Development and validation of a nomogram for discriminating between benign and malignant breast masses by conventional ultrasound and dual-mode elastography: a multicenter study
Original Article

Development and validation of a nomogram for discriminating between benign and malignant breast masses by conventional ultrasound and dual-mode elastography: a multicenter study

Keen Yang1#, Xiuqin Ye1#, Hongtian Tian1, Qiaoying Li2, Qinghua Liu3, Jingjing Li3, Jinhan Guo4, Jinfeng Xu1, Fajin Dong1

1Department of Ultrasound, Shenzhen People’s Hospital (The Second Clinical Medical College, Jinan University; The First Affiliated Hospital, Southern University of Science and Technology), Shenzhen, China; 2Department of Ultrasound, Tangdu Hospital, Fourth Military Medical University, Xi’an, China; 3Department of Ultrasound, Rizhao People’s Hospital, Rizhao, China; 4Department of Ultrasound, Longhua Branch of Shenzhen People’s Hospital, Shenzhen, China

Contributions: (I) Conception and design: K Yang, X Ye, J Xu, F Dong; (II) Administrative support: J Xu, F Dong; (III) Provision of study materials or patients: H Tian, Q Li, Q Liu, J Li, J Guo; (IV) Collection and assembly of data: K Yang, X Ye, H Tian, Q Li, Q Liu, J Li, J Guo; (V) Data analysis and interpretation: K Yang, X Ye; (VI) Manuscript writing: All authors; (VII) Final approval of manuscript: All authors.

#These authors contributed equally to this work.

Correspondence to: Jinfeng Xu. Department of Ultrasound, Shenzhen People’s Hospital, 1017 Dongmen North Road, Luohu District, Shenzhen 518020, China. Email: xujinfeng@yahoo.com; Fajin Dong. Department of Ultrasound, Shenzhen People’s Hospital, 1017 Dongmen North Road, Luohu District, Shenzhen 518020, China. Email: dongfajin@szhospital.com.

Background: This study developed and validated an ultrasound nomogram based on conventional ultrasound and dual-mode elastography to differentiate breast masses.

Methods: The data of 234 patients were collected before they underwent breast mass puncture or surgery at 4 different centers between 2016 and 2021. Patients were divided into 5 datasets: internal validation and development sets from the same hospital, and external validation sets from the 3 other hospitals. In the development cohort, age and 294 different ultrasound and elastography features were obtained from ultrasound images. Univariate logistic regression and least absolute shrinkage and selection operator (LASSO) regression were used for data reduction and visualization. Multivariable logistic regression analysis was used to develop the prediction model and ultrasound nomogram. Receiver operating characteristic (ROC) curve analysis, calibration curves, integrated discrimination improvement, and the net reclassification index were used to evaluate nomogram performance; decision curve analysis (DCA) and clinical impact curves were used to estimate clinical usefulness.

Results: In the development cohort, margin, posterior features, shape, vascularity, (the mean shear wave elastography value of 1.5 mm surrounding tissues in a breast mass) divided by (the mean shear wave elastography value of the breast mass)—shell mean/A mean1.5(E), (the ratio of strain elastography of adipose tissue near a breast mass) divided by [the ratio of strain elastography of (the breast mass adds the 1.5 mm surrounding tissues in the breast mass)]—B/A'1.5 were selected as predictors in multivariable logistic regression analysis, comprising Model 1. Among the 5 cohorts, Model 1 performed best, with areas under the curve (AUC) of 0.92, 0.84, 0.87, 0.93, and 0.89, respectively. The AUCs were 0.90, 0.82, 0.83, 0.91, and 0.85, respectively, in Model 2 (margin + posterior features + shape + vascularity) and 0.80, 0.76, 0.77, 0.87, and 0.80, respectively, in Model 3 [shell mean/A mean1.5(E) + B/A'1.5].

Conclusions: Our ultrasound nomograms facilitate exposure to the features and visualization of breast cancer. Shell mean/A mean1.5(E), B/A'1.5 integrated with margin, posterior features, shape, and vascularity are superior at identifying breast cancer, and are worthy of further clinical investigation.

