A computed tomography (CT)-derived radiomics approach for predicting primary co-mutations involving TP53 and epidermal growth factor receptor (EGFR) in patients with advanced lung adenocarcinomas (LUAD)
Introduction
Lung cancer remains the most common malignancy and the leading cause of cancer-related mortality worldwide (1). In East Asia, approximately one third of all lung cancer patients are never-smokers and predominantly with female gender (2-5). These patients are more often diagnosed with adenocarcinoma and epidermal growth factor receptor (EGFR) activating mutations (2,4,6,7). Patients with this genotype usually confer exquisite sensitivity to tyrosine kinase inhibitors (TKIs) (8,9), and EGFR mutation has become the most important molecular marker for TKI therapy selection (9,10). However, approximately 20–30% non-small cell lung cancer (NSCLC) patients harboring EGFR mutation are primary resistance to TKIs (11) and not all the patients show equal response to TKIs. Recently, some studies found that multiple primary driver gene mutations, such as EGFR and TP53, could affect patients’ prognosis and response to TKIs (12,13). They deem that identifying mutation types in different combinations can help to select best responders to target therapy. Primary multiple mutations may be an important factor that affects curative efficacy of TKI in NSCLC patients.
TP53, encoding the p53 protein known as a tumor suppressor gene in preventing and suppressing of abnormal cell growth, is the most frequently mutated gene in NSCLC, with mutation rates up to approximately 40% in lung adenocarcinoma (LUAD) (14-16). So far, there are a series of clinical studies (12,13) focused on primary overlapping mutations involving TP53. They found that, in EGFR-mutated NSCLC patients treated with TKIs, EGFR co-mutated with TP53 could reduce responsiveness to TKIs and worsen patients’ prognosis compared to TP53 wild type patients, with almost a fourfold risk of disease progression (12). Primary TP53 overlapping mutation may play a potential role in TKI resistance and act as an important factor in determining TKI sensitivity. Thus, to identify this genetically unique subset of lung cancer patients prior to treatment is of great clinical significance.
Tissue biopsy based mutational sequencing have become the gold standard of driver-gene mutation detection. However, it still has some shortcomings with regards to the situation of overlapping mutations. First, gene types depend on the scale of the testing panel. In some institutes, TP53 may not be routinely detected and large panel sequencing is a heavy financial burden for patients in the developing countries. In addition, intolerance of repeated biopsies and difficulty of accessing tissue samples limits its applicability and impedes dynamic molecular monitoring. Therefore, to identify an alternative tool to predict TP53 co-mutation status in EGFR-mutated LUAD is necessary.
Computed tomography (CT) as a routinely used technique has been wildly studied in lung cancer diagnosis and therapeutic effect evaluation. Recently, with the rapid development of artificial intelligence technique in the field of medical imaging, CT derived imaging features have been reported to be a noninvasive biomarker to predict gene expression patterns in lung cancer patients (17,18), and EGFR is the most commonly studied gene and the method showed predictive power (19-21). Therefore, it is feasible to predict overlapping mutations based on CT features.
Based on previous studies and considering the impact of co-mutation status of TP53 on therapeutic efficacy of TKIs in EGFR-mutated LUAD, we aimed to noninvasively identify the genetically unique subsets concerned EGFR and TP53, to help preselect the best responders to TKIs via pretreatment CT images. To the best of our knowledge, this approach has not been previously reported. We present the following article in accordance with the STARD reporting checklist (available at http://dx.doi.org/10.21037/atm-20-6473).
