Hyperplasia without atypia

Hyperplasia without atypia encompasses the older terms simple hyperplasia and complex hyperplasia without atypia. The endometrium may have dilated glands with some outpouching and abundant endometrial stroma ( Fig. 32.2 ). Alternatively, the glands may demonstrate crowding with very little endometrial stroma, a very complex gland pattern, and outpouching formations but no cytologic atypia ( Fig. 32.3 ).

Benign simple hyperplasia.

(From Kurman RJ, Kaminski PF, Norris HJ. Behavior of endometrial hyperplasia: a long-term study of “untreated” hyperplasias in 170 patients. Cancer. 1985;56:403.)

Complex hyperplasia characterized by crowded back-to-back glands with complex outlines.

(From Kurman RJ, Kaminski PF, Norris HJ. Behavior of endometrial hyperplasia: a long-term study of “untreated” hyperplasias in 170 patients. Cancer. 1985;56:403.)

Hyperplasia with atypia

Hyperplasia with atypia refers to hyperplasias that contain glands with cytologic atypia and are considered premalignant. There is an increase in the nuclear/cytoplasmic ratio with irregularity in the size and shape of the nuclei ( Fig. 32.4 ). The term complex atypical hyperplasia can also be used, as well as the term endometrial intraepithelial neoplasia (EIN ).

Severely atypical hyperplasia (complex) of the endometrium with marked irregularity of nuclei (original magnification ×720).

(From Welch WR, Scully RE: Hum Pathol. 1977;8:503, 1977.)

Natural history

The rate at which endometrial hyperplasia progresses to endometrial carcinoma has not been accurately determined because many of the studies have been retrospective and were based on the 1994 classification of endometrial hyperplasia. Kurman and associates studied 170 patients with endometrial hyperplasia diagnosed by D&C at least 1 year before hysterectomy. Overall, complex atypical hyperplasias had the highest risk of progression to carcinoma. Simple hyperplasia had a 1% rate of progression to cancer, complex hyperplasia without atypia had a 3% rate of progression to cancer, and complex atypical hyperplasia had a 29% rate of progression to cancer. Lacey found up to 27.5% cumulative risk of endometrial cancer in women with atypical hyperplasia, compared with a 4.6% cumulative risk of endometrial cancer in women with nonatypical hyperplasia ( ). In addition to possible progression to cancer, 42% of women who undergo hysterectomy for complex atypical hyperplasia have a concurrent endometrial cancer in their hysterectomy specimen. This high rate of cancer suggests that complex atypical hyperplasia often may be present with low-grade endometrial cancer and that endometrial sampling may not identify an endometrial cancer when admixed with a complex atypical hyperplasia. Clearly there is a spectrum of histologic types that make a definitive diagnosis of atypical hyperplasia/EIN difficult, and the clinician must be aware of this fact when planning management strategies.

Diagnosis and endometrial sampling

Abnormal vaginal bleeding is the most common symptom of endometrial hyperplasia. In younger patients, hyperplasia may develop during anovulatory cycles and may be detected after prolonged periods of oligomenorrhea or amenorrhea. It can occur at any time during the reproductive years but is most common with abnormal bleeding in the perimenopausal period. Premenopausal women with irregular vaginal bleeding and postmenopausal women with any vaginal bleeding should be evaluated with an office endometrial sampling or a D&C. The office sampling instruments, such as a thin plastic Pipelle, are introduced through the cervical os into the endometrial cavity and can provide sufficient tissue for accurate histologic diagnoses. Studies have had conflicting results regarding whether a D&C provides more sensitivity in detecting cancer compared with an office Pipelle procedure. Importantly, both modalities still miss a significant number of cancers. Suh-Bergmann reported that preoperative D&C lowered the risk of an unrecognized cancer in women with complex atypical hyperplasia from 45% to 30%.

