The diagnosis of endometrial cancer can be made preoperatively by obtaining a sample of endometrial tissue either with office endometrial biopsy, most commonly done with a Pipelle aspiration catheter, hysteroscopy (HSC), or dilatation and curettage (D&C).1 The latter two procedures are most commonly used in Slovenia. HSC has been shown to be highly accurate in diagnosing endometrial cancer2,3 and is considered a gold standard.1 Conflicting evidence has been published in the past regarding the risk of intraperitoneal spread of malignant cells after HSC with the use of distension media.4-7 In 2007, a retrospective study from our institution reported a significantly higher incidence of positive peritoneal washings after HSC compared to D&C.8 However, only 24 patients in this study had undergone HSC compared to 122 who were diagnosed with D&C.8 In recent years, HSC has become an established diagnostic tool at our institution and is now performed more frequently than D&C. The aim of our present study was to find out whether the difference in the incidence of positive peritoneal washings between HSC and D&C persists after including a higher number of patients with hysteroscopy.
Patients and methods
This retrospective study included all consecutive patients who had endometrial carcinoma diagnosed preoperatively with either D&C or HSC between January 2008 and December 2014 at the University Medical Centre Maribor, Slovenia. The study included patients who had more than one D&C or more than one HSC. Patients who had undergone both D&C and HSC were excluded from the study. The study was approved by our institution’s ethics committee (Approval No. 13-03/15, November 26, 2015). All patients signed a written informed consent that their medical records can be used for research matters retrospectively.
HSC was performed in the office setting or under general anesthesia. Saline solution warmed to body temperature was used as the distension medium. In the office setting, the distension medium was installed into the pressure cuff and the intrauterine pressure was set between 80–150 mmHg. Intrauterine pressure was controlled with the Vario Flow device (Pelta, Slovenia) in operative HSC.9 D&C was performed under general anesthesia. Curettage of the cervical canal and the uterine cavity was performed separately. Tissue samples for histologic examination were obtained during both procedures.
During the final surgery for endometrial carcinoma, samples of peritoneal washings from the pouch of Douglas were obtained for cytologic examination. Irrigation of the peritoneal cavity with saline solution was performed to obtain samples in cases with no free fluid. The samples were inspected by an expert cytopathologist. In cases of suspicious peritoneal cytology additional calretinin, MOC 31, HBME 1 and Ber-EP4 immunostaining was performed during the clarification process. In cases of small numbers of positive cells after immunostaining peritoneal cytology was described as suspicious. We therefore included suspicious results in the analysis of positive peritoneal cytology.
The primary statistical outcome was the incidence of positive peritoneal washings after HSC and after D&C. A detailed analysis of tumour histopathologic characteristics was performed including histopathologic type, tumour differentiation, depth of myometrial invasion, lymphovascular invasion and FIGO stage. Different types of endometrial carcinomas were identified in the study population with endometrioid carcinoma representing the majority of cases (N = 211; 93.0%). Other carcinomas (serous adenocarcinoma: N = 8; clear cell adenocarcinoma: N = 8) were assigned into non-endometriod group for the purpose of the study. Tumour differentiation was reported as good, moderate or poor. The depth of myometrial invasion was reported as no invasion, less than half of myometrium or more than half of myometrium. Patients treated before 2009 who had been staged according to the 1988 FIGO classification were restaged according to the new 2009 FIGO classification for statistical analysis. The time interval from diagnosis to final surgery was also analyzed.
Statistical analysis was performed with SPSS software version 22.0 (IBM, Armonk, NY, USA). Descriptive analysis, chi-square test and t-test of independent samples were performed as applicable. A p value of less than 0.05 was considered statistically significant.
Between January 2008 and December 2014, 266 patients had uterine cancer diagnosed with D&C and/or HSC. 227 patients who had either HSC (N = 144) or D&C (N = 83) as well as available information on peritoneal washings were included in the statistical analysis.
Two hundred and eleven (93.0%) patients had endometrioid endometrial carcinoma and 16 (7.0%) had non-endometrioid endometrial carcinoma. The differences between both groups regarding the differentiation, myometrial invasion and tumour stage are shown in Table 1. Significantly higher rate of poorly differentiated tumours (chi-square = 29.114; p < 0.001) and higher stages (chi-square = 16.019; p = 0.025) have been noted in the non-endometrioid group.
