Proliferative index using Ki-67 index in reactive mesothelial versus metastatic adenocarcinoma cells in serous fluid
Noushin Afshar Moghaddam1, Alireza Rahmani2, Diana Taheri1, Mojtaba Mokhber Desfuli1
1 Department of Pathology, Faculty of Medicine, Isfahan University of Medical Sciences, Isfahan, Iran
2 Department of Gastroenterology, Faculty of Medicine, Isfahan University of Medical Sciences, Isfahan, Iran
|Date of Submission||10-Dec-2011|
|Date of Acceptance||08-Mar-2012|
|Date of Web Publication||06-Jul-2012|
Noushin Afshar Moghaddam
Department of Pathology, Faculty of Medicine, Isfahan University of Medical Sciences, Isfahan
© 2012 Moghaddam et al; This is an open-access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Background: The cytological diagnoses of serous effusions are usually made by routine cytomorphology with certainty. However, overlapping cases sometimes exist between reactive mesothelial and adenocarcinoma cells. We tried to evaluate the diagnostic utility of proliferative index using a Ki-67 monoclonal antibody in distinguishing between reactive mesothelial cells and adenocarcinoma in serous effusions.
Materials and Methods: Paraffin blocks and H and E stained slides of peritoneal and pleural fluid cell blocks were retrieved from cytology archive of Alzahra Hospital, Medical University of Isfahan, between 2006 and 2010, from among 1025 slides which were screened to ascertain their appropriate diagnoses. Among of these 80 paraffin-embedded cell blocks, 40 cases for each reactive and adenocarcinoma groups were selected. The proliferative index was calculated by using the Ki 67 monoclonal antibody against nuclear proteins.
Results: The mean ages of the patients in the reactive mesothelial and adenocarcinoma groups were 60.58 and 58.45 years, respectively. The gender distribution for the malignant group included 23 cases (%57.5) of females and 17 cases (42.5%) of males. This ratio for reactive group included 14 cases (35%) and 26 cases (65%). The mean of Ki-67 index in adenocarcinomatous cells was 17.15 (SD=15.11) and in reactive mesothelial cells was 3.58 (SD= 3.59) (P=0.001). We consider to using the proliferative marker of Ki-67 on benign and malignant lesions revealed 12% as cut off level. The means of Ki-67 index according to serousal spaces were included: Pleura: 10.56 (SD= 13.06) and peritoneum: 10.03 (SD= 12.78), (P=0.9).
Conclusion: Ki-67 index is useful immunostaining panel for differentiation of mesothelial and adenocarcinoma cells in malignancy like ovarian carcinoma that sometimes mimics mesothelial morphology.
Keywords: Adenocarcinoma cell, Ki-67 antibody, mitosis, reactive mesothelial cell, serous effusion
|How to cite this article:|
Moghaddam NA, Rahmani A, Taheri D, Desfuli MM. Proliferative index using Ki-67 index in reactive mesothelial versus metastatic adenocarcinoma cells in serous fluid. Adv Biomed Res 2012;1:29
|How to cite this URL:|
Moghaddam NA, Rahmani A, Taheri D, Desfuli MM. Proliferative index using Ki-67 index in reactive mesothelial versus metastatic adenocarcinoma cells in serous fluid. Adv Biomed Res [serial online] 2012 [cited 2014 Apr 17];1:29. Available from: http://www.advbiores.net/text.asp?2012/1/1/29/98155
| Introduction|| |
Cytologic examination of the serous fluid is very important because the specimens represent a significant percentage of nongynecologic samples and this cytologic examination may be the first, best, or only chance for making the diagnosis of an underlying malignancy.  The major purpose of cytologic examination of serous effusions is to determine whether malignant cells are present. This is an extremely important task since in most cases the presence of malignant cells in effusions indicates an advanced or terminal stage of malignancy and it is associated with poor survival. 