Keywords: Breast cancer; elastography; nomogram; prediction model; ultrasound

Submitted Mar 12, 2022. Accepted for publication Dec 07, 2022. Published online Jan 11 2023.

doi: 10.21037/qims-22-237

Introduction

Among cancers affecting females, breast cancer ranks first in incidence (31%) and second in mortality (15%) (1). Breast cancer mortality has decreased as treatments have improved (2). An effective population-based screening study showed that early detection of breast cancer can lead to reduced local and distant recurrence rates, as well as better 5-year survival rate (3). Breast masses can be diagnosed via ultrasound, mammography, and magnetic resonance imaging (4,5). Although each of these modalities has its advantages, ultrasound is particularly attractive due to its lack of radiation, high patient acceptance, and ability to detect lesions in dense breasts that would otherwise be obscured on mammography (6,7). However, the main drawbacks of ultrasound are the vast number of false positives identified and the low specificity of biopsies. In previous studies, the specificity of ultrasound has ranged from 60% to 75% (8,9).

Elastography, a new technique, can monitor the response of tissue to acoustic energy (10,11). As a breast mass progresses, it can affect the stiffness of the tissue, providing new imaging targets to assess biological features of the disease (12). By detecting the stiffness of the mass and its surrounding tissue, strain elastography (SE) and shear wave elastography (SWE) can be used to differentiate between benign and malignant breast masses, improving the efficiency and accuracy of breast cancer detection (13-15).

The “shell” is defined as the tissue surrounding breast masses. Previous studies have investigated the importance of different shell sizes (e.g., 1, 2, and 3 mm) in distinguishing benign from malignant breast masses (16-20). However, the prediction value of different shear modulus values combined with SE and conventional ultrasound in differentiating benign from malignant breast masses has not been explored. Furthermore, some radiologists regard elastography as an unreliable method for which they are unsure how to interpret results; consequently, they are hesitant to use elastography in regular practice to diagnose breast tumors (21).

To overcome these barriers to using elastography, the primary aim of the present study was to develop and validate an ultrasound nomogram based on conventional ultrasound and dual-mode elastography for the diagnosis of breast masses. A secondary aim was to validate our findings using various validation sets. We present the following article in accordance with the TRIPOD reporting checklist (available at https://qims.amegroups.com/article/view/10.21037/qims-22-237/rc).

Methods

Patients

This retrospective study included patients from 4 different hospitals in 4 distinct regions of China. The study period was from 2016 to 2021.

The study was conducted in accordance with the Declaration of Helsinki (as revised in 2013) and was approved by the Regional Ethics Board of Shenzhen People’s Hospital. All patients provided informed consent.

Initially, 499 patients met the inclusion criteria and were enrolled in the study. Specifically, to be eligible for inclusion, patients had to have had: (I) an ultrasound-detected mass; (II) a solid or nearly solid (<20% cystic) mass; (III) a mass between 5 and 50 mm in size; (IV) at least a 3-mm tissue margin surrounding the lesions; and (V) surgery or biopsy within a week after ultrasound detection of the mass.

Patients were excluded if they had no pathology results (n=15), lacked clinical information (n=6), had unsatisfactory elastography images (n=7), had received neoadjuvant chemotherapy (n=3), and/or had missing values for elastography data (n=234), leaving 234 patients for analysis. These 234 patients were separated into 5 datasets according to hospital: the internal validation and development sets came from the same hospital, whereas the external validation sets came from the 3 other hospitals.

Patient inclusion and exclusion pathways are shown in Figure S1.

Image acquisition

For image acquisition, patients were placed in the supine position with the breast fully exposed. Sonographers noted the size, shape, margin, echogenicity, posterior features, and vascularity of the suspected mass using a Mindray Resona 7 (L11-3U probe) (Mindray, Shenzhen, China).

Conventional ultrasound features are based on the American College of Radiology descriptions (22). In the present study, the final conventional ultrasound features considered included the following: shape (regular =0; irregular =1); margin (distinct =0, indistinct =1); echo (saccadic echo =0, iso-echo =1, heterogeneous echo =2, hypo-echo =3); posterior features (enhancement =0; no posterior acoustic features =1; shadowing =2); and vascularity (no =0; little =1, rich =2).

During SWE measurements, probes were kept perpendicular to the skin and the skin was touched gently with as little additional pressure as possible. A shear wave quality mode quality control chart (QCC) was used to assess the reliability of the SWE image. When 95% of the QCC was filled with green (indicating high quality of the SWE image) and the largest diameter was located, the image was stored for further analysis. Then, the breast mass was segmented and the edge was outlined manually. The tissue surrounding the edge of the breast mass was automatically circled to obtain Young’s modulus (E), shear wave velocity (Cs), and shear modulus (G) data for –0.5-, 0.5-, 1.0-, 1.5-, 2.0-, 2.5-, and 3.0-mm shells.

