Thursday, March 7, 2019

Breast Cancer Treatment (PDQ®) 1/3 —Health Professional Version - National Cancer Institute

Breast Cancer Treatment (PDQ®)—Health Professional Version - National Cancer Institute

National Cancer Institute



Breast Cancer Treatment (PDQ®)–Health Professional Version

General Information About Breast Cancer

This summary discusses primary epithelial breast cancers in women. The breast is rarely affected by other tumors such as lymphomas, sarcomas, or melanomas. Refer to the following PDQ summaries for more information on these cancer types:
Breast cancer also affects men and children and may occur during pregnancy, although it is rare in these populations. Refer to the following PDQ summaries for more information:

Incidence and Mortality

Estimated new cases and deaths from breast cancer (women only) in the United States in 2019:[1]
  • New cases: 268,600.
  • Deaths: 41,760.
Breast cancer is the most common noncutaneous cancer in U.S. women, with an estimated 62,930 cases of in situ disease and 268,600 cases of invasive disease in 2019.[1] Thus, fewer than one of six women diagnosed with breast cancer die of the disease. By comparison, it is estimated that about 66,020 American women will die of lung cancer in 2019.[1] Men account for 1% of breast cancer cases and breast cancer deaths (refer to the Special Populations section in the PDQ summary on Breast Cancer Screening for more information).
Widespread adoption of screening increases breast cancer incidence in a given population and changes the characteristics of cancers detected, with increased incidence of lower-risk cancers, premalignant lesions, and ductal carcinoma in situ (DCIS). (Refer to the Ductal carcinoma in situ (DCIS) section in the Pathologic Evaluation of Breast Tissue section in the PDQ summary on Breast Cancer Screening for more information.) Population studies from the United States [2] and the United Kingdom [3] demonstrate an increase in DCIS and invasive breast cancer incidence since the 1970s, attributable to the widespread adoption of both postmenopausal hormone therapy and screening mammography. In the last decade, women have refrained from using postmenopausal hormones, and breast cancer incidence has declined, but not to the levels seen before the widespread use of screening mammography.[4]

Anatomy

ENLARGEDrawing of female breast anatomy showing  the lymph nodes, nipple, areola, chest wall, ribs, muscle, fatty tissue, lobe, ducts, and lobules.
Anatomy of the female breast. The nipple and areola are shown on the outside of the breast. The lymph nodes, lobes, lobules, ducts, and other parts of the inside of the breast are also shown.

Risk Factors

Increasing age is the most important risk factor for most cancers. Other risk factors for breast cancer include the following:
  • Family health history.[5]
  • Major inheritance susceptibility.[6,7]
    • Germline mutation of the BRCA1 and BRCA2 genes and other breast cancer susceptibility genes.[8,9]
  • Alcohol intake.
  • Breast tissue density (mammographic).[10]
  • Estrogen (endogenous).[11-13]
    • Menstrual history (early menarche/late menopause).[14,15]
    • Nulliparity.
    • Older age at first birth.
  • Hormone therapy history.
    • Combination estrogen plus progestin hormone replacement therapy.
  • Obesity (postmenopausal).[16]
  • Personal history of breast cancer.[17]
  • Personal history of benign breast disease (BBD) (proliferative forms of BBD).[18-20]
  • Radiation exposure to breast/chest.[21]
Age-specific risk estimates are available to help counsel and design screening strategies for women with a family history of breast cancer.[22,23]
Of all women with breast cancer, 5% to 10% may have a germline mutation of the genes BRCA1 and BRCA2.[24] Specific mutations of BRCA1 and BRCA2 are more common in women of Jewish ancestry.[25] The estimated lifetime risk of developing breast cancer for women with BRCA1 and BRCA2 mutations is 40% to 85%. Carriers with a history of breast cancer have an increased risk of contralateral disease that may be as high as 5% per year.[26] Male BRCA2 mutation carriers also have an increased risk of breast cancer.[27]
Mutations in either the BRCA1 or the BRCA2 gene also confer an increased risk of ovarian cancer [27,28] or other primary cancers.[27,28] Once a BRCA1 or BRCA2 mutation has been identified, other family members can be referred for genetic counseling and testing.[29-32] (Refer to the PDQ summaries on Genetics of Breast and Gynecologic CancersBreast Cancer Prevention; and Breast Cancer Screening for more information.)
(Refer to the PDQ summary on Breast Cancer Prevention for more information about factors that increase the risk of breast cancer.)

Protective Factors

Protective factors and interventions to reduce the risk of female breast cancer include the following:
  • Estrogen use (after hysterectomy).[33-35]
  • Exercise.[36-38]
  • Early pregnancy.[39-41]
  • Breast feeding.[42]
  • Selective estrogen receptor modulators (SERMs).[43]
  • Aromatase inhibitors or inactivators.[44,45]
  • Risk-reducing mastectomy.[46]
  • Risk-reducing oophorectomy or ovarian ablation.[47-50]
(Refer to the PDQ summary on Breast Cancer Prevention for more information about factors that decrease the risk of breast cancer.)

Screening

Clinical trials have established that screening asymptomatic women using mammography, with or without clinical breast examination, decreases breast cancer mortality. (Refer to the PDQ summary on Breast Cancer Screening for more information.)

Diagnosis

Patient evaluation

When breast cancer is suspected, patient management generally includes the following:
  • Confirmation of the diagnosis.
  • Evaluation of the stage of disease.
  • Selection of therapy.
The following tests and procedures are used to diagnose breast cancer:
  • Mammography.
  • Ultrasound.
  • Breast magnetic resonance imaging (MRI), if clinically indicated.
  • Biopsy.

