Department of Anatomical Pathology, SA Pathology, Adelaide, SA, Australia.
Faculty of Health and Medical Sciences, University of Adelaide, Adelaide, SA, Australia.
Virchows Arch. 2024 Apr;484(4):645-656. doi: 10.1007/s00428-024-03761-4. Epub 2024 Feb 16.
Differentiating BRAF V600E- and RAS-altered encapsulated follicular-patterned thyroid tumors based on morphology remains challenging. This study aimed to validate an 8-score scale nuclear scoring system and investigate the importance of nuclear pseudoinclusions (NPIs) in aiding this differentiation. A cohort of 44 encapsulated follicular-patterned tumors with varying degrees of nuclear atypia and confirmed BRAF V600E or RAS alterations was studied. Nuclear parameters (area, diameter, and optical density) were analyzed using a deep learning model. Twelve pathologists from eight Asian countries visually assessed 22 cases after excluding the cases with any papillae. Eight nuclear features were applied, yielding a semi-quantitative score from 0 to 24. A threshold score of 14 was used to distinguish between RAS- and BRAF V600E-altered tumors. BRAF V600E-altered tumors typically demonstrated higher nuclear scores and notable morphometric alterations. Specifically, the nuclear area and diameter were significantly larger, and nuclear optical density was much lower compared to RAS-altered tumors. Observer accuracy varied, with two pathologists correctly identifying genotype of all cases. Observers were categorized into proficiency groups, with the highest group maintaining consistent accuracy across both evaluation methods. The lower group showed a significant improvement in accuracy upon utilizing the 8-score scale nuclear scoring system, with notably increased sensitivity and negative predictive value in BRAF V600E tumor detection. BRAF V600E-altered tumors had higher median total nuclear scores. Detailed reevaluation revealed NPIs in all BRAF V600E-altered cases, but in only 2 of 14 RAS-altered cases. These results could significantly assist pathologists, particularly those not specializing in thyroid pathology, in making a more accurate diagnosis.
区分 BRAF V600E 和 RAS 改变的包裹滤泡模式甲状腺肿瘤基于形态仍然具有挑战性。本研究旨在验证 8 分核评分系统,并研究核假包涵体(NPIs)在辅助这种分化中的重要性。研究了一组 44 例具有不同程度核异型性且证实存在 BRAF V600E 或 RAS 改变的包裹滤泡模式肿瘤。使用深度学习模型分析核参数(面积、直径和光密度)。12 位来自 8 个亚洲国家的病理学家在排除任何乳头病例后,对 22 例病例进行了视觉评估。应用了 8 种核特征,得出 0 至 24 分的半定量评分。使用 14 分的阈值评分来区分 RAS 和 BRAF V600E 改变的肿瘤。BRAF V600E 改变的肿瘤通常表现出更高的核评分和显著的形态计量学改变。具体而言,与 RAS 改变的肿瘤相比,核面积和直径明显更大,核光密度明显更低。观察者的准确性不同,两位病理学家正确识别了所有病例的基因型。观察者分为熟练组,最高组在两种评估方法中均保持一致的准确性。较低组在使用 8 分核评分系统后准确性显著提高,在 BRAF V600E 肿瘤检测中灵敏度和阴性预测值显著提高。BRAF V600E 改变的肿瘤具有更高的中位总核评分。详细的重新评估显示,所有 BRAF V600E 改变的病例均存在 NPIs,但在 14 例 RAS 改变的病例中仅有 2 例存在。这些结果可以显著帮助病理学家,特别是非甲状腺病理专业的病理学家,做出更准确的诊断。
