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. 2020 Jan 3;27(3):445–455. doi: 10.1007/s12282-019-01041-7

Growth pattern can be used as a new characteristic to predict malignancy in breast cancer

Bin Wang 1,#, Lizhe Zhu 1,#, Chenyang He 1, Minghui Tai 2, Can Zhou 1, Guanqun Ge 1, Huimin Zhang 1, Jianjun He 1, Ke Wang 1,
PMCID: PMC7196087  PMID: 32030658

Abstract

Background

To date, anatomic tumor length is a key criterion for cancer staging and can be used to evaluate the effectiveness of therapies. This article describes growth pattern that can be used as a new characteristic to represent disease burden and tumor features and predict lymphatic metastasis.

Methods

Patients with breast cancer were included in this 10-year (1999–2008) hospital-based multicenter retrospective study. The pathologic length/height ratio was used to illustrate the correlation between tumor features, behaviors and treatments in breast malignancies. The most appropriate ratio was chosen based on the comprehensive evaluation of p value and changing trend of each characteristic.

Results

The sample consisted of 4211 women diagnosed with breast cancer. Among them, 2037 patients with complete pathologic length, width and height information were included in the final analysis. There were 2.34 ± 4.77 metastatic lymph nodes for spheroid tumors and 3.21 ± 5.82 for ellipsoid tumors when the cutoff point was 2. In addition, the proportion of ellipsoidal tumors gradually increased from 54.36 to 56.67% in the upper outer quadrant (UOQ) and from 6.7 to 9.03% in the central region with an increase in the cutoff point. The proportion of ER + PR + ellipsoid tumors significantly decreased from 50.1 to 45.35% and that of ER–PR ellipsoid tumors significantly increased from 32.73 to 36.24% with an increase in the cutoff point. Additionally, the best length/weight ratio to distinguish spheroid and ellipsoid tumors was 2.

Conclusion

This study described for the first time how growth pattern is correlated with tumor malignancy and how it influences the selection of therapeutic strategies for patients.

Electronic supplementary material

The online version of this article (10.1007/s12282-019-01041-7) contains supplementary material, which is available to authorized users.

Keywords: Breast neoplasms, Growth, Prognosis, Public health

Introduction

Breast cancer is the most prevalent malignancy in women and the second most common cause of cancer-related death worldwide [1, 2]. The accumulation of cancer cells can be reflected by the spatial shape of the tumor. The formation of a solid mass is the result of constant interactions between proliferating cancer cells and their micro-environment. The cells of solid tumors initiate the process of invasion and metastasis along their spatial growth that can ultimately lead to fatal distant diseases. In women with breast cancer, up to 30% node-negative cases and 70% of node-positive cases will recur [3].

The anatomic TNM classification provides a common language for communicating disease burden. Tumor size is a key criterion for cancer staging and can be used to evaluate the effectiveness of therapies [4]. However, T only describes the largest tumor diameter of the tumor and provides limited description of tumor features despite each tumor having a unique three-dimensional shape. In particular, Wapnir et al. demonstrated that there is a significant overestimation of tumor volume when using the greatest diameter alone for early breast cancer cases [5]. Biological behaviors vary in invasive breast tumors and should not be neglected even though molecular biology is currently widely used in disease staging and prognostic prediction. A larger tumor size, a greater number of metastatic lymph nodes, and distant metastasis represent a later stage. For tumors sharing the same immunophenotype and histologic type, T3 or T4 stage tumors display a rather indolent behavior without rapidly progressing or metastasizing, while some T1 stage tumors have been found to be highly proliferate and metastatic with extremely aggressive behavior. This compels us to investigate whether other tumor features may be associated with tumor behaviors. The morphological growth pattern of tumors is one characteristic that can vary, whereby some tumors display a relative spheroid growth pattern, while others have an ellipsoid growth pattern. Whether the morphological growth pattern can be incorporated with other clinical characteristics is still largely unknown.

In this study, tumors were divided into spheroid and ellipsoid groups based on pathologic length, width and height. We observed a relationship between growth pattern and age, side, primary tumor quadrant, number of lesions, metastatic lymph node number, histologic type, hormone receptor expression, HER-2 expression and treatment. We aimed to investigate whether growth patterns affect tumor features and behaviors and treatment decision making.

Materials and methods

Data and patients

Our data were obtained from the Nationwide Multicenter 10-year (1999–2008) Retrospective Clinical Epidemiological Study of Breast Cancer in China. The study was led by Cancer Hospital/Institute, Chinese Academy of Medical Sciences (CICAMS), and seven Grade Three A hospitals nationwide were included.

The details of region and hospital selection have been previously described. Seven geographic regions that cover most areas and represent different levels of breast cancer burden were selected, including the North, Northeast, Central, South, East, Northwest, and Southwest regions. The selected Grade Three A hospitals were some of the best leading regional public hospitals and referral centers. The source of the inpatients was able to cover the corresponding research area. Information on pathologic analysis, diagnosis, surgery, radiotherapy, medical oncology, and routine follow-up care for breast cancer patients was provided. The Zhang group has proven and demonstrated that this sampling can represent the basic characteristics of breast cancer in China in particular [6].