Contralateral disease

Pathologically, breast cancer can be a multicentric and bilateral disease. Bilateral disease is somewhat more common in patients with infiltrating lobular carcinoma. At 10 years after diagnosis, the risk of a primary breast cancer in the contralateral breast ranges from 3% to 10%, although endocrine therapy decreases that risk.[51-53] The development of a contralateral breast cancer is associated with an increased risk of distant recurrence.[54] When BRCA1/BRCA2 mutation carriers were diagnosed before age 40 years, the risk of a contralateral breast cancer reached nearly 50% in the ensuing 25 years.[55,56]
Patients who have breast cancer will undergo bilateral mammography at the time of diagnosis to rule out synchronous disease. To detect either recurrence in the ipsilateral breast in patients treated with breast-conserving surgery or a second primary cancer in the contralateral breast, patients will continue to have regular breast physical examinations and mammograms.
The role of MRI in screening the contralateral breast and monitoring women treated with breast-conserving therapy continues to evolve. Because an increased detection rate of mammographically occult disease has been demonstrated, the selective use of MRI for additional screening is occurring more frequently despite the absence of randomized, controlled data. Because only 25% of MRI-positive findings represent malignancy, pathologic confirmation before treatment is recommended. Whether this increased detection rate will translate into improved treatment outcome is unknown.[57-59]

Prognostic and Predictive Factors

Breast cancer is commonly treated by various combinations of surgery, radiation therapy, chemotherapy, and hormone therapy. Prognosis and selection of therapy may be influenced by the following clinical and pathology features (based on conventional histology and immunohistochemistry):[60]
  • Menopausal status of the patient.
  • Stage of the disease.
  • Grade of the primary tumor.
  • Estrogen receptor (ER) and progesterone receptor (PR) status of the tumor.
  • Human epidermal growth factor type 2 receptor (HER2/neu) overexpression and/or amplification.
  • Histologic type. Breast cancer is classified into a variety of histologic types, some of which have prognostic importance. Favorable histologic types include mucinous, medullary, and tubular carcinomas.[61-63]
The use of molecular profiling in breast cancer includes the following:[64]
  • ER and PR status testing.
  • HER2/neu receptor status testing.
  • Gene profile testing by microarray assay or reverse transcription-polymerase chain reaction (e.g., MammaPrint, Oncotype DX).
On the basis of ER, PR, and HER2/neu results, breast cancer is classified as one of the following types:
  • Hormone receptor positive.
  • HER2/neu positive.
  • Triple negative (ER, PR, and HER2/neu negative).
ER, PR, and HER2 status are important in determining prognosis and in predicting response to endocrine and HER2-directed therapy. The American Society of Clinical Oncology/College of American Pathologists consensus panel has published guidelines to help standardize the performance, interpretation, and reporting of assays used to assess the ER-PR status by immunohistochemistry and HER2 status by immunohistochemistry and in situ hybridization.[65,66]
Gene profile tests include the following:
  • MammaPrint: The first gene profile test to be approved by the U.S. Food and Drug Administration was the MammaPrint gene signature. The 70-gene signature classifies tumors into high- and low-risk prognostic categories. [67-71] The aim of the MINDACT(NCT00433589) trial (see below) is to determine the clinical usefulness and patient benefit of adjuvant chemotherapy .
  • Oncotype DX: The Oncotype DX 21 gene assay is the gene profile test with the most extensive clinical validation thus far and applies to hormone receptor–positive breast cancer. A 21-gene recurrence score is generated based on the level of expression of each of the 21 genes:
    • Recurrence score <18: low risk.
    • Recurrence score ≥18 and <31: intermediate-risk.
    • Recurrence score ≥31: high risk.
The following trials describe the prognostic and predictive value of multigene assays in early breast cancer:
  1. The prognostic ability of the Oncotype DX 21-gene assay was assessed in two randomized trials.
    • The National Surgical Adjuvant Breast and Bowel Project (NSABP B-14) trial randomly assigned patients to receive tamoxifen or placebo; the results favoring tamoxifen changed clinical practice in the late 1980s.[72] Formalin-fixed, paraffin-embedded tissue was available for 668 patients. The 10-year distant recurrence risk for patients treated with tamoxifen was 7% for those with a low recurrence score, 14% for those with an intermediate recurrence score, and 31% for those with high recurrence score (P < .001).[73]
    • A community-based, case-control study examined the prognostic ability of the recurrence score to predict breast cancer deaths after 10 years in a group of tamoxifen-treated patients and observed a similar prognostic pattern to that seen in patients from NSABP B-14.[74]
  2. The use of Oncotype Dx to predict benefit from chemotherapy in patients with nodenegative-, ER-positive breast cancer was initially assessed in a prospective-retrospective way using the tamoxifen alone (n = 227) and the combination arms (n = 424) of the NSABP B-20 trial.[72] Patients in the NSABP B-20 trial were randomly assigned to receive tamoxifen alone or tamoxifen concurrently with methotrexate and 5-fluorouracil (MF) or cyclophosphamide with MF (CMF).[75]
    • The 10-year distant disease-free survival (DFS) improved from 60% to 88% by adding chemotherapy to tamoxifen in the high-risk group, while no benefit was observed in the low recurrence score group.[76]
  3. Similar findings were reported in the prospective-retrospective evaluation of the Southwestern Oncology Group (SWOG-8814 [NCT00929591]) trial in hormone receptor–positive lymph node-positive postmenopausal patients treated with tamoxifen with or without cyclophosphamide, doxorubicin, and fluorouracil.[77] However, the sample size in this analysis was small, follow-up was only 5 years, and the prognostic impact of having positive nodes needs to be taken into consideration.
