Abstract
Purpose
Breast cancer (BC) is the most common malignancy among women and prognosis is strongly influenced by tumor subtype. Neoadjuvant chemotherapy (NAC) is the standard treatment for both locally advanced- and early-stage triple-negative and Her2-positive BC. Pathologic complete response (pCR) to NAC is an important predictor of patient outcomes. Neutrophil-to-lymphocyte-ratio (NLR) in peripheral blood is associated with prognosis in various malignancies. Here, we investigated the value of the pretreatment NLR as a response predictor in neoadjuvant-treated patients with BC.
Methods
A retrospective chart analysis of 862 patients with invasive BC treated with NAC at the Heidelberg University Hospital during 2003–2015 was conducted. NLR was calculated as the ratio of the absolute neutrophil and lymphocyte counts in peripheral blood, and pCR was defined as absence of invasive or in situ carcinoma in breast and axillary lymph nodes.
Results
A total of 151 patients with invasive BC who underwent NAC were included in this study. NLR tended to be higher in the pCR group than the non-pCR group (p < 0.1). Analyses of BC subtypes demonstrated that NLR was significantly higher in the pCR- compared with the non-pCR group (3.304 vs. 2.379, respectively; p = 0.048) in patients with luminal B/Her2-negative tumors. Further, we found a significant difference in NLR according to remission status in postmenopausal patients (2.861 vs. 2.313, respectively; p = 0.043).
Conclusion
NLR was significantly higher only for patients achieving pCR in the Luminal B/Her2-negative and postmenopausal subgroups. Hence, NLR is a candidate additional predictive factor in patients with Luminal B/Her2-negative BC.
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A high NLR in patients with early breast cancer may correlate with a good response to neoadjuvant chemotherapy. In our study, we observed this effect in postmenopausal patients and patients with Luminal B/Her2-negative tumors. |
Introduction
Breast cancer (BC) is the most common malignancy among women worldwide [1]. BC intrinsic subtype (Luminal A, Luminal B/Her2-positive, Her2-negative, Her2-enriched, and Triple-negative subtype), tumor characteristics (e.g., tumor size, nodal status), patient characteristics (e.g., age, menopausal status), and particularly response to treatment are important parameters in estimating patient prognosis [2, 3]. Regarding response to treatment, pathologic complete response (pCR) to neoadjuvant chemotherapy is of particular prognostic value for determining the outcomes of patients with BC. Recent trials showed that patients with several BC subtypes who attain pCR have improved survival; however, not all patients benefited equally [4,5,6,7].
According to current research, the host immune system also plays a crucial role in cancer development, progression, and metastasis [8, 9]. Systemic inflammatory markers, such as platelet-to-lymphocyte-ratio, neutrophil-to-lymphocyte-ratio (NLR), and lymphocyte-to-monocyte-ratio, have been reported to correlate with prognosis or pCR in various types of malignancy, including BC [10,11,12,13,14]. Some years ago, Templeton and colleagues assessed the prognostic effect of NLR undertaking a meta-analysis of 100 studies comprising 40,559 patients with unselected solid tumors. They found that an elevated NLR was associated with decreased overall survival (hazard ratio 1.81; 95% confidence interval = 1.67–1.97; p < 0.001) with the highest NLR in mesothelioma (hazard ratio 2.35; 95% confidence interval = 1.89–2.92), followed by pancreatic cancer (hazard ratio = 2.27; 95% confidence interval = 1.01–5.14) and renal cell carcinoma (hazard ratio = 2.22; 95% confidence interval = 1.01–5.14). [15]
While lymphocytes are important key contributors to immune reactions against tumors, neutrophils can suppress the anti-tumor activity of lymphocytes and promote tumor cell migration, as well as angiogenesis [16,17,18]. These blood-based parameters could provide an additional, cost-effective, and easy to perform method of risk assessment.
The main aim of this study was to investigate the role of the NLR as a response predictor in neoadjuvant-treated patients with BC.
