Evaluation of Tumor Elasticity and Clinicopathologic Factors Affecting Neoadjuvant Chemotherapy Response in Patients with Breast Cancer
Article information
Abstract
Purpose
This study aimed to determine the clinicopathologic factors, including tumor elasticity, affecting neoadjuvant chemotherapy response in breast cancer.
Methods
Among 95 patients who received neoadjuvant chemotherapy for clinical stage IIa-IIIc primary breast cancer, 75 underwent strain elastography assessments. The patients were divided into soft and hard tumor groups based on the Tsukuba elasticity scoring system. Pathologic factors, including tumor cellularity and stromal characteristics, were evaluated using core needle biopsy specimens collected before neoadjuvant chemotherapy. Pathologic complete response (pCR) was defined as the absence of invasive carcinoma in the breast and axillary lymph nodes. Residual cancer burden (RCB) was also calculated in 79 cases.
Results
Twenty-two patients achieved pCR (23.2%). The rates of estrogen receptor (ER) negativity (p=0.04), progesterone receptor (PR) negativity (p=0.03), and nuclear grade 3 (p=0.03) were higher in patients with pCR than those in patients without pCR. The rates of PR negativity (p=0.03), nuclear grade 3 (p=0.01), and high tumor-infiltrating lymphocyte (TIL) levels (p=0.04) were significantly higher in the favorable RCB group (RCB-0 and I) than those in the unfavorable RCB group (RCB-II and III). No significant difference in tumor elasticity was observed between the groups (p=0.30). Hormone receptor (HR) negativity was an independent predictor of favorable RCB in the multivariate analysis (p=0.04).
Conclusion
Tumor elasticity was not associated with pCR or RCB. HR negativity was an independent predictor of favorable RCB.
INTRODUCTION
Neoadjuvant chemotherapy is commonly performed for breast cancer patients because of its benefits [1-3]. Accordingly, efforts to predict neoadjuvant chemotherapy responses have been reported. Biologic subtypes are well known for their predictive value for neoadjuvant chemotherapy response [4-7]. Some studies [8-10] reported a significant correlation between a higher tumor-infiltrating lymphocyte (TIL) density and pathologic complete response (pCR). Other studies have reported the predictive value of pathological factors such as Ki-67 index, p53, topoisomerase II alpha, and nuclear factor kappa/B-cell lymphoma-2 [11-14]. Despite these studies, no predictive model can accurately predict whether patients will achieve pCR after neoadjuvant chemotherapy.
As malignant tumors progress, the amounts of stromal tissues, especially the extracellular matrix, such as collagen, elastin, and fibrous adhesive protein, increase. These stromal tissues contribute to a poor response to neoadjuvant chemotherapy by acting as a physical barrier and increasing interstitial fluid pressure. Elevated interstitial fluid pressure interferes with the diffusion of chemotherapy agents and aggravates hypoxia, which degrades or deactivates chemotherapeutic agents by compressing intratumoral vessels [15]. Accumulation of the fibrous component of the stroma in the tumor results in decreased tumor elasticity that is categorized as a hard tumor in elastography. Chamming et al. [16] reported a correlation between tumor elasticity measured by shear wave elastography and fibrosis in a human breast cancer model. Thus, tumor elasticity measured by elastography might be a predictive factor for neoadjuvant chemotherapy response.
Elastography can be simultaneously performed during conventional ultrasonography (US), which is a basic imaging tool for breast cancer. Elastography is usually initially performed to differentiate between benign and malignant tumors [17,18]. Recently, several studies have assessed whether strain elastography or shear wave elastography can predict neoadjuvant chemotherapy response in patients with breast cancer [19-21].
The present study evaluated the effects of clinicopathologic factors, including tumor elasticity, on neoadjuvant chemotherapy response in patients with stage II or III breast cancer.
METHODS
From April 2014 to March 2017, 95 patients were scheduled to receive neoadjuvant chemotherapy for clinical stage IIa-IIIc breast cancer at Yeungnam University Hospital. Mammography, breast US, strain elastography, and positron emission tomography (PET) were performed for clinical staging. Fine needle aspiration or axillary surgery (sentinel lymph node biopsy [SLNB] or axillary lymph node dissection [ALND]) was performed to assess lymph node (LN) metastasis if such metastasis was not obvious in imaging studies. The Institutional Review Board of Yeungnam University Hospital approved this prospective study and written informed consent was obtained from each patient (IRB No. 2014-01-459).