    • Of note, both analyses (NSABP B-20 and S8814) were underpowered for any conclusive predictive analysis among patients identified as having an intermediate recurrence score.
  4. Results from the prospective, randomized TAILORx (NCT00310180) trial indicate that chemotherapy is unlikely to provide substantial benefit to patients older than 50 years with ER-PR–positive and node-negative disease and a recurrence score of 11 to 25.[78] In this study, a low-risk score was defined as less than 11, an intermediate score was 11 to 25, and a high-risk score was greater than 25. These cut points differ from those described above.
    Patients in this study with a low-risk score were found to have very low rates of recurrence at 5 years with endocrine therapy.[79]
    • Rate of invasive DFS was 93.8% at 5 years and 84.0% at 9 years.
    • Rate of freedom from recurrence of breast cancer at a distant site was 99.3% at 5 years and 96.8% at 9 years.
    • Rate of freedom from recurrence of breast cancer at a distant or local-regional site was 98.7% at 5 years and 95.0% at 9 years.
    • Rate of overall survival (OS) was 98.0% at 5 years and 93.7% at 9 years.
    In the middle-risk group in the TAILORx study (recurrence score, 11–25), 6,907 women were randomly assigned to endocrine therapy alone or endocrine therapy plus chemotherapy.[78] Of these, 3,399 women on the endocrine therapy-alone arm and 3,312 women on the endocrine therapy-plus-chemotherapy arm were available for an analysis according to the randomized treatment assignments. After a median follow-up of 90 months, the difference in invasive DFS, the main study endpoint, met the prespecified noninferiority criterion (P > .10 for a test of no difference after 835 events had occurred) suggesting the noninferiority of endocrine therapy compared with endocrine therapy plus chemotherapy.
    • In this population, the 9-year invasive DFS was 83.3% for endocrine therapy alone and 84.3% for endocrine therapy plus chemotherapy (hazard ratio [HR], 1.08; 95% confidence interval [CI], 0.94–1.24; P = .26).[78][Level of evidence: 1iiD]
    • One hundred eighty-five patients in the endocrine-only arm received chemotherapy, and 608 patients in the endocrine therapy-plus-chemotherapy arm did not receive their assigned chemotherapy. In an analysis based on the actual treatment received, the HR for invasive DFS was 1.14 (95% CI, 0.99–1.31; P =.06).
    • Outcomes for the other endpoints examined (freedom of distant breast cancer recurrence, freedom from local and distant recurrence, and OS) were similar between the two treatment arms and none were significant at P < 0.10.
    • There was a significant interaction between treatment assignment and age (P = .03) with respect to invasive DFS, suggesting that chemotherapy might be beneficial in women younger than 50 years with recurrence scores ranging from 11 to 25.
  5. The MINDACT (NCT00433589) trial tested whether adding MammaPrint genomic risk to a clinical-risk classification (modified from Adjuvant! Online) might guide more appropriate choices of chemotherapy in women with node negative- or 1-to-3 node-positive disease.[80][Level of evidence: 3iiiDii] Unlike the TAILORx study, which only had hormone receptor–positive patients, this trial included hormone receptor–negative patients. In this prospective study, women with both genomic and clinical high-risk classification received chemotherapy, while those with both genomic and clinical low-risk classification did not receive chemotherapy. Participants with discordant results (clinical high-risk- with genomic low-risk classification, or clinical low-risk- with genomic high-risk classification) were randomly assigned to receive or not receive chemotherapy. A total of 1,550 women with high clinical risk and low genomic risk, and 592 women with low clinical risk and high genomic risk, were randomly assigned to receive or not receive chemotherapy. The primary goal of the study was to determine whether patients with high clinical risk, but low genomic risk, who did not receive chemotherapy had a 5-year survival rate without distant metastases (primary study endpoint) of 92% or lower (a noninferiority design).
    • This endpoint was met because the observed rate in the group was 94.7% (95% CI, 92.5%–96.2%). However, among patients with high clinical risk but low genomic risk, the rate of 5-year survival without distant metastases was 1.5% higher in the arm that did receive chemotherapy than in the arm that did not receive chemotherapy, although the study was not powered to detect a difference between these arms (HR chemotherapy vs. no chemotherapy, 0.78; 95% CI, 0.50–1.21; P = .27)
    • Patients in the low clinical risk group with high genomic risk did well, and there was little evidence of benefit from chemotherapy in this group (5-year survival without distant metastases, 95.8% with chemotherapy vs. 95.0% without; HR, 1.17; 95% CI, 0.59–2.28; P = .66).
Results from the prospective, randomized RxPONDER (NCT01272037) trial will help to determine if there is a benefit from adjuvant chemotherapy in patients with ER-positive-, node-positive early breast cancer treated with endocrine therapy, and a recurrence score below 25.
Many other gene-based assays may guide treatment decisions in patients with early breast cancer (e.g., Predictor Analysis of Microarray 50 [PAM50] Risk of Recurrence [ROR] score, EndoPredict, Breast Cancer Index).
Although certain rare inherited mutations, such as those of BRCA1 and BRCA2, predispose women to develop breast cancer, prognostic data on BRCA1/BRCA2 mutation carriers who have developed breast cancer are conflicting. These women are at greater risk of developing contralateral breast cancer. (Refer to the Prognosis of BRCA1- and BRCA2-related breast cancer section of the PDQ Genetics of Breast and Gynecologic Cancerssummary for more information.)

