Validation of MYC and BCL6 rapid break apart digital fluorescence in situ hybridization assays for clinical use.

OBJECTIVE: Detection of gene rearrangements in MYC (a family of regulator genes and proto-oncogenes) and human B-cell lymphoma 6 (BCL6) using fluorescence in situ hybridization (FISH) are important in the evaluation of lymphomas, in particular diffuse large B-cell lymphoma (DLBCL) and Burkitt lymphoma. Our current clinical MYC and BCL6 FISH workflow involves an overnight hybridization of probes with digital analysis using the GenASIs Scan and Analysis instrument (Applied Spectral Imaging). In order to improve assay turnaround time SureFISH probes were validated to reduce the hybridization time from 16 hours down to 1.5 hours. METHODS: Validation was a four-phase process involving initial development of the assays by testing new probes in a manual protocol, and cytogenetic studies to confirm the probe specificity, sensitivity, and localization. In the next phase, the assays were validated as a manual assay. The third phase involved development of the digital FISH assays by testing and optimizing the GenASIs Scan and Analysis instrument. In the final phase, the digital FISH assays were validated. RESULTS: Cytogenetic studies confirmed 100% probe sensitivity/specificity, and localization patterns. Negative reference range cutoffs calculated from 20 normal lymph nodes using the inverse of the beta cumulative probability density function (Excel BETAINV calculation) were 11% inclusive for both manual and digital MYC and BCL6 assays. There was 100% concordance between the manual and digital methods. The shortened hybridization time decreased the overall workflow time by 14.5 hours. CONCLUSIONS: This study validates the use of the SureFISH MYC and BCL6 probes on formalin fixed paraffin embedded (FFPE) tissue sections using a hybridization time of 1.5 hours that shortened the overall workflow by 14.5 hours. The process described also provides a standardized framework for validating digital FISH assays in the future.

Quantitative Imaging Analysis Fluorescence In Situ Hybridization Validation for Clinical HER2 Testing in Breast Cancer.

CONTEXT.­: Quantitative imaging is a promising tool that is gaining wide use across several areas of pathology. Although there has been increasing adoption of morphologic and immunohistochemical analysis, the adoption of evaluation of fluorescence in situ hybridization (FISH) on formalin-fixed, paraffin-embedded tissue has been limited because of complexity and lack of practice guidelines. OBJECTIVE.­: To perform human epidermal growth factor receptor 2 (HER2) FISH validation in breast carcinoma in accordance with the American Society of Clinical Oncology/College of American Pathologists (ASCO/CAP) 2018 guideline. DESIGN.­: Clinical validation of HER2 FISH was performed using the US Food and Drug Administration-approved dual-probe HER2 IQFISH (Dako, Carpinteria, California) with digital scanning performed on a PathFusion (Applied Spectral Imaging, Carlsbad, California) system. Validation parameters evaluated included z-stacking, classifier, accuracy, precision, software, and hardware settings. Finally, we evaluated the performance of digital enumeration on clinical samples in a real-world setting. RESULTS.­: The accuracy samples showed a final concordance of 95.3% to 100% across HER2 groups 1 to 5. During clinical implementation for HER2 groups 2, 3, and 4, we achieved a final concordance of 76% (95 of 125). Of these cases, only 8% (10 of 125) had discordances with clinical impact that could be identified algorithmically and triaged for manual review. CONCLUSIONS.­: Digital FISH enumeration is a useful tool to improve the efficacy of HER2 FISH enumeration and capture genetic heterogeneity across HER2 signals. Excluding cases with high background or poor image quality and manual review of cases with ASCO/CAP group discordances can further improve the efficiency of digital HER2 FISH enumeration.

Application of the Roche Cobas® HPV 4800 in Formalin-Fixed, Paraffin-Embedded Samples for Head and Neck Squamous Cell Carcinomas.