Histologic characteristics of the patients with endometrioid endometrial carcinoma (N = 211) and non-endometrioid endometrial carcinoma (N = 16)
|Histologic parameter||Endometrioid endometrial carcinoma||Non-endometrioid endometrial carcinoma||p*|
|Tumour differentiation||< 0.001|
|G1||125 (59.2%)||2 (13.3%)|
|G2||63 (29.9%)||4 (26.6%)|
|G3||23 (10.9%)||9 (60.0%)|
|none||8 (3.8%)||1 (6.3%)||0.888|
|less than ½||123 (58.3%)||9 (56.2%)|
|more than ½||80 (37.9%)||6 (37.5%)|
|2009 FIGO stage|
|IA||114 (54.0%)||7 (43.8%)||0.025|
|IB||54 (25.6%)||1 (6.3%)|
|II||14 (6.6%)||2 (12.5%)|
|IIIA||7 (3.3%)||1 (6.3%)|
|IIIB||5 (2.4%)||0 (0.0%)|
|IIIC1||11 (4.7%)||2 (12.5%)|
|IIIC2||0 (0.0%)||0 (0.0%)|
|IVA||1 (0.5%)||1 (6.3%)|
|IVB||5 (2.4%)||2 (12.5%)|
Overall, there was no significant difference in the incidence of positive or suspicious peritoneal washings regarding the procedure performed during the diagnostic evaluation (13.2% after HSC, 12.0% after D&C; chi-square = 0.062; p = 0.803).
The groups (HSC vs. D&C) did not differ in the prevalence of histologic types of the tumour, depth of myometrial invasion and lymphovascular invasion (Table 2). However, there were significant differences in tumour differentiation as well as FIGO stage, with more patients having FIGO stage I disease in the hysteroscopy group (Table 2). Due to this difference we conducted analysis only in the subgroup of patients with stage I disease. The HSC and D&C groups of stage I patients did not differ in tumour differentiation, the prevalence of histologic types of the tumour, the time from diagnosis to operation and in myometrial invasion. A separate evaluation of patients with stage I tumours showed that 12.8% in the HSC group and only 3.4% in the D&C group had positive peritoneal washings. This difference was statistically significant (chi-square = 2.422; p = 0.046) (Table 3).
Histologic characteristics of the patients with endometrial carcinoma (N = 227) who were diagnosed with hysteroscopy (HSC) or dilatation and curettage (D&C)
|Histologic parameter||HSC (N = 144)||D&C (N = 83)||P value|
|endometrioid adenocarcinoma||137 (95.1%)||74 (89.2%)||0.090*|
|non-endometrioid adenocarcinoma||7 (4.9%)||9 (10.8%)|
|G1||90 (62.5%)||37 (45.1%)||0.012*|
|G2||40 (27.8%)||27 (32.9%)|
|G3||14 (9.7%)||18 (22.0%)|
|none||5 (3.5%)||4 (4.8%)||0.726*|
|less than ½||82 (56.9%)||50 (60.2%)|
|more than ½||57 (39.6%)||29 (34.9%)|
|present||20 (13.9%)||14 (16.9%)||0.545*|
|absent||124 (86.1%)||69 (83.1%)|
|2009 FIGO stage|
|IA||75 (52.1%)||46 (55.4%)|
|IB||42 (29.2%)||13 (15.7%)|
|II||10 (6.9%)||6 (7.2%)|
|IIIA||1 (0.7%)||7 (8.4%)|
|IIIB||3 (2.1%)||2 (2.4%)||0.040*|
|IIIC1||9 (6.3%)||4 (4.8%)|
|IIIC2||0 (0.0%)||0 (0.0%)|
|IVA||1 (0.7%)||1 (1.2%)|
|IVB||3 (2.1%)||4 (4.8%)|
|Peritoneal cytology positive or suspicious negative||19 (13.2%) 125 (86.8%)||10 (12.0%) 73 (88.0%)||0.803*|
|Time from diagnosis to operation (days)||35.8 ± 13.8||32.8 ± 15.4||0.140**|
Histologic characteristics of the patients with stage 1 endometrial carcinoma (N = 187) who were diagnosed with hysteroscopy (HSC) or dilatation and curettage (D&C)
|Stage 1||HSC (N = 117)||D&C (N = 59)||P value|
|endometrioid adenocarcinoma||112 (95.7%)||56 (94.9%)||0.807*|
|non-endometrioid adenocarcinoma||5 (4.3%)||3 (5.1%)|
|G1||75 (64.1%)||29 (49.2%)||0.156*|
|G2||32 (27.4%)||22 (37.3%)|
|G3||10 (8.5%)||8 (13.5%)|
|none||5 (4.3%)||3 (5.1%)||0.079*|
|less than ½||71 (60.7%)||45 (76.2%)|
|more than ½||41 (35.0%)||11 (18.6%)|
|Peritoneal cytology positive or suspicious negative||15 (12.8%) 102 (87.2%)||2 (3.4%) 57 (96.6%)||0.046*|
|Time from diagnosis to operation (days)||35.6 ± 14.0||33.1 ± 12.7||0.255**|
One out of 15 FIGO stage I patients with positive peritoneal washings after hysteroscopy had disease recurrence by the end of April 2015 (mean follow-up 40.2 months). Neither of the two FIGO stage I patients with positive peritoneal washings after D&C had disease recurrence in the same period (mean follow-up 39.5 months).
