Non-atypical endometrial hyperplasia: risk factors for occult endometrial atypia and malignancy in patients managed with hysterectomy

Article information

Obstet Gynecol Sci. 2021;64(3):300-308
Publication date (electronic) : 2021 February 25
doi : https://doi.org/10.5468/ogs.20294
1Department of Obstetrics & Gynecology, KK Women’s and Children’s Hospital, Singapore
2Department of Gynaecological Oncology, KK Women’s and Children’s Hospital, Singapore
Corresponding author: Lee Shi Hui, MBBS, Department of Obstetrics & Gynecology, KK Women’s and Children’s Hospital, 100 Bukit Timah Road, Singapore 229899, Singapore, E-mail: shihui.lee@mohh.com.sg
Received 2020 September 29; Revised 2020 December 7; Accepted 2021 February 21.

Abstract

Objective

To determine the risk factors for occult endometrial atypia and malignancy in patients diagnosed with non-atypical endometrial hyperplasia (NEH) on endometrial biopsy.

Methods

All new cases of NEH diagnosed between April 2015 and March 2016 at KK Women’s and Children’s Hospital, who underwent hysterectomy as first-line treatment, were included in the study. Patients with a history of endometrial hyperplasia or malignancy were excluded from the study. Patient demographics (e.g., age, parity, body mass index [BMI]), medical history, and clinical presentation were obtained for analysis.

Results

In total, 262 patients were diagnosed with NEH, of which 18.3% (n=48) underwent hysterectomy as first-line management. The average time to surgery was 77.0±35.7 days. All cases were diagnosed by dilation and curettage, and hysteroscopy. The mean age was 51 years, and the mean BMI was 26.9±5.8 kg/m2. Histology from the hysterectomy specimen showed 9 (18.8%) patients with atypical hyperplasia and 2 (4.2%) with grade 1, stage 1A endometrioid adenocarcinoma. Patients with higher grade final pathology had significantly lower median parity (1 vs. 2, P=0.039), higher mean BMI (30.1±6.5 vs. 25.9±5.3 kg/m2, P=0.033), and BMI ≥30 kg/m2 (54.5% vs. 13.5%, P=0.008, odds ratio 7.68), compared to patients whose final histology showed NEH or no residual hyperplasia.

Conclusion

Occult endometrial atypia and malignancy were found in 18.8% and 4.2% of patients with an initial diagnosis of NEH, respectively. High BMI and low parity were identified as significant risk factors for high-grade endometrial lesions in patients with NEH.

Introduction

Endometrial hyperplasia (EH) was classified by the World Health Organization in 2014 into two categories based on the presence of cytological atypia [1]. Approximately, 200,000 new cases of EH are diagnosed annually in developed countries [2,3]. EH is of significant clinical importance, given that it is the precursor of endometrial carcinoma [4], the most common gynecological cancer in developed countries [5]. The risk of progression to carcinoma is less than 5% for non-atypical endometrial hyperplasia (NEH) and up to 30% in atypical hyperplasia (AH) [4,6].

A diagnosis of EH requires histological analysis of endometrial tissue via endometrial biopsy, which can be obtained from outpatient endometrial sampling or endometrial curettage. A comparison of histology from these methods to the corresponding hysterectomy specimen has found a concordance rate ranging from 60% to 70% [79] for outpatient endometrial sampling and approximately 70% [8,9] for dilation and curettage (D&C).

The first-line treatment for NEH is medical therapy with oral or local intrauterine progestins. Successful regression rates with different forms of progestins vary, with reported regression rates ranging from 69% to 92% [10]. Surgery for NEH is generally reserved for patients who have progression or persistence despite medical management or relapse of hyperplasia on follow-up [11]. Some patients undergo surgery as first-line management upon diagnosis of NEH due to contraindications to progestins, other gynecological indications for surgery, or patient preferences.