Methods
Cohorts and clinical characteristics
Advanced LUAD [American Joint Committee on Cancer (AJCC) stage III and IV] patients with known mutation status of EGFR and TP53 were collected from The First Affiliated Hospital of Sun Yat-sen University (May 1, 2017 to June 1, 2020). This project was approved by the Ethics Committee and Institutional Review Board of Sun Yat-sen University {No.[2013]C-084}. Informed consent was waived. This study conformed to the provisions of the Declaration of Helsinki (as revised in 2013) (available at https://www.wma.net/wp-content/uploads/2016/11/DoH-Oct2013-JAMA.pdf). The study patients were confirmed by biopsy of the original tumor tissue, as well as immunohistochemistry. Metastasis were evaluated by contemporaneous multi-site CT/magnetic resonance imaging (MRI) or positron emission tomography (PET)-CT scans of the whole body. All the enrolled patients were first-visit and prior to treatment. CT images were acquired within one week after admission and before therapy. Patients previously treated were excluded in this study. Patient enrollment algorithm is shown in detail in Figure 1. Cohort clinical characteristics are demonstrated in Table 1. Patients were categorized into three subtypes according to the mutation status of EGFR and TP53: EGFR positive combined with TP53 positive (EGFR+ & TP53+); EGFR positive combined with TP53 negative (EGFR+ & TP53−); EGFR negative (EGFR−), including EGFR negative combined with TP53 positive or TP53 negative. The aim of this study is to prescreen the potential best responders to TKI therapy which is not recommended for EGFR negative patients. Therefore, TP53 overlapping mutation analysis is not performed in EGFR negative group.
Full table
Next-generation sequencing (NGS) for gene status
Archival tissue from 199 patients was adequate for assessment of genetic analyses including TP53, EGFR, etc. mutational status by NGS. Genomic profiling was performed by using a commercially available capture based targeted sequencing panel (Burning Rock Biotech Ltd., Guangzhou, China), targeting at least 13 genes and spanning 1.44 MB of human genomic regions. The mutations found were confirmed by a second, independent analysis.
Scan protocol
All preoperative enhanced chest CT images were obtained with multidetector CT scanners (Aquilion 64, Canon Medical Systems, Otawara, Japan) during inspiration. Scan parameters: tube voltage of 120 kVp; maximum of 500 mA with automatic tube current modulation. Axial thin-section CT images of the whole lung were reconstructed with a section thickness of 1.0 mm at the same increment. Iopromide (300 mg I/mL, Schering Pharmaceutical Ltd.) was used as the contrast agent for enhanced scanning protocol, and 80–100 mL was injected at 3–4 mL/s flow rate. In order to ensure the uniformity of image features extracted by machine learning and to avoid feature extraction bias, patients with imaging thickness other than 1mm were excluded in our study, as shown in Figure 1.
Semantic CT characteristics
Enhanced chest CT images were acquired within one week prior to treatment and the CT imaging features were evaluated by three experienced chest radiologists (XY Yang, DD Chang and X Wu, with experience of 21, 13 and 25 years respectively) through PACS reading workstation blinded to gene mutation status to control potential bias. The order of all patients was disrupted during analysis. Consensus was reached when the radiologists disagreed.
Semantic CT imaging characteristics for evaluation included (Table 2) maximum diameter; location; morphology; contour; shape; enhanced attenuation [Hounsfield units (HU)]; presence of ground-glass opacity (GGO), peri-lesion emphysema, air bronchogram, bubble-like lucency, lobulation, spiculation, pleural tag, vascular convergence, vascular involvement, homogenous attenuation, pleural effusion.
Full table
Imaging features designation: maximum diameter indicated maximal axial size (mm); axial location were classified as inner, middle or peripheral region of the lung lobe; presence of GGO indicated GGO component surrounded or within the tumor; peri-lesion emphysema indicated concurrent emphysema of any cause; bubble-like lucency indicated the presence of air in the tumor; homogenous attenuation indicated the density of the lesion was homogenous after contrast administration and without definite necrosis; vascular involvement indicated vessels were narrowed, occluded, or encased by tumor tissue.
Lesion segmentation and radiomics features extraction
All enhanced CT images were manually segmented with an open-source software ITK-SNAP (http://www.itksnap.org/pmwiki/pmwiki.php) to obtain whole lesion’s three-dimensional volume segmentation of interest (VOI), which will be used for further feature extraction. DICOM data from two hospitals were blinded together and outlined by a chest radiologist (DD Chang) with 13 years of experiences, and then validated by a senior chest radiologist (X Wu) with 25-year experience.