Testing for high risk human papillomavirus (HR-HPV) status is standard of care in squamous cell carcinomas of the oropharynx as well as cervical lymph node squamous cell carcinomas of unknown primary origin. DNA or RNA in-situ hybridization (ISH) and p16 immunohistochemistry, widely used currently for HPV detection are operator-dependent. In addition, DNA ISH has a relatively low sensitivity, and p16 is not entirely specific for HR-HPV infection. In this study, we examined the performance of the cobas® HPV genotyping assay in formalin-fixed, paraffin-embedded (FFPE) samples of head and neck squamous cell carcinoma. FFPE samples from head neck and other anatomic sites tested by ISH and p16 for HR-HPV at ARUP Laboratories were selected for this study. Samples were deparaffinized, stained and micro-dissected for tumor contents followed by tissue lysis, then tested with cobas® for HR-HPV. All the samples were also tested by HPV Linear Array for confirmation. All (N = 18) high risk HPV positive specimens tested by cobas® were confirmed as positive by the Linear Array test. All the specimens tested as negative by cobas® were tested as negative (N = 5) or positive only for low risk HPV (N = 3) by Linear Array, as cobas® only detects HR HPV. Limits of detection for HPV16 and 18 were established at 160-320 and 320-1600 copies, respectively. Our data suggest that cobas® HR-HPV genotyping is a viable option for detection of HR-HPV in formalin-fixed, paraffin-embedded samples from head and neck and other anatomic sites and has been validated for clinical use.

Braddock-Carey syndrome: A 21q22 contiguous gene syndrome encompassing RUNX1.

In 1994, Braddock and Carey first reported two unrelated girls with a new multiple malformation syndrome. The primary features included Pierre Robin sequence, persistent neonatal-onset thrombocytopenia, agenesis of the corpus callosum, a distinctive facies, enamel hypoplasia, and severe developmental delay. Since that time, there have been multiple other reported patients with a similar phenotype. In addition, several reports of thrombocytopenia and developmental delay have been documented in association with deletions in the Down syndrome critical region at 21q22. The similarity of the reported cases with deletions involving 21q22 with the clinical presentation of the two patients with Braddock-Carey syndrome resulted in a reinvestigation of the genetic etiology of these two patients 20 years after the original study. This investigation provides evidence that the etiology of this and other "Fanconi-like" disorders represent a newly recognized contiguous gene deletion syndrome involving 21q22 and specifically, the RUNX1 gene. © 2016 Wiley Periodicals, Inc.

Validation of break-apart and fusion MYC probes using a digital fluorescence in situ hybridization capture and imaging system.

INTRODUCTION: Detection of MYC translocations using fluorescence in situ hybridization (FISH) is important in the evaluation of lymphomas, in particular, Burkitt lymphoma and diffuse large B-cell lymphoma. Our aim was to validate a digital FISH capture and imaging system for the detection of MYC 8q24 translocations using LSI-MYC (a break-apart probe) and MYC 8;14 translocation using IGH-MYC (a fusion probe). MATERIALS AND METHODS: LSI-MYC probe was evaluated using tissue sections from 35 patients. IGH-MYC probe was evaluated using tissue sections from forty patients. Sections were processed for FISH and analyzed using traditional methods. FISH slides were then analyzed using the GenASIs capture and analysis system. RESULTS: Results for LSI-MYC had a high degree of correlation between traditional method of FISH analysis and digital FISH analysis. Results for IGH-MYC had a 100% concordance between traditional method of FISH analysis and digital FISH analysis. CONCLUSION: Annotated whole slide images of H and E and FISH sections can be digitally aligned, so that areas of tumor within a section can be matched and evaluated with a greater degree of accuracy. Images can be archived permanently, providing a means for examining the results retrospectively. Digital FISH imaging of the MYC translocations provides a better diagnostic tool compared to traditional methods for evaluating lymphomas.

Observations of the genomic landscape beyond 1p19q deletions and EGFR amplification in glioma.

BACKGROUND: With recent advancements in molecular techniques, the opportunities to gather whole genome information have increased, even in degraded samples such as FFPE tissues. As a result, a broader view of the genomic landscape of solid tumors may be explored. Whole genome copy number and loss of heterozygosity patterns can advance our understanding of mechanisms and complexity of various tumors. RESULTS: Genome-wide alterations involving copy number changes and loss of heterozygosity were identified in 17 glioma samples with positive FISH results for 1p19q co-deletions (n = 9) or EGFR amplification (n = 8). Gliomas positive for 1p19q co-deletions did not have other frequently recurrent genomic alterations. Additional copy-number alterations were observed in individual cases, and consisted primarily of large-scale changes, including gains or losses of entire chromosomes. The genomic architecture of EGFR amplified gliomas was much more complex, with a high number of gains and losses across the genome. Recurrent alterations in EGFR amplified gliomas were both focal, such as CDKN2A homozygous deletions, and large, such as chromosome 10 loss. CONCLUSIONS: Microarray enabled a broader picture of the genomic alterations occurring in glioma cases. Gliomas with 1p19q co-deletion had a relatively quiet genome, apart from the selected co-deletion. Additional alterations in isolated cases, involved primarily larger aberrations. On the other hand, EGFR amplified cases tended to be more complex and have specific abnormalities associated with the EGFR amplification. Furthermore, 1p19q co-deletions and EGFR amplification associated copy number changes appeared to often be mutually exclusive.