During SE measurements, probes were kept perpendicular to the skin and the skin was gently touched with as little additional pressure as possible. Images were saved after 3 seconds of image stabilization. For image analysis, the breast mass was segmented and the edge was outlined manually, and, as a reference point, the adipose tissue was manually delineated at the same depth as the mass. The tissue surrounding the edge of the breast mass was automatically circled to obtain the strain ratios for –0.5-, 0.5-, 1.0-, 1.5-, and 2.0-mm shells.

In summary, we gathered E, Cs, and G data for –0.5-, 0.5-, 1.0-, 1.5-, 2.0-, 2.5-, and 3.0-mm shells (i.e., tissue surrounding the breast mass), A (mass), and A' (shell + mass), as well as for –0.5-, 0.5-, 1.0-, 1.5-, and 2.0-mm shells, A, B (adipose tissue near the lesions), and A' on SE. In all, 287 ultrasound elastography features were included for analysis.

The image acquisition process is shown in Figure 1.

Figure 1 A 59-year-old woman with invasive ductal carcinoma. (A,B) There is a mass at 10 o'clock in the right breast, with a length of approximately 12 mm, irregular shape, indistinct margin, heterogeneous echo, no posterior acoustic features, and rich vascularity within the mass. (C) The value of the shell mean/A mean1.5(E) is 1.16; the area between the red and white lines is the shell, which is 1.5 mm. (D) The value of B/A'1.5 is 3.35; the area between the green and white lines is the shell, which is 1.5 mm. According to the nomogram, the probability of breast cancer is 0.88. shell mean/A mean1.5(E): (in Young’s modulus, the mean shear wave elastography value of 1.5 mm surrounding tissues in a breast mass) divided by (in Young’s modulus, the mean shear wave elastography value of the breast mass). B/A'1.5: (the ratio of strain elastography of adipose tissue near a breast mass) divided by (the ratio of strain elastography of (the breast mass adds the 1.5 mm surrounding tissues in the breast mass).

In this study, ultrasound images were captured, stored, and analyzed by sonographers with 5 years of experience in breast ultrasound at 4 centers. The senior sonographer-F.D, with 15 years of breast ultrasound experience, then assessed image quality and analysis findings. To reduce the impact of subjective factors, a single-blinded approach was adopted, meaning that until the 5 sonographers had acquired and analyzed the images or evaluated them, they were unaware of the patients’ pathology findings and other imaging data.

Statistical analysis

Normally distributed continuous variables were presented as the mean ± SD, whereas categorical data were presented as numbers and percentages.

Statistical analyses were performed using R (R Foundation for Statistical Computing, Vienna, Austria). Univariable logistic regression was used to select conventional ultrasound features. The R packages “glmnet”, “rms”, “pROC”, “ggplot2”, “rmda”, and “nricens” were used for least absolute shrinkage and selection operator (LASSO) regression (23), to draw nomograms, receiver operating characteristic (ROC) curves, decision curve analysis (DCA), and clinical impact curves, as well as to calculate the net reclassification index (NRI), respectively. It is important to note that for SWE and SE features, LASSO regression was performed and the variable with the highest lamda value was chosen for the multivariable logistic regression analysis.

Multivariate logistic regression was used in the development cohort to calculate the prediction model. To provide physicians with a quantitative and visual tool to predict the incidence of individual breast cancer, we built an ultrasound nomogram based on multivariate logistic analysis in the development cohort (24).

Prediction performance of the nomogram

First, we used data from the 4 validation cohorts to draw calibration curves, and the calibration performance of the nomogram was assessed using the unreliability test. Second, the area under the curve (AUC), integrated discrimination improvement (IDI) (25), and NRI were used to evaluate the model in the development and validation cohorts.

Clinical use

DCA can obtain one-to-one correspondence between threshold probability and net benefit value, and can also draw this relationship as a line graph (26). DCA and clinical impact curves were used to evaluate the additional diagnostic value of dual-mode elastography.

Results

Patient characteristics

The study initially included a total of 499 breast mass samples. After application of the exclusion criteria, 234 patients were retained the data analysis.

The development cohort consisted of 116 patients (mean age 44.9±13.7 years) and 116 lesions (58 benign, 58 malignant). The Breast Imaging-Reporting and Data System (BI-RADS) was used to classify benign and malignant breast masses in the development cohort. Of the benign breast masses, 35 (60.3%) were BI-RADS 3, 11 (19.0%) were BI-RADS 4A, 8 (13.8%) were BI-RADS 4B, and 4 (6.9%) were BI-RADS 4C. Of the malignant breast masses 1 (1.7%) was BI-RADS 3, 8 (13.8%) were BI-RADS 4A, 8 (13.8%) were BI-RADS 4B, 40 (69.0%) were BI-RADS 4C, and 1 (1.7%) was BI-RADS 5.

