Surrogate endpoints for early-stage breast cancer: a review of the state of the art,controversies,and future prospects

Pathological complete response

The preferred definition of pathological complete response (pCR) is the absence of residual invasive cancer within both the breast and lymph nodes through hematoxylin and eosin staining of the complete resected breast specimen and all sampled regional lymph nodes. ¹¹ No standard definition of pCR exists across different studies, and the FDA has proposed two different definitions: (1) no invasive and non-invasive residual cancer in the breast and lymph nodes (ypT0 ypN0)^11,12 and (2) no invasive residual cancer in the breast and lymph nodes irrespective of residual non-invasive disease (ypT0/is ypN0).^13–15 Despite uncertainty about the exact definition and its prognostic impact on survival, pCR is included in the FDA’s Surrogate Endpoint Table only for breast cancer and is used as an intermediate measure in clinical trials for patients with EBC who complete systemic neoadjuvant therapy. For high-risk EBC, pCR has been used as a surrogate endpoint reflective of treatment effect to support accelerated approval and a surrogate endpoint to support traditional approval. ¹⁶

A critical aspect that remains unanswered is whether the inclusion of patients with residual ductal carcinoma in situ (DCIS) among patients with pCR results in decreased recurrence-free survival (RFS) or OS. Pooled analyses with a large enough sample size have been carried out from different expert panels to draw a definitive conclusion on the best definition of pCR in terms of prognostic discrimination.

In 2007, an analysis of a US study group investigated whether the inclusion of patients with residual DCIS among patients with pCR results in decreased RFS or OS after preoperative chemotherapy. The retrospective review of a database of 2302 breast cancer patients who received neoadjuvant chemotherapy and attained either pCR (ypT0 ypN0) or pCR plus DCIS (ypT0/is ypN0) showed that both the DFS at 5 (87.1% in both groups) and 10 years (81.3% versus 81.7%, respectively) and the OS at 5 (91.9% versus 92.5%, respectively) and 10 years (91.8% versus 92.5%, respectively), as well as the 5-year locoregional RFS (92.8% versus 90.9%, respectively) did not differ significantly between the groups of patients. The authors concluded that the inclusion of residual DCIS did not confer any significant adverse prognostic effect for patients who experience a complete eradication of invasive cancer from the breast and lymph nodes after preoperative chemotherapy. Thus, considering patients with residual DCIS in the definition of pCR is justified when this outcome is used as an early surrogate for long-term survival. ¹⁵

In contrast, a more recently pooled analysis conducted by two German study groups examined the impact on survival of different pCR definitions on 6377 patients with primary breast cancer receiving neoadjuvant chemotherapy and revealed that patients who experienced ypT0 ypN0 had better DFS [hazard ratio (HR) = 1.74, 95% confidence interval (95% CI) = 1.28–2.36, p < 0.001] and a trend in better OS (HR = 1.41, 95% CI = 0.87–2.29, p = 0.166) compared with patients who attained ypT0/is ypN0. Thus, ypTis, ypT1mic, and ypN+ residuals are associated with increased relapse risk and should therefore no longer be considered in the definition of pCR. ¹¹

Thus, the definition of pCR associated with the most favorable outcome seems to be ypT0 ypN0.

pCR by breast cancer subtypes

The inability to demonstrate a clear correlation between early response to neoadjuvant therapy and prognosis of patients with breast cancer could be explained by heterogeneity across breast cancer patients with different tumor subtypes who received different treatment regimens and contributing with different improvements of pCR.