Posttherapy Considerations

Hormone replacement therapy

After careful consideration, patients with severe symptoms may be treated with hormone replacement therapy. For more information, refer to the following PDQ summaries:

Related Summaries

Other PDQ summaries containing information related to breast cancer include the following:
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  63. Rakha EA, Lee AH, Evans AJ, et al.: Tubular carcinoma of the breast: further evidence to support its excellent prognosis. J Clin Oncol 28 (1): 99-104, 2010. [PUBMED Abstract]
  64. Sørlie T, Perou CM, Tibshirani R, et al.: Gene expression patterns of breast carcinomas distinguish tumor subclasses with clinical implications. Proc Natl Acad Sci U S A 98 (19): 10869-74, 2001. [PUBMED Abstract]
  65. Wolff AC, Hammond MEH, Allison KH, et al.: Human Epidermal Growth Factor Receptor 2 Testing in Breast Cancer: American Society of Clinical Oncology/College of American Pathologists Clinical Practice Guideline Focused Update. J Clin Oncol 36 (20): 2105-2122, 2018. [PUBMED Abstract]
  66. Hammond ME, Hayes DF, Dowsett M, et al.: American Society of Clinical Oncology/College of American Pathologists guideline recommendations for immunohistochemical testing of estrogen and progesterone receptors in breast cancer. Arch Pathol Lab Med 134 (6): 907-22, 2010. [PUBMED Abstract]
  67. Buyse M, Loi S, van't Veer L, et al.: Validation and clinical utility of a 70-gene prognostic signature for women with node-negative breast cancer. J Natl Cancer Inst 98 (17): 1183-92, 2006. [PUBMED Abstract]
  68. Wittner BS, Sgroi DC, Ryan PD, et al.: Analysis of the MammaPrint breast cancer assay in a predominantly postmenopausal cohort. Clin Cancer Res 14 (10): 2988-93, 2008. [PUBMED Abstract]
  69. Mook S, Knauer M, Bueno-de-Mesquita JM, et al.: Metastatic potential of T1 breast cancer can be predicted by the 70-gene MammaPrint signature. Ann Surg Oncol 17 (5): 1406-13, 2010. [PUBMED Abstract]
  70. Ishitobi M, Goranova TE, Komoike Y, et al.: Clinical utility of the 70-gene MammaPrint profile in a Japanese population. Jpn J Clin Oncol 40 (6): 508-12, 2010. [PUBMED Abstract]
  71. Knauer M, Mook S, Rutgers EJ, et al.: The predictive value of the 70-gene signature for adjuvant chemotherapy in early breast cancer. Breast Cancer Res Treat 120 (3): 655-61, 2010. [PUBMED Abstract]
  72. Fisher B, Jeong JH, Bryant J, et al.: Treatment of lymph-node-negative, oestrogen-receptor-positive breast cancer: long-term findings from National Surgical Adjuvant Breast and Bowel Project randomised clinical trials. Lancet 364 (9437): 858-68, 2004. [PUBMED Abstract]
  73. Paik S, Shak S, Tang G, et al.: A multigene assay to predict recurrence of tamoxifen-treated, node-negative breast cancer. N Engl J Med 351 (27): 2817-26, 2004. [PUBMED Abstract]
  74. Habel LA, Shak S, Jacobs MK, et al.: A population-based study of tumor gene expression and risk of breast cancer death among lymph node-negative patients. Breast Cancer Res 8 (3): R25, 2006. [PUBMED Abstract]
  75. Mamounas EP, Tang G, Fisher B, et al.: Association between the 21-gene recurrence score assay and risk of locoregional recurrence in node-negative, estrogen receptor-positive breast cancer: results from NSABP B-14 and NSABP B-20. J Clin Oncol 28 (10): 1677-83, 2010. [PUBMED Abstract]
  76. Paik S, Tang G, Shak S, et al.: Gene expression and benefit of chemotherapy in women with node-negative, estrogen receptor-positive breast cancer. J Clin Oncol 24 (23): 3726-34, 2006. [PUBMED Abstract]
  77. Albain KS, Barlow WE, Shak S, et al.: Prognostic and predictive value of the 21-gene recurrence score assay in postmenopausal women with node-positive, oestrogen-receptor-positive breast cancer on chemotherapy: a retrospective analysis of a randomised trial. Lancet Oncol 11 (1): 55-65, 2010. [PUBMED Abstract]
  78. Sparano JA, Gray RJ, Makower DF, et al.: Adjuvant Chemotherapy Guided by a 21-Gene Expression Assay in Breast Cancer. N Engl J Med : , 2018. [PUBMED Abstract]
  79. Sparano JA, Gray RJ, Makower DF, et al.: Prospective Validation of a 21-Gene Expression Assay in Breast Cancer. N Engl J Med 373 (21): 2005-14, 2015. [PUBMED Abstract]
  80. Cardoso F, van't Veer LJ, Bogaerts J, et al.: 70-Gene Signature as an Aid to Treatment Decisions in Early-Stage Breast Cancer. N Engl J Med 375 (8): 717-29, 2016. [PUBMED Abstract]