The internal validation cohort consisted of 24 patients (mean age 46.2±13.8 years) and 24 lesions (13 benign, 11 malignant). There were 3 external validation cohorts. Cohort 1 consisted of 35 patients (mean age 40.7±11.7 years) and 35 lesions (19 benign, 16 malignant); Cohort 2 consisted of 29 patients (mean 44.3±12.4 years) and 29 lesions (16 benign, 13 malignant); Cohort 3 consisted of 30 patients (mean age 46.3±11.2 years) and 30 lesions (14 benign, 16 malignant).

Patient characteristics in the development and validation cohorts are provided in Table 1.

Table 1

Patient characteristics in the development and validation cohorts

Characteristics Development cohort Validation cohorts
Internal External 1 External 2 External 3
Benign (n=58) Malignant (n=58) P value OR (95% CI) Benign (n=13) Malignant (n=11) Benign (n=19) Malignant (n=16) Benign (n=16) Malignant (n=13) Benign (n=14) Malignant (n=16)
Age (years)a 38.53±12.18 51.33±12.22 1.09 (1.05–1.14) 39.62±10.21 54.00±13.90 35.68±9.24 46.69±11.75 41.94±12.57 47.23±11.97 41.86±11.04 50.19±10.13
Size of mass (mm)a 16.71±6.70 18.14±7.35 0.27 18.92±8.77 25.45±11.63 17.01±7.50 21.58±21.58 16.26±8.10 24.20±10.14 18.41±6.87 21.10±8.31
Shapeb <0.01
   Regular 30 (85.7) 5 (14.3) 3 (100.0) 0 (0) 10 (83.3) 2 (16.7) 7 (87.5) 1 (12.5) 8 (88.9) 1 (11.1)
   Irregular 28 (34.6) 53 (65.4) 11.36 (4.27–36.27) 10 (47.6) 11 (52.4) 9 (39.1) 14 (60.9) 9 (42.9) 12 (57.1) 6 (28.6) 15 (71.4)
Marginb <0.01
   Distinct 50 (82.0) 11 (18.0) 8 (88.9) 1 (11.1) 11 (73.3) 4 (26.7) 10 (100.0) 0 9 (100.0) 0
   Indistinct 8 (14.5) 47 (85.5) 26.70 (10.40–76.95) 5 (33.3) 10 (66.7) 8 (40.0) 12 (60.0) 6 (31.6) 13 (68.4) 5 (23.8) 16 (76.2)
Echob <0.01
   Saccadic echo 2 (3.5) 0 2 (15.4) 0 3 (15.8) 0 2 (12.5) 1 (7.7) 2 (14.3) 0
   Iso-echo 20 (34.5) 3 (5.2) 8.64×105
(2.36×10–64–NA)		 7 (53.8) 3 (27.3) 6 (31.6) 2 (12.5) 5 (31.3) 3 (23.1) 6 (42.9) 3 (18.8)
   Heterogeneous echo 17 (29.3) 17 (29.3) 5.76×106
(4.90×10–64–NA)		 1 (7.7) 3 (27.3) 8 (42.1) 5 (31.3) 6 (37.5) 2 (15.4) 4 (28.6) 4 (25.0)
   Hypo-echo 19 (32.8) 38 (65.5) 1.15×107
(8.98×10–64–NA)		 3 (23.1) 5 (45.5) 2 (10.5) 9 (56.3) 3 (18.8) 7 (53.8) 2 (14.3) 9 (56.3)
Posterior featuresb <0.01
   Enhancement 37 (84.1) 7 (15.9) 2 (22.2) 7 (77.8) 16 (57.1) 12 (42.9) 14 (77.8) 4 (22.2) 13 (48.1) 14 (51.9)
   No posterior acoustic features 14 (40.0) 21 (60.0) 7.93 (2.88–24.14)
   Shadowing 7 (18.9) 30 (81.1) 22.65 (7.62–77.88) 11 (73.3) 4 (26.7) 3 (42.9) 4 (57.1) 2 (18.2) 9 (81.8) 1 (33.3) 2 (66.7)
Vascularityb 0
   None 22 (66.7) 11 (33.3) 8 (72.7) 3 (27.3) 15 (78.9) 4 (21.1) 11 (25.0) 3 (75.0) 6 (85.7) 1 (14.3)
   A little 30 (65.2) 16 (34.8) 1.07 (0.42–2.79)
   Rich 6 (16.2) 31 (83.8) 10.33 (3.50–4.65) 5 (38.5) 8 (61.5) 4 (25.0) 12 (75.0) 5 (33.3) 10 (66.7) 8 (37.8) 15 (65.2)
Pathology
   Intraductal papilloma 3 (5.2) 1 (7.7) 1 (5.3) 1 (7.1)
   Atypical hyperplasia 3 (5.2) 0 1 (5.3) 1 (6.25) 0
   Mammary duct expansion 1 (1.7) 2 (15.4) 0 0
   Inflammation 1 (1.7) 1 (7.7) 0 1 (6.25) 1 (7.1)
   Adenosis 10 (17.2) 2 (15.4) 5 (26.3) 4 (25.0) 2 (14.3)
   Fibroadenoma 40 (70.0) 7 (53.8) 12 (63.2) 10 (62.5) 10 (71.4)
   Ductal carcinoma in situ 1 (1.7) 2 (18.2) 0 1 (7.7) 2 (12.5)
   Invasive ductal carcinoma 53 (91.4) 7 (63.6) 14 (87.5) 12 (92.3) 14 (87.5)
   Lymphoma 0 0 1 (6.3) 0
   Mucinous carcinoma 2 (3.4) 0 0 0
   Breast invasive lobular carcinoma 2 (3.4) 2 (18.2) 1 (6.3) 0

