Computer-assisted scatter plot analysis of cell and nuclear areas distinguishes urothelial carcinoma in urine cytology specimens.

IF 3.1 4区医学 Q2 PATHOLOGY

Cytojournal Pub Date : 2025-02-08 eCollection Date: 2025-01-01 DOI:10.25259/Cytojournal_213_2024

Chinami Hoshino, Sayaka Kobayashi, Yoshimi Nishijima, Seiji Arai, Kazuhiro Suzuki, Masanao Saio

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引用次数: 0

Abstract

Objective: Image analysis in urine cytology typically focuses on individual cells, particularly nuclear features. This study aimed to analyze non-tumor and urothelial carcinoma cases by examining scatter plots of cell or cell cluster areas and the maximum nuclear area within them.

Material and methods: The study included 192 cases: 52 negative and 140 positive. Whole slide images were generated using a virtual slide scanner, and image analysis was conducted with cytological analysis software. Scatter plots were created for cells/cell cluster areas and the largest connected nuclear areas (scatter plot for cells/cell cluster), as well as for nuclear area and perimeter (scatter plot for nucleus).

Results: In the scatter plot for the nucleus, significant differences were noted between cytology-negative and cytology-positive groups (P = 0.0134). However, when divided into cytology-negative, non-invasive, and invasive groups, a significant difference was only found between negative and non-invasive groups (P = 0.0281), not between negative and invasive groups (P = 0.1266). In the scatter plot for cell/cell cluster, plotting cell cluster area (X-axis) and maximum nuclear area (Y-axis) revealed three distribution patterns: horizontal (X-axis), vertical (Y-axis), and diagonal. Cytology-negative cases mainly showed horizontal patterns, while cytology-positive cases exhibited vertical patterns. In the non-tumor group, horizontal patterns were dominant, while vertical patterns were common in non-invasive and invasive tumor groups. The pTa low-grade group mainly showed diagonal patterns, whereas the pTa high-grade, pTis, and pTis + pTa groups predominantly showed vertical patterns. The percentage of cell/cell clusters in tumor-rich areas (along with Y-axis) was significantly higher in non-invasive and invasive tumors compared to non-tumor cases (P < 0.0001), although lower in invasive tumors compared to non-invasive ones (P = 0.0299). In addition, neutrophil-rich images were significantly more common in stromal and muscle invasion groups than in non-invasion groups.

Conclusion: In urine cytology, cellular overlap and cluster density were key factors for distinguishing malignant from benign cells. This image analysis algorithm was useful in identifying malignant clusters with large, connected nuclear regions. The algorithm could potentially detect both invasive and early-stage tumors, highlighting the need for further development of such tools for routine diagnosis.

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计算机辅助的细胞和核区散点图分析在尿细胞学标本中区分尿路上皮癌。

目的：尿液细胞学图像分析通常侧重于单个细胞，特别是核特征。本研究旨在分析非肿瘤和尿路上皮癌病例，通过检查细胞或细胞簇区域的散点图及其内的最大核区域。材料与方法：纳入192例，其中阴性52例，阳性140例。使用虚拟切片扫描仪生成全片图像，并用细胞学分析软件进行图像分析。为细胞/细胞簇区域和最大连接的核区域（细胞/细胞簇的散点图）以及核区域和周长（核的散点图）创建散点图。结果：细胞核散点图中，细胞学阴性组与细胞学阳性组差异有统计学意义（P = 0.0134）。而在细胞学阴性、无创、有创组中，只有阴性组与无创组有显著性差异（P = 0.0281），阴性组与有创组无显著性差异（P = 0.1266）。在细胞/细胞簇散点图中，绘制细胞簇面积（x轴）和最大核面积（y轴）显示三种分布模式：水平（x轴）、垂直（y轴）和对角线。细胞学阴性病例以水平型为主，细胞学阳性病例以垂直型为主。非肿瘤组以水平模式为主，而非侵袭性和侵袭性肿瘤组均以垂直模式为主。pTa低分级组以斜向分布为主，pTa高分级组、pTis组和pTis + pTa组以垂直分布为主。与非肿瘤病例相比，非侵入性和侵入性肿瘤中富肿瘤区域（沿y轴）的细胞/细胞簇的百分比显著高于非肿瘤病例（P < 0.0001），尽管浸润性肿瘤中细胞/细胞簇的百分比低于非侵入性肿瘤（P = 0.0299）。此外，中性粒细胞丰富的图像在基质和肌肉侵袭组明显比非侵袭组更常见。结论：在尿细胞学中，细胞重叠和细胞簇密度是鉴别良性和恶性细胞的关键因素。这种图像分析算法在识别具有大的、连接的核区域的恶性聚类方面是有用的。该算法可以潜在地检测侵入性和早期肿瘤，突出了进一步开发此类常规诊断工具的必要性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Cytojournal PATHOLOGY-

CiteScore

2.20

自引率

42.10%

发文量

审稿时长

>12 weeks

期刊介绍： The CytoJournal is an open-access peer-reviewed journal committed to publishing high-quality articles in the field of Diagnostic Cytopathology including Molecular aspects. The journal is owned by the Cytopathology Foundation and published by the Scientific Scholar.