Patients with an initial diagnosis of NEH may be diagnosed with AH or endometrial malignancy from their final hysterectomy specimen. The risk of high-grade lesions in patients with NEH has not been well established. The aim of this study was to determine the risk of concurrent atypia and endometrial malignancy in patients with NEH and to establish the risk factors for higher grade final pathology.

Materials and methods

This retrospective study was conducted at a single tertiary hospital in Singapore. All new cases of NEH diagnosed by histopathological analysis of endometrial biopsy conducted between April 2015 and March 2016 were considered for inclusion. Patients with a history of EH or malignancy were excluded. Only patients who underwent hysterectomy as a first-line treatment were included in the analysis. All preoperative and postoperative histological slides were assessed by gynecology pathologists at our tertiary institution.

Patient demographics (e.g., age, ethnicity, parity, body mass index [BMI], and menopausal status), medical history, and use of tamoxifen were obtained. Their clinical presentation, method of diagnosis of NEH (e.g., outpatient endometrial sampling vs. D&C with hysteroscopy), ultrasound and hysteroscopic findings, and subtype of NEH (e.g., simple vs. complex) were obtained. We also collected data on the indications and routes of surgery, as well as postoperative complications.

Continuous data were presented as mean±standard deviation, or median and data range. The independent samples t-test or independent-samples Mann-Whitney U test were used for comparisons of continuous variables between the groups. Categorical data were presented as counts and percentages, and comparisons were performed using the Pearson χ2 test or Fisher’s exact test, as appropriate. Simple logistic regression analysis was applied to screen several clinical parameters, including age, menopausal status, parity, BMI, diabetes, use of tamoxifen, and ultrasound or hysteroscopic findings of a thickened endometrium. Statistical significance was set at a two-sided P-value of <0.05. All statistical analyses were performed using SPSS 19 software (IBM Corp., Armonk, NY, USA).

Results

A total of 262 patients were diagnosed with non-atypical simple and/or complex hyperplasia over a one-year study period. Of these, 48 patients (18.3%) underwent hysterectomy as first-line management. All 48 patients were diagnosed by means of a D&C with hysteroscopy, of which 39 patients (81.3%) had complex hyperplasia without atypia and the remaining patients had simple hyperplasia without atypia. The mean age at diagnosis was 51 years (range, 38–78 years). In our study population, 38 patients (79.1%) were of Chinese ethnicity. The median parity was 2 (range, 0–5) and the mean BMI was 26.9±5.8 kg/m2. A total of 35 patients (72.9%) presented with abnormal uterine bleeding (AUB) or post-menopausal bleeding. The demographics, clinical presentation, and hysteroscopic findings of our study population are presented in Table 1.

Demographics and clinical presentation of study group

The risk factors for EH among our patients are presented in Table 2. Of note, 50% of our patients (n=24) had at least one risk factor for EH, with the most common being nulliparity (n=12, 25.0%) and obesity (n=11, 22.9%), defined as BMI ≥30 kg/m2. A total of 18.7% (n=9) of patients had diabetes mellitus, and 6.3% (n=3) were receiving hormone therapy with tamoxifen for breast cancer treatment. One patient had polycystic ovarian syndrome with associated complications of obesity and diabetes mellitus. One patient underwent laparoscopic salpingo-oophorectomy and D&C with hysteroscopy for a known ovarian cyst and endometrial polyp, revealing complex EH without atypia and an ovarian granulosa cell tumor on histology.

Risk factors for endometrial hyperplasia

The average time to surgery was 77.0±35.7 days, with half of the patients undergoing laparoscopic hysterectomy (n=24) as the mode of surgery. Table 3 shows the mode and indications for surgery. A total of 25 patients (52.1%) opted for surgical management as they had concurrent indications for surgery, such as fibroids, urogynecological symptoms, contraindication to progestins, or symptomatic AUB despite the use of progestin prior to diagnosis of EH. The mean length of hospital stay was 2.9±1.2 days.