a, continuous variables are presented as the mean ± SD and were compared using t-tests. b, categorical variables are presented as n (%) and were compared using chi-squared tests. SD, standard deviation; NA, missing value.

Selection of ultrasound features

According to univariable logistic regression, posterior features [if=2, odds ratio (OR) 22.65, 95% confidence interval (CI): 7.62–77.88], shape (if=1, OR 11.36, 95% CI: 4.27–36.27), margin (if=1, OR 26.70, 95% CI 10.40–76.95), vascularity (if=2, OR 10.33, 95% CI: 3.50–4.65) are appropriate predictors because their OR values are higher than that of age (OR 1.09, 95% CI: 1.05–1.14; Table 1). Based on the results of LASSO regression, 264 SWE features were reduced to 7 (Figure S2A,S2B) and 23 SE features were reduced to 1 (Figure S2C,S2D) in the development cohort. Finally, in Young’s modulus, (the mean shear wave elastography value of 1.5 mm surrounding tissues in a breast mass) divided by (the mean shear wave elastography value of the breast mass)-shell mean/A mean1.5(E), (the ratio of strain elastography of adipose tissue near a breast mass) divided by [the ratio of strain elastography of (the breast mass adds the 1.5 mm surrounding tissues in the breast mass)]—B/A'1.5, posterior features, shape, margin, and vascularity were used to construct Model 1, the nomogram (Table 2).

Table 2

Diagnostic performance of multivariable combined diagnosis

Model Cut-off Sensitivity (%) Specificity (%) AUC 95% CI
Development cohort
   Model 1 0.51 87.9 86.2 0.92 0.87–0.97
   Model 2 0.65 81.0 89.7 0.90 0.84–0.96
   Model 3 0.62 63.7 91.4 0.80 0.71–0.88
Internal validation cohort
   Model 1 0.73 90.9 76.9 0.84 0.66–1.00
   Model 2 0.48 100.0 61.5 0.82 0.65–0.99
   Model 3 0.50 100.0 53.8 0.76 0.55–0.96
External validation cohort 1
   Model 1 0.44 87.5 68.4 0.87 0.75–0.98
   Model 2 0.48 87.5 63.2 0.83 0.70–0.96
   Model 3 0.55 68.8 89.5 0.77 0.60–0.95
External validation cohort 2
   Model 1 0.62 100.0 75.0 0.93 0.84–1.00
   Model 2 0.78 92.3 87.5 0.91 0.80–1.00
   Model 3 0.64 92.3 81.3 0.87 0.74–1.00
External validation cohort 3
   Model 1 0.70 100.0 71.4 0.89 0.77–1.00
   Model 2 0.80 93.8 78.6 0.85 0.69–1.00
   Model 3 0.42 87.5 71.4 0.80 0.63–0.97

Model 1 consisted of margin, posterior features, shape, vascularity, shell mean/A mean1.5(E), and B/A'1.5. Model 2 consisted of margin, posterior features, shape, and vascularity. Model 3 consisted of shell mean/A mean1.5(E) and B/A'1.5. shell mean/A mean1.5(E): (in Young’s modulus, the mean shear wave elastography value of 1.5 mm surrounding tissues in a breast mass) divided by (in Young’s modulus, the mean shear wave elastography value of the breast mass). B/A'1.5: (the ratio of strain elastography of adipose tissue near a breast mass) divided by (the ratio of strain elastography of (the breast mass adds the 1.5 mm surrounding tissues in the breast mass). AUC, area under the curve; CI, confidence interval.