The flow chart of radiomics model building was illustrated in Figure 2. Radiomic features were extracted with an open-source python platform Pyradiomics (version 2.1.2, https://pyradiomics.readthedocs.io/en/latest/#). Features used in this study include the following three classes: (I) shaped-based features (14 features): descriptions of three dimensional size and shape of VOI; (II) first order statistics features (18 features): distribution of voxel intensities within the image region from gray-level histogram of HU; (III) texture features in total 68 features including the gray-level co-occurrence matrix (GLCM, 22 features), gray level run length matrix (GLRLM, 16 features), gray level size zone matrix (GLSZM, 16 features) and gray level dependence matrix (GLDM, 14 features). Besides the original image, 15 filtered images were also generated for feature extraction, including wavelet transform filter (eight decompositions with low and high frequencies), Laplacian of Gaussian filter over three-sigma levels (1.0, 3.0, 5.0); square filter; square root filter; logarithm filter; gradient filter. All the feature classes, with the exception of shape, were calculated on the original and filtered images. Therefore, in this study, (18+68+14) + (18+68) ×15=1,390 features were statistically analyzed.
Prediction models and workflow
All the patients were randomly split into training (80%) and testing set (20%). And all feature selections, classifiers establishment were based by the data in the training dataset to ensure independence from testing dataset.
Since the gene status of LUAD were classified into three groups, traditional machine learning based classifiers, including support vector machine (SVM), k-nearest neighbors (KN), random forest (RF), decision tree (DT), logistic regression (LR), were applied to build multiclass models. The performance was compared by using 5-fold cross-validation in the training cohort, with the best one being selected. One-versus-one was used here as the multiclass classification strategy, where the problem consists in using many binary classifiers to discriminate between each pair of classes, then the final result was predicted by the combination of the outputs of these base classifiers. In this study, these 3 base binary classifiers were: (EGFR+ & TP53+) vs. (EGFR+ & TP53−); (EGFR+ & TP53+) vs. (EGFR−); (EGFR+ & TP53−) vs. (EGFR−). The flowchart of feature selection and model building was shown in Figure 2. Four types of models were built for the comparison in classifiers: (I) clinical features only, represented by clinical model; (II) semantic features only, represented by semantic model; (III) radiomics features only, represented by radiomics model; (IV) clinical & semantic & radiomics features, represented by integrated model.
Feature selection
Feature selection was performed separately for each type of features. Three steps were applied to reduce dimensionality: (I) features with variance larger than 0.8 were included for further analysis; (II) univariate feature selection is done by ANOVA (continuous variable) or chi-square test (discrete variable) to explore the associations between features and genotype. The features with P value above 0.05 were excluded from further analysis; (III) the most significant features were selected by the least absolute shrinkage and selection operator (LASSO) method, which is very effective to reduce dimensionality. For clinical model and semantic model, since the features number before selection was small, only step one was applied for feature reduction. For radiomics model and integrated model, all three steps were executed, and the nonzero feature coefficients ranking the first five were selected for each binary classifier to avoid overfitting.
Statistical analysis
Statistical analyses were performed by using SPSS 22.0 (IBM, USA). Continuous variables were expressed as median [interquartile range (IQR)]. Categorical variables were displayed as frequency, n (%). All machine learning analyses were performed using the Python package scikit-learn (0.19.0), and statistical plots were generated by Matplotlib (2.0.2). Area under the receiver-operating characteristic curves (AUCs) were calculated to evaluate the binary classifiers, and the best ones were applied for the final result. Statistical metrics, including accuracy, sensitivity, specificity, precision, recall, F1 score, were also calculated to evaluate the overall performance of the multiclass classifier. These statistical metrics for multiclass classification were defined similar as those for binary classification. It should be noted that once we picked up one category as positive, the other two are automatically negative. The Youden Index was used to generate the optimal threshold to convert probabilities into binarized labels.
Results
Basic clinical and semantic CT imaging characteristics
A total of 199 patients were included in our study, including 66 (41.5%) cases of EGFR−, 44 (27.7%) cases of EGFR+ & TP53+, 49 (30.8%) cases of EGFR+ & TP53− in the training cohort and 17 (42.5%) cases of EGFR−, 11 (27.5%) cases of EGFR+ & TP53+, 12 (30.0%) cases of EGFR+ & TP53− in the validation cohort. Patient clinicopathological characteristics in the training and validation cohorts are given in Table 1. Gender, smoking status, bone metastasis, lung metastasis, pleural metastasis shows significant differences between the three groups both in the training and validation cohorts, with P value <0.05 respectively.
For the three groups of EGFR−, EGFR+ & TP53+, EGFR+ & TP53−, the detailed information of semantic CT imaging characteristics before treatment in the training and validation cohorts are given in Table 2. The differences in air bronchogram, vascular convergence, homogenous attenuation between the three groups both in the training and validation cohorts are significant. Presence of GGO shows significant differences in the training cohort and peri-lesion emphysema shows significant differences in the validation cohort.