Patients and methods
Study design and patients
In this study, we performed a retrospective chart analysis of 862 patients with invasive BC who were treated with neoadjuvant chemotherapy at the Heidelberg University Hospital in the years 2003–2015. Data were collected using the patient data management program ISHmed® (SAP GmbH Walldorf, Germany). As shown in Fig. 1, according to the exclusion criteria, 711 patients were excluded: 672 because of incomplete laboratory data, 11 with bilateral invasive BC with various cancer phenotypes, 10 with autoimmune disease, 8 with a secondary malignancy, 3 with acute or chronic inflammatory disease, 2 with cardiovascular disease, 3 due to primary metastasis, and 2 because they were pregnant or breast feeding. Finally, the medical records of 151 patients with BC were eligible for inclusion in the present investigation.
Concerning patient characteristics, we collected data on patient medical history, age, body mass index (BMI), menopausal status, tumor characteristics (size, stage, nodal status, histopathological characteristics), and laboratory results (absolute neutrophil count, absolute monocyte count, absolute platelet count, absolute lymphocyte count). Using a differential blood count performed after BC diagnosis and before treatment initiation, NLR was calculated as the ratio of the absolute neutrophil count to the absolute lymphocyte count.
Estrogen receptor (ER), progesterone receptor (PR), and human epidermal growth factor receptor 2 (Her2) expression were primarily assessed by immunohistochemistry. Fluorescent or chromogenic in situ hybridization was performed for cases with intermediate Her2 scores (2 +). According to the definition of Goldhirsch et al., we used clinicopathological parameters to define the BC subtypes: luminal A (ER + , PR ± , Her2-, Ki-67 < 20%), luminal B/Her2-negative (ER + , PR ± , Her2-, Ki-67 ≥ 20%), luminal B/Her2-positive (ER + , PR ± , Her2 +), Her2-enriched (ER-, PR-, Her2 +), and triple-negative BC (TNBC) (ER-, PR-, Her2-) [18]. A pCR was defined as the total absence of invasive or in situ carcinoma within the breast and axillary lymph nodes (ypT0 ypN0).
The present investigation was approved by the University of Heidelberg Ethics Committee (S-094/2017).
Statistics
Accrued data were pseudonymized and analyzed using SPSS statistics version 24.0 (SPSS Inc., Chicago, USA). Data are presented as mean ± standard deviation (SD) (unless stated otherwise) in case of continuous variables and as absolute and relative frequencies in case of categorical variables. For statistical comparisons of mean values, t tests or ANOVA models were applied. To assess differences in ordinal variables Mann–Whitney U tests were used, Pearson’s chi-squared tests were applied in case of nominal (categorical) variables. The level of significance was set to 5%; therefore, a p value of < 0.05 was considered statistically significant; for p values of < 0.1, a tendency toward difference was assumed. Since this was an exploratory study, we did not apply any adjustment for multiplicity.
Results
Patient and tumor characteristics
From 2003 to 2015, a total of 862 patients with invasive BC who underwent neoadjuvant chemotherapy were eligible for this study. Based on the exclusion criteria, 711 patients were not included in the statistical analyses (Fig. 1). Hence, the total study cohort comprised 151 patients. As shown in Table 1, the mean age at primary diagnosis was 50 years (± 11.03; range 27–77 years). The majority (58.9%, n = 89) of our cohort were premenopausal, while 41.1% (n = 62) were postmenopausal. At 55% (n = 83), the majority of our patients had an initial tumor size of cT2, while 23.2% (n = 35), 11.2% (n = 17), and 10.6% (n = 16) had cT1-, cT3-, and cT4-stage tumors, respectively (Table 1). At primary diagnosis, 87 patients were node-negative (cN0; 57.6%). Regarding the tumor subtypes in our cohort, 42 patients (27.8%) had luminal B/Her2-negative, 36 (23.8%) luminal B/Her2-positive, 56 (37.1%) triple-negative, and 17 (11.3%) Her2-enriched subtype tumors. There were no luminal A tumors in our cohort. All patients were treated with standardized neoadjuvant chemotherapy, which in most cases consisted of taxane + anthracycline and/or cyclophosphamide (Table 1). All Her2-positive patients were additionally treated with trastuzumab. A total of 66 patients achieved pCR (43.7%) while 85 (56.3%) showed residual invasive or in situ carcinoma. The highest pCR rate (88%; n = 15/17) was observed for patients with Her2-enriched subtype tumors.