Mode and indication of surgery

Two patients had operative complications. One patient with a history of three previous Caesarean sections underwent abdominal hysterectomy and sustained a 1.5 cm bladder dome injury due to dense bladder adhesions. The postoperative recovery was uneventful, and the patient was discharged two days later. Another patient with severe pelvic endometriosis, obliteration of the pouch of Douglas, and dense adhesions over the bilateral adnexa underwent a laparoscopic hysterectomy. She was readmitted twelve days post-surgery with abdominal pain and was found to have a urinoma secondary to distal ureteric injury. She was referred to the urology department and underwent drainage and ureteric stenting. The ureteric stent was removed, and she was discharged from the urology follow-up.

In the final histology of the hysterectomy specimen, 11 of 48 patients (22.9%) were found to have higher grade pathology, of which 9 patients (18.8%) were diagnosed with AH and 2 patients (4.2%) with endometrial carcinoma. The remaining 20 patients (41.7%) had NEH, and 17 patients (35.4%) had no residual hyperplasia. Two patients diagnosed with carcinoma were found to have grade 1, stage 1A endometrioid adenocarcinoma. The characteristics of the 11 patients are shown in Table 4.

Characteristics of patients with higher grade pathology of the final hysterectomy specimen

The patients with higher grade pathology on final histology (AH and endometrial carcinoma) were found to have significantly lower median parity (1 vs. 2, P=0.039) compared to the patients whose final histology showed NEH or no residual hyperplasia (Table 5). Nulliparous patients were found to have a higher likelihood of having higher grade final pathology compared to patients with ≥2 previous pregnancies (41.7% [5 in 13 cases] vs. 12.0% [3 in 25 cases], P=0.051, odds ratio 5.24) (Table 5). Also, patients with higher grade final histology had significantly higher mean BMI (30.1±6.5 vs. 25.9±5.3 kg/m2, P=0.033). There was a statistically significant difference between the two groups when comparing a BMI of ≥30 kg/m2 (54.5% [6 in 11 cases] vs. 13.5% [5 in 37 cases], P=0.008, odds ratio 7.68).

Predictive factors for higher grade final histology

No significant difference was noted between the two groups for the remaining risk factors, such as age, menopausal status, diabetes, or use of tamoxifen. There was also no significant difference between the two groups for ultrasound or hysteroscopic findings of a thickened endometrium, and among the experience of the surgeon performing the D&C with hysteroscopy (trainee vs. specialist). The initial histology showing simple vs. complex NEH and time to surgery between the two groups was also not significantly different. Other risk factors, such as polycystic ovarian syndrome and granulosa cell tumors, were not used for statistical comparison, as only one patient was diagnosed with each of these risk factors.

There were 23 patients who received progestin therapy for the management of AUB or for interim treatment of NEH while awaiting surgery. The type of progestin used included norethisterone, medroxyprogesterone, and megestrol acetate. The dose ranged from 10–30 mg/day for patients given norethisterone and medroxyprogesterone, and 80–160 mg/ day for patients given megestrol acetate. The use of progestin therapy before surgery was not found to be significantly associated with the grade of the final histology (Table 5).

Discussion

EH is diagnosed via histological analysis of endometrial tissue obtained from outpatient endometrial sampling or endometrial curettage. D&C has traditionally been considered the gold standard procedure for the investigation of endometrial pathologies. In our study, all patients were diagnosed with NEH using D&C with hysteroscopy. However, 4.2% of patients had a final diagnosis of endometrial cancer from hysterectomy specimens. These results are similar to those of previous studies where 1.1% to 13.7% of patients initially diagnosed with NEH were found to have endometrial cancer in the final hysterectomy specimen [1216]. Our study also found that 18.8% of patients with an initial diagnosis of NEH had a final histology of AH from the hysterectomy specimen. Previous studies have found a wide range of misdiagnoses of atypia between endometrial biopsy and hysterectomy specimens, ranging from 1.1% to 50% [12,1719]. The limitation of endometrial curettage is thought to be due to endometrial pathologies in focal lesions, and other authors have recommended that patients with a diagnosis of NEH require close follow-up or further investigations, such as targeted hysteroscopic biopsy of the endometrium in addition to curettage, especially if AUB persists [18,2022].