Ultrasound nomogram and prediction models

The diagnostic performance of the different variables used in Model 1 is presented in the Table S1. Model 1 included all the selected features [i.e., margin + posterior features + shape + vascularity + shell mean/A mean1.5(E) + B/A'1.5]; the nomogram according to Model 1 is plotted in Figure 2. To better compare the diagnostic value of dual-mode elastography imaging in breast masses, we built another 2 models: Model 2 contained margin + posterior features + shape + vascularity and Model 3 contained shell mean/A mean1.5(E) + B/A'1.5.

Figure 2 Breast cancer rate nomogram. The ultrasound nomogram was developed in the development cohort, with margin, posterior features, shape, vascularity, shell mean/A mean1.5(E), and B/A'1.5. shell mean/A mean1.5(E): (in Young’s modulus, the mean shear wave elastography value of 1.5 mm surrounding tissues in a breast mass) divided by (in Young’s modulus, the mean shear wave elastography value of the breast mass). B/A'1.5: (the ratio of strain elastography of adipose tissue near a breast mass) divided by (the ratio of strain elastography of (the breast mass adds the 1.5 mm surrounding tissues in the breast mass).

Model validation

Using data from the development and validation cohorts, we performed ROC curve analysis for the 3 models (Table 2; Figure 3) and used the validation data to draw calibration curves (Figure 4). Table 2 presents the sensitivity and specificity of cut-off values determined using each of the 3 models in all 5 cohorts (development, internal validation, and external Cohorts 1, 2, and 3). Across the 5 cohorts, Model 1 had the best AUC compared to Model 2 and Model 3.

Figure 3 ROC curves of the (A) development, (B) internal validation, and (C-E) external validation cohorts (C, Cohort 1; D, Cohort 2; E, Cohort 3). Red, green, and blue lines indicate Models 1, 2, and 3, respectively. Model 1 consisted of margin, posterior features, shape, vascularity, shell mean/A mean1.5(E), and B/A'1.5. Model 2 consisted of margin, posterior features, shape, and vascularity. Model 3 consisted of shell mean/A mean1.5(E) and B/A'1.5. shell mean/A mean1.5(E): (in Young’s modulus, the mean shear wave elastography value of 1.5 mm surrounding tissues in a breast mass) divided by (in Young’s modulus, the mean shear wave elastography value of the breast mass). B/A'1.5: (the ratio of strain elastography of adipose tissue near a breast mass) divided by (the ratio of strain elastography of (the breast mass adds the 1.5 mm surrounding tissues in the breast mass). ROC, receiver operating characteristic.
Figure 4 Calibration curves in the internal validation cohort (A1,B1,C1) and external validation cohorts 1 (A2,B2,C2), 2 (A3,B3,C3), and 3 (A4,B4,C4). (A-C) Calibration curves for Models 1 (A), 2 (B), and 3 (C). P>0.05 as the standard, all the models mentioned above passes unreliability test.

Across the 5 cohorts, Model 1 obviously improved the reclassification performance compared with Models 2 and 3, with the results presented in Table 3.

Table 3

The net reclassification index and integrated discrimination improvement in the five cohorts

Cohort NRI (%) categorical
(95% CI)		 P value NRI (%) continuous
(95% CI)		 P value IDI, % (95% CI) P value
Development cohort
   Model 1 vs. Model 2 18.97 (3.85, 34.08) 0.01 75.86 (42.19, 109.54) <0.01 4.04 (0.04, 8.01) 0.05
   Model 1 vs. Model 3 55.17 (35.08, 75.26) <0.01 131.03 (103.57, 158.50) <0.01 30.42 (22.02, 38.83) <0.01
Internal validation cohort
   Model 1 vs. Model 2 30.77 (–2.16, 63.70) 0.07 74.13 (10.16, 138.1) 0.02 4.29 (–3.92, 12.5) 0.31
   Model 1 vs. Model 3 30.77 (–2.16, 63.70) 0.07 104.90 (42.03, 167.76) <0.01 20.83 (7.03, 34.63) <0.01
External validation cohort 1
   Model 1 vs. Model 2 14.80 (–13.07, 42.67) 0.30 95.40 (37.02, 153.77) <0.01 6.51 (–2.85, 15.87) 0.17
   Model 1 vs. Model 3 8.22 (–26.34, 42.79) 0.64 78.29 (19.68, 136.89) 0.01 10.73 (–3.76, 25.21) 0.15
External validation cohort 2
   Model 1 vs. Model 2 25.00 (–2.39, 52.39) 0.07 122.12 (68.24, 175.99) <0.01 8.76 (0.78, 16.74) 0.03
   Model 1 vs. Model 3 25.00 (–11.75, 61.75) 0.18 97.12 (40.52, 153.71) <0.01 17.65 (2.62, 32.68) 0.02
External validation cohort 3
   Model 1 vs. Model 2 28.57 (4.91, 52.24) 0.02 83.93 (23.04, 144.82) 0.01 2.8 (–2.39, 7.98) 0.29
   Model 1 vs. Model 3 55.36 (18.93, 91.78) <0.01 114.29 (62.44, 166.13) <0.01 30.01 (12.97, 47.06) <0.01