Whenever the serous membranes are irritated in a process of inflammation or longstanding effusion, mesothelial cells proliferate, shed in the fluid, and show morphological changes in nucleus and cytoplasm including enlargement of the nucleus binucleation or multinucleation. Occasional mitotic figures are often present and do not indicate malignancy, but the presence of numerous mitoses is suspicious, particularly in a highly cellular effusion. In some cases, morphological differentiation of reactive mesothelial cells from adenocarcinoma in serous effusions is extremely difficult.  So adoption of complementary methods will increase diagnostic accuracy.  Nowadays immunocytochemistry (ICC) is one of the suggested methods which helps distinguishing between mesothelial and adenocarcinoma. , It seems counting the cellular proliferation by monoclonal antibody against Ki-67 is a reliable method to evaluate fractions of rapidly growing cells in both reactive mesothelial and carcinoma cells. 
The expression of the human protein Ki-67 is associated with cell proliferation. The fact that Ki-67 protein is present during all the active phases of the cell cycle (G1, S, G2, and mitosis), and absent from the G0 phase, has made it an excellent marker for determining the growth fraction of a determined cell population (normal or tumoral). ,,,
The aim of this study was to evaluate whether immunocytochemical expressions of proliferation markers for Ki-67 in reactive mesothelial cells and adenocarcinoma cells obtained from serousal fluids could be useful for their differential diagnosis.
| Material and Methods|| |
Paraffin-embedded cell blocks and HandE-stained slides of peritoneal and pleural fluid were retrieved from cytology archive of Alzahra Hospital, Medical University of Isfahan, between 2006 and 2010, from among 1025 slides which were screened to ascertain their appropriate diagnoses. Among these 80 paraffin-embedded cell blocks, 40 cases for each reactive and adenocarcinoma groups were selected. The cases of reactive mesothelial were confirmed with review of the previous and/or current medical records without any past history or clinical or imaging documents in favor of malignancy. Adenocarcinomacases had confirmatory biopsy specimens. Only cases with cellular cell blocks were selected for immunocytochemical (ICC) staining.
For Immunocytochemistry (ICC) staining with a Ki-67 monoclonal antibody, ht avidin-biotin method was performed. In the first step, 3 μm thin sections were obtained from selected blocks, and then the specimens underwent deparaffinization and hydration. Exposure of the antigen to citrate buffer 1% (PH=6) was done in microwave for 20 minu. Slides were incubated with the Ki-67 anti-human monoclonal antibody, clone MIB-1, code no: M7249 with 1/50 dilution (DAKO Co., Denmark) at room temperature. The staining intensity of cells was evaluated with a high power field (×400) Zeiss microscope, in 0.46 mm dimension. 
Ki-67 determination by pathologist
Immunoreactivity was evaluated as the percentage in all adequate specimens by counting all positive epithelial cells' nuclei over the total number of epithelial cells. Sections stained for Ki-67 were initially screened microscopically. The areas with the highest numbers of Ki-67-labeled nuclei were encircled, and the Ki-67 index was calculated by the percentage of positive cells. On immunohistochemical stains for Ki-67, the colored (brown) reaction product at the antigen site was in the cell nucleus, and the slide was counterstained with hematoxylin to allow evaluation of cells' morphology and assessment of the localization of staining on routine light microscopy. At least 8 fields were chosen within previously encircled "hotspots" to be evaluated at 20× to obtain the percentage of cells positive for Ki-67 (the Ki-67 index). 
For data analysis, the Mann-Whitney test was used. This test is an alternative for t-test that used to compare two independent groups of sampled data.
| Results|| |
The mean ages of the patients in the reactive mesothelial and adenocarcinoma groups were 60.58 and 58.45 years, respectively. The gender distribution for malignant group included: 23 cases (%57.5) female and 17 cases (42.5%) male. This ratio for reactive group included: 14 cases (35%) and 26 cases (65%).
The mean of Ki-67 index in adenocarcinomatous cells was: 17.15 (SD=15.11) and in reactive mesothelial cells was: 3.58 (SD= 3.59) (P=0.001). The mean of Ki-67 index according to serousal spaces were included: Pleura: 10.56 (SD= 13.06) and peritoneum: 10.03 (SD= 12.78), (P=0.9).
