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. Author manuscript; available in PMC: 2017 Sep 1.
Published in final edited form as: Mod Pathol. 2016 Jun 3;29(9):1083–1094. doi: 10.1038/modpathol.2016.94

Pattern Classification of Endocervical Adenocarcinoma: Reproducibility and Review of Criteria

Joanne KL Rutgers 1, Andres Roma 2, Kay Park 3, Richard J Zaino 4, Abbey Johnson 5, Isabel Alvarado 6, Dean Daya 7, Golnar Rasty 8, Teri Longacre 9, Brigitte Ronnett 10, Elvio Silva 11
PMCID: PMC5506840  NIHMSID: NIHMS876270  PMID: 27255163

Abstract

Previously, our international team proposed a 3-tiered pattern classification (Pattern Classification) system for endocervical adenocarcinoma of the usual type that correlates with nodal disease and recurrence. Pattern Classification- A have well demarcated glands lacking destructive stromal invasion or lymphovascular invasion (lymphovascular invasion), Pattern Classification- B show localized, limited destructive invasion arising from A-type glands, and Pattern Classification- C have diffuse destructive stromal invasion, significant (filling a 4× field) confluence, or solid architecture. 24 Pattern Classification-A, 22 Pattern Classification-B, 38 Pattern Classification-C from the tumor set used in the original description were chosen using the reference diagnosis (reference diagnosis) originally established. 1 H&E slide per case was reviewed by 7 gynecologic pathologists, 4 from the original study. Kappa statistics were prepared, and cases with discrepancies reviewed. We found a majority agreement with reference diagnosis in 81% of cases, with complete or near complete (6 of 7) agreement in 50%. Overall concordance was 74%. Overall Kappa (agreement among pathologists) was .488 (moderate agreement). Pattern Classification- B has lowest kappa, and agreement is not improved by combining B+C. 6 of 7 reviewers had substantial agreement by weighted kappas (>.6), with one reviewer accounting for the majority of cases under or overcalled by 2 tiers. Confluence filling a 4× field, labyrinthine glands, or solid architecture accounted for undercalling other reference diagnosis-C cases. Missing a few individually infiltrative cells was the most common cause of undercalling reference diagnosis- B. Small foci of inflamed, loose or desmoplastic stroma lacking infiltrative tumor cells in reference diagnosis-A appeared to account for those cases up-graded to Pattern Classification-B. In summary, an overall concordance of 74% indicates that the criteria can be reproducibly applied by gynecologic pathologists. Further refinement of criteria should allow use of this powerful classification system to delineate which cervical adenocarcinomas can be safely treated conservatively.

Introduction

Endocervical adenocarcinoma accounts for 15–20% of cervical carcinoma, is increasing in incidence and often occurs in young women (1). Recently our international collaborative team proposed a novel histopathologic pattern classification system for endocervical adenocarcinoma that strongly correlates with the risk of nodal metastases and recurrence (2, 3). Pattern Classification classifies endocervical adenocarcinoma into one of three patterns based on the degree of destructive stromal invasion and lymphovascular invasion, regardless of the depth of invasion. Pattern Classification- A tumors have a non-destructive pattern of stromal invasion without lymphovascular invasion. Pattern Classification-B have early, small foci of destructive stromal invasion typically arising from Pattern Classification- A type glands, and may show lymphovascular invasion. Pattern Classification- C tumors have diffuse destructive invasion, confluent patterns of invasion filling a 4× field, or high architectural grade (solid growth), and frequent lymphovascular invasion. In the two sets of patients studied to date including over 400 patients (3, 4) Pattern Classification-A has not shown nodal metastases or recurrences, Pattern Classification- B has <5% risk of nodal metastases or recurrences, with those cases with positive nodes only found in tumors with lymphovascular invasion, and Pattern Classification- C captures those endocervical adenocarcinoma with a high rate, approximately 25%, of nodal metastases and recurrences. Pattern Classification- A and B have only been identified in FIGO stage I tumors, with an approximately equal distribution between FIGO stages IA and IB. In contrast, 15% of Pattern Classification- C tumors were stage II or higher. These studies suggest that Pattern Classification-A endocervical adenocarcinoma can be safely treated by excision with negative margins without nodal sampling, and likely do not need adjuvant therapy following surgery, Pattern Classification-C may need aggressive therapy, and treatment of Pattern Classification-B may be individualized by the presence or absence of lymphovascular invasion.