Data collection and quality control

One month was randomly selected from each year between 1999 and 2008 for the collection of inpatient data from each hospital. January and February were excluded from the random selection to avoid the influence of the biggest annual Chinese holiday. At least 50 pathologically diagnosed inpatient cases from the selected month each year were enrolled in the review. If the number of available cases was lower than 50 in a selected month, the cases from 2 months immediately before and after the selected month were included.

As previously described, the following data were systematically collected for all enrolled patients via medical chart review: (1) general information; (2) demographic characteristics at the time of diagnosis/admission; (3) breast cancer risk factors; (4) results of clinical breast examination (CBE); (5) results of diagnostic imaging; (6) use of currently available surgical approaches, radiotherapy, chemotherapy and molecular targeted therapy for breast cancer; and (7) pathologic characteristics. Pathological examinations included the detection of ER, PR and HER-2 expression by immunohistochemistry (IHC). IHC analysis was conducted prior to the study. ER+ or PR+ cases were defined as hormone receptor positive. For HER-2, cases without staining in the cytomembrane of cancer cells was defined as HER-2-. Any proportions of cancer cells exhibiting weak or incomplete cytomembrane staining or < 10% of cancer cells exhibiting weak or complete cytomembrane staining were defined as HER-2+; ≥ 10% of cancer cells exhibiting weak or moderately intact cytomembrane staining or < 10% cancer cells exhibiting uniform, strong and complete cytomembrane staining were defined as HER-2++; ≥ 10% of cancer cells exhibiting consistent, strong and intact cytomembrane staining were defined as HER-2+++; HER-2- or HER-2+ was considered as HER-2 low expression, which was considered negative in clinical therapy; HER-2+++ was considered HER-2 positive; and HER-2++required further confirmation with fluorescent in situ hybridization (FISH). If no gene expression was observed in the FISH analysis, HER-2 was categorized as negative; otherwise, it was positive.

All of the patients’ information was collected by standard case report forms (CRFs) designed by the Cancer Hospital/Institute, Chinese Academy of Medical Sciences (CICAMS). Data on general information, risk factors, diagnostic imaging tests, therapy models, and pathologic characteristics were independently entered twice from the paper to a computer-based database by two well-trained clerks from each hospital. The data were transmitted to CICAMS and verified by EpiData (https://www.epidata.dk/). After inconsistency and logical errors were corrected, the revised database was sent back to CICAMS for final analysis. Specific details were described in our previous study [6].

Patient and variable selection

A total of 4211 patients with breast cancer were included in the study. Due to the lack of some of the tumor pathologic width and height data, only data from 2037 of 4211 patients who had complete tumor pathologic information of length, width and height were analyzed in this paper. Age at diagnosis was considered a continuous variable, side of tumor, primary tumor location [categorized into upper inner quadrant (UIQ), upper outer quadrant (UOQ), lower inner quadrant (LIQ), lower outer quadrant (LOQ), and central], pathological type (categorized into ductal carcinoma in situ with microinvasion (DCIS-Mi), invasive ductal carcinoma (IDC), invasive lobular carcinoma (ILC), tubular carcinoma, mucinous carcinoma, medullary carcinoma and other types of invasive carcinoma), expression of estrogen receptor (ER), progesterone receptor (PR), and human epidermal growth factor receptor-2 (HER-2) (categorized as positive and negative), treatment (categorized into excision of breast mass, non-conserving surgery and conserving surgery), and metastatic LN numbers were recorded according to H&E and IHC exams.

Definition

Three diameters of the tumors were provided in pathologic data: the longest axis was defined as the length, the shortest axis was defined as the height, and the axis in the middle was defined as the width. The ratio was defined as length/height and was used to measure the growth pattern. The typical figures of the tumor growth patterns (spheroid and ellipsoid groups) were shown in the supplementary Fig. 1. The mean length/height was 1.73, and we set up 3 length/height cutoff points (1.5, 1.73, and 2) to describe eccentricity to varying degrees. For example, if the ratio is < 2 when the cutoff point is 2, the growth pattern would be more spheroid. ER and PR were considered positive if immunostaining was positive in more than 1% of tumor cells. HER-2 positivity was defined by a score of 3+ on IHC or amplification on FISH.

Statistical analysis

The mean ± SD was calculated to describe continuous variables, and a constituent ratio was used to describe categorical variables. T tests were used for the comparison of continuous variables, and the Chi-square test was used for comparison of categorical variables.

All statistical analyses were performed using SPSS (version 19.0, Chicago, IL, USA) and GraphPad Prism (version 7, GraphPad Software Inc., California, USA). A two-tailed p value < 0.05 was considered statistically significant.

Ethics statement

This study was approved by the Institutional Review Board of the Cancer Foundation of China. Because of the retrospective nature of the study, we were unable to contact all patients or their families. In addition, informed consent was not obtained because this study was not a risk to patients. All patient identifiers were removed, as per the approved procedures. Deidentified data were saved in a secured database, to which only researchers in our teams had access.