Streamlining the OncoScan® Array Procedure for Use in a Clinical Laboratory.

Microarray analysis has found tremendous utility in the clinical laboratory testing for detection of copy number changes (CNCs) and loss of heterozygosity (LOH). Recently the OncoScan® array was introduced as a tool for identification of CNCs and LOH in formalin-fixed paraffin-embedded oncology samples. The objective of this study was to identify steps in the OncoScan procedure that could be modified to make the process more efficient and technician-friendly in the clinical laboratory setting. Eighteen samples previously processed according to the manufacturer-recommended protocol were reprocessed using a modified protocol. The two primary modifications to the protocol included the elimination of a brief "chill and spin" step and an adjustment to the overnight hybridization temperature to allow for simultaneous hybridization of OncoScan and CytoScan® arrays. A comparison of paired samples processed using both protocols showed that our modified protocol performs similarly to the manufacturer-recommended protocol, yielding equivalent quality control metrics and calls.

Two cases of Scimitar syndrome associated with multiple congenital skeletal anomalies and lacking abnormalities by genomic microarray analysis.

Scimitar syndrome is a congenital anomaly occurring in approximately 1/50,000 births, consisting of partial anomalous pulmonary venous return, right lung hypoplasia, and several associated defects. The condition generally has significant morbidity and mortality, but the underlying cause is poorly understood. In this report, we describe 2 autopsy cases of Scimitar syndrome associated with multiple skeletal anomalies and attempt to characterize possible genetic abnormalities in this condition. In light of these findings, we discuss the embryology and direct timing during development of the anomalies associated with this syndrome.

Molecular inversion probe array for the genetic evaluation of stillbirth using formalin-fixed, paraffin-embedded tissue.

Array comparative hybridization has been used successfully to identify genomic alterations in stillbirth material; however, high DNA quantity and quality requirements may limit its utility in some fetal samples. Molecular inversion probe (MIP) array analysis of FFPE stillbirth autopsy samples circumvents the challenges associated with karyotype and short-term fetal cell culture, requires limited DNA input, and allows for retrospective evaluation of fetal loss. We performed MIP analysis on archival FFPE autopsy tissue to identify underlying genetic abnormalities not previously detected using traditional cytogenetic methods. Archival FFPE stillbirth cases (≥20 weeks gestation) were identified with the following characteristics: i) the phenotype suggested underlying genomic alterations; ii) the karyotype was either normal or not available and there were no other known genetic abnormalities; or iii) previous microarray testing was not performed. Genomic DNA (75 ng) was processed onto a 330,000-feature MIP array. Twenty-seven of 29 (93.1%) FFPE samples had passing MIP quality control scores. Abnormalities were seen in 3 of 27 (11%) archival samples (deletion of 17q12, trisomy 18, and a case of 4qter duplication and 13qter deletion arising from an unbalanced 4q;13q translocation), which, if identified at the time of autopsy, may have changed the course of medical management. This study highlights the benefits of using MIP array analysis for identification of genomic alterations in FFPE stillbirth autopsy tissue.

PAM50 breast cancer subtyping by RT-qPCR and concordance with standard clinical molecular markers.