FIGO staging, the presence or absence of lymphovascular invasion, tumor size > 2 cm, and proportion of cervical wall thickness involved by tumor currently guide treatment of endocervical adenocarcinoma (5). FIGO staging applies to both squamous cell carcinoma and endocervical adenocarcinoma of the cervix. When surgical therapy is undertaken, the National Comprehensive Cancer Network (National Comprehensive Cancer Network) treatment guidelines mandate radical surgery with pelvic nodal dissection for stage IA1 with lymphovascular invasion and any tumor stage IA2 or higher, albeit with consideration of fertility sparing surgery (6). The staging is a hybrid of clinical examination and pathologic examination of the tumor, with clinically visible tumors staged IB, and those tumors only identified by microscopic examination are staged according to depth of invasion and horizontal extent of tumor. Thus, it is essential to accurately measure depth of invasion, which is intended to measure the depth of invasion from the basement membrane of the epithelium from which the invasion arose. It is often much easier for the pathologist to measure depth of invasion for squamous cell carcinoma; for instance if a small tongue of invasive disease arises from an endocervical gland involved by squamous carcinoma-in-situ (High grade squamous intraepithelial lesion, HSIL) only that group of cells will be measured, even when there is extensive HSIL. In contrast, determining which gland from which a small endocervical adenocarcinoma arose can be difficult, and for endocervical adenocarcinoma many suggest measuring depth of invasion from the basement membrane of the surface epithelium (8, 9), a method that renders depth of invasion equivalent to tumor thickness. This practice may upstage endocervical adenocarcinoma when the invasive component is admixed with endocervical adenocarcinoma in situ (adenocarcinoma in-situ).

Studies suggest that the Pattern Classification better identifies those tumors with a low to no risk of nodal metastases and recurrences than FIGO substaging (24). Application of Pattern Classification to clinical practice mandates that pathologists can use it reproducibly. Moderate agreement (mean pairwise kappa value of .51) was achieved in a prior study of 49 endocervical adenocarcinoma (4). The goal of this study is to further test the reproducibility in a larger study using a subset of the original cases (2, 3), and examine those cases with variability to clarify and illustrate the Pattern Classification criteria.

Materials and Methods

84 cases were chosen from the original group of 352 to include 24 cases of Pattern Classification-A, 22 Pattern Classification-B, and 38 Pattern Classification-C. Cases were chosen to achieve an approximate equal distribution of the 3 pattern classifications as in the original study, to include cases so that each criteria will need to be used, and to choose cases with the highest quality and representative single H&E slide. The reference diagnosis (reference diagnosis) was established by the original studies that included follow-up information, with arbitration of difficult cases by the first and senior authors, in the absence of a 'gold standard'. One H&E slide per case was distributed to seven gynecologic pathologists, 4 from the original group. There was a time delay of more than a year between the original review and this study, in an attempt to obviate bias amongst the original group. The reviewers were provided with reproductions of our second paper, including a table listing criteria (Table 1), clues to distinguish Pattern Classification-A from Pattern Classification-C (Table 2) (3) and additional hints for distinguishing Pattern Classification-A from Pattern Classification-B (Chart 1).

Table 1.

Histologic criteria of the three Pattern Classifications

Pattern
Classification		 Criteria
Pattern Classification-A

  • Well-demarcated glands with rounded contours, frequently forming groups

  • No destructive stromal invasion

  • No single cells or cell detachment

  • No lymphovascular invasion

  • Complex intraglandular growth acceptable, i.e., cribriform, papillae

  • Lack of solid growth, i.e., architecturally well-moderately differentiated

  • Depth of the tumor or relationship to large cervical vessels not relevant
Pattern Classification-B

  • Localized (limited, early) destructive stromal invasion arising from pattern A (well-demarcated) glands

  • Individual or small groups of tumor cells, separated from the rounded gland, often in a focally desmoplastic or inflamed stroma

  • Foci may be single, multiple, or linear at base of tumor

  • Lymphovascular invasion ±

  • Lack of solid growth, i.e., architecturally well-moderately differentiated
Pattern Classification-C

  • Diffuse destructive stromal invasion, characterized by diffusely infiltrative glands, with associated extensive desmoplastic response

  • Confluent growth filling a x4 field (5mm): glands, papillae (stroma only within papillae), or mucin lakes

  • Glands often angulated or with a canalicular pattern, with interspersed open glands

  • Solid, poorly differentiated component (architecturally high grade); nuclear grade is disregarded

  • Lymphovascular invasion ±
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Table 2.