Results

General characteristics of 2037 breast cancer cases

A total of 4211 eligible breast cancer patients were enrolled in this study. We excluded 2174 patients because they lacked complete 3-D tumor size data in their pathologic reports. A total of 2037 patients (48.37%) with complete 3-D tumor size data were ultimately included in this study. Table 1 summarizes the demographic and clinicopathological characteristics of all enrolled patients. Figure 1 shows a flow diagram of data processing.

Table 1.

Characteristics of participants who completed the analysis

Characteristics Number of cases %
Age at diagnosis
 N 2037
Side
 N 2020
 Left 1074 53.17
 Right 946 46.83
Primary tumor quadrant
 N 1794
 UIQ 336 18.73
 UOQ 972 54.18
 LIQ 135 7.53
 LOQ 227 12.65
 Central 124 6.91
Numbers of lesions
 N 1852
 1 1784 96.33
 2 68 3.67
Histologic type
 N 1965
 DCIS-Mi 61 3.10
 IDC 1765 89.82
 ILC 55 2.80
 Medullary carcinoma 39 1.98
 Mucinous carcinoma 28 1.42
 Others 17 0.87
Pathologic LN numbers 1973
Hormone receptor status
 N 1811
 ER (+) PR (+) 920 50.80
 ER (+) PR (−) 157 8.67
 ER (−) PR (+) 169 9.33
 ER (−) PR (−) 565 31.20
T stage
 N 2037
 T1 710 34.86
 T2 1067 52.38
 T3 260 12.76
N stage
 N 1973
 N0 988 50.08
 N1 570 28.89
 N2 243 12.32
 N3 172 8.72
M stage
 N 2037
 M0 1982 97.30
 M1 55 2.70
HER-2 status
 N 1589
 Positive 528 33.23
 Negative 1061 66.77
Treatment
 N 2012
 Excision of breast mass 23 1.14
 Conserving 107 5.32
 Non-conserving 1882 93.54
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UIQ upper inner quadrant, UOQ upper outer quadrant, LIQ lower inner quadrant, LOQ lower outer quadrant, DCIS-Mi ductal carcinoma in situ with micro-invasion, IDC invasive ductal carcinoma, ILC invasive lobular carcinoma, LN lymph nodes, ER estrogen receptor, PR progesterone receptor, HER-2 human epidermal growth factor receptor-2

Fig. 1.

Fig. 1

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A schematic representation of how the data were included or excluded. HR hormone receptor, LN lymph nodes, ER estrogen receptor, PR progesterone receptor, HER-2 human epidermal growth factor receptor-2

Comparison of clinical characteristics among groups with different growth patterns

For the primary tumor quadrant, the p value gradually decreased from 0.81 (cutoff point 1.5) (Table 2) to 0.032 (cutoff point 2) (Table 4), with a statistically significant difference between the spheroid and ellipsoid groups at the cutoff point of 2. In addition, the proportions of ellipsoidal tumors gradually increased from 54.36 to 56.67% in the UOQ and 6.7 to 9.03% in the central region (Fig. 2a). The percentage distribution indicated that ellipsoid tumors are more likely to be present in the UOQ and central region. Our data also showed that age at diagnosis was significantly different (t = 2.28, p = 0.023) only when the cutoff point was 1.5 (Table 2), and we considered these negative data because further significant differences were not observed. The side of the tumor did not influence the growth pattern of breast tumors in 3 classifications.

Table 2.

Comparison of characteristics between different growth patterns at cutoff point of 1.5

Characteristics Spheroid Ellipsoid p value
number % number %
Age at diagnosis 808 1229 0.023a
50.15 ± 11.00 48.97 ± 10.42
Side 800 1220 0.739b
 Left 429 53.63 645 52.87
 Right 371 46.37 575 47.13
Primary tumor quadrant 705 1089 0.810b
 UIQ 129 18.30 207 19.01
 UOQ 380 53.90 592 54.36
 LIQ 59 8.37 76 6.98
 LOQ 86 12.20 141 12.95
 Central 51 7.23 73 6.70
Numbers of lesions 1153 699 0.000b
 1 1127 97.75 657 93.99
 2 26 2.25 42 6.01
Histologic type 764 1201 0.311b
 DCIS-Mi 21 2.75 40 3.33
 IDC 679 88.87 1086 90.42
 ILC 26 3.40 29 2.41
 Medullary carcinoma 19 2.49 20 1.67
 Mucinous carcinoma 14 1.83 14 1.17
Others 5 0.65 12 1.00
Pathological LN numbers 761 1212 0.037a
2.35 ± 4.67 2.85 ± 5.50
Hormone receptor status 705 1106 0.308b
 ER (+)PR (+) 366 51.91 554 50.09
 ER (+)PR (−) 67 9.50 90 8.14
 ER (−)PR (+) 69 9.79 100 9.04
 ER (−)PR (−) 203 28.79 362 32.73
HER-2 status 619 970 0.717b
 Positive 209 33.76 319 32.89
 Negative 410 66.24 651 67.11
Treatment 794 1218 0.000b
 Excision of breast mass 23 2.90 0 0.00
 Conserving 51 6.42 56 4.60
 Non-conserving 720 90.68 1162 95.40
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UIQ upper inner quadrant, UOQ upper outer quadrant, LIQ lower inner quadrant, LOQ lower outer quadrant, DCIS-Mi ductal carcinoma in situ with micro-invasion, IDC invasive ductal carcinoma, ILC invasive lobular carcinoma, LN lymph nodes, ER estrogen receptor, PR progesterone receptor, HER-2 human epidermal growth factor receptor-2