Houssami and colleagues performed a meta-analysis on 11,695 breast cancer subjects from 30 eligible studies, aiming to report summary estimates of pCR by tumor subtype, and to compare pCR rates according to different subtypes, using methods that allow for heterogeneity across studies. The overall pooled pCR (ypT0 ypN0) rate was 18.9% (16.6–21.5%) with a great difference among breast cancer subtypes: the highest odds of pCR were observed in the HER2-positive/hormone receptor-negative subtype (38.9%), followed by the triple-negative subtype (31.1%), the HER2-positive/hormone receptor-positive subtype (18.7%), and the hormone receptor-positive/HER2-negative subtype (8.3%). ¹⁷

In another pooled analysis on 6377 patients with primary breast cancer receiving neoadjuvant chemotherapy, von Minckwitz and colleagues demonstrated that pCR (ypT0 ypN0) is not associated with improved DFS in subgroups having slowly proliferating tumors (luminal A, p = 0.39, or luminal B/HER2-positive, p = 0.45), whereas pCR is a suitable surrogate endpoint for patients with HER2-positive/non-luminal, triple-negative (both ps < 0.001), and luminal B/HER2-negative (p = 0.005) tumors. ¹¹

The confirmation that the prognostic relevance of pCR differs across breast cancer subtypes emerged from the meta-analysis funded by the FDA and conducted by the CTNeoBC on 11,955 patients who received neoadjuvant treatment of breast cancer. Cortazar and colleagues reported that the association between pCR (ypT0/is ypN0) and long-term EFS or OS outcomes was strongest in patients with TNBC (EFS: HR = 0.24, 95% CI = 0.18–0.33; OS: HR = 0.16, 95% CI = 0.11–0.25) and in those with HER2-positive/hormone receptor-negative tumors who received trastuzumab (EFS: HR = 0.15, 95% CI = 0.09–0.27; OS: HR = 0.08, 95% CI = 0.03–0.22). ¹⁸

Taken together, the results of both analyses^11,18 suggest that pCR’s association with survival is greatest in aggressive tumor subtypes, such as triple-negative and HER2-positive/hormone receptor-negative breast cancers, whereas less obvious in patients with hormone receptor-positive/HER2-negative tumors.

pCR as a trial-level surrogate for long-term survival outcomes

A surrogate endpoint must be validated opportunely to be considered as a substitute for the reference endpoint. Meta-analysis of randomized controlled trials constitutes a widely accepted approach for surrogacy evaluation in oncology, assessing the correlation between the surrogate endpoint and the final endpoint. ¹⁹ The standard meta-analytical approach considers two levels of validation for a surrogate endpoint: the individual level and the trial level. If an individual-level surrogate will correlate to the final endpoint means that, for each patient, it reliably predicts who will have relatively good outcomes from those who will have relatively poor outcomes. Whereas an intermediate endpoint will be considered a trial-level surrogate if findings of a between-arm comparison trial using an intermediate endpoint accurately predict the possible findings of a between-arm comparison trial using the definitive endpoint.

Different measures of validation have been proposed at individual level for pCR and time-to-event surrogates of long-term survival outcomes: (1) the adjusted HR between patients with and without pCR, (2) the coefficient of determination (R²) between endpoints at patient level, and the (3) Kendall’s τ or Spearman’s rank correlation coefficient (r_s) using a copula model. Alternatively, the usual measure of validation at the trial level was the coefficient of determination (R²) of the trial computed via a linear regression of the estimated treatment effects (R² of 0 indicates no association and an R² of 1 is a perfect association).^18,20–22

Although the lower risk of death among patients who experienced a pCR in breast and/or lymph nodes compared with patients with residual tumor at the end of neoadjuvant therapy, the statistically significant association between increased pCR rate and longer survival is not so obvious and does not automatically mean that treatment response also represents a surrogate measure for long-term survival.