In our study, when patients with lower and higher final grade histology were compared, high BMI, especially BMI ≥30 kg/m2, and lower parity were identified as significant risk factors for higher grade final histology (Table 5). Prior studies that identified risk factors for higher grade final histology mostly included both NEH and AH patients. Only one other study included patients with NEH undergoing hysterectomy. Lee et al. [23] found that 12.1% and 3.2% of patients with NEH had occult AEH or endometrial carcinoma in hysterectomy specimens, respectively, and identified age (odds ratio=1.09, P<0.01) and complex subtype (odds ratio=3.34, P<0.01) as independent risk factors for higher grade final histology. Other studies that included patients with both NEH and AH at initial diagnosis had similar outcomes to ours. Dolanbay et al. [13] reviewed 82 women with NEH and AH diagnosed by endometrial sampling or D&C. In this study,13.7% of patients with NEH and 66.6% of patients with AH had endometrial carcinoma in their final hysterectomy specimen. Similar to our study, it was found that patients with a final histology of endometrial cancer had significantly higher BMI (28.75±4.08 vs. 32.42±3.4, P<0.05). They also identified age, mean weight, and diabetes as factors that were significantly higher in patients with a final diagnosis of endometrial cancer [13]. Kadirogullari et al. [19] reviewed 158 patients diagnosed with NEH or AH and found that 15 patients had endometrial cancer on final hysterectomy specimen. Two patients were diagnosed with NEH on initial biopsy, and the other 13 patients were diagnosed with AH. Similar to our study, patients with endometrial carcinoma in the final hysterectomy specimen had significantly lower parity (3.11±1.62 vs. 1.93±1.79, P<0.05). They also found age, postmenopausal status, and endometrial thickness as predictive risk factors for endometrial cancer in the final histology specimen.

The NEH group had a high spontaneous regression rate. Our study found that 35.4% of the patients had no residual hyperplasia on the final histology. This is similar to previous studies, with results ranging from 37.4% to 59.49% [12,17]. Given the high spontaneous regression rate of NEH and high success rate with treatment with progestins, current guidelines by the Royal College of Obstetricians and Gynecologists recommend conservative treatment as first-line management [11]. However, caution must be exercised for patients who are managed conservatively, as in patients with NEH who were found to have complete regression after progestin treatment; long-term follow-up noted a relapse rate ranging from 12.7–41% [24,25]. Gallos et al. [26] found that in patients treated with the levonorgestrel-releasing intrauterine system for complex NEH, 32.6% of those with a BMI ≥35 kg/ m2 experienced relapse compared to only 3.3% of women with a BMI <35 kg/m2 (P<0.001) over a 9 years study period. Hence, patients managed conservatively need to be aware of the high risk of relapse, especially in those with a high BMI, and this should be considered when formulating a management plan.

Moreover, there remains a risk of progression to AH and endometrial cancer. Iversen and Dueholm [27] found that, in patients with complex NEH, the 5-year risk of developing endometrial cancer or atypia was 20%. While most of the endometrial cancers were diagnosed in the first year, indicating the possibility of missed diagnosis at the time of baseline sample, they also noted a significant risk of progression to atypia or endometrial cancer of 9% after one year, and a 30% risk of hysterectomy within five years. A long-term study of postmenopausal women with NEH had higher rates of progression to type 1 endometrial cancer (8.2% vs. 0.8%, P<0.0001), persistent EH (21.9% vs. 0.7%, P<0.0001), future surgical intervention (50.7% vs. 15.4%, P<0.0001), and future hysterectomy (34.3% vs. 9.6%, P<0.0001), compared to postmenopausal women with atrophic endometrium [28].