aThe p value of t test

bThe p value of Chi-square test

Table 4.

Comparison of characteristics between different growth patterns at cutoff point of 2

Characteristics Spheroid Ellipsoid P value
number % number %
Age at diagnosis 1472 565 0.450a
49.15 ± 10.49 49.55 ± 10.73
Side 1462 558 0.387b
 Left 786 53.76 288 51.61
 Right 676 46.24 270 48.39
Primary tumor quadrant 1307 487 0.032b
 UIQ 248 18.97 88 18.07
 UOQ 696 53.25 276 56.67
 LIQ 107 8.19 28 5.75
 LOQ 176 13.47 51 10.47
 Central 80 6.12 44 9.03
Numbers of lesions 1312 538 0.090b
 1 1270 96.80 512 95.17
 2 42 3.20 26 4.83
Histologic type 1410 555 0.207b
 DCIS-Mi 36 2.55 25 4.50
 IDC 1269 90.00 496 89.37
 ILC 42 2.98 13 2.34
 Medullary carcinoma 31 2.20 8 1.44
 Mucinous carcinoma 21 1.49 7 1.26
 Others 11 0.78 6 1.08
Pathological LN numbers 1414 559 0.003a
2.44 ± 4.87 3.22 ± 5.91
Hormone receptor status 1306 505 0.018b
 ER (+)PR (+) 691 52.91 229 45.35
 ER (+)PR (−) 114 8.73 43 8.51
 ER (−)PR (+) 119 9.11 50 9.90
 ER (−)PR (−) 382 29.25 183 36.24
HER-2 status 1153 436 0.584b
 Positive 383 33.22 145 33.26
 Negative 770 66.78 291 66.74
Treatment 1454 558 0.009b
 Excision of breast mass 23 1.58 0 0.00
 Conserving 80 5.50 27 4.84
 Non-conserving 1351 92.92 531 95.16
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UIQ upper inner quadrant, UOQ upper outer quadrant, LIQ lower inner quadrant, LOQ lower outer quadrant, DCIS-Mi ductal carcinoma in situ with micro-invasion, IDC invasive ductal carcinoma, ILC invasive lobular carcinoma, LN lymph nodes, ER estrogen receptor, PR progesterone receptor, HER-2 human epidermal growth factor receptor-2

aThe p value of t test

bThe p value of Chi-square test

Fig. 2.

Fig. 2

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The trends and changes in hormone receptor, quadrant, lymph node metastasis and treatment with different cutoff points. a The proportion of each hormone receptor status according to the two growth patterns at different cutoff points. b The proportion of different quadrants according to the two growth patterns at different cutoff points. c Metastatic lymph nodes according to the two growth patterns at different cutoff points. d The proportion of different treatments according to the two growth patterns at different cutoff points. *p < 0.05, **p < 0.01, NS p ≥ 0.5. UIQ upper inner quadrant, UOQ upper outer quadrant, LIQ lower inner quadrant, LOQ lower outer quadrant, ER estrogen receptor, PR progesterone receptor, HER-2 human epidermal growth factor receptor-2

Comparison of pathological characteristics among groups with different growth patterns

We analyzed the number of tumors and pathologically confirmed metastatic lymph nodes, as these factors may be affected by the growth pattern of breast cancer. We found that the number of average metastatic lymph nodes was 2.85 in ellipsoid tumors vs 2.35 in spheroid tumors at the cutoff point of 1.5 (Table 2), 3.21 in ellipsoid tumors vs 2.34 in spheroid tumors at the cutoff point of 1.73 (Table 3), and 3.22 in ellipsoid tumors vs 2.44 in spheroid tumors at the cutoff point of 2 (Table 4). Although the p value did not strictly increase gradually based on the cutoff point, the average number of metastases was significantly increased to 1.73 vs 1.5 (Fig. 2c). This trend showed that patients with ellipsoid tumors were more susceptible to lymph node metastasis. Although a significant difference was found in the numbers of tumors at the cutoff point of 1.5 (Table 2) and ellipsoidal tumors were more likely to have 2 lesions in pathologic reports, we failed to see a positive result at the cutoff point of 1.73 (Table 3) or 2 (Table 4). In our study, no difference in pathologic type was found among the 3 cutoff points.

Table 3.

