Department of Pathology, Northwestern University Feinberg School of Medicine, Northwestern Memorial Hospital, Chicago, Illinois.
Department of Pathology, Northwestern University Feinberg School of Medicine, Northwestern Memorial Hospital, Chicago, Illinois.
J Am Soc Cytopathol. 2024 Sep-Oct;13(5):340-345. doi: 10.1016/j.jasc.2024.04.007. Epub 2024 May 6.
There is an increasing demand to optimize the workflow and maximize tissue available for next-generation sequencing (NGS) for non-small cell carcinoma. We looked at transbronchial needle endobronchial ultrasound-guided bronchoscopy with transbronchial needle aspiration samples and evaluated the performance of supernatant (SN) fluid processed from a dedicated aspirate collected for NGS testing.
Nineteen samples were collected and processed using a new workflow. Five aspirates were collected in formalin. One additional dedicated pass was collected fresh and centrifuged. The resulting cell pellet was added to formalin for cell block (CB) processing. DNA and RNA were extracted from concentrated SN for targeted testing using the Oncomine Precision Assay (Thermo Scientific, Waltham, MA). NGS results from the corresponding CB samples were used as "controls" for comparison.
Thirty-one mutations were detected in SN (Table 1). The most frequently mutated genes were TP53 (35%), EGFR (23%), KRAS (13%), CTNNB1 (6%), and ERBB2 (6%). There was 100% concordance between the mutations detected in SN and corresponding CBs with comparable variant allele frequencies. Turnaround time of NGS results was 1 day for SN compared to 4-10 days for CB.
We were able to demonstrate the usefulness of SN for reliable rapid molecular results. We successfully incorporated the workflow for tissue handling and processing among our clinical, cytopathology, and molecular teams. Molecular results were available at the same time as the cytologic diagnosis, allowing for timely reporting of a comprehensive diagnosis. This approach is particularly useful in patients with advanced disease requiring urgent management.
对于非小细胞癌,人们越来越需要优化工作流程并最大限度地利用可用于下一代测序(NGS)的组织。我们观察了经支气管针吸活检(TBNA)的支气管内超声引导下的经支气管针吸活检,评估了为 NGS 检测而专门采集的抽吸物上清液(SN)的性能。
收集了 19 个样本并使用新的工作流程进行处理。5 个抽吸物用福尔马林固定。另外进行了一次新鲜抽吸并离心。得到的细胞沉淀加入福尔马林进行细胞块(CB)处理。从浓缩的 SN 中提取 DNA 和 RNA,用于使用 Oncomine Precision Assay(Thermo Scientific,Waltham,MA)进行靶向检测。相应 CB 样本的 NGS 结果用作比较的“对照”。
SN 中检测到 31 个突变(表 1)。最常突变的基因是 TP53(35%)、EGFR(23%)、KRAS(13%)、CTNNB1(6%)和 ERBB2(6%)。SN 中检测到的突变与相应 CB 之间具有 100%的一致性,并且变异等位基因频率相似。与 CB 相比,SN 的 NGS 结果的周转时间为 1 天,而 CB 为 4-10 天。
我们能够证明 SN 用于可靠快速分子结果的有用性。我们成功地将组织处理和处理工作流程纳入了我们的临床、细胞病理学和分子团队。分子结果与细胞学诊断同时获得,允许及时报告全面的诊断。这种方法在需要紧急管理的晚期疾病患者中特别有用。