Features to distinguish Pattern -A from Pattern-C

Pattern -A Pattern -C
Diffuse desmoplasia No Yes
Gland contours Round Angulated
Interspersed open glands* No Yes
Cluster or groups of glands Yes No
Canalicular patternƗ No No
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*

Open glands (incomplete glandular structures) describe glands with a discontinuous contour showing a break opening to the stroma, often associated with loosened stroma and/or inflammatory cells.

Ɨ

Canalicular pattern means labyrinthine, interconnected glands.

Statistical analysis included a 7 rater (overall) kappa, simple and weighted kappas and Spearman correlation coefficient for each reviewer, and Pattern Classification- A vs Pattern Classification- B+C kappa statistics, performed by a biostatistician using SAS version 9.2 (SAS Institute, Cary, North Carolina). Kappa of 0-.2 is slight, .2-.4 fair, 4-.6 moderate, .6-.8 substantial, and .8-1 almost perfect agreement (10). The proportions of diagnoses overinterpreted or underinterpreted, by one or two steps, relative to the reference diagnosis were determined (11).

After results and comments from the reviewers were collated, problematic cases, including those with majority disagreement with the reference diagnosis, those in which there were choices from all three categories, or those with a discrepancy of 2 tiers were re-reviewed by the first and senior authors .

Results

The majority of reviewers agreed with the reference diagnosis in 68 (81%) cases, with complete or near-complete (6/7) agreement in 50%. Examples of cases with excellent concordance are illustrated in Figure 1.

Figure 1.

Figure 1

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Cases with excellent reproducibility. (a) Low power of reference diagnosis- A correctly diagnosed by all 7 reviewers. This tumor has deep invasion lacking a stromal response, with lobulated groups of rounded glands, some adjacent to thick-walled vessels (original magnification ×2). (b) Another reference diagnosis-A correctly diagnosed by all reviewers. There is intraglandular complexity but the shape of each gland in relation to the stroma is rounded. There is no stromal response (original magnification ×4). (c) This reference diagnosis- B tumor was correctly diagnosed by 5 of 7 reviewers. There are small buds of infiltrating tumor cells, with slightly more abundant, eosinophilic cytoplasm arising from type-A glands. The focus of destructive invasion also shows an inflammatory infiltrate (original magnification ×20). (d) This reference diagnosis-B tumor was correctly diagnosed by 6 of 7 reviewers. There are a variety of patterns, with adenocarcinoma in-situ lower right, type A glands upper left, type B glands on the right, and lymphovascular invasion (arrow) (original magnification ×10). (e) Many Pattern Classification-C tumors can be easily recognized immediately by both diffuse destructive invasion with extensive desmoplasia and confluence; this tumor was diagnosed as Pattern Classification-C by all 7 reviewers (original magnification ×4). (f) Pattern Classification-C tumors may be smaller than a 4× field, but show an extensive desmoplastic response filling all of the stroma between the glands; this case was called Pattern Classification-C by 6 of 7 reviewers (original magnification ×4).

Correlation statistics calculated for Pattern Classification-A versus Pattern Classification-B versus Pattern Classification-C are provided for each of the reviewers; P1 to P4 were pathologists from the original group (Table 3). The simple kappa (non-ordinal test) showed substantial agreement by 3 reviewers, and moderate by 4. Weighted kappa showed substantial agreement by 6 reviewers (86%) and moderate agreement by 1 reviewer. Spearman’s correlation coefficient ranged from 0.581 to 0.853. The overall kappa of .49 represents moderate agreement. Overall kappa for Pattern Classification-A was .54, for Pattern Classification-B .32, and for Pattern Classification-C .59, indicating the greatest reproducibility for Pattern Classification-C. Agreement is more than can be expected from chance (p<0.0001) for each kappa. Combining Pattern Classification-B+C achieves the same kappa, .54 as for Pattern Classification-A alone.

Table 3.