NRI categorical refers to the net reclassification index (NRI) of clinically meaningful categories (the thresholds are 0.2 and 0.4). For NRI continuous, no classifications are considered. Model 1 consisted of margin, posterior features, shape, vascularity, shell mean/A mean1.5(E), and B/A'1.5. Model 2 consisted of margin, posterior features, shape, and vascularity. Model 3 consisted of shell mean/A mean1.5(E) and B/A'1.5. shell mean/A mean1.5(E): (in Young’s modulus, the mean shear wave elastography value of 1.5 mm surrounding tissues in a breast mass) divided by (in Young’s modulus, the mean shear wave elastography value of the breast mass). B/A'1.5: (the ratio of strain elastography of adipose tissue near a breast mass) divided by (the ratio of strain elastography of (the breast mass adds the 1.5 mm surrounding tissues in the breast mass). CI, confidence interval; IDI, integrated discrimination improvement.

Prediction performance of the nomogram

As shown in the DCA (Figure 5), although the threshold probability is 0.4, all models performed better than all-negative samples or all-positive samples. This also reveals that, when the high risk threshold above 0.6, the Model 1 had the highest net benefit among the 3 models. In addition, the clinical impact curve of Model 1 performed best.

Figure 5 DCA (A) and clinical impact curves of Models 1 (B), 2 (C), and 3 (D) in the development cohort. In the DCA, the y-axis shows the net benefit and the x-axis shows the threshold probability. The horizontal black line indicates that all samples were negative, none were treated, and the net benefit was 0. The slanting black line means that all the samples are positive, all are treated. Red, blue, and yellow lines indicate Models 1, 2, and 3, respectively. On the clinical impact curves, red represents the number of people classified as positive by the model under each threshold probability, and the blue represents the number of people who are true positives under each threshold probability. DCA, decision curve analysis.

Discussion

We have developed and validated a diagnostic nomogram based on conventional ultrasound and dual-mode elastography ultrasound to differentiate between benign and malignant breast masses. The nomogram combines 2 elastography features with 4 conventional ultrasound features. The accuracy of differentiating between benign and malignant breast masses is greatly improved by dual-mode elastography ultrasound.

In this study, 264 SWE features were reduced to 7 features and 23 SE features were reduced to 1. The number of survivals and deaths should be more than 10-fold the number of variables used to generate the nomogram in order to lower the predicted error in the prediction probability to <10% (24). In particular, our case load was too small to build a 12-variable logistics model because the number of case samples needed to be more than 10-fold the number of control samples (24). So, we only chose the maximum coefficient correlation variable in the shear wave elastography and the strain elastography into the multivariable logistic model based on the results of LASSO regression. Surprisingly, Model 1 outperformed Models 2 and 3 in terms of AUC, sensitivity, and specificity across all 5 data cohorts. This demonstrates that the ability of Model 1 to predict breast cancer is credible, reducing biopsies and the physical and mental toll on patients.

Studies have shown that elastography plays an important role in discriminating breast masses (27-29). Zhang et al. (20) found that G and Cs parameters of SWE can guide the differentiation of benign and malignant breast masses. Xie et al. (16) showed that the shell of maximum elastography value (Emax) can help to identify breast masses. Xu et al. (18) reported that within a shell range of 1–3 mm, the 2.5-mm Emax shell performs best in the differential diagnosis of non-mass lesions in the breast. Yang et al. (17) found that among the 1-, 2-, and 3-mm shells, the 3-mm shell combination of Emax and minimum elastography value (Emin) differentiated breast masses most effectively. However, to the best of our knowledge, the proportions of the maximum, minimum, mean, and standard deviation of different shells and lesions in E, Cs, and G, such as (the mean shear wave elastography value of 1.5 mm surrounding tissues in a breast mass) divided by (the mean shear wave elastography value of the breast mass), have not been studied yet. We examined the significance of these factors in the ultrasound detection of breast cancer, and found that the combination of shell mean/A mean1.5(E) and B/A'1.5 performed best in the diagnosis of breast masses.