Comparison of characteristics between different growth patterns at cutoff point of 1.73

Characteristics Spheroid Ellipsoid P value
number % number %
Age at diagnosis 1300 737 0.271a
49.62 ± 10.77 49.11 ± 10.47
Side 1290 730 0.870b
 Left 691 53.76 383 51.61
 Right 599 46.24 347 48.39
Primary tumor quadrant 1146 648 0.155b
 UIQ 215 18.76 121 18.67
 UOQ 615 53.66 357 55.09
 LIQ 96 8.38 39 6.02
 LOQ 150 13.09 77 11.88
 Central 70 6.11 54 8.33
Numbers of lesions 1150 700 0.280b
 1 1112 96.70 670 95.71
 2 38 3.30 30 4.29
Histologic type 1240 725 0.095b
 DCIS-Mi 30 2.13 31 5.59
 IDC 1114 79.01 651 117.30
 ILC 36 2.55 19 3.42
 Medullary carcinoma 30 2.13 9 1.62
 Mucinous carcinoma 20 1.42 8 1.44
 Others 10 0.71 7 1.26
Pathological LN numbers 1245 728 0.000a
2.34 ± 4.77 3.21 ± 5.82
Hormone receptor status 1153 658 0.202b
 ER (+) PR (+) 607 52.65 313 47.57
 ER (+) PR (−) 99 8.59 58 8.81
 ER (−) PR (+) 104 9.02 65 9.88
 ER (−) PR (−) 343 29.75 222 33.74
HER-2 status 1020 569 0.988b
 Positive 334 32.75 194 34.09
 Negative 686 67.25 375 65.91
Treatment 1283 729 0.001b
 Excision of breast mass 23 1.79 0 0.00
 Conserving 69 5.38 38 5.21
 Non-conserving 1191 92.83 691 94.79
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UIQ upper inner quadrant, UOQ upper outer quadrant, LIQ lower inner quadrant, LOQ lower outer quadrant, DCIS-Mi ductal carcinoma in situ with micro-invasion, IDC invasive ductal carcinoma, ILC invasive lobular carcinoma, LN lymph nodes, ER estrogen receptor, PR progesterone receptor, HER-2 human epidermal growth factor receptor-2

aThe p value of t test

bThe p value of Chi-square test

Comparison of molecular subtypes among groups with different growth patterns

HER-2 status and HR status were analyzed separately. A gradually decreasing p value from 0.308 at a cutoff point of 1.5–0.018 at a cutoff point of 2 was observed regarding the HR status. As shown in Fig. 2b, the proportions of 4 subtypes according to HR status (ER+ PR+, ER+ PR−, ER-PR+, and ER-PR−) of spheroid tumors did not change much, while the proportion of ER+PR+ ellipsoid tumors significantly decreased from 50.1 to 45.35% and that of ER–PR ellipsoid tumors significantly increased from 32.73 to 36.24% with the increase in cutoff point. This result indicated that HR-negative breast cancer cases were more likely to exhibit ellipsoid growth than HR-positive breast cancer cases. There were no significant differences in the subgroups between the two HER-2 statuses.

Comparison of treatment among groups with different growth patterns

Apart from objective differences, growth pattern also affected the doctors’ decisions for treatment. Irrespective of the cutoff point, compared with ellipsoid tumors, spheroid tumors showed significant differences in surgery type (Tables 2, 3 and 4 and Fig. 2d). 23 of 2037 patients received excision of breast mass only in local hospitals instead of standard breast conserving surgery in these 7 Grade 3A hospitals/institutes, and all of these patients had spheroid tumors. Meanwhile, patients who underwent breast-conserving surgery were more likely to have spheroid tumors.

Discussion

In this study, we preliminarily investigated the association between growth patterns and tumor features, tumor behavior and surgery decision making. Our approach provides new insights into tumor features, as we focused on identifying a new way to distinguish breast cancer by dividing growth patterns into spheroids and ellipsoids. The length/height ratio can partially reflect how the masses progressed and help us to infer the possible dynamic nature of the tumor. In particular, we chose postoperative pathologic data (length, width, height, HR status, and HER-2 status) to make our analysis more accurate and reliable. This is because preoperative imaging data have more measurement error when calculating the true size of tumors, and preoperative biopsy samples of a small tumor region may not enable the representative characterization of the tumor as a whole.