Correlation Statistics

Pathologist # Simple Kappa Weighted Kappa Spearman
Correlation
1 0.710 0.781 0.853
2 0.681 0.737 0.808
3 0.549 0.522 0.581
4 0.529 0.602 0.717
5 0.704 0.779 0.867
6 0.595 0.640 0.700
7 0.535 0.635 0.719
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The distribution of scoring opportunities (Table 4) shows agreement with the reference diagnosis in 129 of 168 (77%) of reference diagnosis- A, 104 of 154 (68%) of reference diagnosis- B, and 205 of 266 (77%) of reference diagnosis- C, for an overall concordance of 74%. The 6 scoring opportunities of reference diagnosis-A called Pattern Classification-C were 6 cases all from one reviewer and represent 3% of scoring opportunities. The 16 scoring opportunities of reference diagnosis-C under-called by two steps were 6 cases under-called by various reviewers, representing 6% of reference diagnosis-C scoring opportunities. Thus, the scoring opportunity date indicate a 9% significant (2=tier) under- or over-interpretation rate.

Table 4.

Distribution of scoring opportunities by reference diagnosis

7 pathologists diagnoses of 84
cases
Pattern A
# (%)		 Pattern B
# (%)		 Pattern C
# (%)		 total
Reference Diagnosis A (24 cases) 129 (77) 33 (20) 6 (3) 168
Reference Diagnosis B (22 cases) 31 (20) 104 (68) 19 (12) 154
Reference Diagnosis C (38 cases) 16 (6) 45 (17) 205 (77) 266
total 180 179 229 588
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There were 16 cases in which the majority of pathologists did not agree with the reference diagnosis, including 4 reference diagnosis-A, 4 reference diagnosis-B, and 8 reference diagnosis-C. These cases and those cases misclassified by two steps underwent intensive review of the glass slides to determine potential reasons for discrepancy. The most common reason identified for undercalling reference diagnosis-C was to not apply the criterion of confluent tumor filling a 4× field (Figure 2a). The term confluent has been used for different patterns over time, but in this context indicates a lack of stroma separating the malignant glands, or confluence of tumor papillae, with stroma only within the papillary cores. These confluence criteria are not intended to apply to the exophytic papillary component (3), but this distinction proved difficult in several cases (Figure 2b-c). A canalicular, or labyrinthine growth pattern is a criterion for Pattern Classification- C even if the tumor is smaller than a 4× field (Figure 2d).

Figure 2.

Figure 2

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Cases of reference diagnosis-C without full concurrence. (a) Confluent growth filling a low power field (4×) is seen in this reference diagnosis-C; this case was called Pattern Classification-B by 5 reviewers, and Pattern Classification-C by 2 (original magnification ×4). (b) This reference diagnosis-C case was called Pattern Classification-B by 4 and Pattern Classification-C by 3 reviewers. There is both confluence of glands and papillae at the luminal aspect (left), as well as an inflamed, desmoplastic stromal response in the lower right (original magnification ×4). (c) This polypoid tumor with confluence only towards the luminal portion of the tumor, a reference diagnosis-C due to confluence filling a 4× field was called Pattern Classification-C by only 3 reviewers (original magnification ×2). Further experience with exophytic tumors is necessary. (d) This reference diagnosis-C tumor was called Pattern Classification-A by 2, Pattern Classification-B by 3, and Pattern Classification-C by 2 reviewers, respectively. This small tumor shows a labyrinthine pattern and a spindled, desmoplastic and inflamed stroma (original magnification ×10).

Non-recurrent issues were also identified. One reference diagnosis-C case with subtle diffuse infiltration but without a significant desmoplastic response nevertheless had extensive lymphovascular invasion, lack of clustering of glands, and focal angulated glands (Figure 3a-b). The one reference diagnosis-C case with a solid architecture included in this study proved controversial, with only one reviewer classifying as Pattern Classification-C and 6 as Pattern Classification-A (Figure 3c). When a linear area of destructive invasion exceeds a 4× field, it is classified as Pattern Classification- C; not applying these criteria resulted in under calling a few reference diagnosis-C cases (Figure 3d). A final factor identified was difficulty in interpretation due to a partially obscuring inflammatory infiltrate.

Figure 3.