In 2012, the FDA distributed its first draft guidelines to the industry stating that a new neoadjuvant treatment for high-risk patients with EBC could receive accelerated FDA approval if sufficient improvement in pCR rates over a standard treatment in a randomized controlled trial was demonstrated. ²³ The FDA guidelines were finalized in 2014. ²⁴ When first released, investigators commissioned by the FDA were performing the first large meta-analysis to assess pCR surrogacy. In the CTNeoBC pooled analysis of 12 international neoadjuvant randomized controlled trials, the HR for improved EFS was 0.44 (95% CI = 0.39–0.51) and improved OS was 0.36 (95% CI = 0.30–0.44) in patients with breast cancer who obtained pCR, and this effect was more marked in patients with more aggressive tumor subtypes. However, in the trial-level analysis, increased pCR frequency was not predictive of the improved clinical outcome by the same treatment in terms of both EFS (R² = 0.03, 95% CI = 0–0.25) and OS (R² = 0.24, 95% CI = 0–0.70); thus, the authors were not able to demonstrate pCR’s validity as a surrogate endpoint for improved survival. ¹⁸ This was probably due to several factors, including the overall low rates of pCR in the trials analyzed, population heterogeneity, and that only one trial out of 12 used targeted therapies.

The aforementioned lone trial was the NeOAdjuvant Herceptin (NOAH) phase 3 study, which randomized 235 patients with HER2-positive, locally advanced breast cancer to receive preoperative anthracycline/taxane regimen alone or in combination with trastuzumab. Gianni and colleagues showed that chemotherapy plus trastuzumab significantly improved pCR rates and, subsequently, that 5-year EFS was strongly associated with pathological complete remission (ypT0/is ypN0) in patients in the trastuzumab group compared with those in the chemotherapy group (58%; 95% CI = 48–66 versus 43%; 95% CI = 34–52, respectively), resulting in a 36% reduction in risk of death or recurrence (unadjusted HR = 0.64, 95% CI = 0.44–0.93, p = 0.016). ²⁵ In addition, the benefit of adjuvant trastuzumab in combination with chemotherapy was confirmed in the combined National Surgical Adjuvant Breast and Bowel Project (NSABP) B-31/North Central Cancer Treatment Group (NCCTG) N9831 trials reporting an absolute improvement in RFS during the first 5 years (HR = 0.65, 95% CI = 0.56–0.77, p < 0.001). ²⁶ Taken together, the findings from these studies suggest that a correlation between a complete response and long-term survival outcomes can be identified in randomized, controlled trials in selected subjects with specific breast cancer subtypes treated with more homogeneous therapeutic regimens.

Berruti and colleagues performed a trial-based meta-regression of 29 randomized studies that compared different systemic neoadjuvant treatments in a total of 14,641 unselected patients with breast cancer. A minimal association between the effect of the treatment on pCR and the effect on both DFS (R² = 0.08, 95% CI = 0–0.4) and OS (R² = 0.09, 95% CI = 0.01–0.41) was observed, thereby not supporting the use of pCR (regardless of the definition) as a surrogate endpoint for long survival. ²⁷ Intriguingly, an exploratory analysis of this meta-regression focusing on a subset of trials comparing intensified/dose-dense chemotherapy with standard-dose regimens revealed stronger associations between DFS (R² = 0.79, 95% CI = 0.26–0.95, p = 0.003) and OS (R² = 0.57, 95% CI = 0.19–0.93, p = 0.03). Besides the prognostic heterogeneity among breast cancer subtypes and differential responses to neoadjuvant chemotherapy, as observed in the CTNeoBC pooled analysis, the distinct pCR definitions used in addition to the disparate treatment regimens administered before and after surgery are confounders that potentially underlie the inability to demonstrate a clear pCR surrogacy.