US and strain elastography
US and strain elastography were performed using a Philips iU22 ultrasound system (Philips Medical System, Bothell, USA) with a 5–12 MHz linear transducer by an expert radiologist with >30 years of experience in US and >2 years of experience in strain elastography. To perform strain elastography, light manual compression was performed above the targeted tumors and the surrounding normal tissues. Real-time elastography images were displayed on a 256-color map and tumor elasticity was evaluated using the Tsukuba elasticity scoring system (score 1–5) [22]. A cut-off score between 3 and 4 was used to categorize patients into soft (Tsukuba score ≤3; Figure 1A) and hard (Tsukuba score ≥4; Figure 1B) tumor groups [22]. Strain elastography was performed in 74 cases. In 47 cases, a second US was performed for follow-up after the first cycle of neoadjuvant chemotherapy. The reduction rate of tumor size between the first and second US was calculated.
Neoadjuvant chemotherapy and operations
Sixty-three patients received four cycles of AC (adriamycin 60 mg/m2 and cyclophosphamide 600 mg/m2) followed by four cycles of paclitaxel (175 mg/m2), eight patients received four cycles of AC followed by four cycles of docetaxel (75 mg/m2), 16 patients received eight cycles of docetaxel (75 mg/m2) plus adriamycin (50 mg/m2), and four patients received eight cycles of docetaxel (75 mg/m2) plus epirubicin (50 mg/m2). The other four patients received eight cycles of FEC (5-FU 500 mg/m2, epirubicin 100 mg/m2, and cyclophosphamide 500 mg/m2). In 22 cases with human epidermal growth factor receptor 2 (HER2)-positive breast cancers, trastuzumab was administered concurrently with taxane following four cycles of AC.
After neoadjuvant chemotherapy, the patients underwent breast-conserving surgery (BCS), mastectomy, or skin-sparing mastectomy. In 45 patients who underwent SLNB or ALND before neoadjuvant chemotherapy, axillary surgery was omitted. ALND was performed in 13 patients. In the other 50 cases, SLNB was performed and ALND was added when tumor metastasis of sentinel LN was confirmed by frozen section biopsy.
Evaluation of pathologic characteristics
Histologic type; nuclear grade; TILs; tumor cellularity; stromal characteristics; estrogen receptor (ER), progesterone receptor (PR), and HER2 statuses; and Ki-67 index were evaluated from core needle biopsy (CNB) specimens obtained before the administration of neoadjuvant chemotherapy. The evaluation of TIL was performed on hematoxylin and eosin H&E-stained slides according to the International TIL Working Group recommendations [23]. The TIL density was assessed inside the borders of the invasive carcinoma and calculated by expressing stromal areas occupied by lymphocytes and plasma cells as percentages of total intratumoral stromal areas. Tumor cellularity was evaluated in H&E-stained slides as the percentage of tumor area occupied by tumor cells. The stromal characteristics were assessed in H&E-stained slides and categorized into three types (fibroblastic, collagenous, or myxoid) according to the dominant component. Immunohistochemistry (IHC) for ER (SP1, Ventana Medical Systems, Tucson, AZ, USA), PR (IE2, Ventana Medical Systems), and HER2 (4B5, Ventana Medical Systems) were performed. ER and PR positivity were defined as >1% positive tumor cells. HER2 positivity was indicated by an IHC score of 3+ or HER2/CEP17 ratio of ≥2.0, or an average HER2 copy number of ≥6.0 in silver-enhanced in situ hybridization (SISH). After surgery of the breast and axillary LNs, histologic type, histologic grade, tumor size, LN tumor metastasis, TILs, tumor cellularity, ER, PR, HER2, and Ki-67 index were evaluated.
Pathologic response to neoadjuvant chemotherapy
pCR was defined as the absence of invasive carcinoma in the surgically resected breast (ypT0 and ypTis) and axillary LNs (ypN0). We divided the patients into pCR and non-pCR groups. The residual cancer burden (RCB) [24] was calculated using the MD Anderson RCB calculator [25]. RCB could not be calculated in patients who underwent ALND before neoadjuvant chemotherapy. We categorized patients into two groups: favorable RCB (RCB-0, RCB-I) and unfavorable RCB (RCB-II, RCB-III).
Statistical analysis
All analyses were performed using PASW Statistics for Windows version 18.0 (SPSS, Inc., Chicago, IL, USA). T-, chi-square, and Fisher’s exact tests were used to compare clinicopathologic factors between the soft and hard, pCR and non-pCR, and favorable RCB and unfavorable RCB groups. Univariate and multivariate logistic regression analysis were performed to evaluate the correlations between clinicopathological factors and pCR or favorable RCB. Multivariate logistic regression analysis using backward elimination was performed with significant variables (p<0.10 in univariate analysis). Statistical significance was set at p<0.05.