Feature selection and the performance of base binary classifiers
The selected features for the clinical, semantic, radiomics, and integrated models were shown in Table 3. Each group contained three different base binary classifiers used in multiclass classifier.
Full table
Algorithms of SVM, KN, RF, and LR were applied to build base binary classifiers using selected features from the training cohort, and their performance were compared. We selected the SVM algorithm with the best performance for the training dataset as shown in Table 4, and all the analysis and validation were based on it. The Radial basis function (RBF) kernel, also called the RBF kernel, were utilized in the SVM algorithm, and the key hyperparameters gamma and C values were shown in Table S1. For the SVM model, the results indicated that the AUCs were 0.731, 0.653, 0.843 for the three base binary classifiers in the clinical model, and the values were 0.792, 0.613, 0.781 for the semantic model. The radiomics model yielded relatively higher efficacy, with AUCs of 0.785, 0.771, and 0.812, compared with the former two models. When integrating all the information, the performance of the model was improved, with AUCs of 0.831, 0.767, and 0.892. Moreover, it revealed that it would be possible to differentiate precisely (EGFR+ & TP53−) from (EGFR−), with >0.780 AUC across all models. Moderate performance was achieved in differentiating (EGFR+ & TP53+) from (EGFR+ & TP53−), (EGFR+ & TP53+) from (EGFR−), except the poor accuracy was achieved when discriminating (EGFR+ & TP53+) from (EGFR−) using the clinical (AUC, 0.653±0.112) and semantic model (AUC, 0.613±0.057).
Full table
Multiclass classification strategy
The performance of the multiclass classification for the validation dataset, in our study was three-type classification, was shown in Table 5 and Figure 3. When AUCs were used to evaluate the distinguishing efficacy of the models, the integrated model displayed the best performance for all the three subtypes of co-mutations: EGFR− (AUC, 0.857; accuracy, 0.817; sensitivity, 0.998; specificity, 0.663), EGFR+ & TP53+ (AUC, 0.791; accuracy, 0.758; sensitivity, 0.762; specificity, 0.783), EGFR+ & TP53− (AUC, 0.761; accuracy, 0.813; sensitivity, 0.594; specificity, 0.977). Although the integrated model showed the best prediction efficiency, the radiomics model showed only a slight decrease for all the three subtypes compared with it: EGFR− (AUC, 0.836; accuracy, 0.796; sensitivity, 0.728; specificity, 0.816), EGFR+ & TP53+ (AUC, 0.762; accuracy, 0.842; sensitivity, 0.528; specificity, 0.957), EGFR+ & TP53− (AUC, 0.753; accuracy, 0.773; sensitivity, 0.829; specificity, 0.687). The clinical model and the semantic model showed unsatisfied distinguishing efficiency, with AUCs less than 0.700 for all the three subtypes.
Full table
Discussion
In the present study, we developed and validated a multiclass classification strategy for the pretherapeutic individualized prediction of primary overlapping mutations involving TP53 and EGFR in advanced LUAD. The integrated model is promising to distinguish EGFR+ & TP53+, EGFR+ & TP53−, EGFR−, with AUC more than 0.750. According to recent studies, in EGFR-mutated NSCLC patients treated with TKIs, EGFR co-mutated with TP53 could reduce responsiveness to TKIs and worsen patients’ prognosis compared to TP53 wild type patients (12,13). Identify mutation types in different combinations can help to select best responders to target therapy. The model built by our team has the potential to preselect patients who will be sensitive to TKI therapy and patients who may have a better clinical outcome. Our study provided an alternative way to non-invasively assess TP53 genotype combined with EGFR, offered a great supplement to biopsy. To the best of our knowledge, this is the first study to predict overlapping mutations regarding TP53 based on CT images, it may serve as an alternative marker to select the best responders to TKIs in EGFR-mutated LUAD.