Transvaginal ultrasonography has been evaluated as an adjunct for the diagnosis of endometrial hyperplasia and cancer. In postmenopausal women with any vaginal bleeding, Gull and colleagues found that an endometrial stripe of less than 4 mm had a 100% negative predictive value. A finding of endometrial thickness less than 4 mm is a reasonable predictor of lack of endometrial pathologic changes, even in a postmenopausal patient with bleeding; however, persistent vaginal bleeding should lead to endometrial sampling regardless of the ultrasound findings. In addition, measurement of endometrial stripe in a premenopausal woman is not clinically useful.

Management

The therapy employed for endometrial hyperplasia depends on the patient’s age, desire for future childbearing, comorbidities, and the type of hyperplasia. For younger women with benign endometrial hyperplasia, the risk of developing endometrial cancer is extremely low and patients can be treated with progestins or combination oral contraceptive agents. For patients with hyperplasia with atypia/EIN, the risk of developing endometrial cancer may be close to 30%.

For patients who do not desire future childbearing, hysterectomy is the definitive treatment. Oophorectomy can be considered, but long-term risks and benefits should be discussed with the patient. Because of the 40% risk of a concomitant cancer, many surgeons send the uterus for frozen section evaluation intraoperatively, with staging as needed.

Women who desire preservation of childbearing function or who are poor surgical candidates are treated with progestin therapy, usually megestrol acetate 40 mg four times a day. A common alternative is the use of a progestin-eluting intrauterine device (IUD), which has the benefit of local delivery to the endometrium with minimal systemic side effects and which has an overall response rate for women with complex atypical hyperplasia of 80% ( ). One study found a higher rate of regression in patients treated with a progestin-eluting IUD compared with those treated with oral progestins (Gallos, 2013). Patients require long-term follow-up and periodic sampling. In these patients the risk factors that led to the development of hyperplasia with atypia/EIN are likely to remain. In those for whom progestin therapy is ineffective, hysterectomy should be considered.

Symptoms, signs, and diagnosis

Postmenopausal bleeding, abnormal premenopausal bleeding, and perimenopausal bleeding are the primary symptoms of endometrial carcinoma.

The diagnosis of endometrial carcinoma is established by histologic examination of the endometrium. Initial diagnosis often can be made on an outpatient basis, with an office endometrial biopsy. A routine cytologic examination (Papanicolaou [Pap] smear) from the exocervix, which screens for cervical neoplasia, detects endometrial carcinoma in only approximately 50% of the cases.

If adequate outpatient evaluation cannot be obtained or if the diagnosis or cause of the abnormal bleeding is not clear from the tissue obtained, a hysteroscopy and D&C should be performed. If cervical involvement is suspected, the endocervix should be sampled first, followed by hysteroscopy to visualize the endometrial cavity and then a complete uterine curettage.

Histologic types

The various types are listed in Box 32.2 . Fig. 32.5 illustrates typical adenocarcinomas of the endometrium and demonstrates varying degrees of differentiation (G1, well differentiated; G2, intermediate differentiation; G3, poorly differentiated). Grading is determined by the percentage of solid components found in the tumor: Grade 1 has less than 5% solid components, grade 2 has 6% to 50% solid components, and grade 3 has more than 50% solid components.

A, Well-differentiated adenocarcinoma of the endometrium. The glands are confluent. (Original magnification ×130.) B, Moderately differentiated adenocarcinoma of the endometrium. The glands are more solid, but some lumens remain. (Original magnification ×100.) C, Poorly differentiated adenocarcinoma of the endometrium. The epithelium shows solid proliferation with only a rare lumen. (Original magnification ×100.)

(From Kurman RJ, Norris HJ. Endometrial neoplasia: hyperplasia and carcinoma. In Blaustein A, ed. Pathology of the Female Genital Tract. 2nd ed. New York: Springer-Verlag; 1982.)

Squamous epithelium commonly coexists with the glandular elements of endometrial carcinoma. Previously the term adeno-acanthoma was used to describe a well-differentiated tumor and adenosquamous carcinoma to describe a poorly differentiated carcinoma with squamous elements. More recently, the term adenocarcinoma with squamous elements has been used with a description of the degree of differentiation of both the glandular and squamous components. Zaino and colleagues, in a Gynecologic Oncology Group (GOG) study of 456 cases with squamous elements, showed that prognosis was related to the grade of the glandular component and the degree of myometrial invasion. They suggested the term adenocarcinoma with squamous differentiation, and this has been generally adopted.