The descriptive statistics of Ki-67 index according to origin of metastatic adenocarcinomatous are shown in [Table 1]. We considered to use the proliferative marker of Ki-67 on benign and malignant lesions, revealed 12% as cut off level.
|Table 1: Comparison of mean and SD of Ki-67 index in metastatic adenocarcinomas by specific origin (P value=0.5)|
Click here to view
| Discussion|| |
Although native serous cavity cells "mesothelial cells" do not proliferate in effusions after exfoliation, they may complete an already started mitotic division. The presence of mitotic figures in effusion cytology suggests a process that is capable of causing significant proliferative activity in response to whatever in causing the effusion. As with cytopathological evaluation in general, the presence of mitotic figures should not lead to a false interpretation of malignancy. , Recently, benign mesothelial proliferative conditions are increasingly reported, because benign mesothelial conditions are occasionally difficult to distinguish from malignant cells  due to their severe nuclear changes, including enlargement and irregularity of nuclei with coarse chromatin and conspicuous nucleoli and the presence of mitotic figures. Clinical data with respect to such diseases as anemia, cirrhosis, systemic lupus erythematosus, pulmonary infarction, renal failure, and AIDS can help interpretation of these conditions; however, in many cases, especially outpatients, clinical data is not easily available. 
Several methods are available for the evaluation of the degree of cellular proliferation. The older and still widely used method is mitotic count in a certain number (usually 10 to 50) of consecutive "high-power" fields (40× objective).  The mitotic phase constitutes only a small part of the cell proliferation cycle. Several factors may have contributed to the superiority of the Ki-67 index in predicting cellular proliferation in our study. Mitotic count has been shown to be influenced by multiple factors, including tissue fixation and thickness of tissue sections. It can be difficult to differentiate mitotic figures from apoptosis. Furthermore, immunohistochemical staining for Ki-67 identifies proliferating cells in the G1, S, G2, and mitosis phases of the cell cycle, whereas mitotic count identifies only a small proportion of the proliferating cells in the mitosis phase. , So in this study, we evaluated cellular proliferation using immunocytochemistry with the monoclonal antibody Ki-67 that reacted with a nuclear antigen present in all proliferating cells. ,,
The diagnostic and prognostic value of Ki-67 immunostaining of human tumors has been widely documented and accepted. , In review of English Medical literature investigated the role of proliferative markers in differentiation between malignant mesothelioma and mesothelial hyperplasia, , Sington et al. demonstrated that Ki-67 can differentiate malignant from reactive proliferation of mesothelial cells; Schonherr et al. in their study on pleural cytology specimens showed 100% specificity for Ki-67 to differentiate MM from MH taking a cut off level of 20% for proliferating cells. In a study in regard to using the proliferative marker of Ki-67 on benign and malignant lesions, Taheri et al. showed that by taking 9% as a cut off level for proliferating cells in regions with most proliferative activity, differentiation between MM and MH is possible with sensitivity and specificity of 88% and 94%, respectively. A 20% cut off level could diagnose all hyperplasias except for one case who was a young man with spontaneous pneumothorax; the Ki-67 was 25%. They believed that the increased proliferation index in this case was due to acute injury to the pleura,  but in most studies material were histologic sections instead of cytologic preparation and a few studies have investigated the role of proliferative markers in differentiation between reactive mesothelial cells and metastatic adenocarcinoma.
Immunocytochemical profiles for Ki-67 of normal and reactive mesothelial cells are unknown. In Terada's study, the proliferative index for normal mesothelium and reactive one were respectively: 1% and 20%.  Schönherr et al. demonstrated highly significant difference (P=0.001) between Ki-67 proliferation rates of mesothelial cells from patients with malignant tumors other than mesothelial origin (7.0% to 25.5%) and mesothelial cells of patients without any malignant disease (1.8% to 16.3%). Setting a threshold at 10% for identification of a malignant disease,  Kimura et al. showed significantly higher Ki-67 index in malignant cells as compared with reactive mesothelial cells (cut-off value = 30%).  In Hasteh et al. study for reactive cases, the proliferative index was high in 6 of 64 (9%) cases, moderate in 22 of 64 (34%) cases, and negative to low in 36 of 64 (56%) cases. 