Lymph node metastasis acts as a very strong prognostic indicator in breast cancer. In this study, the results showed that an ellipsoid growth pattern has greater potential to cause lymph node metastasis. More metastasis further indicates a worse prognosis. Consistent with our study, Han et al. had shown that tumors with high eccentricity result in worse survival outcomes due to the high incidence of unfavorable prognostic factors, their results also showed that there was a significant association between the degree of eccentricity and the time to distant metastasis in patients with hormone receptor-negative tumors [7]. Our results showed that HR-positive tumors had a more spheroid shape than other subtypes, while the HER-2 status alone had no influence on the growth pattern. This result is in conflict with breast imaging studies that showed triple-negative tumors having more round shapes and smooth margins [8]. We think our finding is more reliable mainly because of two reasons: (1) pathologic data are more accurate than imaging results. (2) There were 176 patients in their study, and the number of patients in their study was small. Therefore, the statistical significance of their data may be insufficient. We also observed that ellipsoid masses are more likely to be located in the central or UOQ of the breast. The reasons for the increase in ellipsoid tumors in the UOQ of the breast remain unknown at this time. This may be due to the development of genetic alterations and more blood supply from axillary in that region. We have also explored the relationship between growth patterns and several closely related breast cancer factors, such as patient age, tumor side, number of lesions and pathologic classification. The lack of meaningful significance prompted us to explore whether the growth pattern has an impact on treatment decision making. Our data showed that the rate of breast-conserving surgery was significantly reduced in patients with ellipsoid masses. Breast-conserving surgery in China often relies on the incision margin of intraoperative frozen pathology. Chinese surgeons prefer to remove a larger area to ensure a clear margin. For ellipsoid tumors, more excised tissue based on length is not conducive to maintain the breast shape, less excised tissue based on height is not conducive to clear margin. Thus, spheroid tumors are more conducive to the extent of resection and margin control. There were 23 patients whose breast masses had already been removed in other small hospitals when they came to these 7 hospitals. Surgical margin was not reported, because small hospitals do not perform intraoperative frozen pathology. They were reluctant to receive further standard breast-conserving surgery due to poor economic conditions or aging. All of the 23 patients’ cancer types were luminal A/B without high-risk factors. Tumors were considered less malignant and can be well controlled by endocrine therapy. Interestingly, all patients who only received mass removal as treatment had spheroid tumors. This phenomenon was also consistent with our data that HR-positive breast cancer cases were more likely to exhibit spheroid growth. We had also tracked the survival status of all patients in our single center. The total number of patients whom we could track with the follow-up was 483. We divided them into four groups according to the molecular subtypes (HR+/HER2−; HR+/HER2+; HR−/HER2+; HR−/HER2−). The survival curves could be seen in supplementary Fig. 2 and 3. The survival analysis also showed that the ellipsoid-like HR+/HER2− and HR−/HER2+ tumors were more likely to have bad RFS and OS.

We explored 3 cutoff points to characterize the growth pattern to find the best criterion. Although the age of patients and number of lesions showed significant differences when the length/height was 1.5, we failed to observe a further positive p value when the ratio was 1.73 or 2. Taking all the characteristics into consideration, we would prefer to set the cutoff point at 2. We also tested the ROC curves in different ratios including 1.5, 1.73 and 2. The supplementary Fig. 4 showed that when the cutoff point was 2, the model could best reflect the prognostic value of breast cancer patients based on the lymph node status. When the tumor length is more than double the height, the tumor may have more lymph node metastasis and may be more likely to be HR negative and located in the UOQ or central part of the breast. In addition, patients who receive breast-conserving surgery are more likely to have spheroid tumors.

We believe that the growth pattern of tumors is not random, but determined by the expression of certain genes. It was interesting to notice that increased IL-6 secretion and activation of STAT3 were observed in a Ras-transformed subculture of mammary epithelial cells in 3D cell culure, a phenotype also seen in xenografts and human tumors, but not in standard 2D cultures [9]. Han's team had found that 54 genes were significantly correlated with tumor eccentricity in breast cancer. Among the genes with the highest p value, some genes related to extracellular matrix remodeling such as MMP13 and adamts12 were related to the tumors’ growth pattern [7]. Besides, breast cancer lesions are not homogeneous. Evidence of intratumor heterogeneity has been discovered by chromosomal- and microarray-based comparative genomic hybridization (CGH) and massively parallel sequencing (MPS) analyses [10, 11]. According to the clonal evolution model, intratumoral heterogeneity includes differences in their genetic, phenotypic or behavioral characteristics [1012]. In individual breast cancer cases, different subclonal populations of cancer cells may exist across different geographical regions of a tumor (spatial heterogeneity) or evolve over time between the primary tumor and a subsequent local or distant recurrence (temporal heterogeneity) [13, 14]. We hypothesized that different growth patterns may be one of the visible manifestations of genetic heterogeneity. Similar with breast cancer, colorectal tumors which have a laterally spreading pattern show unique expression features of various genes including β-catenin, type IV collagen, and PKC [15]. If highly proliferative clones are located in one marginal area, they are likely to form ellipsoid tumors and cause more metastasis. This finding also supported the idea that a small proportion of cancer cells located at the invading front of solid tumors can determine local invasion and metastasis, while the remaining tumor cells remain nonmetastatic [16].

