A PET/CT nomogram incorporating SUVmax and CT radiomics for preoperative nodal staging in non-small cell lung cancer

Lung cancer is considered the leading cause of cancer death worldwide. In patients with non-small cell lung cancer (NSCLC), nodal staging (N staging) is usually closely associated with the prediction of prognosis [1‐4] and clinical therapeutic planning [5, 6]. Previous studies [7‐10] have found that N staging after induction therapy for stage IIIA lung cancer may determine patient survival. For advanced patients with positive N2, preoperative downstaging from N2 to N0 can improve the 5-year survival rate for up to 35.8%, while those with a persistent tumor in their lymph nodes (LNs) (N1 and N2) tend to have a 5-year survival of 9% [8]. Therefore, accurate preoperative clinical N staging and restaging is the key to clinically individualized decision making, which may enable patients to receive more effective treatment and improve prognosis.

¹⁸F-Fluorodeoxyglucose positron-emission tomography/computed tomography (¹⁸F-FDG PET/CT) is considered to be the most reliable functional imaging method for assessing the status of mediastinal and hilar LNs [11, 12]. This non-invasive method can simultaneously provide metabolic and anatomical information. Metastatic LN is usually accompanied by tumor cells’ active metabolism of ¹⁸F-FDG and lymphadenopathy, increased standard uptake value (SUV) [13]. It often appears as a bright light spot on PET images and enlarged in size as round lesions on CT images, mainly in short-axis diameter (SAD) [14]. ¹⁸F-FDG PET has become a standard imaging procedure for N and M staging in NSCLC. However, due to the complications, such as inflammatory, granulomatous, and infectious diseases, highly sensitive PET may detect false-positive LNs [15‐18]. Low spatial and organizational resolution of PET images, the small size of LNs, and inevitably cardiac and breathing motion artifacts during the long duration of the PET imaging process result in a missed diagnosis of small-sized metastatic LNs. Moreover, CT is the most widely used clinical examination. SAD ≥ 1 cm is often used as the diagnostic criterion. However, normal, inflammatory proliferative, and metastatic LNs partly overlap in size, and normal LNs vary in size and shape [19, 20], which results in a missed diagnosis of micro-metastatic LNs and misdiagnosis of inflammatory hyperplastic LNs, leading to an increase in the false-negative rate. Therefore, there is an urgent need to develop a more effective method to predict LN status preoperatively.

Radiomics is a medical image (PET, CT, and MRI) method based on high-throughput extraction of quantitative image features, which is used to predict underlying tumor biology and behavior [21, 22]. Over the last decade, a variety of prediction models [23‐26] have been established using primary tumor as the region of interest (ROI) based on the changes in the tumor-induced microenvironment [27‐29], which can be used to classify LN metastasis in N⁻ or N⁺, thus providing a qualitative diagnosis of LN metastasis of cancer, including lung cancer, colorectal cancer, breast cancer, and others fields. However, with the promotion of precision medicine, qualitative diagnosis of LN metastasis still does not meet the requirement for individualized treatment; thus, quantitative N staging has become of urgent importance in clinical practice.

To the best of our knowledge, so far, there is a rare correlated study that investigated high-latitude radiomics features and maximum standard uptake value (SUVmax) based on LNs for prediction of N staging in NSCLC. Therefore, the objective of our study was to establish and validate a PET/CT nomogram that incorporates the metabolic information (SUVmax) and structural information (radiomics features) of LNs for preoperative quantitative estimation of LN metastasis that could further help clinicians in making individualized therapeutic decisions and predict prognosis.

In the present research, a radiomics model (Rad-Score) based on CT which aimed to noninvasively predict LN status was established, compared to, and combined with SUVmax (functional information) and SAD (measurable anatomical information), after which a PET/CT nomogram was built and validated. The PET/CT nomogram, here we called Int-Score, provides a more accurate preoperative estimation of LN status in patients with NSCLC, and, in turn, may guide N staging and further clinical decisions.

PET/CT is a widely used non-invasive imaging tool for evaluating the TNM stage in NSCLC patients. When using traditional diagnostic procedures, we comprehensively judge LN status by measuring SAD and attenuation, observing morphology and edges on CT image, and measuring SUV on PET image. Yet, artificially judging the change in density and evaluating the morphological edge of the lesion, many subjective outcomes would inevitably appear and a lot of information that cannot be visually perceived may be missed. In this study, we quantitatively extracted the information that is difficult to be visually perceived of LNs using radiomics, and accurately described the attenuation variation and shape difference of LNs [21, 22, 35], thus avoiding the one-sidedness of subjective judgments and visual differences to some extent. By using a nomogram (Int-Score) that incorporates the function information (SUVmax) and structural information (radiomics features), we provided a scale for the preoperative estimation of LN status. Previously, Billé A et al [16] suggested an AUC for the ratio of LN to primary tumor SUVmax multiplied by the maximal diameter of tumor, the ratio of LN to primary tumor SUVmax, and SUVmax of 0.709, 0.590, and 0.673, respectively. In this study, the Int-Score showed moderate improvement of the efficiency with AUC of 0.881 (95% CI, 0.834–0.928) in the training cohort and AUC of 0.872 (95% CI, 0.797–0.946) in the testing cohort. Moreover, compared with other studies [35], which examined texture features and multi-resolution histograms from ¹⁸F-FDG PET/CT images, Int-Score had better diagnostic efficacy. In addition, more detailed radiomics features were extracted to avoid the deviation of results caused by incomplete information. Previously, Bayanati H et al [36] combined three texture features and three shape-based features to predict LN metastasis with an accuracy of 0.71 and AUC of 0.87. By contrast, we examined the generalization and diagnostic efficacy of the model with an independent validation group, incorporating metabolic information, and accurately assessing the global morphology of focal using 3D VOI.

In this study, 20 patients of NSCLC with N2 were evaluated as clinical N1 or even N0 and underwent surgical resection. The sensitivity of PET/CT nomogram for N2 disease was 85% (17/20). Endobronchial ultrasound-guided transbronchial needle aspiration (EBUS-TBNA) is an invasive diagnostic tool for N2 diseases, which also can help improve the preoperative staging of these patients [37], but the puncture path is often restricted by anatomical location. Therefore, PET/CT nomogram seems to be more flexible and non-invasive in clinical use than minimally invasive EBUS-TBNA staging for patients with uncertain N2.

This study also has a few limitations. Firstly, the sample size was relatively small for radiomics analysis; however, we used a sample size estimation method [38] to prove that the testing cohort exceeded the minimum sample size required. A future multicenter study with an external validation dataset is necessary to improve and generalize our model. Secondly, there was some bias in the selection of LNs, and we may choose false-positive LNs with higher SUVmax, leading to a high false-positive rate in the overall data. Nevertheless, no significant differences were found in the distribution of SUVmax and SAD values between training and testing cohorts. Thirdly, our study did not include clinical information, such as CEA, CA125, and CA153 levels. Yang X et al [39] found that these clinical parameters were not independent predictors for LN metastasis; yet, a comprehensive assessment is still needed for clinical decisions.

This study analyzed radiomics features extracted from LN CT imaging, and also developed and validated a PET/CT nomogram, which incorporated Rad-score and SUVmax for preoperative estimation of N staging in NSCLC. The PET/CT nomogram, which is a non-invasive predictive tool that improves the diagnostic accuracy, specificity, and sensitivity of N staging compared to SUVmax and SAD alone, can be used to better assist clinicians in making individual treatment decisions.