BACKGROUND: Many methodologies have been used in research to identify the "intrinsic" subtypes of breast cancer commonly known as Luminal A, Luminal B, HER2-Enriched (HER2-E) and Basal-like. The PAM50 gene set is often used for gene expression-based subtyping; however, surrogate subtyping using panels of immunohistochemical (IHC) markers are still widely used clinically. Discrepancies between these methods may lead to different treatment decisions. METHODS: We used the PAM50 RT-qPCR assay to expression profile 814 tumors from the GEICAM/9906 phase III clinical trial that enrolled women with locally advanced primary invasive breast cancer. All samples were scored at a single site by IHC for estrogen receptor (ER), progesterone receptor (PR), and Her2/neu (HER2) protein expression. Equivocal HER2 cases were confirmed by chromogenic in situ hybridization (CISH). Single gene scores by IHC/CISH were compared with RT-qPCR continuous gene expression values and "intrinsic" subtype assignment by the PAM50. High, medium, and low expression for ESR1, PGR, ERBB2, and proliferation were selected using quartile cut-points from the continuous RT-qPCR data across the PAM50 subtype assignments. RESULTS: ESR1, PGR, and ERBB2 gene expression had high agreement with established binary IHC cut-points (area under the curve (AUC) ≥ 0.9). Estrogen receptor positivity by IHC was strongly associated with Luminal (A and B) subtypes (92%), but only 75% of ER negative tumors were classified into the HER2-E and Basal-like subtypes. Luminal A tumors more frequently expressed PR than Luminal B (94% vs 74%) and Luminal A tumors were less likely to have high proliferation (11% vs 77%). Seventy-seven percent (30/39) of ER-/HER2+ tumors by IHC were classified as the HER2-E subtype. Triple negative tumors were mainly comprised of Basal-like (57%) and HER2-E (30%) subtypes. Single gene scoring for ESR1, PGR, and ERBB2 was more prognostic than the corresponding IHC markers as shown in a multivariate analysis. CONCLUSIONS: The standard immunohistochemical panel for breast cancer (ER, PR, and HER2) does not adequately identify the PAM50 gene expression subtypes. Although there is high agreement between biomarker scoring by protein immunohistochemistry and gene expression, the gene expression determinations for ESR1 and ERBB2 status was more prognostic.

Differentiation of malignant melanoma from benign nevus using a novel genomic microarray with low specimen requirements.

CONTEXT: Histologic examination of clinically suspicious melanocytic lesions is very sensitive and specific for the detection of malignant melanoma. Yet, the malignant potential of a small percentage of melanocytic lesions remains histologically uncertain. Molecular testing offers the potential to detect the genetic alterations that lead to malignant behavior without overt histologic evidence of malignancy. OBJECTIVE: To differentiate benign melanocytic nevi from malignant melanoma and to predict the clinical course of melanocytic lesions with ambiguous histology using a novel genomic microarray. DESIGN: We applied a newly developed single-nucleotide polymorphism genomic microarray to formalin-fixed, paraffin-embedded melanocytic lesions to differentiate benign nevi (n  =  23) from malignant melanoma (n  =  30) and to predict the clinical course of a set of histologically ambiguous melanocytic lesions (n  =  11). RESULTS: For cases with unambiguous histology, there was excellent sensitivity and specificity for identifying malignant melanoma with this genomic microarray (89% sensitivity, 100% specificity). For cases with ambiguous histology, the performance of this genomic microarray was less impressive. CONCLUSIONS: Without microdissection and with quantities of DNA one-tenth what is required for more commonly used microarrays, this microarray can differentiate between malignant melanoma and benign melanocytic nevi. For histologically ambiguous lesions, longer clinical follow-up is needed to confidently determine the sensitivity and specificity of this microarray. Some of the previous technical hurdles to the clinical application of genomic microarray technology are being overcome, and the advantages over targeted fluorescence in situ hybridization assays currently in clinical use are becoming apparent.

Chromosomal loss of 3q26.3-3q26.32, involving a partial neuroligin 1 deletion, identified by genomic microarray in a child with microcephaly, seizure disorder, and severe intellectual disability.

Neuroligin 1 (NLGN1) is one of five members of the neuroligin gene family and may represent a candidate gene for neurological disorders, as members of this family are involved in formation and remodeling of central nervous system synapses. NLGN1 is expressed predominantly in the central nervous system, where it dimerizes and then binds with ß-neurexin to form a functional synapse. Mutations in neurexin 1 (NRXN1) as well as two other members of the neuroligin family, NLGN3 and NLGN4, have been associated with autism and mutations in NLGN4 have also been associated with intellectual disability, seizures, and EEG abnormalities. Genomic microarray is recommended for the detection of chromosomal gains or losses in patients with intellectual disability and multiple congenital anomalies. Results of uncertain significance are not uncommon. Parental studies can provide additional information by demonstrating that the imbalance is either de novo or inherited, and therefore is more or less likely to be causative of the clinical phenotype. However, the possibility that even inherited deletions and duplications may play a role in the phenotype of the proband cannot be excluded as many copy number variants associated with neurodevelopmental conditions show incomplete penetrance and may be inherited from an unaffected parent. Here, we report on a patient with a 2.2 Mb deletion at 3q26.3-3q26.32-encompassing the terminal end of NLGN1 and the entire NAALADL2 gene-detected by genomic microarray, and confirmed by FISH and real-time quantitative PCR. The same size deletion was subsequently found in her healthy, asymptomatic, adult mother.