There are some limitations in our analysis as follows: (i) we did not explore any mechanism regarding why the growth pattern is associated with tumor location, hormone receptor status or number of metastatic lymph nodes. (ii) Although postoperative specimens were used, the tumor size was measured after formalin fixation. Hsu et al. reported that formalin fixation may cause tumor shrinkage and that the measurement after formalin fixation results in an underestimation of actual tumor size [17]. (iii) The complex contour of the malignant mass can be radial and cannot be fully characterized by the dimensional diameter alone. (iv) The concept of TNBC subtypes was first proposed in China in 2019 [18], but our data were obtained from 1999–2008 when the Chinese doctors did not have advanced knowledge of triple negative breast cancer subtypes. The relationship between tumor growth pattern and tumor malignancy in each subtype of TNBC was not included in the analysis. Further study is still necessary to elucidate the mechanism of emergence of different shapes.

Conclusions

In the present study, we performed simple categorization of breast cancer patients based on tumor growth patterns. Our findings indicate that the tumor growth pattern can be a useful indicator to predict tumor malignancy and the prognostic value of breast cancer and that it can contribute to the selection of an optimal therapeutic strategy for individual patients.

Availability of data and materials

The data generated during this study are included in this article. Raw data are available upon reasonable request.

Electronic supplementary material

Below is the link to the electronic supplementary material.

12282_2019_1041_MOESM1_ESM.tif (1.2MB, tif)

Supplementary figure 1. Typical figures of the tumor growth patterns (A: spheroid ; B: ellipsoid groups). (TIF 1213 kb)

12282_2019_1041_MOESM2_ESM.tif (4.4MB, tif)

Supplementary figure 2. The relationship between growth pattern and recurrent-free survival (RFS) in our single center. (TIF 4466 kb)

12282_2019_1041_MOESM3_ESM.tif (4.4MB, tif)

Supplementary figure 3. The relationship between growth pattern and overall survival (OS) in our single center. (TIF 4456 kb)

12282_2019_1041_MOESM4_ESM.jpg (25.4KB, jpg)

Supplementary figure 4. The ROC curves based on the lymph nodes status. (JPG 25 kb)

Acknowledgements

We thank Cancer Foundation of China for originating this retrospective clinical epidemiological study of breast cancer. We thank the local investigators from Beijing, Liaoning (Shenyang), Hunan (Changsha), Guangdong (Guangzhou), Zhejiang (Hangzhou), Shaanxi (Xi’an), and Sichuan (Chengdu) for data collection and completion of the project. We thank department of statistics of the First affiliated hospital of Xi’an Jiaotong University for statistical support. We thank Minya Xu for English editing.

Abbreviations

HR

Hormone receptor

LN

Lymph nodes

UIQ

Upper inner quadrant

UOQ

Upper outer quadrant

LIQ

Lower inner quadrant

LOQ

Lower outer quadrant

ER

Estrogen receptor

PR

Progesterone receptor

HER-2

Human epidermal growth factor receptor-2

Authors’ contributions

BW: Collection and/or assembly of data, data analysis and interpretation, manuscript writing, methodology and software. LZZ: Collection and/or assembly of data, data analysis and interpretation, manuscript writing and editing. CYH: Data analysis, manuscript writing and interpretation. MHT: Ultrasound assistance. CZ: Manuscript writing and project administration. GQG: Manuscript writing. HMZ: Manuscript writing. JJH: Conception/design. KW: Conception/design, supervision and editing. All authors: Article writing and final approval of article.

Funding

This study is funded by the National Natural Science Fund of China (number 81702633).

Compliance with ethical standards

Conflict of interest

The authors declare no conflict of interest.

Ethics approval

The research has been approved by Institutional Review Board of the Cancer Foundation of China. Because of the study’s retrospective nature, we were unable to contact all the patients or their families.

Informed consent

Informed consent was not obtained because this study was not a risk to patients. All patient identifiers were removed, as per the approved procedures. Deidentified data were saved in a secured database, to which only researchers in our teams had access. Patient consent for this study was not required due to the retrospective nature of our analysis.

Footnotes

Publisher's Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Bin Wang and Lizhe Zhu contributed equally to this paper.