By closely re-examining the evidence from Cortazar and Berruti’s previously published meta-analyses, Korn and colleagues found no evidence that pCR is a trial-level surrogate for EFS or OS. ²⁸

In contrast, a larger meta-analysis of 36 studies representing 5768 patients with stages I to III HER2-positive breast cancer found that improved pCR rates with the neoadjuvant therapy were associated with substantially longer times until recurrence (R² = 0.63) and death (R² = 0.29). ²⁹

Ki67 proliferation index

Ki67 represents a protein encoded by the MKI67 gene associated with cellular proliferation as it identifies cells in the G1/S and M phases of the cell cycle. High levels of Ki67 expression – which is examined as a continuous variable – routinely indicate increased cellular proliferation and, in breast cancer, elevated Ki67 is associated with impaired prognosis. In addition to being a surrogate for proliferative capacity and a useful breast cancer prognosticator, the Ki67 proliferation index has been proposed as a predictor of therapeutic benefit among patients with hormone receptor-positive breast cancer under treatment with neoadjuvant aromatase inhibitors. This is due to neoadjuvant endocrine treatment mainly inducing cell cycle arrest, hence the suppression of the proliferative marker Ki67, among other effects.

In the IMPACT trial comparing the preoperative use of tamoxifen with anastrozole alone or both combined in 330 postmenopausal women with primary hormone receptor-positive breast cancer, a decrease in the proliferative marker Ki67 occurred in the majority of patients. Intriguingly, significantly greater suppression of Ki67 was observed after 2 weeks in the anastrozole-treated group than in the tamoxifen- or combination-treated groups. ⁴⁴ Interestingly, in a multivariable analysis of the same trial, Dowsett and colleagues found that higher Ki67 expression after 2 weeks of presurgical endocrine therapy for primary breast cancer was statistically significantly associated with lower RFS (p = 0.004) and, thus, predicted outcome more faithfully than Ki67 levels at baseline. ⁴⁰

The POETIC phase 3 randomized controlled trial was designed to assess whether tumor Ki67 values after 2 weeks of perioperative aromatase inhibitor predict individual patient outcome better than baseline Ki67. ⁴⁵ Recent data indicate that women with low tumor levels of Ki67 both at baseline and 2 weeks have less 5-year recurrence risk (4.3%, 95% CI = 2.9–6.3) than women with high Ki67 levels at baseline and low at 2 weeks (8.4%, 95% CI = 6.8–10.5), or high both at baseline and 2 weeks (21.5%, 95% CI = 17.1–27.0). ⁴⁶

While the ALTERNATE phase 3 study is ongoing to provide the definitive clinical evidence to inform future practice, a Ki67 score >10% after 2 or 4 weeks of preoperative endocrine therapy has been suggested as the cutoff for accurately selecting individual non-responders who are, therefore, suitable for other treatment strategies, including investigational agents and/or chemotherapy.

PEPI score

PEPI is an algorithm combining anatomy and biology, to estimate the amount of residual cancer in a surgical specimen following preoperative therapy. It includes features from the initial diagnosis prior to neoadjuvant endocrine therapy and treatment responses to separate patients into prognostic groups, thus representing the major drawback because the final score cannot be obtained until patients have completed 4 months of endocrine therapy and undergone surgery. Specifically, the PEPI score takes into account pathological stage (tumor size and nodal status), Ki67 expression, and the Allred estrogen receptor (ER) score measured on the primary tumor during uninterrupted endocrine therapy. The scoring process produces three groups (risk groups 0, 1–3, and ⩾4) that were associated with different relapse risks (risk score 0 associated with a low risk of relapse/death and risk score ⩾4 associated with a high risk of relapse/death).

Data from the neoadjuvant P024 study comparing letrozole and tamoxifen in postmenopausal women with ER-positive breast cancer^38,47,48 were used to generate a PEPI score that was subsequently validated in an independent study of 203 postmenopausal women enrolled in the IMPACT trial, which compared treatment with anastrozole, tamoxifen, and the combination of anastrozole and tamoxifen for 3 months before surgery. ⁴⁹ Women from the P024 trial with PEPI scores of 0 (pT1 or pT2, pN0, Ki67 ⩽ 2.7%, Allred score > 2) after neoadjuvant endocrine therapy had an extremely low risk of relapse (10% of PEPI score 0 versus 23% of PEPI scores 1–3 versus 48% of PEPI score ⩾4) and, as such, are unlikely to benefit from adjuvant chemotherapy. ⁴⁹ The PEPI model based on these factors effectively predicted RFS in the IMPACT trial (p = 0.002).