Uterine serous carcinomas are a highly virulent and a less common histologic subtype of endometrial carcinomas (5% to 10%). These tumors histologically resemble papillary serous carcinomas of the ovary ( Fig. 32.6 ). Slomovitz and associates evaluated 129 patients with uterine serous carcinoma (USC) and found a high rate of extrauterine disease even in cases without myometrial invasion. They recommend a thorough operative staging (see the next section) with all cases of these tumors because of the high risk of extrauterine disease even in cases where the tumor is admixed with other histologic types (endometrial and/or clear cell).

Serous carcinoma characterized by a complex papillary architecture resembling serous carcinoma of the ovary.

(From Kurman RJ. Blaustein’s Pathology of the Female Genital Tract. 3rd ed. New York: Springer-Verlag; 1987.)

Clear cell carcinomas of the endometrium are less common (<5%). Histologically they resemble clear cell adenocarcinomas of the ovary, cervix, and vagina; they tend to develop in postmenopausal women and carry a prognosis much worse than typical endometrial adenocarcinomas. Survival rates of 39% to 55% have been reported, much less than the 65% or better usually recorded for endometrial carcinoma. When diagnosed at an early stage, however, prognosis can be favorable. Armbruster and colleagues reviewed 112 cases of clinical early stage clear cell cancer of the uterus. Patient with pure clear cell or mixed tumors with more than 50% clear cell type had an overall survival approaching 10 years. Women older than 70 years had the worst prognosis

Staging

In 2009, a revised International Federation of Gynecology and Obstetrics (FIGO) surgical staging classification was introduced in which the staging was modified to better define clinically relevant risk strata based on the FIGO Annual Report and other supporting publication ( Table 32.1 ).

Prognostic factors

Many variables affect the behavior of endometrial adenocarcinomas. These variables can be divided into clinical and pathologic factors. The clinical determinants are patient age at diagnosis, race, and clinical tumor stage. The pathologic determinants are tumor grade, histologic type, tumor size, depth of myometrial invasion, microscopic involvement of vascular spaces in the uterus by tumor, and spread of tumor outside the uterus to the retroperitoneal lymph nodes, peritoneal cavity, or uterine adnexa.

Pathologic factors

Tumor stage is a well-recognized prognostic factor for endometrial carcinoma ( Table 32.2 ). Fortunately, most cases are diagnosed in stage I, which provides a favorable prognosis.

TABLE 32.2

Carcinoma of the Corpus Uteri: Patients Treated in 1990-1992: Survival by 1988 FIGO Surgical Stage, N = 5562

Modified from Pecorelli S, Creasman WT, Pettersson F, et al. FIGO annual report on the results of treatment in gynaecological cancer. Vol 23. Milano, Italy. J Epidemiol Biostat. 1998.

Stage	5-Year Survival Rate
IA	90.9%
IB	88.2%
IC	81.0%
II	71.6%
III	51.4%
IV	8.9%

FIGO, International Federation of Gynecology and Obstetrics.

The histologic grade of the tumor is a major determinant of prognosis. Endometrial carcinomas are divided into three grades: grade 1, well differentiated; grade 2, intermediate differentiation; and grade 3, poorly differentiated. Fig. 32.7 shows the survival of 895 patients studied by the GOG that relates endometrial carcinoma survival to tumor grade and demonstrates the worsening of prognosis with advancing grade.

Recurrence-free interval by histologic grade.

(Redrawn from Morrow CP, Bundy BN, Kurman RJ, et al. Relationship between surgical-pathologic risk factors and outcome in clinical stage I and II carcinoma of the endometrium: a Gynecologic Oncology Group study. Gynecol Oncol. 1991;40:55.)