Histopathologic Classification of Breast Cancer

Table 1 describes the histologic classification of breast cancer based on tumor location.[1] Infiltrating or invasive ductal cancer is the most common breast cancer histologic type and comprises 70% to 80% of all cases.
Table 1. Tumor Location and Related Histologic Subtype
Tumor LocationHistologic Subtype
NOS = not otherwise specified.
Carcinoma, NOS 
DuctalIntraductal (in situ)
Invasive with predominant component
Invasive, NOS
Comedo
Inflammatory
Medullary with lymphocytic infiltrate
Mucinous (colloid)
Papillary
Scirrhous
Tubular
Other
LobularInvasive with predominant in situ component
Invasive [2]
NipplePaget disease, NOS
Paget disease with intraductal carcinoma
Paget disease with invasive ductal carcinoma
OtherUndifferentiated carcinoma
Metaplastic
The following tumor subtypes occur in the breast but are not considered typical breast cancers:
  • Phyllodes tumor.[3,4]
  • Angiosarcoma.
  • Primary lymphoma.
References
  1. Breast. In: Edge SB, Byrd DR, Compton CC, et al., eds.: AJCC Cancer Staging Manual. 7th ed. New York, NY: Springer, 2010, pp 347-76.
  2. Yeatman TJ, Cantor AB, Smith TJ, et al.: Tumor biology of infiltrating lobular carcinoma. Implications for management. Ann Surg 222 (4): 549-59; discussion 559-61, 1995. [PUBMED Abstract]
  3. Chaney AW, Pollack A, McNeese MD, et al.: Primary treatment of cystosarcoma phyllodes of the breast. Cancer 89 (7): 1502-11, 2000. [PUBMED Abstract]
  4. Carter BA, Page DL: Phyllodes tumor of the breast: local recurrence versus metastatic capacity. Hum Pathol 35 (9): 1051-2, 2004. [PUBMED Abstract]

Stage Information for Breast Cancer

The American Joint Committee on Cancer (AJCC) staging system provides a strategy for grouping patients with respect to prognosis. Therapeutic decisions are formulated in part according to staging categories but also according to other clinical factors such as the following, some of which are included in the determination of stage:
  • Tumor size.
  • Lymph node status.
  • Estrogen-receptor and progesterone-receptor levels in the tumor tissue.
  • Human epidermal growth factor receptor 2 (HER2/neu) status in the tumor.
  • Tumor grade.
  • Menopausal status.
  • General health of the patient.
The standards used to define biomarker status are described as follows:
  • Estrogen receptor (ER) expression: ER expression is measured primarily by immunohistochemistry (IHC). Any staining of 1% of cells or more is considered positive for ER.[1]
  • Progesterone receptor (PR) expression: PR expression is measured primarily by IHC. Any staining of 1% of cells or more is considered positive for PR.
  • HER2 expression: HER2 is measured primarily by either IHC to assess expression of the HER2 protein or by in situ hybridization (ISH) to assess gene copy number. The American Society of Clinical Oncology/College of American Pathologists consensus panel has published guidelines for cases when either IHC or ISH testing is equivocal.[2]
    IHC:
    • Negative: 0 or 1+ staining
    • Equivocal: 2+ staining
    • Positive: 3+ staining
    ISH (dual probe):
    • Possible negative results:
      • HER2/chromosome enumeration probe (CEP17) ratio <2.0 AND HER2 copy number <4
    • Possible equivocal results: (requires performing alternative ISH test to confirm equivocal or IHC if not previously performed)
      • HER2/CEP17 ratio <2.0 AND HER2 copy number ≥4 but <6
    • Possible positive results:
      • HER2/CEP17 ratio ≥2.0 by ISH
      • HER2 copy number ≥6 regardless of ratio by ISH
    ISH (single probe):
    • Negative: <4 HER2 copies
    • Equivocal: ≥4 HER2 copies but <6 HER2 copies
    • Positive: ≥6 HER2 copies