1. Strengths and limitations

Patients with an initial diagnosis of NEH whose hysterectomy specimen reveals higher-grade pathology are not commonly reviewed. To our knowledge, this is the second study to investigate the risk factors for concurrent atypia and malignancy in patients with NEH. In addition, we present a unique group of patients who were all diagnosed by D&C with hysteroscopy. All preoperative and postoperative histology slides were assessed by gynecology pathologists in our tertiary institution, where cases with challenging histopathological diagnoses are discussed in the departmental multidisciplinary team to achieve a consensus. However, this study was limited by the small sample size of 48 patients. Our study outcome grouped patients with a final histological diagnosis of low- vs. higher-grade lesions, as subgroup analysis to predict risk factors separately for patients with atypia and endometrial cancer were not significant due to the small sample size.

2. Conclusion

The current guidelines recommend conservative therapy for NEH, given its high spontaneous regression rate and high treatment success rate [11], although the optimal duration and frequency for follow-up are yet to be determined. The limitations of curettage must be acknowledged, with 22.9% of patients in our study with an initial diagnosis of NEH having higher grade final pathologies, including 4.2% diagnosed with endometrial cancer. Our study identified high BMI and low parity as significant risk factors for the presence of highgrade endometrial lesions in patients with NEH. Larger studies will be useful in confirming these study findings and help guide future clinicians in deciding the optimal management of NEH. In view of the possibility of underdiagnosis in the initial sample, as well as a high risk of relapse and progression to higher grade lesions in patients with risk factors, the diagnosis of NEH should not be taken lightly. Perhaps not all patients with NEH should be managed the same; patients with risk factors may benefit from closer follow-up, with hysterectomy as a management option, especially if conservative management has failed.

Notes

Conflict of interest

No potential conflict of interest relevant to this article was reported.

Ethical approval

Ethics approval for this study was obtained from the Singhealth Centralized Institution Review Board. The study was performed in accordance with the principles of the Declaration of Helsinki.

Patient consent

Written informed consent and the use of images from patients are not required for the publication.

Funding information

None.

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Article information Continued

Table 1

Demographics and clinical presentation of study group

Value
Demographics
 Age at diagnosis (yr) 51±7.3
 Ethnicity
  Chinese 38 (79.2)
  Malay 6 (12.5)
  Indian 4 (8.3)
 Gravidity 2 (0–8)
 Parity 2 (0–5)
 Body mass index (kg/m2) 26.9±5.8
 Menopausal status
  Premenopausal 32 (66.7)
  Postmenopausal 16 (33.3)
Clinical presentation
 Abnormal uterine bleeding or postmenopausal bleeding 35 (72.9)
 Thickened endometrium 21 (43.8)
 Endometrial/endocervical polyp 8 (16.7)
 Abnormal cervical screening test-Endometrial cells/Atypical glandular cells of uncertain significance 3 (6.3)
Hysteroscopic findings
 Thickened endometrium 24 (50.0)a)
 Endometrial polyp 22 (45.8)a)
 Normal hysteroscopy 6 (12.5)

Values are presented as mean±standard deviation or number (%).

a)

Four patients had hysteroscopic findings of both thickened endometrium and endometrial polyp.

Table 2

Risk factors for endometrial hyperplasia

Risk factor Value (n=48)
Nulliparous 12 (25.0)
Obesity (BMI ≥30 kg/m2) 11 (22.9)
Diabetes mellitus 9 (18.7)
Use of tamoxifen 3 (6.3)
Polycystic ovarian syndrome 1 (2.1)
Granulosa cell tumor 1 (2.1)
At least 1 risk factor 24 (50.0)

Values are presented as number (%).

BMI, body mass index.

Table 3

Mode and indication of surgery

Value
Mode of surgery
 Laparoscopic hysterectomy 24 (50.0)
 Abdominal hysterectomy 13 (27.1)
 Vaginal hysterectomy 8 (16.7)
 Laparoscopic/vaginal converted to laparotomy 3 (6.3)
Indication of surgery
 Patient’s preference 23 (47.9)
 Benign gynecology conditions (fibroids, endometriosis, tubo-ovarian abscess etc) 12 (25.0)
 Urogynecological symptoms 6 (12.5)
 Contraindication to progestins 4 (8.3)
 Symptomatic AUB despite progestins 2 (4.2)
 Ovarian cancer 1 (2.1)

Values are presented as number (%).