In terms of using conventional ultrasound to diagnose breast masses, many studies have used BI-RADS (30-32); however, the AUCs in those studies ranged from approximately 0.79 to 0.83, which is not that different from the AUC of Model 2 in the present study. In the present study, the conventional ultrasound features were derived from the fifth edition of the BI-RADS lexicon, so Model 2 (margin, posterior features, shape, and vascularity) can represent the results of BI-RADS classification to a certain extent. Furthermore, the diagnostic AUC value of the BI-RADS classification is 0.90, lower than that of the nomogram derived from the present study. In addition, it has been shown that for BI-RADS categories, the highest concordance was typically found in the benign group, with generally lower concordance in the malignant and suspicious groups (33). Therefore, we used conventional ultrasound features and color Doppler features instead of the BI-RADS classification to construct our model.

Age is known to play a significant role in predicting breast cancer (34). However, according to univariate logistic regression analysis, the OR for age is 1.091, which is much lower than the ORs for margin, shape, vascularity, and posterior features. Therefore, age was not included in the multivariate logistic regression analysis in this study. A possible explanation for this strange phenomenon may be that Shenzhen is a young one, and most of the patients treated at the Shenzhen People’s Hospital are young. Another reason could be that our case load was too small, indicating that the study should be repeated with a larger sample size.

In the development cohort, Model 1 reduced the rate of misdiagnosis of benign and malignant breast masses, with an estimated net gain of 3.85–34.08% of patients compared with Model 2. This finding implies that dual-mode elastography can help with breast cancer diagnosis. Moreover, compared with Model 3, Model 1 lowered the rate of incorrectly diagnosed benign and malignant breast masses, with an estimated net gain of 35.08–75.26% of patients. We used the IDI to reflect the overall improvement of the model (25). In the development cohort, Model 1 had a better prediction ability than Model 2 based on the IDI of Model 1 versus Model 2, which was 4.04% (P=0.05). All these results were well validated in all the validation cohorts, which supports the wide applicability of our results.

To assess clinical value, we used DCA and clinical impact curves (26) because the aforementioned results were explored with statistical rigor. The results of these analyses showed that the net benefit rate of Model 1 was higher than those of Models 2 and 3, suggesting that Model 1 has better clinical utility and is worthy of consideration for clinical use.

This study has several limitations. First, retrospective study designs have inherent limitations, such as selection bias and recall bias. In addition, our case load was too small. Finally, shell functionality was limited to 1 instrument, which is not conducive to the generalization of the results.

Conclusions

Our ultrasound nomograms provide exposure to the features and visualization of breast cancer. Dual-mode elastography plays an important role in the diagnosis of breast cancer; in particular, shell mean/A mean1.5(E), B/A'1.5 integrated with margin, posterior features, shape, and vascularity may be more helpful in differentiating breast masses and are worthy of consideration for clinical use.

Acknowledgments

The authors are grateful for the support and help of our team in the Ultrasound Department, Shenzhen People’s Hospital.

Funding: This project was supported by the Commission of Science and Technology of Shenzhen (No. GJHZ20200731095401004).

Footnote

Reporting Checklist: The authors have completed the TRIPOD reporting checklist. Available at https://qims.amegroups.com/article/view/10.21037/qims-22-237/rc

Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at https://qims.amegroups.com/article/view/10.21037/qims-22-237/coif). All authors reported that this work was supported by the Commission of Science and Technology of Shenzhen (No. GJHZ20200731095401004). The authors have no other conflicts of interest to declare.

Ethical Statement: The authors are accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved. The study was conducted in accordance with the Declaration of Helsinki (as revised in 2013). The study was approved by the Regional Ethics Board of Shenzhen People’s Hospital and informed consent was provided by all patients.

Open Access Statement: This is an Open Access article distributed in accordance with the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International License (CC BY-NC-ND 4.0), which permits the non-commercial replication and distribution of the article with the strict proviso that no changes or edits are made and the original work is properly cited (including links to both the formal publication through the relevant DOI and the license). See: https://creativecommons.org/licenses/by-nc-nd/4.0/.

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Cite this article as: Yang K, Ye X, Tian H, Li Q, Liu Q, Li J, Guo J, Xu J, Dong F. Development and validation of a nomogram for discriminating between benign and malignant breast masses by conventional ultrasound and dual-mode elastography: a multicenter study. Quant Imaging Med Surg 2023;13(2):865-877. doi: 10.21037/qims-22-237

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