NLR
We investigated associations of NLR with both clinical and histopathological parameters and found that it was significantly higher in younger patients (age < 50 years, NLR = 3.129 ± 1.725 vs. age ≥ 50 years, 2.628 ± 1.225; p = 0.042), premenopausal patients (premenopausal patients, mean NLR = 3.151 ± 1.742 vs. postmenopausal patients 2.499 ± 1.014; p = 0.009), and patients with BMI < 25 kg/m2 (BMI < 25 kg/m2, NLR = 3.186 ± SD 1.793 vs. BMI ≥ 25 kg/m2 2.655 ± 1.232; p = 0.033). Furthermore, patients with Her2-positive tumors also had significantly higher NLR values than those with Her2-negative tumors (3.263 ± 1.546 vs. Her2-negative 2.678 ± 1.468; p = 0.023). No significant differences in NLR were detected according to ER- and PR-status (Table 2).
Our primary objective was to investigate the association between NLR and pCR. Hence, we divided our cohort into two subgroups: pCR and non-pCR. With a mean ratio of 3.118 ± 1.783, NLR tended to be higher in the pCR group than the non-pCR-group (NLR = 2.702 ± 1.253); however, the difference was not statistically significant (p = 0.095) (Table 2). To better understand the role of BC subtype, we conducted a sub-analysis. The results demonstrated that, for luminal B/Her2-negative patients, NLR was also higher in the pCR-subgroup compared with the non-pCR-subgroup; however, the difference was significant in this case (3.304 ± 1.582 vs. non-pCR 2.378 ± 1.0435; p = 0.048). Regarding the TNBC, luminal B/Her2-positive, and Her2-enriched subtypes, no association was detected between NLR and achieving pCR.
Since we found differences in NLR depending on age and menopausal status, we performed sub-analyses for the premenopausal (n = 89) and postmenopausal (n = 62) patient cohorts (Table 3). In the postmenopausal cohort, NLR was significantly higher among patients achieving pCR (2.861 ± 1.068) than for those who did not (non-pCR) (2.313 ± 0.945; p = 0.043). Furthermore, we also found that NLR was significantly higher among postmenopausal patients with luminal B/Her2-negative subtype tumors who achieved pCR (5.338 ± 0.370) compared with those who did not (2.362 ± 1.241; p = 0.004). For the premenopausal cohort, we did not detect any significant differences in NLR among the different subsets (Table 3).
Discussion
The present investigation focused on the role of NLR as a response predictor in neoadjuvant-treated patients with different BC subtypes. Several previous reports have suggested that patients with cancer who have an elevated pretreatment NLR have worse prognosis than those with low values for this parameter [10,11,12]; however, the data relating to NLR in BC are heterogeneous [20]. On the one hand, Noh and Han found that there was a significant correlation between a low NLR and superior disease-specific survival in patients with BC, although analysis by subtype only detected a significant difference for the luminal A cohort [12]. On the other hand, Patel et al. showed that low NLR was significantly associated with longer overall survival in TNBC patients. [21] In contrast, Suppan et al. and Goto et al. did not detect an association between NLR and disease-free survival, independent of the BC subtype [22, 23].