It is possible that reactive mesothelial cells like any other reactive cells show higher proliferation index. The other possibility is contamination with many lymphocytes in the effusion specimens, which can cause difficulty in estimating the proliferative index by immunostain.
| Conclusion|| |
Ki-67 index is a useful immunostaining panel for differentiation of mesothelial and adenocarcinoma cells in malignancy like ovarian carcinoma that sometimes mimics mesothelial morphology, but the proliferative index alone, however, cannot be used to discriminate benign lesions from malignant ones.  We recommend panel of immunocytochemical markers and study the larger sample for determining a Ki-67 index in gastrointestinal malignancy.
| Acknowledgments|| |
Authors wish to express their gratitude to all patients who participated in this study. We would also like to thank the technicians of cytopathology and IHC departments Mr. Nasr for their sincere technical assistance.
| References|| |
|1.||Hong EK. The cytopathology of body cavity fluid. Korean J Cytopathol 2008;19:72-85. |
|2.||Naylor B. Pleural, peritoneal, and pericardial effusions. In: Bibbo M, Wilbur D, editors. Comprehensive cytopathology. 3 rd ed. Philadelphia: Saunders - Elevier; 2008. p. 515-65. |
|3.||Weinstein LJ, Cibas ES. Effusions (Pleural, Pericardial, and Peritoneal and Peritoneal Washing Cytopathology). In: Atkinson BF, editor. Atlas of diagnostic cytopathology. 2nd ed. Philadelphia: Saunders; 2003. p. 106-10. |
|4.||Sayed DM, el-Attar MM, Hussein AA. Evaluation of flow cytometric immunophenotyping and DNA analysis for detection of malignant cells in serosal cavity fluids. Diagn Cytopathol 2009;37:498-504. |
|5.||Fetsch PA, Abati A. Immunocytochemistry in effusion cytology. Cancer Cytopathol 2001;93:293-308. |
|6.||Rahmani A, Zahedi Dehghani M, Afshar Moghaddam N, Heidarian H, Tahririan R. HBME-1 immunostaining in reactive mesothelial versus metastatic adenocarcinoma cells in serous fluid. Indian J Pathol Microbiol 2011;54:460-3. |
|7.||Gerdes J, Lemke H, Baisch H, Wacker HH, Schwab U, Stein H. Cell cycle analysis of a cell proliferation-associated human nuclear antigen defined by the monoclonal antibody Ki-67. J Immunol 1984;133:1710-5. |
|8.||Muñoz E, Gómez F, Paz JI, Casado I, Silva JM, Corcuera MT, et al. Ki-67 immunolabeling in pre-malignant lesions and carcinoma of the prostate. Histological correlation and prognostic evaluation. Eur J Histochem 2003;47:123-8. |
|9.||Radovanovic-Dinic B, Nagorni A, Katic V, Stamenkovic I, Zlatic A. An immunohistochemical study of Ki-67 in colorectal adenoma. Med Arch 2009;63:16-8. |
|10.||Preusser M, Heinzl H, Gelpi E, Höftberger R, Fischer I, Pipp I, et al. Ki67 index in intracranial ependymoma: A promising histopathological candidate biomarker. Histopathology 2008;53:39-47. |
|11.||Wiesner FG, Magener A, Fasching PA, Wesse J, Bani MR, Rauh C, et al. Ki 67 as a prognostic molecular marker in routine clinical use in breast cancer patients. Breast 2009;18:135-41. |
|12.||Cazzaniga M, Severi G, Casadio C, Chiapparini L, Veronesi U, Decensi A. Atypia and Ki-67 Expression from Ductal Lavage in Women at Different Risk for Breast Cancer. Cancer Epidemiol Biomarkers Prev 2006;15:1311-5. |
|13.||Dhall D, Mertens R, Bresee C, Parakh R, Wang HL, Li M, et al. Ki-67 proliferative index predicts progression-free survival of patients with well-differentiated ileal neuroendocrine tumors. Hum Pathol 2012;43:489-95. |