So far, there have been many studies reported the correlation between imaging features and somatic mutations (22-31) as well as molecular expression (32). Image as a non-invasive method has great potency in predicting genotype and molecular for many kinds of tumors, it is likely to become an important alternative marker for treatment decision making. For lung cancer, most previous studies focus on the predictive value of CT features on EGFR mutation (22-27), and achieved favourable outcome, with AUC more than 0.800 (22). The established models may be helpful in selecting patients who will be adaptable to TKIs prior to treatment. Considering the potential impact of TP53 mutation on the therapeutic effect of TKI, further attention should be paid to the co-mutation status of TP53. We try to apply the multiclass classification strategy to solve the problem of overlapping mutations involving EGFR and TP53. The model proposed by our team can predict of the specific three mutational status by one step. Therefore, our model extends the potential application value of the existed model, it can better help to select the best responders to TKI therapy.
Several studies have explored the correlation between imaging features and TP53 mutation in some kinds of cancers, including LUAD (33), pancreatic ductal adenocarcinoma (34,35), head and neck cancer (36), colorectal cancer (37), glioma (38). In the study conducted by Wang et al. (33), they enrolled 51 patients with resectable early stage LUAD. The radiomics signature yielded a median AUC value of 0.604, and 0.586 respectively in predicting EGFR and TP53 mutations. The combined radiomics and clinical model further improved the prediction performance, with AUC 0.697 for EGFR mutation, and 0.656 for TP53 mutation, respectively. Different from their study, we focused on advanced LUAD which may need TKI therapy if a sensitive gene mutation is detected. As for TP53, we studied the overlapping mutation status of EGFR and TP53, instead of predicting the mutation status of EGFR and TP53 alone. Despite the concurrent TP53 genomic alteration in EGFR mutant LUAD demonstrated distinctive therapeutic responses to TKIs, so far there is no relevant predicting biomarkers to distinguish this co-mutation condition. The multiclass classification radiomics model proposed by our team may be an auxiliary in screening the best responder to TKIs in advanced lung cancer.
In this study, the proposed multiclass classification radiomics model provides potential clinical utility from the following perspectives. (I) The proposed radiomics model can be used as an alternative tool to noninvasively predict TP53 genotype easily through routine CT images which is necessary for lung cancer patients to perform pretherapeutic staging, without adding cost. (II) As well studied by other researchers that CT-based imaging features can predict EGFR genotype (19,39-42), thus further distinguish TP53 genotype at the same time becomes feasible. This is promising for patients who are unable to afford large panel sequencing due to poor economic conditions. (III) For patients who have poor response to TKI therapy during treatment and are unwilling to conduct re-biopsy for repetitive sequencing or unable to acquire enough tumor tissue for re-biopsy, the proposed model is an alternative for treatment decision making. This approach makes dynamic molecular diagnosis and timely adjustment of treatment possible. (IV) Although there is no targeted drug for TP53 co-mutation at present, with the rapid development of treatment modalities for advanced lung cancer, there may be some new therapeutic regimens for the clinical condition of TP53 overlapping mutation in the future to improve patient prognosis.
Despite the encouraging and promising findings of our present study, it still has several limitations. First, our findings deserve further study with expanded samples and extra external validation. A large-scale study enrolling more patients may definitely help validate and improve its applicability as an effective prediction tool for predicting TP53 genotype in treatment decision making for LUAD. Second, our study focused on LUAD and did not address other histologic subtypes. Third, despite the present study was a multicenter study, the results cannot be generalized to other populations because gene mutation rate can be affected by race. Fourth, a large number of the gene sequencing results in this study were based on fine needle aspiration biopsy, so tumor heterogeneity is inevitable.
In conclusion, the proposed radiomics model is expected to distinguish co-mutation status involving TP53 and EGFR. It may have a potential application value in preselecting patients who will be adaptable to and sensitive to TKIs and have better prognosis.
Acknowledgments
Funding: None.
Footnote
Reporting Checklist: The authors have completed the STARD reporting checklist. Available at http://dx.doi.org/10.21037/atm-20-6473
Data Sharing Statement: Available at http://dx.doi.org/10.21037/atm-20-6473
Peer Review File: Available at http://dx.doi.org/10.21037/atm-20-6473
Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at http://dx.doi.org/10.21037/atm-20-6473). The authors have no 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. This study conformed to the provisions of the Declaration of Helsinki (as revised in 2013). This study was approved by the institutional ethics committee of the First Affiliated Hospital of Sun Yat-sen University {No.[2013]C-084}. Informed consent was waived.
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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