The histologic type of the endometrial carcinoma is also related to prognosis, with the best prognosis associated with endometrioid adenocarcinomas, in particular well-differentiated tumors. Approximately 80% of all endometrial carcinomas fall into the favorable category. Histologic types that carry poor prognoses are serous carcinoma, clear cell carcinoma, carcinosarcoma, and poorly differentiated carcinoma with or without squamous elements.

The degree of myometrial invasion correlates with the risk of tumor spread outside the uterus, but the higher-grade and higher-stage tumors in general are more likely to have deep myometrial penetration ( Fig. 32.8 ). In a study by Schink and colleagues, tumor size greater than 2 cm was also found to be prognostic. Only 4% of those with tumors 2 cm or less had lymph node metastases. The rate increased to 15% for those with tumors greater than 2 cm and to 35% when the entire endometrial cavity was involved. Table 32.3 summarizes the clinical and pathologic factors affecting outcomes in patients with early-stage tumors. Peritoneal cytologic characteristics have been studied as a prognostic factor, and the results are conflicting. In a study of 567 surgical stage I cases, Turner and associates found that positive peritoneal cytologic evaluation was an independent prognostic factor. In contrast, Grimshaw and coworkers evaluated 322 clinical stage I cases and found that positive peritoneal cytology was an adverse prognostic factor, but they did not find it to be an independent risk factor when other variables were considered. In 2018 Seagle and colleagues evaluated 16,851 women though the National Cancer Database and found that positive washings were associated with decreased survival among women with stage I/II endometrial cancer, including those with low-grade tumors. In addition, treatment of women with positive cytology with adjuvant chemotherapy was associated with increased survival. Although these large database studies have limitations, this is something to consider. In the 2009 revised FIGO surgical staging, positive cytology is no longer classified as stage IIIA.

A, Technique for intraoperative assessment of the depth of myometrial invasion. B, Cross section of uterine wall demonstrating superficial myometrial invasion. Arrow shows the tumor–myometrial junction.

(From Doering DL, Barnhill DR, Weiser EB, et al. Intraoperative evaluation of depth of myometrial invasion in stage I endometrial adenocarcinoma. Obstet Gynecol. 1989;74:930.)

TABLE 32.3

Surgical Stage I and II Tumors: The Proportional Hazards Modeling of Relative Survival Time

Modified from Zaino RJ, Kurman RJ, Diana KL, Morrow CP. Pathologic models to predict outcome for women with endometrial adenocarcinoma. Cancer. 1996;77:1115.

Variable	Regression Coefficient	Relative Risk	Significance Test * ( P value)
Endometrioid
Grade 1	—	1.0	—
Grade 2	0.28	1.3	2.7 (.1)
Grade 3	0.56	1.8
Endometrioid with squamous differentiation			0.1 (.7)
Grade 1	0.20	1.2
Grade 2	–0.01	1.0	0.3 (.6)
Grade 3	0.22	0.8
Villoglandular			2.2 (.1)
Grade 1	–4.91	0.01
Grade 2	–0.59	0.5	10.4 (.001)
Grade 3	3.73	41.9
M YOMETRIAL INVASION
Endometrium only	—	1.0
Superficial	0.39	0.5
Middle	1.20	3.3	19.6 (.0002)
Deep	1.53	4.6
Age	0.17	—
Age	–0.000837	—	20.7 (.0001)
45 (arbitrary reference)	—	1.0
55	0.85	2.3
65	1.52	4.6
75	2.03	7.6
Vascular space involvement	0.32	1.4	1.2 (.3)

P value for grading is for overall grade within cell type.

* Wald x ² test.

Patterns of spread of endometrial carcinoma.

Plentl and Friedman noted four major channels of lymphatic drainage from the uterus that serve as sites for extrauterine spread of tumor: (1) a small lymphatic branch along the round ligament that runs to the inguinal femoral nodes; (2) branches from the tubal and (3) ovarian pedicles (infundibulopelvic ligaments), which are large lymphatics that drain into the paraaortic nodes; and (4) the broad ligament lymphatics that drain directly to the pelvic nodes. The pelvic and paraaortic node drainage sites (2, 3, and 4) are the most important clinically. In addition, direct peritoneal spread of tumor can occur through the uterine wall or via the lumen of the fallopian tube. Therefore the clinician must assess the retroperitoneal nodes, the peritoneal cavity, and the uterine adnexa for the spread of endometrial carcinoma ( Fig. 32.9 ).