|14.||Shidham VB, Falzon M. Serous effusions. In: Gray W, Kocjan G, editors. Diagnostic cytopathology. 3rd ed. London: Churchill-Livingstone-Elsevier; 2010. p. 119. |
|15.||Cibas ES. Pleural, pericardial and peritoneal fluids. In: Cibas ES, Ducatman BS, editors. Cytology. 3rd ed. Philadelphia: Saunders -Elsevier; 2009. p. 131-2. |
|16.||Churg A, Cagle PT, Roggli VL: Separation of benign and malignant mesothelial proliferations. In: AFIP Atlas of tumor pathology. Series 4. Tumors of the serosal membrane. Silver Spring, Maryland: ARP Press; 2006. p. 83-101. |
|17.||Rosai J. Special techniques in surgical pathology. In: Rosai J .Rosai and Ackerman`s surgical pathology. USA: Mosby; 2011. p. 45-65. |
|18.||Loukas CG, Wilson GD, B. Vojnovic B, Linney A. An image analysis-based approach for automated counting of cancer cell nuclei in tissue sections. Cytometry Part A 2003;55:30-42. |
|19.||Gerdes J. Ki-67 and other proliferation markers useful for immunohistological diagnostic and prognostic evaluations in human malignancies. Semin Cancer Biol 1990;1:199-206. |
|20.||Haegens A, van der Vliet A, Butnor KJ, Heintz N, Taatjes D, Hemenway D, et al. Asbestos-induced lung inflammation and epithelial cell proliferation are altered in myeloperoxidase-null mice. Cancer Res 2005;65:9670-7. |
|21.||Bendary ME, Elalfy H, Zalata K. Predictors of hepatocyte proliferative activity in chronic hepatitis B and C vs. steatohepatitis as assessed by the monoclonal antibody MIB1-Ki-67. Arab J Gastroenterol 2011;12:119-24. |
|22.||Gerdes J, Li L, Schlueter C, Duchrow M, Wohlenberg C, Gerlach C, et al. Immunobiochemical and molecular biologic characterization of the cell proliferation-associated nuclear antigen that is defined by monoclonal antibody Ki-67. Am J Pathol 1991;138:867-73. |
|23.||Cattoretti G, Becker MH, Key G, Duchrow M, Schluter C, Galle J, et al. Monoclonal antibodies against recombinant parts of the Ki-67 antigen (MIB 1 and MIB 3) detect proliferating cells in microwave-processed formalin-fixed paraffin sections. J Pathol 1992;168:357-63. |
|24.||Sington JD, Morris LS, Nicholson AG, Coleman N. Assessment of cell cycle state may facilitate the histopathological diagnosis of malignant mesothelioma. Histopathology 2003;42:498-502. |
|25.||Schonherr A, Bayer M, Bocking A. Diagnostic and prognostic value of Ki67 proliferation fraction in serous effusions. Cell Oncol 2004;26:57-62. |
|26.||Mohammad Taheri Z, Mehrafza M, Mohammadi F, Khoddami M, Bahadori M. Proliferative marker in distinction between benign and malignant mesothelial proliferations. Tanaffos 2006;5:9-12. |
|27.||Terada T. Immunohistochemical profile of normal mesothelium and histiocytic/methothelial hyperplasia: A case report. Int J Clin Exp Pathol 2011;4:631-6. |
|28.||Schönherr A, Bayer M, Böcking A. Diagnostic and prognostic value of Ki67 proliferation fraction in serous effusions. Cell Oncol 2004;26:57-62. |
|29.||Kimura F, Kawamura J, Watanabe J, Kamoshida S, Kawai K, Okayasu L, et al. Significance of cell proliferation markers (Minichromosome maintenance protein 7, topoisomerase IIalpha and Ki-67) in cavital fluid cytology: Can we differentiate reactive mesothelial cells from malignant cells? Diagn Cytopathol 2010;38:161-7. |
|30.||Hasteh F, Lin GY, Weidner N, Michael CW. The use of immunohistochemistry to distinguish reactive mesothelial cells from malignant mesothelioma in cytologic effusions. Cancer Cytopathology 2010;118:90-6. |
|31.||Minato H, Nojima T, Kurose N, Kinoshita E. Adenomatoid tumor of the pleura. Pathol Int 2009;59:567-71. |