Figure 3

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Additional cases of reference diagnosis-C without full concurrence. (a) reference diagnosis-C tumor called Pattern Classification-A by 1, Pattern Classification-B by 3, and Pattern Classification-C by 3 reviewers, respectively. The tumor demonstrates small, often angulated glands irregularly sprinkled in the stroma lacking a lobulated architecture (original magnification ×4). (b) The same tumor as in 3a with lymphovascular invasion (arrow) and angulated gland (original magnification ×20). (c) reference diagnosis-C case classified as Pattern Classification-C by 1 and Pattern Classification-A by 6 reviewers. The tumor has a predominantly solid growth pattern, meeting criteria for solid growth in Pattern Classification-C, despite the rounded interface of the tumor nests with the stroma (original magnification ×10). (c) reference diagnosis- C due to a linear area of destructive invasion at the base of the tumor exceeding a 4× field (> 5 mm). This case was called Pattern Classification-B by 4 and Pattern Classification-C by 3 reviewers, respectively (original magnification ×4).

Early destructive invasion in a Pattern Classification-B can be focal, multifocal or a linear area at the advancing front of the tumor measuring less than a 4× field, i.e. <5 mm. Missing a small focus of individual cells or small detached fragments of adenocarcinoma cells appeared to be the cause of the 20% of scoring opportunities in which reference diagnosis-B was classified as Pattern Classification-A.

Six reference diagnosis-A cases were called Pattern Classification-C by one reviewer; one possible reason is that the lobulation characteristic of Pattern Classification-A may be subtle (Figure 4a). Another reference diagnosis-A tumor with branched, irregularly sized glands, but overall rounded shape also proved difficult (Figure 4b). reference diagnosis-A cases with minor foci of inflamed, loose or desmoplastic stroma without infiltrative tumor cells accounted for up-grading to Pattern Classification-B in a few cases (Figure 4c). The intended meaning of the criterion of a desmoplastic response is spindled, loose stroma that contains individual or small detached groups of adenocarcinoma cells. Thus, Pattern Classification-A tumors may show minor, focal desmoplasia, loosening of the stroma, or an inflammatory response so long as these foci do not contain individual or small groups of infiltrative tumor cells; this distinction requires a high-power examination.

Figure 4.

Figure 4

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Reference diagnosis-A cases without full concurrence. (a) reference diagnosis-A tumor called Pattern Classification-A by 2, Pattern Classification-B by 4 and Pattern Classification-C by 1 reviewer, respectively. At low power a lobulated architecture by rounded glands can be appreciated. There is crowding and surface inflammation but no individual infiltrative cells were present (original magnification ×4). (b) reference diagnosis- A tumor called Pattern Classification-A by 5, Pattern Classification-B by 1, and Pattern Classification-C by 1 reviewer, respectively. There are deeply invasive glands adjacent to thick-walled vessels and small nerve twigs. Although the glands are branched they are generally rounded (original magnification ×10). (c) This reference diagnosis-A case was called Pattern Classification-A by 3 and Pattern Classification-B by 4 reviewers. Loosening may be present focally surrounding Pattern A type glands, but without infiltrative individual or small groups of tumor cells within the loosened stroma (original magnification ×10).

The comments were collated for recurrent issues. One reviewer in particular entertained adenocarcinoma in-situ rather than an invasive tumor in 11 reference diagnosis-A cases, whereas the other reviewers predominantly classified these cases as Pattern Classification-A. Several reviewers indicated that in practice, in particular for Pattern Classification-B cases, they would have ordered additional levels. There was considerable controversy about the application of confluent growth only when located in the polypoid or luminal aspect of the tumor. A villoglandular pattern was suggested by at least one reviewer in 5 cases, including 1 with reference diagnosis of A, 1 B, and 3 C. Other comments related to the precise cut-off between focal/limited versus diffuse invasion distinguish Pattern Classification-B from Pattern Classification-C; thus these comments indicate issues on the application of the quantitative criteria.

Discussion

There are two competing views of endocervical adenocarcinoma, first that it has a more aggressive and unpredictable behavior than the more common squamous cell carcinoma (12, 13). In addition, although the majority of endocervical adenocarcinoma are related to high-risk HPV, rare non-HPV related subtypes including clear cell, minimal deviation, and gastric (1418) can be difficult to recognize and are aggressive. Thus, in practice there is a tendency to accept radical surgery and nodal dissection even for FIGO stage IA1 tumors lacking lymphovascular invasion (19). Alternatively, the opposing viewpoint is that endocervical adenocarcinoma do not have a worsened prognosis compared to squamous cell carcinoma (19), and that identifying reproducible criteria for which patients can be treated less aggressively is urgently needed (2022). Studies suggest that Pattern Classification provides a safe and reproducible means to predict the risks of nodal disease and recurrence for endocervical adenocarcinoma (24).