Spread of endometrial carcinoma. The major pathways of tumor spread are illustrated (see text).

Extensive studies by the GOG have elucidated both the frequency of lymph node metastases in endometrial carcinoma and the pathologic factors that modify this risk in stage I disease. Tumor grade, size of the uterus, and degree of myometrial invasion were studied. Table 32.4 illustrates the frequency of lymph node metastases according to tumor grade and depth of myometrial invasion. The frequency of nodal involvement becomes much greater with high-grade tumors and with greater depth of myometrial invasion. The risk of lymph node involvement appears to be negligible for endometrial carcinoma involving only the endometrium. With invasion of the inner third of the myometrium, there is minimal risk of node involvement for grade 1 and 2 cases. If the outer third of the myometrium is involved, the risk of nodal metastases is greatly increased. These data emphasize the importance of myometrial invasion and tumor spread, providing the basis for the FIGO Surgical Staging System. Tables 32.5 and 32.6 summarize the risk of nodal metastases based on the GOG studies published by Creasman and colleagues. Mariani and colleagues at the Mayo Clinic found that tumor size could also be incorporated into a staging paradigm to identify patients at highest risk for nodal spread. They found that in grade 1 and 2 tumors with less than 50% invasion and tumor size less than 2 cm, the risk of lymph node involvement was virtually zero ( ).

TABLE 32.4

Grade, Depth of Myometrial Invasion, and Node Metastasis—Stage I

Adapted from Creasman WT, Morrow CP, Bundy BN, et al. Surgical pathologic spread patterns of endometrial cancer. Cancer 1987;60:2035.

Depth of Invasion	G1 n = 180	G2 n = 288	G3 n = 153
P ELVIC
Endometrium only (n = 86)	0 (0%)	1 (3%)	0 (0%)
Inner (n = 281)	3 (3%)	7 (5%)	5 (9%)
Middle (n = 115)	0 (0%)	6 (9%)	1 (4%)
Deep (n = 139)	2 (11%)	11 (19%)	23 (34%)
Aortic
Endometrium only (n = 86)	0 (0%)	1 (3%)	0 (0%)
Inner (n = 281)	1 (1%)	5 (4%)	2 (4%)
Middle (n = 115)	1 (5%)	0 (0%)	0 (0%)
Deep (n = 139)	1 (6%)	8 (14%)	15 (23%)

G, grade.

TABLE 32.5

FIGO Staging and Nodal Metastasis

From Creasman WT, Morrow CP, Bundy BN, et al. Surgical pathologic spread patterns of endometrial cancer. Cancer. 1987;60:2035.

	Metastasis
Staging	Pelvic	Aortic
IA G1 (n = 101)	2 (2%)	0 (0%)
G2 (n = 169)	13 (8%)	6 (4%)
G3 (n = 76)	8 (11%)	5 (7%)
IB G1 (n = 79)	3 (4%)	3 (4%)
G2 (n = 119)	12 (10%)	8 (7%)
G3 (n = 77)	20 (26%)	12 (16%)

FIGO, International Federation of Gynecology and Oncology; G, grade.

TABLE 32.6

Risk Factors for Nodal Metastases—Stage I

Adapted from Creasman WT, Morrow CP, Bundy BN, et al. Surgical pathologic spread patterns of endometrial cancer. Cancer. 1987;60: 2035.

Factor	Pelvic	Aortic
Low risk Grade 1 Endometrium only No intraperitoneal spread	0/44 (0%)	0/44 (0%)
Moderate risk Grade 2 or 3 Invasion to middle third	15/268 (6%)	6/268 (2%)
High risk Invasion to outer third	21/116 (18)	17/118 (15%)

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