial conventional chordomas showed simple genome with loss of chromosome 22 or a heterozygous deletion of SMARCB1. Both poorly differentiated chordomas demonstrated a complex hyperdiploid genomic profile with gain of multiple chromosomes and homozygous deletion of SMARCB1. Our findings show that heterozygous deletion of SMARCB1 or the loss of chromosome 22 is a consistent abnormality in extra-axial chordoma and transformation to poorly differentiated chordoma is characterized by homozygous loss of SMARCB1 associated with genomic complexity and instability such as hyperdiploidy.

The Neurological Manifestations of Phelan-McDermid Syndrome.

Phelan-McDermid syndrome (PMS) is a genetic disorder, caused by haploinsufficiency of the SHANK3 gene on chromosome 22q13.3. PMS is characterized by neurobehavioral symptoms and signs including intellectual disability, speech and language impairment, autism spectrum disorder (ASD), hypotonia, and other motor abnormalities. In the brain, SHANK3 is expressed in neurons, especially in the synapse, and encodes a master scaffolding protein that forms a key framework in the postsynaptic density of glutamatergic synapses. Mutations in SHANK3 have also been identified in individuals with ASD, intellectual deficiency (ID), and schizophrenia. Shank3 deficient mice have defects in basal glutamatergic synaptic transmission in the hippocampus, and in synaptic transmission plasticity, including deficits in long-term potentiation, and show behavioral deficits compatible with the clinical manifestations of PMS. The PMS phenotype varies between affected individuals, but ID and speech and language impairment are present in all cases. ASD is present in a great majority of these individuals. Neurological examination demonstrates hypotonia and abnormalities of motor coordination, visual motor coordination, and gait in the majority of affected individuals. Sleep disturbances and increased pain tolerance are frequent parental complaints. Seizures and epilepsy are common, affecting more than 40% of individuals. Brain magnetic resonance imaging abnormalities include corpus callosum hypoplasia, delayed myelination and white matter abnormalities, dilated ventricles, and arachnoid cysts. Recent advanced imaging anatomic studies including diffusion tensor imaging, point to abnormal brain connectivity. The natural history of the syndrome is not yet fully known, but some individuals with PMS have a later onset of psychiatric illnesses including bipolar disease, accompanied by functional and neurological regression. Individuals with the syndrome are treated symptomatically. Advances in understanding the pathophysiology of this syndrome and the generation of animal models have raised opportunities for a biological cure for PMS. A pilot clinical trial with insulin-like growth factor-1 (IGF-1) showed positive effects on some behavioral core symptoms.

Lymphedema complicated by protein-losing enteropathy with a 22q13.3 deletion and the potential role of CELSR1: A case report.

INTRODUCTION: 22q13.3 deletion syndrome is a well-known syndrome characterized by typical clinical findings including neonatal hypotonia, absent or severely delayed speech, intellectual disability, and other various features, and detection of a heterozygous deletion of chromosome 22q13.3 with the involvement of at least part of SHANK3. It is reported that 10% to 29% of patients with 22q13.3 deletion syndrome present lymphedema. Protein-losing enteropathy (PLE) has never been reported in 22q13.3 deletion syndrome. PATIENT CONCERNS: The patient presented to our institution for refractory hypoalbuminemia and chronic lymphedema in both legs. DIAGNOSIS: The patient manifested intellectual disability, absent speech, tooth grinding, dysmorphic face, and abnormal hands and toenails. Copy-number variation sequencing confirmed the maternal deletion in 22q13.31-q13.33 (chr22:46285592-51244566, hg19). The patient was genetically diagnosed with 22q13.3 deletion syndrome. INTERVENTIONS: Low-fat diets and medium-chain triglycerides supplements were prescribed. The patient was recommended to wear compression garments and elevate legs. OUTCOMES: The symptom of diarrhea was resolved, but hypoalbuminemia persisted. Lower extremities lymphedema was gradually becoming severe. CONCLUSIONS: Primary lymphedema and PLE can occur simultaneously in a patient with 22q13.3 deletion syndrome. The 2 phenotypes could share the same genetic etiology of congenital lymphatic abnormalities. CELSR1 deletion may play a role in lymphatic dysplasia. The case also provides additional proof of the pathogenic effect of CELSR1 on hereditary lymphedema.

Frequent breakpoints of focal deletion and uniparental disomy in 22q11.1 or 11.2 segmental duplication region reveal distinct tumorigenesis in rhabdoid tumor of the kidney.