Subsequently, the ACOSOG Z1031A randomized phase 2 trial was designed to determine which aromatase inhibitor – anastrozole, letrozole, or exemestane – should be used in future testing against chemotherapy in the neoadjuvant setting. When enrollment in ACOSOG Z1031A was complete, an amendment was introduced (ACOSOG Z1031B) that triaged patients with tumors exhibiting a Ki67 > 10% upon biopsy 2–4 weeks after starting aromatase inhibitors to standard chemotherapy. The hypothesis being tested was that the pCR rate would be at least 20% in this aromatase inhibitor-resistant population. For the 3.7% of patients (4 of 109) with PEPI score of 0, the relapse risk over 5 years was only 3.6% without chemotherapy compared with 14.4% of patients (49 of 341) with PEPI scores ⩾0 (recurrence HR = 0.27, p = 0.014), supporting the study of adjuvant endocrine monotherapy in this group. ⁴¹

As for the Ki67 proliferation score, the PEPI triage approach is being definitively investigated in the ALTERNATE trial, which will provide an indication for adjuvant chemotherapy.

Genomic signatures

The introduction of innovative, advanced molecular technologies such as RNA sequencing and DNA microarray analysis has allowed us to decipher the molecular subtypes of each tumor, with distinct biological features that lead to differences in response patterns and clinical outcomes, shedding light on the heterogeneous complexity of luminal breast tumors. Global gene expression profiling analyses have provided evidence for classifying breast cancer into the following five distinct molecular classes according to the hierarchical clustering of thousands of genes simultaneously expressed: (1) Luminal A [representing the immunohistochemically defined tumors with ER-/Progesterone receptor (PR)-positive, HER2-negative, histological grade I/II, low Ki67 index], (2) Luminal B (ER-/PR-positive, HER2-negative/positive, histological grade II/III, high Ki67 index), (3) HER2-enriched (ER-/PR-negative, HER2-positive, histological grade II/III), (4) Basal-like (ER-/PR-/HER2-negative, histological grade III), and (5) Normal-like (ER-/PR-positive, HER2-negative, histological grades I–III, low Ki67 index). ⁵⁰ In the context of the luminal-like subclasses, the low-proliferating luminal A breast tumors – accounting for 50–60% of all breast cancers – present a more favorable clinical than the luminal B subtype and seem to benefit more from endocrine therapy alone versus the combination of chemotherapy and endocrine therapy.^51,52 While the highly proliferative and more aggressive luminal B breast tumors – comprising 15–20% of all breast cancers – may derive more benefit from the combined therapeutic strategy of chemotherapy and endocrine therapy. ⁵³ In luminal EBC, additional prognostic indicators are required to identify patients with a late recurrence risk and provide them with a reliable and effective therapeutic plan. In addition, several gene-expression-based prognostic signatures describe the unique molecular portrait associated with a tumor, and estimate the residual risk of recurrence (ROR) and post-surgery survival. The availability of these multigene signatures is nowadays paving the way for the development of de-escalation and escalation treatment strategies.

The Oncotype DX^® Recurrence Score (RS), ⁵⁴ MammaPrint^®, ⁵⁵ EndoPredict (EP/EPclin), ⁵⁶ Prosigna^® Risk of Recurrence Score, ⁵⁷ and Breast Cancer Index^SM (BCI) are the five commercially available multigene assays and the most widely used prognostic signatures in early luminal breast cancer to be endorsed by clinical practice guidelines. In addition, these multiparameter prognostic signatures can be used to guide the treatment of patients with ER-positive/HER2-negative primary breast cancer, thus helping to de-escalate systemic therapy.