RESULTS
Clinicopathologic characteristics of patients
The mean patient age and initial tumor size were 46.43±8.62 years and 3.63±1.95 cm, respectively. Strain elastography was performed in 74 patients, 24 (32.4%) and 50 (67.6%) of whom were categorized into the soft and hard groups, respectively. In six patients, pathologic factors, except hormone receptor (HR), HER2 and Ki-67, could not be evaluated from CNB specimens because of their poor condition. Histologic grade, TILs, cellularity and characteristics of stroma were analyzed from 89 CNB specimens (Table 1).
Comparison of clinicopathologic factors between soft and hard groups according to strain elastography
No significant differences in HR and HER2 positivity or nuclear grade 3 were observed between the soft and hard groups. The mean tumor cellularity from CNB specimens was 43.86±21.04% in the soft group and 39.18±14.41% in the hard group (p=0.35). Stromal characteristics did not differ between the two groups (p=0.79). The rates of pCR or favorable RCB did not differ significantly between the two groups (p=0.28, and p=0.30, respectively) (Table 2).
Comparisons of clinicopathologic factors between pCR and non-pCR groups
Twenty-two patients (23.2%) achieved a pCR. The clinical stage did not differ between the pCR and non-pCR groups. Tumor elasticity was not correlated with pCR (p=0.28). Patients with a pCR were more likely to have ER- or PR-negative breast cancer compared to those without a pCR (p=0.04 and p=0.03, respectively). The rate of nuclear grade 3 was higher in patients with pCR than in those without pCR (95.5% vs. 73.1%, p=0.03). There also was no significant difference in tumor cellularity (p=0.34) or stromal characteristics (p=0.95) between the two groups (Table 3).
Comparisons of clinicopathologic factors between favorable and unfavorable RCB groups
RCB was calculated for 79 patients. Thirty patients (38.0%) achieved favorable RCB, while 49 patients (62.0%) had unfavorable RCB. There was no significant difference in clinical stage and tumor elasticity between the two groups. The proportion of patients with ER negativity was higher in the favorable RCB group than that in the unfavorable RCB group; however, the difference showed borderline significance (63.3% vs. 40.8%, p=0.05). Compared to the unfavorable RCB group (49%), the favorable RCB group was significantly more likely to have PR-negative breast cancer (73.3%, p=0.03). Nuclear grade 3 was observed in 96.4% of patients in the favorable RCB group and 73.3% in the unfavorable RCB group (p=0.01). The rate of patients with ≥10% TILs was higher in the favorable RCB group than those in the unfavorable RCB group (p=0.04). No significant differences were observed in the other pathologic factors between the two groups (Table 3).
Univariate and multivariate analysis for clinicopathologic factors associated with pCR or favorable RCB
Univariate analysis showed a significant association between HR negativity (p=0.04) and pCR and a borderline significant association between nuclear grade 3 (p=0.05) and pCR (Table 4). In multivariate analysis, no factors showed a significant correlation with pCR, although the odds ratio (OR) of nuclear grade 3 was 5.77 (95% confidence interval [CI], 0.70–47.67; p=0.10) and that of HR negativity was 2.44 [95% CI, 0.87–6.85; p=0.09).
Univariate analysis showed a significant correlation between high TIL level (≥10%) (p=0.04), nuclear grade 3 (p=0.03), and favorable RCB (Table 4). In multivariate analysis, HR negativity was an independent predictor of favorable RCB (OR, 2.93; 95% CI, 1.04–8.28; p=0.04).
DISCUSSION
Neoadjuvant chemotherapy can facilitate BCS in locally advanced breast cancer and convert inoperable cases into possible ones [10]. pCR is associated with a good prognosis [2,3]. However, not all patients achieved favorable results after neoadjuvant chemotherapy. Thus, it is important to select appropriate patients with clinicopathologic factors that are expected to respond well to neoadjuvant chemotherapy.
Recently, many articles have reported on elastography as a potential tool for predicting the response to neoadjuvant chemotherapy [19-21]. Hayashi et al. [19] evaluated tumor elasticity by strain elastography using the Tsukuba elasticity scoring system and found that tumor elasticity was an independent predictor of pCR in multivariate analysis. Ma et al. [21] reported strain elastography and shear wave elastography as predictive tools for a favorable pathologic response to neoadjuvant chemotherapy for breast cancer.