SMARCB1 is mutated in most rhabdoid tumors (RTs) developing in the kidney (RTK) and various other organs. Focal deletions found in patients with 22q11.2 deletion syndrome show breakpoints within clusters of segmental duplications (SDs), and those in some RTs show breakpoints in the 22q11-q12 region. SDs are known to cause focal deletion mediated by non-allelic homologous recombination. The present study identified SMARCB1 alterations in all 30 RTKs, using SNP array CGH, MLPA, and sequence analyses. Twenty-eight tumors had a total of 51 breakpoints forming focal 22q deletion and/or uniparental disomy (22qUPD), and the other two had compound mutation with no breakpoints in 22q. Twenty-four (47.1%) of the 51 breakpoints were within SDs, and occurred in 16 (53.3%) of the 30 tumors. The association of breakpoints with SDs was found not only in focal deletion, but also in 22qUPD, indicating that SDs mediate the first and second hits (focal deletion) and the second hit (22qUPD) of SMARCB1 alteration. Of the 51 breakpoints, 14 were recurrent, and 10 of the 14 were within SDs, suggesting the presence of hotspots in the 22q11.2 region. One recurrent breakpoint outside SDs resided in SMARCB1, suggesting inactivation of the gene by out-of-frame fusion. The association between SDs and focal deletion has been reported in two other types of cancer. RTKs may be the third example of SD-associated tumors. Thus, the present study indicated that RTKs exploit genomic instability in the 22q11.1-11.2 SDs region, and 22qUPD caused by mitotic recombination may also be mediated by SDs.

BCR-ABL1 positive AML or CML in blast crisis? A pediatric case report with inv(3) and t(9;22) in the initial clone.

The co-occurrence of an inversion inv(3)(q21q26)/GATA2-MECOM and a Philadelphia translocation t(9;22)(q34;q11)/BCR-ABL1 in the context of chronic myeloid leukemia (CML) in blast crisis or acute myeloid leukemia (AML) has only rarely been described. To our knowledge, this co-occurrence has been reported in six pediatric patients with CML but not in pediatric patients with AML. Here, we report on a 7-year-old girl, who, presented with a t(9;22) and inv(3) in 14 of 15 metaphases and an additional monosomy 7 was detected in 5 of these metaphases (ISCN: 46,​XX,​inv(3)(q21q26),​t(9;22)(q34q11)[9]/45,​idem,​-7[5]/46,​XX[1]). The p190 BCR-ABL1 fusion transcript was detected by multiplex PCR and targeted RNA sequencing. Due to these results, a clear distinction between a CML in blast crisis and a BCR-ABL1 positive AML was not possible. The patient was treated according to the treatment recommendations of the AML-BFM study group and additionally received tyrosine kinase inhibitor therapy (Dasatinib). The treatment with Dasatinib was successful in eliminating the inv(3)/t(9;22) clone, but the ancestral inv(3) clone persisted. Based upon these findings we diagnosed an AML with inv(3) and a secondary acquisition of t(9;22). This treatment as well as an allogenic transplantation has led to a complete remission of the disease up to this date (21 months post diagnosis).

Two Cases of Possible Familial Chronic Myeloid Leukemia in a Family with Extensive History of Cancer.

CML is defined by the presence of an oncogenic fusion protein caused by a reciprocal translocation between chromosomes 9q and 22q. While our molecular understanding of CML pathogenesis has revolutionized drug development for this disease, we have yet to identify many predisposing factors for CML. Familial occurrence of CML has been rarely reported. Here, we describe 2 cases of CML in a 24-year-old woman and in her 73-year-old maternal great aunt. We describe genetic variants in these patients and report on their environmental exposures that may have contributed to CML pathogenesis. The possible familial association of these 2 cases of CML warrants further investigation into more definitive etiologies of this disease.

Analysis of the P53N a Novel Protein Encoded on Chromosome 22q12.1-12.3 in Glioblastomas and Ependymomas Specimens.

The P53N gene maps precisely to human chromosome sub-band 22q12.1-12.3, a region where loss of heterozygosity has been reported in 30% of astrocytic tumors and associated with progression to anaplasia. Moreover, a putative tumor suppressor gene has been indicated on 22q11 region involved in pathogenesis of ependymal tumors. Our objectives to examine the expression level of novel membrane-associated protein (termed P53N) encoded by a novel human gene on chromosome 22q12.1-12.3 in glioblastomas and ependymomas. Serial analysis of gene expression (SAGE) and immunofluorescence analysis of the P53N in the brain tumor tissues were performed. Our analysis revealed that there was high expression of the P53N mRNA in brain ependymoma and brain well-differentiated astrocytoma libraries. The P53N protein. P53N protein contains a high mobility group (HMG) domain at amino acid positions 301 to 360 expressed highly in glioblastoma and ependymoma specimens. Anti-P53N carboxyl-terminal peptide antibody localized the P53N protein to the cytoplasmic membranes of protoplasmic astrocytes in the glioblastoma and ependymoma specimens. These results are in good agreement with the SAGE analysis and the predicted transmembrane topology for the P53N protein and support a possible transmembrane model in which the P53N contains a predicted transmembrane region with its amino terminus localized to the inside of the cytoplasmic membrane.