TNM Definitions

The AJCC has designated staging by TNM (tumor, node, metastasis) classification to define breast cancer.[3] The grade of the tumor is determined by its morphologic features, such as tubule formation, nuclear pleomorphism, and mitotic count.
Table 2. Definition of Primary Tumor (T) – Clinical and Pathologicala
T CategoryT Criteria
DCIS = ductal carcinoma in situ.
aReprinted with permission from AJCC: Breast, revised version. In: Amin MB, Edge SB, Greene FL, et al., eds.: AJCC Cancer Staging Manual. 8th ed. New York, NY: Springer, 2017, pp. 4–96.
bLobular carcinoma in situ is a benign entity and is removed from TNM staging in the AJCC Cancer Staging Manual, 8th ed.
cRules for Classification - The anatomic TNM system is a method for coding extent of disease. This is done by assigning a category of extent of disease for the tumor (T), regional lymph nodes (N), and distant metastases (M). T, N, and M are assigned by clinical means and by adding surgical findings and pathological information to the clinical information. The documented prognostic impact of postneoadjuvant extent of disease and response to therapy warrant clear definitions of the use of the yp prefix and response to therapy. The use of neoadjuvant therapy does not change the clinical (pretreatment) stage. As per TNM rules, the anatomic component of clinical stage is identified with the prefix c (e.g., cT). In addition, clinical staging can include the use of fine-needle aspiration (FNA) or core-needle biopsy and sentinel lymph node biopsy before neoadjuvant therapy. These are denoted with the postscripts and sn, respectively. Nodal metastases confirmed by FNA or core-needle biopsy are classified as macrometastases (cN1), regardless of the size of the tumor focus in the final pathological specimen. For example, if, prior to neoadjuvant systemic therapy, a patient with a 1 cm primary has no palpable nodes but has an ultrasound-guided FNA biopsy of an axillary lymph node that is positive, the patient will be categorized as cN1 (f) for clinical (pretreatment) staging and is assigned to Stage IIA. Likewise, if the patient has a positive axillary sentinel node identified before neoadjuvant systemic therapy, the tumor is categorized as cN1 (sn) (Stage IIA). As per TNM rules, in the absence of pathological T evaluation (removal of the primary tumor), which is identified with prefix p (e.g., pT), microscopic evaluation of nodes before neoadjuvant therapy, even by complete removal such as sentinel node biopsy, is still classified as clinical (cN).
TXPrimary tumor cannot be assessed.
T0No evidence of primary tumor.
TisbDCIS.
Tis (Paget)Paget disease of the nipple NOT associated with invasive carcinoma and/or DCIS in the underlying breast parenchyma. Carcinomas in the breast parenchyma associated with Paget disease are categorized based on the size and characteristics of the parenchymal disease, although the presence of Paget disease should still be noted.
T1Tumor ≤20 mm in greatest dimension.
–T1miTumor ≤1 mm in greatest dimension.
–T1aTumor >1 mm but ≤5 mm in greatest dimension (round any measurement >1.0–1.9 mm to 2 mm).
–T1bTumor >5 mm but ≤10 mm in greatest dimension.
–T1cTumor >10 mm but ≤20 mm in greatest dimension.
T2Tumor >20 mm but ≤50 mm in greatest dimension.
T3Tumor >50 mm in greatest dimension.
T4Tumor of any size with direct extension to the chest wall and/or to the skin (ulceration or macroscopic nodules); invasion of the dermis alone does not qualify as T4.
–T4aExtension to the chest wall; invasion or adherence to pectoralis muscle in the absence of invasion of chest wall structures does not qualify as T4.
–T4bUlceration and/or ipsilateral macroscopic satellite nodules and/or edema (including peau d'orange) of the skin that does not meet the criteria for inflammatory carcinoma.
–T4cBoth T4a and T4b are present.
–T4dInflammatory carcinoma (see Rules for Classificationc).
Table 3. Definition of Regional Lymph Nodes – Clinical (cN)a,b
cN CategorycN Criteria
aReprinted with permission from AJCC: Breast, revised version. In: Amin MB, Edge SB, Greene FL, et al., eds.: AJCC Cancer Staging Manual. 8th ed. New York, NY: Springer, 2017, pp. 4–96.
b(sn) and (f) suffixes should be added to the N category to denote confirmation of metastasis by sentinel node biopsy or fine-needle aspiration/core needle biopsy, respectively.
cThe cNX category is used sparingly in cases where regional lymph nodes have previously been surgically removed or where there is no documentation of physical examination of the axilla.
dcN1mi is rarely used but may be appropriate in cases where sentinel node biopsy is performed before tumor resection, most likely to occur in cases treated with neoadjuvant therapy.
cNXcRegional lymph nodes cannot be assessed (e.g., previously removed).
cN0No regional lymph node metastases (by imaging or clinical examination).
cN1Metastases to movable ipsilateral Level I, II axillary lymph nodes(s).
–cN1midMicrometastases (approximately 200 cells, >0.2 mm, but ≤2.0 mm).
cN2Metastases in ipsilateral Level I, II axillary lymph nodes that are clinically fixed or matted;
or in ipsilateral internal mammary nodes in the absence of axillary lymph node metastases.
–cN2aMetastases in ipsilateral Level I, II axillary lymph nodes fixed to one another (matted) or to other structures.
–cN2bMetastases only in ipsilateral internal mammary nodes in the absence of axillary lymph node metastases.
cN3Metastases in ipsilateral infraclavicular (Level Ill axillary) lymph node(s) with or without Level l, II axillary lymph node involvement; or in ipsilateral internal mammary lymph node(s) with Level l, II axillary lymph node metastases; ormetastases in ipsilateral supraclavicular lymph node(s) with or without axillary or internal mammary lymph node involvement.
–cN3aMetastases in ipsilateral infraclavicular lymph node(s).
–cN3bMetastases in ipsilateral internal mammary lymph node(s) and axillary lymph node(s).
–cN3cMetastases in ipsilateral supraclavicular lymph node(s).
Table 4. Definition of Regional Lymph Nodes – Pathological (pN)a,b
pN CategorypN Criteria
ITCs = isolated tumor cells; RT-PCR = reverse transcriptase-polymerase chain reaction.
aReprinted with permission from AJCC: Breast, revised version. In: Amin MB, Edge SB, Greene FL, et al., eds.: AJCC Cancer Staging Manual. 8th ed. New York, NY: Springer, 2017, pp. 4–96.
b(sn) and (f) suffixes should be added to the N category to denote confirmation of metastasis by sentinel node biopsy or fine-needle aspiration/core needle biopsy, respectively, with NO further resection of nodes.
pNXRegional lymph nodes cannot be assessed (e.g., not removed for pathological study or previously removed).
pN0No regional lymph node metastasis identified or ITCs only.
–pN0(i+)ITCs only (malignant cell clusters ≤0.2 mm) in regional lymph node(s).
–pN0(mol+)Positive molecular findings by RT-PCR; no ITCs detected.
pN1Micrometastases; or metastases in 1–3 axillary lymph nodes; and/or clinically negative internal mammary nodes with micrometastases or macrometastases by sentinel lymph node biopsy.
–pN1miMicrometastases (~200 cells, >0.2 mm, but ≤2.0 mm).
–pN1aMetastases in 1–3 axillary lymph nodes, at least one metastasis >2.0 mm.
–pN1bMetastases in ipsilateral internal mammary sentinel nodes, excluding ITCs.
–pN1cpN1a and pN1b combined.
pN2Metastases in 4–9 axillary lymph nodes; or positive ipsilateral internal mammary lymph nodes by imaging in the absence of axillary lymph node metastases.
–pN2aMetastases in 4–9 axillary lymph nodes (at least 1 tumor deposit >2.0 mm).
–pN2bMetastases in clinically detected internal mammary lymph nodes with or without microscopic confirmation; with pathologically negative axillary nodes.
pN3Metastases in ≥10 axillary lymph nodes; or in infraclavicular (Level Ill axillary) lymph nodes; or positive ipsilateral internal mammary lymph nodes by imaging in the presence of one or more positive Level l, II axillary lymph nodes; or in >3 axillary lymph nodes and micrometastases or macrometastases by sentinel lymph node biopsy in clinically negative ipsilateral internal mammary lymph nodes; or in ipsilateral supraclavicular lymph nodes.
–pN3aMetastases in ≥10 axillary lymph nodes (at least 1 tumor deposit >2.0 mm); ormetastases to the infraclavicular (Level III axillary lymph) nodes.
–pN3bpN1a or pN2a in the presence of cN2b (positive internal mammary nodes by imaging);
or pN2a in the presence of pN1b.
–pN3cMetastases in ipsilateral supraclavicular lymph nodes.
Table 5. Definition of Distant Metastasis (M)a
M CategoryM Criteria
aReprinted with permission from AJCC: Breast, revised version. In: Amin MB, Edge SB, Greene FL, et al., eds.: AJCC Cancer Staging Manual. 8th ed. New York, NY: Springer, 2017, pp. 4–96.
bNote that imaging studies are not required to assign the cM0 category.
M0No clinical or radiographic evidence of distant metastases.b
cM0(i+)No clinical or radiographic evidence of distant metastases in the presence of tumor cells or deposits ≤0.2 mm detected microscopically or by molecular techniques in circulating blood, bone marrow, or other nonregional nodal tissue in a patient without symptoms or signs of metastases.
cM1Distant metastases detected by clinical and radiographic means.
pM1Any histologically proven metastases in distant organs; or if in nonregional nodes, metastases >0.2 mm.
Table 6. Definition of Histologic Grade (G)a
GG Definition
SBR = Scarff-Bloom-Richardson grading system, Nottingham Modification.
aReprinted with permission from AJCC: Breast, revised version. In: Amin MB, Edge SB, Greene FL, et al., eds.: AJCC Cancer Staging Manual. 8th ed. New York, NY: Springer, 2017, pp. 4–96.
GXGrade cannot be assessed.
G1Low combined histologic grade (favorable), SBR score of 3–5 points.
G2Intermediate combined histologic grade (moderately favorable); SBR score of 6–7 points.
G3High combined histologic grade (unfavorable); SBR score of 8–9 points.
Table 7. Ductal Carcinoma in situ: Nuclear Gradea
GG Definition
aReprinted with permission from AJCC: Breast, revised version. In: Amin MB, Edge SB, Greene FL, et al., eds.: AJCC Cancer Staging Manual. 8th ed. New York, NY: Springer, 2017, pp. 4–96.
GXGrade cannot be assessed.
G1Low nuclear grade.
G2Intermediate nuclear grade.
G3High nuclear grade.