In contrast to previous studies [19-21], tumor elasticity was not a predictive factor for response to neoadjuvant chemotherapy in our study. Strain elastography (as used in the present study) is performed by light manual compression of the probe above the targeted lesion, whereas shear wave elastography was performed using acoustic radiation force from a transducer. Thus, the sensitivity of strain elastography is lower than that of shear wave elastography. Chang et al. [26] reported that tumor location, size, and depth can influence elastography quality. Uneven breast surfaces caused by irregularly-shaped tumors can also lead to uneven manual compression. Recent studies have reported that the change in tumor elasticity induced by neoadjuvant chemotherapy is a significant predictive factor for the response to neoadjuvant chemotherapy [16,20]. The necrotic area of the tumor due to neoadjuvant chemotherapy usually appears as a soft lesion on elastography. Ma et al. [21] reported that changes in strain or shear wave elastography after two cycles of neoadjuvant chemotherapy play an important predictive role. In this study, we evaluated the elasticity of the tumor only before neoadjuvant chemotherapy. Although we failed to prove that elastography predicted the pathologic responses, serial changes in tumor elasticity on pathologic responses may predict tumor response to treatment. The stromal characteristics in CNB specimens were not correlated with tumor elasticity in the current study, whereas those from surgically resected specimens were correlated with tumor elasticity in a study by Chamming et al. [16]. CNB specimens may not be representative of whole tumor, especially a large breast cancer. Furthermore, we categorized the stromal characteristics according to the dominant component of the stroma only. The percentages of each stromal component in the mixed stromal types were not considered. Elastography with US is a noninvasive imaging modality for assessing the response of the whole tumor. This may be help to predict the response and determine the optimal time for surgery during neoadjuvant chemotherapy. Further studies with more cases are needed to evaluate tumor elasticity as a potential tool for predicting the response to neoadjuvant chemotherapy.
In our study, HR negativity was an independent predictive factor of favorable RCB. Regarding pCR, HR negativity was a significant predictive factor in univariate analysis, although not in multivariate analysis. Other studies have also reported breast cancer subtypes as predictive tools for neoadjuvant chemotherapy [4-7]. Moon et al. [27] reported a higher pCR rate in HR-negative patients. Boughey et al. [4] and Gentile et al. [5] reported a significantly higher pCR rate in triple-negative and HER2-positive breast cancers compared to that in HR-positive breast cancer. Rouzier et al. [6] also reported significantly different rates of pCR among molecular subtypes.
Histologic grade is reportedly correlated with neoadjuvant chemotherapy response. Miyoshi et al. [28] found that nuclear grade 3 was also a significant predictor of non-pCR. However, the univariate analysis in the present study showed a significant association between nuclear grade 3 and favorable RCB and a borderline significant association between nuclear grade 3 and pCR. Most articles reported results similar to ours. Jaegal et al. [29] reported a higher pCR in patients with a high histologic grade. Wang et al. [30] and Shien et al. [7] reported significantly higher rates of pCR in patients with nuclear grade 3 compared to those in patients with nuclear grades 1 or 2. Additionally, nuclear grade 3 was a significant predictive factor for pCR in a study by Osako et al. [31]. Jung et al. [9] also reported that histologic grade 3 was an independent predictor of pCR in Korean patients with triple-negative breast cancer.
Several studies have reported TILs as predictors of pCR. Jung et al. [9] reported that high TIL levels were significantly associated with pCR in triple-negative breast cancer. Denkert et al. [8] reported intratumoral lymphocytes as an independent predictor of pCR. Yamaguchi et al. [10] found that dense lymphocytic infiltration was a significant independent predictive factor for pCR. In the present study, a significantly higher percentage of patients with ≥10% TIL showed favorable RCB compared to those with unfavorable RCB, although ≥10% TIL was not significantly correlated with favorable RCB in multivariate analysis.
Our study had several limitations. First, we included a small number of cases from a single center. Second, strain elastography could not be performed in 21 patients. In addition, 47 cases underwent a second US after the first cycle of neoadjuvant chemotherapy, whereas 33 cases, underwent follow-up studies by PET. The heterogeneity of imaging tools for follow-up after the first cycle of neoadjuvant chemotherapy made it difficult to interpret the reduction rate of tumor size between the first and second US.
Tumor elasticity has recently emerged as a predictive factor for neoadjuvant chemotherapy response. In this study, tumor elasticity was not associated with pCR or RCB. HR was an independent predictor of RCB. Further large prospective studies are needed to determine the correlation between tumor elasticity or other clinicopathological factors and neoadjuvant chemotherapy response.
Notes
The authors declare that they have no competing interests.