Incidental finding of APC deletion in a child: double trouble or double chance? - a case report.

BACKGROUND: 22q11.2 deletion syndrome is one of the most common genomic disorders, characterized by the variable presence of facial dysmorphisms, congenital cardiac defects, velopharyngeal insufficiency/cleft palate, thymic hypoplasia/aplasia, immunodeficiency, parathyroid hypoplasia, developmental delay, learning disabilities, psychiatric disorders, renal, ocular, and skeletal malformations, hearing loss and laryngeal abnormalities. Chromosomal microarray (CMA) hybridization is one of the most performed diagnostic tests but as a genome wide analysis, it can point out relevant incidental copy number variations. CASE PRESENTATION: We report the case of a 2-year-old boy that came to our attention for mild psychomotor delay, poor growth, and minor facial anomalies. Considering a diagnosis of 22q11.2 deletion syndrome, we performed CMA that not only confirmed our diagnosis, but also pointed out an additional de novo 5q21.3q22.2 microdeletion, encompassing APC gene. As a result of the genetic testing we enrolled the patient in a tailored surveillance protocol that enabled the early detection of a hepatoblastoma. The child underwent surgical and chemotherapic treatments with complete cancer eradication. CONCLUSIONS: The concurrent finding of an expected result and an additional deletion of APC gene represents an example of a relevant issue about the health and ethical management of secondary findings revealed by genome-wide tests. Furthermore, this report highlights the need to develop dedicated surveillance guidelines for children with APC-related polyposis and raise the question whether to suspect and screen for APC-related conditions in cases of sporadic hepatoblastomas.

Fluorescence in situ hybridization detection of chromosome 22 monosomy in pleural effusion cytology for the diagnosis of mesothelioma.

BACKGROUND: Malignant pleural mesothelioma (MPM) is characterized by mutations in several genes, including cyclin-dependent kinase-inhibitor 2A/p16 in the 9p21 locus, BRCA1-associated protein 1 (BAP1), and neurofibromatosis type 2 (NF2) in the 22q12 locus. Recent studies indicate that fluorescence in situ hybridization (FISH) detects hemizygous loss of NF2 in tissue specimens of MPM. The authors investigated whether NF2 FISH, either alone or in combination with other diagnostic assays (9p21 FISH, methylthioadenosine phosphorylase [MTAP] immunohistochemistry [IHC], and BAP1 IHC), effectively distinguishes MPM cells from reactive mesothelial cells (RMCs) in cell blocks prepared from pleural effusions. METHODS: FISH assays were used to examine the deletion status of NF2 and 9p21, and IHC was used to determine the expression of MTAP and BAP1 in cell blocks from 54 cases with MPM and 18 cases with RMCs. RESULTS: Hemizygous NF2 loss (chromosome 22 monosomy or hemizygous deletion) showed 51.9% sensitivity (48.1% for chromosome 22 monosomy and 3.7% for hemizygous deletion) and 100% specificity in differentiating MPM cells from RMCs. Combinations of NF2 FISH, 9p21 FISH, and BAP1 IHC assays yielded greater sensitivity (98.1%) than any assay alone (9p21 FISH, 61.1%; MTAP IHC, 52.8%; or BAP1 IHC, 60.4%). The level of hemizygous NF2 loss in cell blocks positively correlated with that in corresponding tissues. Furthermore, to overcome cytologic specimen-specific challenges, FISH combined with cytokeratin AE1/AE3 immunofluorescence was necessary in 25.9% of MPM cases for FISH assessment of predominantly scattered MPM cells. CONCLUSIONS: NF2 FISH alone or in combination with other diagnostic assays effectively differentiates MPM cells from RMCs in cell blocks prepared from pleural effusions.

Primary Primitive Neuroectodermal Tumor of the Spine With t(11;22): Report of 3 Cases and Review of Literature.

Intradural extramedullary peripheral primitive neuroectodermal tumor (pPNET) with t(11;22) is a rare clinical finding in the pediatric population with few published cases in the literature. The authors report 3 cases of intradural primary pPNET and discuss the clinical presentation, treatment, and survival of the patients. Clinicians should be vigilant in considering pPNET in the differential diagnosis of extradural masses. The authors also compare the clinical course and outcome of therapy with primary PNET of the central nervous system and Ewing sarcoma family of tumors. In addition, this report highlights the risk for leptomeningeal dissemination at recurrence and discusses the importance of central nervous system-targeted therapy for durable disease control.