In our study, we found that elevated pretreatment NLR tended to be associated with a pCR after neoadjuvant chemotherapy, which was significant for postmenopausal patients and those with luminal B/Her2-negative tumors. As described above, pCR after neoadjuvant chemotherapy seems to be of prognostic value for determining better outcomes of patients with BC [4, 6]. Initially, this may appear to be contradictive to the trials that found that a high NLR was associated with a worse prognosis. However, as patients with more aggressive tumors are more likely to achieve a pCR, this may not be the case. Characteristics, such as a high proliferation index, high tumor grade, triple-negative or Her2-enriched subtype or young age at primary diagnosis, are associated with higher rates of pCR [4, 24]. In our patient cohort, we also found that the tumor grade G3, younger age (< 50 years), premenopausal status, and Her2-enriched phenotype were significantly associated with high NLR; these findings are consistent with the current literature [12, 23]. Those characteristics are routinely used as part of the process of indication for undergoing neoadjuvant chemotherapy. While patients with triple-negative or Her2-positive tumors are currently routinely treated with (neo-) adjuvant chemotherapy (± Her2-targeted antibody therapy), the optimal treatment for the luminal B/Her2-negative subgroup of patients remains under discussion. In clinical practice, the original molecularly defined BC subtypes are routinely classified by a pathological examination, according to Goldhirsch et al. [25]; however, using immunohistochemical methods, clear differentiation between luminal A-like and luminal B-like tumors can be challenging. Recently, several gene expression tests, such as Prosigna or Oncotype DX, have been developed as an additional aid to treatment decisions concerning adjuvant chemotherapy in patients with early luminal BC [26]. Although the treatment recommendations are relatively clear for patients with low or high risk of recurrence scores, the interpretation of intermediate risk of recurrence scores remains under investigation. Moreover, to date, gene expression tests are performed using breast tumor specimens usually collected intraoperatively, which stands against the possibility of neoadjuvant treatment. Consequently, those patients may not benefit from the advantages of a neoadjuvant therapy, such as down-staging of tumors with consecutively reduced surgical invasiveness or in vivo analysis of sensitivity to treatment [27]. Combined with the fact that pCR is a suitable predictor of superior outcome, the results of our study, demonstrating that patients with luminal B/Her2-negative tumors achieving pCR had a significantly higher pretreatment NLR, it is possible that patients with elevated NLR, and particularly those with luminal B/Her2-negative tumors, benefit from neoadjuvant treatment.
Still our study has several limitations. Specifically, the investigation was retrospective in design and the sample size was very small; although we investigated a total of 862 patients, 672 were excluded because of insufficient laboratory data. Therefore, data interpretation is only possible to a limited extent and the results should first be verified on a larger cohort. Furthermore, we do not have survival outcome data for the majority of eligible patients. Hence, we could not compare the actual survival data with the prognostic value of pCR.
In conclusion, our results suggest that, for postmenopausal patients with BC and those with luminal B/Her2-negative subtype tumors, pretreatment NLR may provide additional information regarding the likelihood of achieving a pathologic complete response to neoadjuvant chemotherapy. As pCR is a suitable surrogate end point, we assume that pretreatment NLR could be considered as an additional predictive factor for patients with luminal B/Her2-negative subtype BC. Future prospective studies are necessary to confirm our findings in a larger patient cohort and further evaluate the underlying molecular mechanism.
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Acknowledgements
We thank the Medical Faculty of Heidelberg University for supporting this work by a research scholarship for Alexandra von Au.
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Open Access funding enabled and organized by Projekt DEAL. This work was supported by the Medical Faculty of Heidelberg University by a research scholarship for Alexandra von Au.
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AvA: project development, data management, data analysis, manuscript writing/editing. SS: project development, data collection, data analysis, manuscript writing/editing. LU.: statistical analysis, manuscript editing. LMayer: data management, manuscript editing. LMichel: data analysis, manuscript editing. MW: data analysis, manuscript editing. AH: data analysis, manuscript editing. TD: data collection, manuscript editing. FR: data collection, manuscript editing. JH: data analysis, manuscript editing. MG: data analysis, manuscript editing. AS: interpretation of data, manuscript editing. FS: project development, manuscript editing. CD: project development, data analysis, manuscript writing/editing.
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von Au, A., Shencoru, S., Uhlmann, L. et al. Predictive value of neutrophil-to-lymphocyte-ratio in neoadjuvant-treated patients with breast cancer. Arch Gynecol Obstet 307, 1105–1113 (2023). https://doi.org/10.1007/s00404-022-06726-7
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DOI: https://doi.org/10.1007/s00404-022-06726-7