The possibility of microscopic intraperitoneal spread of endometrial cancer cells after hysteroscopy has been a subject of debate for more than a decade. In our study, we did not find an increased incidence of positive peritoneal washings after hysteroscopy in comparison to D&C in the overall study population of patients with endometrial carcinoma. Several other studies similarly found no association between hysteroscopy and an increased rate of positive peritoneal cytology.5,6 On the other hand, Bradley et al.7 reported a higher frequency of positive or suspicious peritoneal cytology after hysteroscopy compared to blind endometrial sampling using logistic regression controlling for confounders of grade and stage. They also reported a higher rate of disease upstaging (according to the 1988 FIGO staging system) after hysteroscopy attributed solely to the positive cytology. Similar results have been reported by Zerbe et al.10 and Obermair et al.11 In a study conducted at our institution in 20078, positive peritoneal cytology was present in 12.5% of patients after hysteroscopy and only in 1.6% after D&C. The difference was statistically significant (chi-square = 4.2455; p < 0.005).
In a meta-analysis of nine trials including 1015 patients with confirmed endometrial carcinoma, Polyzos et al.12 evaluated the rate of positive peritoneal washings after hysteroscopy in comparison to other diagnostic procedures or no diagnostic procedures. They concluded that the frequency of positive peritoneal washings was significantly higher after hysteroscopy. The analysis also revealed a higher rate of disease upstaging based only on the positive peritoneal cytology. A detailed literature search performed by Guralp and Kushner13 revealed 0–83% of positive peritoneal cytology after hysteroscopy and 0–13.6% after D&C. However, the authors emphasized a number of unanswered questions regarding the type and volume of distension medium, intrauterine pressure during the procedure, time interval between hysteroscopy and definitive surgery, stage, grade of the disease and duration of the procedure.13 Another metaanalysis by Chang et al.14 also reported on higher rates of positive peritoneal cytology after hysteroscopy. Nevertheless, a detailed analysis of patients with stages I or II failed to show significantly higher rates of positive peritoneal cytology in patients who had hysteroscopy.
Interestingly, our results showed a significantly higher incidence of positive or suspicious peritoneal cytology in patients with stage I disease who were diagnosed with hysteroscopy compared to those diagnosed with D&C. This is an unexpected finding because the disease at this stage is confined to the uterus. For example, only 3.3% of patients with stage I and II endometrial cancer in a large retrospective analysis by Garg et al.15 had positive peritoneal cytology. In our study, the rate of positive or suspicious peritoneal cytology in stage I disease was 3.3% in the D&C group but as much as 12.1% in the hysteroscopy group. Positive or suspicious peritoneal cytology was shown to be more frequent after hysteroscopy in endometrial carcinoma patients who would be staged as FIGO IA in the new staging system by Obermair et al.11 On the other hand, Biewenga et al.6 showed no association between hysteroscopy and the rate of positive peritoneal washings in stage I disease.
Saline solution was used as the distension medium in all our patients in the hysteroscopy group. Hysteroscopy with saline solution was specifically linked to a higher rate of positive peritoneal cytology in a meta-analysis by Polyzos et al.12 In a metaanalysis by Chang et al. 14, the distension medium was either saline solution or 5% glucose solution. Neither of these two meta-analyses found a connection between intrauterine pressure during hysteroscopy higher than 100 mmHg and a higher incidence of positive peritoneal cytology.12,14 In our study, the exact intrauterine pressure during hysteroscopy was not known for each patient individually due to the retrospective nature of the analysis.