AJCC Anatomic and Prognostic Stage Groups

There are three stage group tables for invasive cancer:[3]
  • Anatomic Stage Group. The Anatomic Stage Group table is used in regions of the world where tumor grading and/or biomarker testing for ER, PR, and HER2 are not routinely available. (Refer to Table 8.)
  • Clinical Prognostic Stage Group. The Clinical Prognostic Stage Group table is used for all patients in the United States. Patients who have neoadjuvant therapy as their initial treatment should have the clinical prognostic stage and the observed degree of response to treatment recorded, but these patients are not assigned a pathological prognostic stage. (Refer to Table 9.)
  • Pathological Prognostic Stage Group. The Pathological Prognostic Stage Group table is used for all patients in the United States who have surgery as initial treatment and have pathological T and N information reported. (Refer to Table 10.)
In the United States, cancer registries and clinicians must use the Clinical and Pathological Prognostic Stage Group tables for reporting. It is expected that testing is performed for grade, HER2, ER, and PR status and that results are reported for all cases of invasive cancer in the United States.
AJCC Anatomic Stage Groups
Table 8. Definition of Anatomic Stage Groupsa
StageTNM
T = primary tumor; N = regional lymph node; M = distant metastasis.
aAdapted with permission from AJCC: Breast, revised version. In: Amin MB, Edge SB, Greene FL, et al., eds.: AJCC Cancer Staging Manual. 8th ed. New York, NY: Springer, 2017, pp. 4–96.
Notes:
1. T1 includes T1mi.
2. T0 and T1 tumors with nodal micrometastases (N1mi) are staged as Stage lB.
3. T2, T3, and T4 tumors with nodal micrometastases (N1mi) are staged using the N1 category.
4. M0 includes M0(i+).
5. The designation pM0 is not valid; any M0 is clinical.
6. If a patient presents with M1 disease before receiving neoadjuvant systemic therapy, the stage is Stage IV and remains Stage IV regardless of response to neoadjuvant therapy.
7. Stage designation may be changed if postsurgical imaging studies reveal the presence of distant metastases, provided the studies are performed within 4 months of diagnosis in the absence of disease progression, and provided the patient has not received neoadjuvant therapy.
8. Staging following neoadjuvant therapy is denoted with a yc or ypn prefix to the T and N classification. There is no anatomic stage group assigned if there is a complete pathological response (pCR) to neoadjuvant therapy, for example, ypT0, ypN0, cM0.
0Tis, N0, M0
IAT1, N0, M0
IBT0, N1mi, M0
T1, N1mi, M0
IIAT0, N1, M0
T1, N1, M0
T2, N0, M0
IIBT2, N1, M0
T3, N0, M0
IIIAT0, N2, M0
T1, N2, M0
T2, N2, M0
T3, N1, M0
T3, N2, M0
IIIBT4, N0, M0
T4, N1, M0
T4, N2, M0
IIICAny T (Tis, T1, T0, T2, T3, T4; N3, M0)
IVAny T (Tis, T1, T0, T2, T3, T4; Any N = N0, N1mi, N1, N2, N3, M1)
AJCC Prognostic Stage Groups
The Clinical Prognostic Stage is used for clinical classification and staging of patients in the United States with invasive breast cancer. It uses TNM information based on the patient’s history, physical examination, imaging results (not required for clinical staging), and biopsies.
Table 9. Definition of Clinical Prognostic Stage Groupsa
TNMGradeHER2 StatusER StatusPR StatusStage Group
T = primary tumor; N = regional lymph node; M = distant metastasis.
aAdapted with permission from AJCC: Breast, revised version. In: Amin MB, Edge SB, Greene FL, et al., eds.: AJCC Cancer Staging Manual. 8th ed. New York, NY: Springer, 2017, pp. 4–96.
bT1 includes T1mi.
cN1 does not include N1mi. T1, N1mi, M0, and T0, N1mi, M0 cancers are included for prognostic staging with T1, N0, M0 cancers of the same prognostic factor status.
dN1 includes N1mi. T2, T3, and T4 cancers and N1mi are included for prognostic staging with T2, N1; T3, N1; and T4, N1, respectively.
Notes:
1. Because N1mi categorization requires evaluation of the entire node, and cannot be assigned on the basis of an fine-needle aspiration or core biopsy, N1mi can only be used with Clinical Prognostic Staging when clinical staging is based on a resected lymph node in the absence of resection of the primary cancer, such as in the situation where sentinel node biopsy is performed before receiving neoadjuvant chemotherapy or endocrine therapy.
2. For cases with lymph node involvement with no evidence of primary tumor (e.g., T0, N1, etc.) or with breast ductal carcinoma in situ (e.g.,Tis, N1, etc.), the grade, human epidermal growth factor receptor 2 (HER2), estrogen receptor, and progesterone receptor information from the tumor in the lymph node should be used for assigning stage group.
3. For cases where HER2 is determined to be equivocal by in situ hybridization (fluorescence in situ hybridization or chromogenic in situ hybridization) testing under the 2013 American Society of Clinical Oncologists/College of American Pathologists HER2 testing guidelines, the HER2-negative category should be used for staging in the Pathological Prognostic Stage Group table.[4,5]
4. The prognostic value of these Prognostic Stage Groups is based on populations of persons with breast cancer that have been offered and mostly treated with appropriate endocrine and/or systemic chemotherapy (including anti–HER2 therapy).
Tis, N0, M0Any (refer to Table 6 and Table 7)AnyAnyAny0
T1b, N0, M0G1PositivePositivePositiveIA
NegativeIA
T0, N1mi, M0NegativePositiveIA
NegativeIA
T1b, N1mi, M0NegativePositivePositiveIA
NegativeIA
NegativePositiveIA
NegativeIB
G2PositivePositivePositiveIA
NegativeIA
NegativePositiveIA
NegativeIA
NegativePositivePositiveIA
NegativeIA
NegativePositiveIA
NegativeIB
G3PositivePositivePositiveIA
NegativeIA
NegativePositiveIA
NegativeIA
NegativePositivePositiveIA
NegativeIB
NegativePositiveIB
NegativeIB
T0, N1c, M0; T1b, N1c, M0; T2, N0, M0G1PositivePositivePositiveIB
NegativeIIA
NegativePositiveIIA
NegativeIIA
NegativePositivePositiveIB
NegativeIIA
NegativePositiveIIA
NegativeIIA
G2PositivePositivePositiveIB
NegativeIIA
NegativePositiveIIA
NegativeIIA
NegativePositivePositiveIB
NegativeIIA
NegativePositiveIIA
NegativeIIB
G3PositivePositivePositiveIB
NegativeIIA
NegativePositiveIIA
NegativeIIA
NegativePositivePositiveIIA
NegativeIIB
NegativePositiveIIB
NegativeIIB
T2, N1d, M0; T3, N0, M0G1PositivePositivePositiveIB
NegativeIIA
NegativePositiveIIA
NegativeIIB
NegativePositivePositiveIIA
NegativeIIB
NegativePositiveIIB
NegativeIIB
G2PositivePositivePositiveIB
NegativeIIA
NegativePositiveIIA
NegativeIIB
NegativePositivePositiveIIA
NegativeIIB
NegativePositiveIIB
NegativeIIIB
G3PositivePositivePositiveIB
NegativeIIB
NegativePositiveIIB
NegativeIIB
NegativePositivePositiveIIB
NegativeIIIA
NegativePositiveIIIA
NegativeIIIB
T0, N2, M0; T1b, N2, M0; T2, N2, M0; T3, N1d, M0; T3, N2, M0G1PositivePositivePositiveIIA
NegativeIIIA
NegativePositiveIIIA
NegativeIIIA
NegativePositivePositiveIIA
NegativeIIIA
NegativePositiveIIIA
NegativeIIIB
G2PositivePositivePositiveIIA
NegativeIIIA
NegativePositiveIIIA
NegativeIIIA
NegativePositivePositiveIIA
NegativeIIIA
NegativePositiveIIIA
NegativeIIIB
G3PositivePositivePositiveIIB
NegativeIIIA
NegativePositiveIIIA
NegativeIIIA
NegativePositivePositiveIIIA
NegativeIIIB
NegativePositiveIIIB
NegativeIIIC
T4, N0, M0; T4, N1d, M0; T4, N2, M0; Any T, N3, M0G1PositivePositivePositiveIIIA
NegativeIIIB
NegativePositiveIIIB
NegativeIIIB
NegativePositivePositiveIIIB
NegativeIIIB
NegativePositiveIIIB
NegativeIIIC
G2PositivePositivePositiveIIIA
NegativeIIIB
NegativePositiveIIIB
NegativeIIIB
NegativePositivePositiveIIIB
NegativeIIIB
NegativePositiveIIIB
NegativeIIIC
G3PositivePositivePositiveIIIB
NegativeIIIB
NegativePositiveIIIB
NegativeIIIB
NegativePositivePositiveIIIB
NegativeIIIC
NegativePositiveIIIC
NegativeIIIC
Any T, Any N, M1Any (refer to Table 6 and Table 7)AnyAnyAnyIV