Allele-specific PCR with competitive probe blocking for sensitive and specific detection of BRAF V600E in thyroid fine-needle aspiration specimens.

OBJECTIVE: To detect BRAF V600E mutation in thyroid fine-needle aspiration (FNA) slides and needle rinses (NR). STUDY DESIGN: Tumor-enriched DNA was extracted from FNA smears, formalin-fixed paraffin-embedded (FFPE) sections, or NR specimens from 37 patients with confirmed papillary thyroid carcinoma or benign findings. An allele-specific primer selectively amplified the 1799 T>A BRAF mutation while simultaneously blocking amplification of wild-type (WT) BRAF with an unlabeled probe during PCR. Mutation detection was accomplished by melting analysis of the probe. RESULTS: Allele-specific/blocking probe PCR confirmed the BRAF mutation status for 20 of 24 paired FNA/FFPE samples previously tested by fluorescent probe real-time PCR. For the other 4 cases, the sensitive PCR method detected the BRAF mutation in all paired FNA/FFPE samples. Previously, the mutation had been detected in only the FFPE samples. The BRAF mutation was also detected in some NR specimens. CONCLUSION: Treatment of patients with thyroid nodules is guided by FNA biopsy, which can be scantly cellular, necessitating a sensitive test that can detect low levels of BRAF V600E mutation in a WT background. We report increased detection of BRAF V600E in FNA specimens using allele-specific/blocking probe PCR, which has an analytical sensitivity of 0.01%.

Cytogenetic and molecular characterization of double inversion 3 associated with a cryptic BCR-ABL1 rearrangement and additional genetic changes.

Rearrangements of chromosome 3 involving bands 3q21 and 3q26 have been reported in about 2% of patients with acute myeloid leukemia, and rarely in myelodysplastic syndrome or chronic myelogenous leukemia (CML). To date, only six cases of inversion of both homologues have been reported. Loss of normal chromosome 3 and duplication of the inverted chromosome have been proposed as the most likely mechanism, but have not been shown experimentally. We present a 36-year-old male with an initial diagnosis of CML and resistance to imatinib mesylate. Chromosome analysis showed an inversion within the long arm of both homologues of chromosome 3 and an interstitial deletion within the long arm of one chromosome 7. The rearrangement of EVI1 locus on both homologues of chromosome 3 was confirmed by fluorescence in situ hybridization (FISH). Additional FISH studies showed a cryptic insertion of ABL1 into the BCR region, and subsequent duplication of the derivative chromosome 22. The single-nucleotide polymorphism array showed copy-neutral loss of heterozygosity on chromosomes 3 and 22, suggesting that a somatic repair mechanism is involved in the evolution of these genetic alterations. This case illustrates the complexity of genetic aberrations in neoplastic cells, and the value of array technology, used in concert with conventional cytogenetic methods, for a better understanding of the pathogenesis.

Large clinically consequential imbalances detected at the breakpoints of apparently balanced and inherited chromosome rearrangements.

When a chromosome abnormality is identified in a child with a developmental delay and/or multiple congenital anomalies and the chromosome rearrangement appears balanced, follow-up studies often examine both parents for this rearrangement. If either clinically unaffected parent has a chromosome abnormality with a banding pattern identical to the affected child's study, then it is assumed that the chromosome rearrangement is balanced and directly inherited from the normal carrier parent. It is therefore unlikely that the chromosome rearrangement is responsible for the child's clinical presentation. We present two unrelated cases in which an identical and apparently balanced abnormal chromosome banding pattern was identified in both an affected child and an unaffected parent of that child. Despite the identical banding patterns, molecular characterization through genomic microarray and fluorescence in situ hybridization showed the parent to be balanced whereas the affected child was significantly unbalanced. These two cases emphasize the utility of genomic microarray for further characterization of apparently balanced inherited chromosome rearrangements and caution against the assumption that identical banding patterns between a child and parent represent identical genomic rearrangements.

Enrichment and detection of rare alleles by means of snapback primers and rapid-cycle PCR.