The gynecologic pathologists in our study were able to correctly identify 77% of reference diagnosis-C, which is in agreement with our initial experience that most Pattern Classification-C tumors can be easily recognized by the irregular infiltrative glands associated with an extensive desmoplastic response. The recognition of labyrinthine glands, solid architecture, or confluence especially in the application of one of the size-related criteria proved somewhat more difficult. The criterion of confluent growth filling a 4× field, composed of glands, papillae (stroma only within papillae), or mucin lakes containing tumor cells can be viewed as a means to detect Pattern Classification-C tumors that may lack an obvious desmoplastic response. The other quantitative criterion for Pattern Classification-C, a linear focus of destructive invasion at the base or advancing front of the tumor filling the diameter of a 4× field (> 5mm) is intended to provide a quantitative guideline for the amount of destructive invasion to distinguish Pattern Classification- B from Pattern Classification-C, although further study of the size-related criteria may be necessary. Additional studies on the individual criteria for Pattern Classification-C are underway to allow refinement of the criteria.

Pattern Classification-B tumors describe those endocervical adenocarcinoma that would be Pattern Classification- A except for early, focal destructive stromal invasion that may be single, multifocal, or linear < 5 mm at the tumor base, and/or lymphovascular invasion. The current study found the least degree of reproducibility for reference diagnosis- B tumors. In 20% of scoring opportunities they were underclassified as Pattern Classification-A, although it should be noted that this may be due in part to the study design, in which only a single H&E slide was available for review. In cases lacking lymphovascular invasion, this would not be expected to affect outcome, however lymphovascular invasion was overlooked in a few cases, making the point that careful screening for lymphovascular invasion is essential.

Pattern Classification-A shows rounded glands lined by columnar cells with pseudostratified cells and no or only focal stromal response, with no cellular budding or individual cells in the stroma. The presence of lymphovascular invasion must be searched for particularly at the edges of the tumor as lymphovascular invasion disqualifies a tumor from Pattern Classification-A. It is important to emphasize that Pattern Classification-A tumors may show deep invasion, and on a biopsy, excisional specimen, or cone biopsy, a definitive Pattern Classification-A or Pattern Classification-B cannot be assigned when the margin is positive. Additionally, tumors with a predominant Pattern Classification-A pattern but with associated desmoplasia, inflammation, localized edema, or broken glands need to be carefully examined, perhaps with multiple levels, to detect any individual or small groups of infiltrative cells, and especially any lymphovascular invasion that would exclude Pattern Classification-A.

The differential diagnosis of a Pattern Classification-A tumor includes adenocarcinoma in-situ. The distinction between adenocarcinoma in-situ and endocervical adenocarcinoma is difficult and can only be made in 80% of cases (23, 24). Standard criteria to distinguish invasive endocervical adenocarcinoma from adenocarcinoma in-situ include fragmented glands with finger-like projections into the stroma, stromal response(25), lymphovascular invasion (9), extension of the neoplastic glands beyond the deepest normal endocervical crypt, glands adjacent to thick walled vessels (26) and significant complexity of glands or papillae (8, 24, 27). It should be noted that all of the cases in the current study were originally diagnosed as invasive according to these standard criteria and treated as such. We acknowledge that use of those criteria that do not involve destructive stromal invasive patterns may result in some in-situ lesions to be called invasive. We would contend that one of the strengths of the Pattern Classification system is that it obviates these difficulties, as such tumors would be termed either in-situ or Pattern Classification- A, and could be treated similarly.