AUB, abnormal uterine bleeding.

Table 4

Characteristics of patients with higher grade pathology of the final hysterectomy specimen

Number of patients Age (yr) Menopausal Parity BMI Presentation Other risk factors Initial histology (type of NEH) Other indications for surgery Route of surgery Final histology
1 47 No 0 26.4 AUB No Complex Fibroid Abdominal CAH
2 48 No 0 34.7 AUB, thickened ET No Complex Fibroid Abdominal SAH
3 67 Yes 1 21.7 Thickened ET Tamoxifen use Complex Contraindication to progestins Abdominal CAH
4 60 Yes 0 37.6 PMB, thickened ET DM Complex No Laparoscopic CAH
5 49 No 1 30.1 Endometrial cells on pap smear No Complex Stress urinary incontinence Abdominal CAH
6 53 No 0 21.1 AUB No Complex No Laparoscopic Carcinomaa)
7 42 Yes 0 31.6 PMB, thickened ET DM Simple No Laparoscopic CAH
8 38 No 1 29.5 AUB No Simple No Vaginal Carcinomaa)
9 57 Yes 2 42.2 Thickened ET DM, tamoxifen use Complex Contraindication to progestins Laparoscopic CAH
10 47 No 2 24.5 AUB No Complex No Abdominal CAH
11 60 Yes 2 31.8 Thickened ET No Complex No Vaginal converted laparoscopic CAH

BMI, body mass index; NEH, non-atypical endometrial hyperplasia; AUB, abnormal uterine bleeding; CAH, complex atypical hyperplasia; ET, endometrial thickness; SAH, simple atypical hyperplasia; PMB, post-menopausal bleeding; DM, diabetes mellitus.

a)

Both patients, grade 1; stage 1A endometrioid adenocarcinoma.

Table 5

Predictive factors for higher grade final histology

Risk factors Higher grade final histology (n=11) Low grade final histology (NEH or no residual hyperplasia, n=37) Odds ratio 95% confidence interval P-value
Age (yr) 51.6±8.7 50.7±6.9 0.72
Menopausal
 No 6 (54.5) 26 (70.3) 1 - -
 Yes 5 (45.5) 11 (29.7) 0.51 0.13–2.0 0.34
Parity
 Median 1 2 - - 0.039
 0 5 (45.5) 7 (18.9) 5.24 0.99–27.69 0.051
 1 3 (27.3) 8 (21.6) 2.75 0.46–16.53 0.269
 ≥2 3 (27.3) 22 (59.5) 1 Reference -
BMI (kg/m2)
 Mean 30.1±6.5 25.9±5.3 - - 0.033
 <30 5 (45.5) 32 (86.5) 1 Reference -
 ≥30 6 (54.5) 5 (13.5) 7.68 1.69–34.96 0.008
Diabetes mellitus
 No 8 (72.7) 31 (83.8) 1 Reference -
 Yes 3 (27.3) 6 (16.2) 1.94 0.40–9.49 0.42
Use of tamoxifen 2 (18.2) 1 (2.7) - - 0.092
Clinical presentation and characteristics
 Thickened endometrium on ultrasound 6 (54.5) 15 (40.5) 0.41
 Thickened endometrium on hysteroscopy 8 (72.7) 16 (43.2) 0.086
 D&C hysteroscopy done by trainee 7 (63.6) 23 (62.2) 0.93
 Initial histology with complex NEH 9 (81.8) 30 (81.1) 0.95
 Time to surgery (days) 87.7±31.0 73.9±36.7 0.26
 Use of progestin therapy before surgery 6 (54.5) 17 (45.9) 0.62

Values are presented as mean±standard deviation or number (%).

NEH, non-atypical endometrial hyperplasia; BMI, body mass index; D&C, dilation and curettage.