AJCC Pathological Prognostic Stage Groups

The Pathological Prognostic Stage applies to patients with invasive breast cancer initially treated with surgery. It includes all information used for clinical staging, surgical findings, and pathological findings following surgery to remove the tumor. Pathological Prognostic Stage is not used for patients treated with neoadjuvant therapy before surgery to remove the tumor.[3]
Table 10. Definition of Pathological Prognostic Stage Groupsa
TNMGradeHER2 StatusER StatusPR StatusStage Group
T = primary tumor; N = regional lymph node; M = distant metastasis.
aAdapted with permission from AJCC: Breast, revised version. In: Amin MB, Edge SB, Greene FL, et al., eds.: AJCC Cancer Staging Manual. 8th ed. New York, NY: Springer, 2017, pp. 4–96.
bT1 includes T1mi.
cN1 does not include N1mi. T1, N1mi, M0 and T0, N1mi, M0 cancers are included for prognostic staging with T1, N0, M0 cancers of the same prognostic factor status.
dN1 includes N1mi. T2, T3, and T4 cancers and N1mi are included for prognostic staging with T2, N1; T3, N1; and T4, N1, respectively.
Notes:
1. For cases with lymph node involvement with no evidence of primary tumor (e.g., T0, N1, etc.) or with breast ductal carcinoma in situ (e.g.,Tis, N1, etc.), the grade, human epidermal growth factor receptor 2 (HER2), estrogen receptor, and progesterone receptor information from the tumor in the lymph node should be used for assigning stage group.
2. For cases where HER2 is determined to be equivocal by in situ hybridization (fluorescence in situ hybridization or chromogenic in situ hybridization) testing under the 2013 American Society of Clinical Oncologists/College of American Pathologists HER2 testing guidelines, the HER2-negative category should be used for staging in the Pathological Prognostic Stage Group table.[4,5]
3. The prognostic value of these Prognostic Stage Groups is based on populations of persons with breast cancer that have been offered and mostly treated with appropriate endocrine and/or systemic chemotherapy (including anti–HER2 therapy).
Tis, N0, M0Any (refer to Table 6 and Table 7)AnyAnyAny0
T1b, N0, M0; T0, N1mi, M0; T1b, N1mi, M0G1PositivePositivePositiveIA
NegativeIA
NegativePositiveIA
NegativeIA
NegativePositivePositiveIA
NegativeIA
NegativePositiveIA
NegativeIA
G2PositivePositivePositiveIA
NegativeIA
NegativePositiveIA
NegativeIA
NegativePositivePositiveIA
NegativeIA
NegativePositiveIA
NegativeIB
G3PositivePositivePositiveIA
NegativeIA
NegativePositiveIA
NegativeIA
NegativePositivePositiveIA
NegativeIA
NegativePositiveIA
NegativeIB
T0, N1, M0; T1b, N1c, M0; T2, N0, M0G1PositivePositivePositiveIA
NegativeIB
NegativePositiveIB
NegativeIIA
NegativePositivePositiveIA
NegativeIB
NegativePositiveIB
NegativeIIA
G2PositivePositivePositiveIA
NegativeIB
NegativePositiveIB
NegativeIIA
NegativePositivePositiveIA
NegativeIIA
NegativePositiveIIA
NegativeIIA
G3PositivePositivePositiveIA
NegativeIIA
NegativePositiveIIA
NegativeIIA
NegativePositivePositiveIB
NegativeIIA
NegativePositiveIIA
NegativeIIA
T2, N1c, M0; T3, N0, M0G1PositivePositivePositiveIA
NegativeIIB
NegativePositiveIIB
NegativeIIB
NegativePositivePositiveIA
NegativeIIB
NegativePositiveIIB
NegativeIIB
G2PositivePositivePositiveIB
NegativeIIB
NegativePositiveIIB
NegativeIIB
NegativePositivePositiveIB
NegativeIIB
NegativePositiveIIB
NegativeIIB
G3PositivePositivePositiveIB
NegativeIIB
NegativePositiveIIB
NegativeIIB
NegativePositivePositiveIIA
NegativeIIB
NegativePositiveIIB
NegativeIIIA
T0, N2, M0; T1b, N2, M0; T2, N2, M0, T3, N1d, M0; T3, N2, M0G1PositivePositivePositiveIB
NegativeIIIA
NegativePositiveIIIA
NegativeIIIA
NegativePositivePositiveIB
NegativeIIIA
NegativePositiveIIIA
NegativeIIIA
G2PositivePositivePositiveIB
NegativeIIIA
NegativePositiveIIIA
NegativeIIIA
NegativePositivePositiveIB
NegativeIIIA
NegativePositiveIIIA
NegativeIIIB
G3PositivePositivePositiveIIA
NegativeIIIA
NegativePositiveIIIA
NegativeIIIA
NegativePositivePositiveIIB
NegativeIIIA
NegativePositiveIIIA
NegativeIIIC
T4, N0, M0; T4, N1d, M0; T4, N2, M0; Any T, N3, M0G1PositivePositivePositiveIIIA
NegativeIIIB
NegativePositiveIIIB
NegativeIIIB
NegativePositivePositiveIIIA
NegativeIIIB
NegativePositiveIIIB
NegativeIIIB
G2PositivePositivePositiveIIIA
NegativeIIIB
NegativePositiveIIIB
NegativeIIIB
NegativePositivePositiveIIIA
NegativeIIIB
NegativePositiveIIIB
NegativeIIIC
G3PositivePositivePositiveIIIB
NegativeIIIB
NegativePositiveIIIB
NegativeIIIB
NegativePositivePositiveIIIB
NegativeIIIC
NegativePositiveIIIC
NegativeIIIC
Any T, Any N, M1Any (refer to Table 6 and Table 7)AnyAnyAnyIV
References
  1. Barnes DM, Harris WH, Smith P, et al.: Immunohistochemical determination of oestrogen receptor: comparison of different methods of assessment of staining and correlation with clinical outcome of breast cancer patients. Br J Cancer 74 (9): 1445-51, 1996. [PUBMED Abstract]
  2. Wolff AC, Hammond MEH, Allison KH, et al.: Human Epidermal Growth Factor Receptor 2 Testing in Breast Cancer: American Society of Clinical Oncology/College of American Pathologists Clinical Practice Guideline Focused Update. J Clin Oncol 36 (20): 2105-2122, 2018. [PUBMED Abstract]
  3. Breast. In: Amin MB, Edge SB, Greene FL, et al., eds.: AJCC Cancer Staging Manual. 8th ed. New York, NY: Springer, 2017, pp. 589–628.
  4. Wolff AC, Hammond ME, Hicks DG, et al.: Recommendations for human epidermal growth factor receptor 2 testing in breast cancer: American Society of Clinical Oncology/College of American Pathologists clinical practice guideline update. J Clin Oncol 31 (31): 3997-4013, 2013. [PUBMED Abstract]
  5. Wolff AC, Hammond ME, Hicks DG, et al.: Recommendations for human epidermal growth factor receptor 2 testing in breast cancer: American Society of Clinical Oncology/College of American Pathologists clinical practice guideline update. Arch Pathol Lab Med 138 (2): 241-56, 2014. [PUBMED Abstract]

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