The time interval between the diagnostic procedure and definitive surgery was similar in patients with positive and negative peritoneal cytology in our study. This is in line with evidence from another retrospective study in 196 patients with endometrial cancer diagnosed with hysteroscopy.16
Based on the data from our retrospective study, we cannot give a definite reason for the significantly higher incidence of positive peritoneal washings after HSC compared to D&C in stage I disease. We used saline solution as the distension medium, which has been previously associated with higher rates of positive peritoneal cytology.12 Unfortunately, we do not have the exact information on the intrauterine pressure during HSC and the duration of the diagnostic procedure for each patient and therefore we cannot draw conclusions about the influence of these factors on peritoneal cytology.
Another important limitation of our study is the inclusion of suspicious peritoneal cytology in the positive peritoneal cytology group. Even after immunostaining most of the cases without evident malignant cells remained cytologically suspicious because positive immune reaction was seen in only a small fraction of cells. However, it is not easy to differentiate positive from suspicious cytology because severe atypia of reactive mesothelial cells may be interpreted as suspicious. We are aware of this methodological limitation and should aim to lower the incidence of suspicious peritoneal cytology in the future firstly by obtaining sufficient amount of fluid for cytological analysis during final surgery and secondly with accurate cytological diagnosis. Some published research on this subject also included positive and suspicious cytology in the same group.7,8,11
Our data show that among patients with positive or suspicious peritoneal washings after hysteroscopy, in FIGO stage I patients, one out of 15 had local disease recurrence during follow-up of approximately 40 months, whereas neither of the two with positive washings after D&C had the recurrence. As these numbers are small, further research is necessary to draw relevant conclusions. Conflicting results exist in the literature regarding the prognostic significance of positive peritoneal cytology.17,18 The updated FIGO staging system from 2009 excluded positive peritoneal cytology as a stage defining variable. Previously, all patients with positive peritoneal cytology were upstaged to stage IIIA.19 In an analysis of 14,704 patients, Garg et al.15 reported peritoneal cytology to be associated with survival in univariate analysis along with race, age, histology, grade and the number of removed lymph nodes. In multivariate analysis, positive peritoneal cytology remained an independent prognostic factor in stages I and II. Shiozaki et al.20 studied the influence of positive peritoneal washings on the prognosis of 265 patients with stage I endometrial cancer. Progression-free survival was significantly lower in the group with positive peritoneal cytology. Other factors associated with progression-free survival in univariate analysis were lymph node dissection and vessel permeation, but positive peritoneal cytology was the most influential factor.20 Disease-free survival has been shown to be 91% in FIGO stage I patients and 52.5% in those with FIGO stage II, III and IV.21 In the study by Garg et al., survival in patients with stage I endometrioid adenocarcinoma with positive peritoneal washings was significantly poorer than in patients with negative peritoneal washings (88.2% vs. 98.6%).15
In conclusion, the diagnostic procedure did not influence the overall incidence of positive peritoneal washings in our study. However, hysteroscopy was associated with a significantly higher rate of positive peritoneal cytology in stage I endometrial carcinoma. Although statistically significant, this finding must be interpreted with caution because of the small sample size of this subgroup. In addition, it is still not known whether iatrogenic dissemination of malignant cells bears the same influence on disease prognosis as spontaneous dissemination. Despite being excluded as the stage defining variable, peritoneal cytology should still be reported separately as requested by FIGO.15 We believe that additional trials are needed to further clarify the prognostic value of positive peritoneal cytology after hysteroscopy, particularly in the early stages of endometrial cancer.
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Burke WM, Orr J, Leitao M, Salom E, Gehrig P, Olawaiye AB, et al. Society of Gynecologic Oncology Clinical Practice Committee. Endometrial cancer: a review and current management strategies: part I.)| false Gynecol Oncol2014; 134: 385-92. 10.1016/j.ygyno.2014.05.018 24905773
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Shiozaki T, Tabata T, Yamada T, Yamamoto Y, Yamawaki T, Ikeda T. Does positive peritoneal cytology not affect the prognosis for stage I uterine endometrial cancer? The remaining controversy and review of the literature.)| false Int J Gynecol Cancer2014; 24: 549-55. 10.1097/IGC.0000000000000072
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