Yinti Shanmukha Raviteja, N Srikant, Boaz Karen, Lewis Amitha J, Ashokkumar Pandya Jay, Kapila Supriya Nikita
Postgraduate, Department of Oral Pathology and Microbiology, Manipal College of Dental Sciences, Manipal University , Light House Hill Road, Mangalore, India .
Additional Professor, Department of Oral Pathology and Microbiology, Manipal College of Dental Sciences, Manipal University , Light House Hill Road, Mangalore, India .
J Clin Diagn Res. 2015 Nov;9(11):EC21-5. doi: 10.7860/JCDR/2015/12931.6837. Epub 2015 Nov 1.
Carcinogenesis follows complex molecular alterations, which are triggered by subtle chromatin architectural changes that are imperceptible to the human eye. As the treatment decisions in Oral Squamous Cell Carcinoma (OSCC) are hindered by the imprecise clinical stage determination and inter-observer variability in histological grading, focus in recent years has shifted to discovering identifiers related to neoplastic cell morphology studied through computer-aided image analysis. One such approach is the assessment of fractal geometry, a technique first described by Mandelbrot, which aids in precise assessment of architecture of natural objects. Assessment and quantification of degree of complexity of these fractal objects (self-similarities in structural complexity at different magnifying scales) is described as fractal dimension (FD).
To evaluate the nuclear fractal dimension (NFD) in OSCC using computer-aided image analysis.
Histological sections of 14 selected cases of Oral Squamous Cell Carcinoma (OSCC) and 6 samples of normal buccal mucosa (as control) were stained with Haematoxylin-Eosin and Feulgen stain for histopathological examination and evaluation of nuclear complexity respectively. Fifteen HPF at Invasive Tumour Front (ITF) and Tumour Proper (TP) of Feulgen-stained sections were selected and photographed in test and control samples. At ITF, TP and normal buccal mucosa 200 nuclei each were selected and analyzed using Image J software to quantify FD. The test and control groups were compared statistically using Independent sample t-test and One-way ANOVA.
Nuclear FD increased progressively towards worst tumour staging as compared to normal buccal mucosa.
Nuclear FD can be considered for quantification of nuclear architectural changes as a prognostic indicator in OSCC.
癌症发生遵循复杂的分子改变,这些改变由人类肉眼难以察觉的细微染色质结构变化引发。由于口腔鳞状细胞癌(OSCC)的治疗决策受到临床分期不精确以及组织学分级观察者间差异的阻碍,近年来重点已转向通过计算机辅助图像分析发现与肿瘤细胞形态相关的标志物。一种这样的方法是分形几何评估,这是一种最初由曼德勃罗描述的技术,有助于精确评估自然物体的结构。这些分形物体复杂性程度的评估和量化(不同放大尺度下结构复杂性的自相似性)被称为分形维数(FD)。
使用计算机辅助图像分析评估口腔鳞状细胞癌中的核分形维数(NFD)。
选取14例口腔鳞状细胞癌(OSCC)病例的组织切片和6例正常颊黏膜样本(作为对照),分别用苏木精 - 伊红染色和福尔根染色进行组织病理学检查和核复杂性评估。在福尔根染色切片的侵袭性肿瘤前沿(ITF)和肿瘤主体(TP)处选取15个高倍视野(HPF)并在测试和对照样本中拍照。在ITF、TP和正常颊黏膜处分别选取200个细胞核,使用Image J软件进行分析以量化FD。使用独立样本t检验和单因素方差分析对测试组和对照组进行统计学比较。
与正常颊黏膜相比,核FD随着肿瘤分期变差而逐渐增加。
核FD可作为口腔鳞状细胞癌预后指标用于量化核结构变化。