BACKGROUND: Selective amplification of minority alleles is often necessary to detect cancer mutations in clinical samples. METHODS: Minor-allele enrichment and detection were performed with snapback primers in the presence of a saturating DNA dye within a closed tube. A 5' tail of nucleotides on 1 PCR primer hybridizes to the variable locus of its extension product to produce a hairpin that selectively enriches mismatched alleles. Genotyping performed after rapid-cycle PCR by melting of the secondary structure identifies different variants by the hairpin melting temperature (T(m)). Needle aspirates of thyroid tissue (n = 47) and paraffin-embedded biopsy samples (n = 44) were analyzed for BRAF (v-raf murine sarcoma viral oncogene homolog B1) variant p.V600E, and the results were compared with those for dual hybridization probe analysis. Needle aspirates of lung tumors (n = 8) were analyzed for EGFR [epidermal growth factor receptor (erythroblastic leukemia viral (v-erb-b) oncogene homolog, avian)] exon 19 in-frame deletions. RESULTS: Use of 18-s cycles and momentary extension times of "0 s" with rapid-cycle PCR increased the selective amplification of mismatched alleles. A low Mg(2+) concentration and a higher hairpin T(m) relative to the extension temperature also improved the detection limit of mismatched alleles. The detection limit was 0.1% for BRAF p.V600E and 0.02% for EGFR exon 19 in-frame deletions. Snapback and dual hybridization probe methods for allele quantification of the thyroid samples correlated well (R(2) = 0.93) with 2 more BRAF mutations (45 and 43, respectively, of 91 samples) detected after snapback enrichment. Different EGFR in-frame deletions in the lung samples produced different hairpin T(m)s. CONCLUSIONS: Use of snapback primers for enrichment and detection of minority alleles is simple, is inexpensive to perform, and can be completed in a closed tube in <25 min.

B-RAF V600E mutational analysis of fine needle aspirates correlates with diagnosis of thyroid nodules.

OBJECTIVE: A mutation of B-type RAF kinase (B-RAF) represents the most common genetic alteration in papillary thyroid cancer (PTC), possibly signifying a more aggressive biology. Fine needle aspiration (FNA) represents the most useful initial diagnostic tool of thyroid nodules. Molecular analysis of the mutation status of B-RAF in thyroid nodule FNAs may provide guidance for treatment planning. STUDY DESIGN: Cross-sectional study. SUBJECTS AND METHODS: A retrospective chart review was undertaken for clinically relevant data of papillary thyroid cancer (PTC), follicular variant of PTC (FV-PTC), and nonmalignant goiters. After blinded pathologic review, histologic and cytologic samples were analyzed by LightCycler PCR (LCPCR) with allele-specific fluorescent probe melting curve analysis (FMCA) for the V600E mutation of B-RAF. RESULTS: Of the 45 patient samples analyzed, B-RAF mutation was found to be significantly higher in papillary carcinomas when compared to follicular variant of papillary thyroid carcinomas (55.6% vs 14.3%, P = 0.05). Pathologic B-RAF mutational status significantly correlated with cytologic B-RAF mutational status (P < 0.0001), cytologic interpretation (P = 0.012), and histologic diagnosis (P = 0.011). CONCLUSIONS: Determination of B-RAF V600E mutation of thyroid nodule FNAs by LCPCR may be a useful tool to guide treatment planning. These data support investigating the utility of this molecular marker in a prospective manner.

Subcutaneous tumor seeding following needle core biopsy of hepatocellular carcinoma.

Hepatocellular carcinoma (HCC) is the most common primary hepatic tumor and one of the most common cancers worldwide. At present, there are two widely used and accepted methods for obtaining diagnostic material for establishing the likelihood of malignancy in a hepatic mass, namely fine-needle aspiration (FNA) cytology and needle core biopsy (NCB). In recent years, however, tumor cell seeding along the needle tract has been shown to be a risk associated with using these procedures to obtain a pathologic diagnosis. We report a case of a patient who presented with a nodule in the anterior abdominal wall at the expected location of the previous NCB tract. FNA biopsy of the abdominal wall lesion confirmed the presence of malignant cells consistent with HCC. The finding of tumor seeding within a NCB tract raises the question of the role of NCB in the diagnostic workup of focal liver lesions.

An inv(16) in Ph-negative cells of a chronic myelogenous leukemia patient after imatinib treatment.

Secondary chromosomal changes are known to develop in Philadelphia chromosome-negative (Ph-) cells of chronic myelogenous leukemia (CML) patients after treatment with imatinib mesylate, an ABL kinase inhibitor. We report here a novel case of a pericentric inversion of chromosome 16 as the sole cytogenetic abnormality in Ph- cells after treatment of Ph+ CML with imatinib.