The Oncotype DX^® RS (Genomic Health) based on the 21-gene breast cancer assay consists of a molecular signature of 16 prognostic genes, 13 of which are grouped into modules of proliferation, with the ER, HER2, and invasion pathways weighted differentially in a final signature algorithm. ⁵⁴ The 5- or 10-year risk of distant relapse is stratified by RS into three risk groups that classify patients as low (RS < 18), intermediate (18 ⩽ RS ⩽ 31), and high risk (RS > 31). The cutoff points for the expression of the individual genes were based on tumor samples from the NSABP B-20 trial, ⁵⁴ and the final validation was performed on ER-positive/HER2-negative and HER2-positive, node-negative patients treated with tamoxifen from the NSABP B-14 trial. The RS has been validated in NSABP B-20, ⁵⁸ TransATAC, ⁵⁹ and Southwest Oncology Group (SWOG) 8814 studies. ⁵¹ Recent findings from the prospective The Trial Assigning Individualized Options for Treatment (TAILORx) study on 10,273 women with hormone receptor-positive/HER2-negative, node-negative breast cancer showed that adjuvant endocrine therapy was non-inferior to chemoendocrine therapy in the analysis of invasive DFS for patients aged >50 years with midrange RS (11–25). ⁶⁰

The ongoing randomized Rx for Positive Node, Endocrine Responsive breast cancer (RxPONDER) (ClinicalTrials.gov identifier: NCT01272037) and West German Study Group-Adjuvant Dynamic marker-Adjusted Personalized Therapy (WSG-ADAPT) trials (ClinicalTrials.gov identifier: NCT01817452) will contribute to defining the optimal RS cutoff values for patients with hormone receptor-positive/HER2-positive EBC who may be spared adjuvant chemotherapy. Finally, the prospective phase 3 WSG-ADAPTcycle trial (ClinicalTrials.gov identifier: NCT04055493) will provide evidence for chemotherapy omission in patients with intermediate RS who can be treated with cyclin-dependent kinase (CDK) 4/6 inhibitor ribociclib combined with endocrine therapy.

MammaPrint^® (Agendia NV) is a microarray-RNA 70-gene prognostic test that provides a numerical index ranging from −1 to +1. This value is used to classify patients with breast cancer into high- and low-risk groups estimating the risk of relapse within 10 years for both untreated patients and patients treated with endocrine therapy alone. ⁵⁵

The microarRAy-prognoSTics-in-breast-cancER (RASTER) trial was the first study designed to prospectively evaluate the performance of the MammaPrint^® signature in patients with node-negative EBC, ⁶¹ and the randomized European Organisation for Research and Treatment of Cancer (EORTC) 10041/BIG3-04 phase 3 trial confirmed its clinical utility in 6693 women with node-negative and 1–3 node-positive EBC thereafter. ⁶² After having determined the genomic risk of relapse by the 70-gene signature and clinical risk of relapse using a modified version of Adjuvant! Online, patients were divided into four groups: women at low clinical and genomic risk did not receive chemotherapy, women at high clinical and genomic risk did receive such therapy, women with a discordant genomic risk or clinical risk were randomized to receive endocrine therapy alone, and women with a discordant genomic risk or clinical risk were randomized to receive combined chemo- and endocrine therapy in an adjuvant setting.