References

  • 1.Cardoso F, Harbeck N, Fallowfield L, Kyriakides S, Senkus E. Locally recurrent or metastatic breast cancer: ESMO Clinical Practice Guidelines for diagnosis, treatment and follow-up. Ann Oncol. 2012;23(suppl 7):vii1-19. doi: 10.1093/annonc/mds232. [DOI] [PubMed] [Google Scholar]
  • 2.Siegel RL, Miller KD, Jemal A. Cancer statistics, 2018. CA Cancer J Clin. 2018;68(1):7–30. doi: 10.3322/caac.21442. [DOI] [PubMed] [Google Scholar]
  • 3.Nakasone ES, Hurvitz SA, Mccann KE. Harnessing the immune system in the battle against breast cancer. Drugs Context. 2018;7:212520. doi: 10.7573/dic.212520. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 4.Giuliano AE, Edge SB, Hortobagyi GN. Eighth edition of the AJCC cancer staging manual: breast cancer. Ann Surg Oncol. 2018;25(7):1783–1785. doi: 10.1245/s10434-018-6486-6. [DOI] [PubMed] [Google Scholar]
  • 5.Wapnir IL, Wartenberg DE, Greco RS. Three dimensional staging of breast cancer. Breast Cancer Res Treat. 1996;41(1):15–19. doi: 10.1007/BF01807032. [DOI] [PubMed] [Google Scholar]
  • 6.Zhang BL, Sivasubramaniam PG, Zhang Q, Wang J, Zhang B, Gao JD, et al. Trends in radical surgical treatment methods for breast malignancies in China: a multicenter 10-year retrospective study. Oncologist. 2015;20:1036–1043. doi: 10.1634/theoncologist.2014-0281. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 7.Moon HG, Kim N, Jeong S, Lee M, Moon H, Kim J, et al. The clinical significance and molecular features of the spatial tumor shapes in breast cancers. PLoS ONE. 2015;10(12):e0143811. doi: 10.1371/journal.pone.0143811. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 8.Uematsu T, Kasami M, Yuen S. Triple-negative breast cancer: correlation between MR imaging and pathologic findings. Radiology. 2009;250(3):638–647. doi: 10.1148/radiol.2503081054. [DOI] [PubMed] [Google Scholar]
  • 9.Leslie K, Gao SP, Berishaj M, Podsypanina K, Ho H, Ivashkiv L, et al. Differential interleukin-6/Stat3 signaling as a function of cellular context mediates Ras-induced transformation. Breast Cancer Res. 2010;12(5):R80. doi: 10.1186/bcr2725. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 10.Shah SP, Roth A, Goya R, Oloumi A, Ha G, Zhao Y, et al. The clonal and mutational evolution spectrum of primary triple-negative breast cancers. Nature. 2012;486(7403):395–399. doi: 10.1038/nature10933. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 11.Geyer FC, Weigelt B, Natrajan R, Lambros MB, de Biase D, Vatcheva R, et al. Molecular analysis reveals a genetic basis for the phenotypic diversity of metaplastic breast carcinomas. J Pathol. 2010;220(5):562–573. doi: 10.1002/path.2675. [DOI] [PubMed] [Google Scholar]
  • 12.Martelotto LG, Ng CK, Piscuoglio S, Weigelt B, Reis-Filho JS. Breast Cancer Res. 2014;16(3):210. doi: 10.1186/bcr3658. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 13.Navin N, Kendall J, Troge J, Andrews P, Rodgers L, McIndoo J, et al. Tumour evolution inferred by single-cell sequencing. Nature. 2011;472(7341):90–94. doi: 10.1038/nature09807. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 14.Bedard PL, Hansen AR, Ratain MJ, Siu LL. Tumour heterogeneity in the clinic. Nature. 2013;501(7467):355–364. doi: 10.1038/nature12627. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 15.Ichikawa Y, Nagashima Y, Morioka K, Akimoto K, Kojima Y, Ishikawa T, et al. Colorectal laterally spreading tumors show characteristic expression of cell polarity factors, including atypical protein kinase C lambda/iota, E-cadherin, beta-catenin and basement membrane component. Oncol Lett. 2014;8(3):977–984. doi: 10.3892/ol.2014.2271. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 16.Thompson EW, Newgreen DF, Tarin D. Carcinoma invasion and metastasis: a role for epithelial-mesenchymal transition? Cancer Res. 2005;65(14):5991–5995. doi: 10.1158/0008-5472.CAN-05-0616. [DOI] [PubMed] [Google Scholar]
  • 17.Hsu PK, Huang HC, Hsieh CC, Hsu HS, Wu YC, Huang MH, et al. Effect of formalin fixation on tumor size determination in stage I non-small cell lung cancer. Ann Thorac Surg. 2007;84(6):1825–1829. doi: 10.1016/j.athoracsur.2007.07.016. [DOI] [PubMed] [Google Scholar]
  • 18.Jiang YZ, Ma D, Suo C, Shi J, Xue M, Hu X, et al. Genomic and transcriptomic landscape of triple-negative breast cancers: subtypes and treatment strategies. Cancer Cell. 2019;35(428–440):e5. doi: 10.1016/j.ccell.2019.02.001. [DOI] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

12282_2019_1041_MOESM1_ESM.tif (1.2MB, tif)

Supplementary figure 1. Typical figures of the tumor growth patterns (A: spheroid ; B: ellipsoid groups). (TIF 1213 kb)

12282_2019_1041_MOESM2_ESM.tif (4.4MB, tif)

Supplementary figure 2. The relationship between growth pattern and recurrent-free survival (RFS) in our single center. (TIF 4466 kb)

12282_2019_1041_MOESM3_ESM.tif (4.4MB, tif)

Supplementary figure 3. The relationship between growth pattern and overall survival (OS) in our single center. (TIF 4456 kb)

12282_2019_1041_MOESM4_ESM.jpg (25.4KB, jpg)

Supplementary figure 4. The ROC curves based on the lymph nodes status. (JPG 25 kb)

Data Availability Statement

The data generated during this study are included in this article. Raw data are available upon reasonable request.

Articles from Breast Cancer (Tokyo, Japan) are provided here courtesy of Springer

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