Most prior studies on conservative therapy focused on very small endocervical adenocarcinoma, termed early invasive (28)or microinvasive. Some use the term microinvasive as equivalent to stage IA1, others for stages IA1 and IA2 regardless of lymphovascular invasion (29), and both Society of Gynecologic Oncology (30) and National Comprehensive Cancer Network as stage IA1 lacking lymphovascular invasion. The rate of nodal disease in microinvasive disease is low, with rates of < 1% (6) to 1.5% (31). A review of SEER data including 560 cases found no significant differences between stages IA1 and IA2 endocervical adenocarcinoma in the frequency of positive lymph nodes, recurrence, or death (32). One contributor to the similar outcome of stages IA1 and IA2 disease may be the problems associated with the pathological measurement of depth of invasion. This is more problematic for endocervical adenocarcinoma than cervical squamous cell carcinoma as the measured tumor thickness may be used as a substitute for depth of invasion, as previously discussed; this approach is purported to be safer, but actually results in overstaging tumors with an extensive adenocarcinoma in-situ component and only a small invasive component. It may be that measuring the "Depth of Destructive Invasion" (DODI) and carefully noting the presence or absence of lymphovascular invasion would allow translation of the pattern classification used in the current study into clinical practice. Pattern Classification-A endocervical adenocarcinoma have a DODI of 0, Pattern Classification-B a DODI < 3 mm and horizontal extent of DODI < 7 mm, and most but not all Pattern Classification-C show more extensive DODI. Although no patient with a Pattern Classification-A endocervical adenocarcinoma reported to date has been found to have nodal metastases, some tumors that would qualify as Pattern Classification-A (including some initially interpreted as adenocarcinoma in-situ) have had ovarian metastases (33, 34). It may be that Pattern Classification-A tumors should be treated similarly to adenocarcinoma in-situ (35). In addition, criteria for adjuvant therapy following surgery often include a size > 2 cm (36), yet some Pattern Classification-A tumors are > 2 cm in size; we suggest that pattern classification could also guide the need for adjuvant therapy.

The pattern of invasion affects prognosis in other organs and other histologic subtypes of carcinoma. Intestinal-type mucinous carcinomas of the ovary with expansile or confluent glandular invasion have a significantly better prognosis compared to those with destructive or infiltrative stromal invasion (37, 38). We had originally discussed whether a two-tiered system of expansile versus destructive stromal invasion could be applied to endocervical adenocarcinoma, as the prognostic implication may be similar. The term expansile, however did not seem to be an adequate descriptor for Pattern Classification-A. A destructive stromal invasive pattern also is associated with a worsened prognosis for squamous cell carcinoma of the vulva and cervix (39, 40). Although our studies have focused only on endocervical adenocarcinoma, it may be that similar tumor mechanisms operate for multiple tumor types. Additionally, our findings confirm many other studies indicating that lymphovascular invasion is an indicator of poor prognosis for endocervical adenocarcinoma (20, 41).

The current reproducibility study found an overall concordance of 74%, and substantial agreement with the reference diagnosis was achieved by 86% of the reviewers. Two studies, including the current, have now shown moderate to substantial reproducibility (4); this level of concordance and reproducibility is in the same range as other pathology studies for well-established diagnostic categories The study by Paquette et al suggested that reproducibility is improved by grouping Pattern Classification-B and –C, and the authors suggested that a 2-tier system may be preferable (4). In the current study, however, the reproducibility of Pattern Classification-A vs Pattern Classification-B + C only achieved the same kappa statistic as that for Pattern Classification-A alone, thus we did not find improved reproducibility with a 2-tier system. Additionally we believe the middle category of Pattern Classification-B improves the clinical utility, as Pattern Classification-B tumors without lymphovascular invasion do very well and even Pattern Classification-B tumors with lymphovascular invasion do not behave as aggressively as Pattern Classification-C tumors. Thus, the 3-tiered pattern classification is recommended.

In summary, the current reproducibility study found overall substantial agreement. Close attention to the presence or absence of lymphovascular invasion, and examination of the entire tumor when initial sections show Pattern Classification-A or Pattern Classification-B, is essential to proper pattern classification. Tumors with overall features of Pattern Classification-A but with small foci of desmoplasia, stromal loosening, or inflammation should be examined carefully at high power, and perhaps with multiple levels to rule out individual or small groups of tumor cells or lymphovascular invasion that would indicate a Pattern Classification-B. The reproducibility of Pattern Classification-C is the highest of the three patterns as diffuse destructive invasion can usually be easily recognized, although further studies on confluence, size criteria, solid growth patterns, and cases that are less than classic may be necessary. We are considering development of a web page with multiple drawing and illustrations of the three patterns. Additional studies on use of DODI, application to endocervical adenocarcinoma variants, and clinical aspects should allow use of this powerful classification system to delineate which endocervical adenocarcinoma can be safely treated conservatively.

Supplementary Material

Chart 1

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