The first aim of Microarray In Node negative Disease may Avoid ChemoTherapy (MINDACT) was to assess the lower boundary of the 95% CI for the rate of the 5-year survival without distant metastasis would be equal to or higher than 92%. At 5 years, among the 1550 patients (23.2%) at high clinical risk and low genomic risk who did not receive chemotherapy, the rate of survival without distant metastasis was 94.7% (95% CI = 92.5–96.2), thereby achieving the study’s primary endpoint. The absolute difference in this survival rate among patients at high clinical risk and low genomic risk who did not receive chemotherapy relative to those who received chemotherapy was 1.5% lower with no clear difference according to nodal status. Thus, these findings suggested that approximately 46% of women with breast cancer who are at high clinical risk could safely omit adjuvant chemotherapy and its toxic effects at a cost of a rate of survival without distant metastasis that was 1.5 percentage points lower than the rate with chemotherapy. ⁶² Long-term results from 5-year ⁶³ and 8-year ⁶⁴ estimates for distant metastasis-free survival showed the intact ability of a 70-gene signature to identify women with high clinical risk and low genomic risk when treated with adjuvant endocrine therapy alone, confirming MINDACT as a positive de-escalation study. Interestingly, an underpowered exploratory analysis confined to the subgroup of patients with luminal EBC revealed an age-dependent benefit with women over 50 years old at clinical high but genomic low risk who benefit the most from the chemotherapy-free strategy. ⁶⁴ On the contrary, however, for women younger than 50 years, the benefit of chemotherapy is present, perhaps due to ovarian function suppression induced by chemotherapy. Further research is needed to better understand the role of genomic information in younger women who can continue to be spared adjuvant chemotherapy and to encourage future investigations into de-escalation strategies.

The EndoPredict^® (Myriad Genetics, Inc.) is a 12-gene signature-based risk score, which ranges between 0 and 15 according to the expression of eight prognostic genes. The more comprehensive risk score EPclin could be obtained combining the EP score with tumor size and nodal status to provide decision-making results on the benefit of chemotherapy and extended endocrine therapy in postmenopausal patients with ER-positive/HER2-negative, node-negative breast tumors. ⁵⁶

EP and EPclin scores were evaluated as independent prognostic parameters in 664 patients with ER-positive/HER2-negative breast cancer with both node-negative and node-positive forms for adjuvant chemotherapy and endocrine therapy. ⁶⁵ Thereafter, EP and EPclin were validated in the ABCSG-6 and ABCSG-8 trials ⁵⁶ and TransATAC. ⁶⁶ This multigene signature was based on the prognostic genes mainly associated with ER signaling pathways, suggesting its ability to predict the benefit of an extended adjuvant endocrine therapy in the low-risk group. However, prospective randomized trials are needed to confirm this assumption.

The Prosigna^®/PAM50/Risk of ROR test (NanoString Technologies) is a 50-gene signature based on NanoString nCounter^® technology, which, in addition to distinguishing between the intrinsic molecular subtypes of a breast tumor, provides the probability of distant recurrence. The clinically applied Prosigna^® score integrated with a proliferation score, and tumor size information generates the ROR score. Depending on the nodal status, the ROR is categorized differently on a scale from 0 to 100 through its association with the 10-year probability of distant recurrence: in node-negative cancers, ROR is classified as low (0–40), intermediate (41–60), or high (61–100); in 1–3 node-positive cancers, ROR is classified as low (0–15), intermediate (16–40), or high (41–100); and in >4 node-positive cancers, ROR is classified as high risk. The ROR score was validated in the TransATAC, ⁴² ABCSG-8, ⁶⁷ and Danish Breast Cancer Cooperative Group (DBCG) cohorts ⁶⁸ to reliably predict the risk of relapse for postmenopausal women with hormone receptor-positive, node-negative (stage I or II), or node-positive (stage II or IIIA) EBC to be treated with adjuvant endocrine therapy. Despite the well-known prognostic value of the Prosigna^® test, the large, prospective Optimal Personalised Treatment of early breast cancer usIng Multiparameter Analysis (OPTIMA) trial is validating the predictive value and cost-effectiveness of the Prosigna^® PAM50-based test-guided chemotherapy decisions in node-positive patients with EBC patients. ⁶⁹

BCI (Biotheranostics, Inc.) represents a combined signature also known as the molecular grade index that combines a ratio of the HOXB13 and IL17BR genes with five proliferation genes measured by reverse-transcription polymerase chain reaction. This test determines the risk of both early and late (>5 years) distant recurrences and the likelihood of a benefit from endocrine therapy in postmenopausal patients with node-negative, ER-positive breast cancer receiving adjuvant endocrine therapy. ⁷⁰ The prognostic utility of the test was first proved in recurrences matched to non-recurrences tumor samples from patients within NCIC CTG MA.17 trial who was investigated for late recurrence and treatment benefits from extended adjuvant letrozole. A subgroup of patients who were ER-positive and disease-free after 5 years of tamoxifen, yet still at risk for late recurrence, were characterized by a high ratio of HOXB13 and IL17BR genes; when an extended adjuvant endocrine therapeutic course with letrozole is prescribed, this gene ratio reveals a subgroup of patients with a 16.5% reduction in their absolute ROR at 5 years. ⁷⁰

Although its prognostic ability for risk of both early and late distant recurrence was further validated in the TransATAC ⁷¹ and Stockholm ⁷² trials, the definitive clinical evidence of the extension of adjuvant endocrine therapy beyond 5 years and the use of the BCI in luminal, node-positive EBC is still missing.

In summary, the deep genetic characterization of EBC is providing a uniquely useful tool in treatment decision making by algorithms based on the combination of biological, clinical, and genomic features. Only the Oncotype DX^® and MammaPrint^® multigene signatures have been validated by prospective, randomized phase 3 trials. The prognostic and predictive role of the other multigene signatures should be prospectively confirmed in large cohorts of patients with hormone receptor-positive/HER2-negative EBC before they are implemented in the clinic for a better individualization of systemic treatments.

HER2-positive early breast cancer

Although the arrival of anti-HER2 therapies has substantially improved the prognosis of HER2-positive breast cancer patients, ⁷⁴ several questions on the appropriate treatment strategies remain unsolved. One year of adjuvant trastuzumab combined with chemotherapy represents the current standard of care. However, some patients will relapse despite receiving the optimal treatment.

On one hand, the addition of trastuzumab to adjuvant anthracycline and taxane-based chemotherapy increases the risk of cardiac events, and trastuzumab-associated cardiotoxicity remains the main cause of its discontinuation.^75,76 On the other hand, patients observed in clinical practice compared with patients enrolled in randomized trials often present histological characteristics associated with a lower risk of relapses, such as small tumors, negative nodes, or hormone receptor-positive status. ⁷⁷

Thus, recent clinical research efforts have focused on improving treatment individualization and the risk/benefit ratio for patients with HER2-positive EBC using two distinct strategies: potentiating the efficacy of standard treatments for high-risk patients and developing de-escalated treatments for low-risk patients.

Triple-negative early breast cancer

TNBC, accounting for approximately 15% of all invasive breast cancers, constitutes the poorest prognostic breast cancer subtype, due mainly to the lack of targeted treatments. Systemic chemotherapy with sequential anthracycline and taxanes is the mainstay treatment. Despite not yet being recommended as a standard of care, platinum-containing regimens showed to increase pCR rate in germinal BRCA1/2 mutated patients. About 33% of patients with TNBC achieve a pCR following neoadjuvant chemotherapy, ¹⁸ which extends up to 53.2% or 54% for the GeparSixto ¹⁰⁰ and CALGB 40603 ¹⁰¹ trials, respectively, following platinum-based neoadjuvant regimens.

The term TNBC actually shows a remarkable diversity of prognosis and clinical response to cancer treatment. Analysis of TNBC gene expression profiling unveiled a highly diverse group of cancers, each displaying unique biology. The TNBC molecular subtypes consist of two basal-like, a mesenchymal, and a luminal androgen receptor (AR) subtype. ¹⁰² The four molecular subtypes present specific somatic alterations and distinct clinicopathological characteristics, such as age at diagnosis, histopathology, tumor grade, and disease progression; however, the transcriptional profiling is not able to predict pCR for neoadjuvant chemotherapy in patients with TNBC.

Hormone receptor-positive/HER2-negative, EBC