- Research
- Open access
- Published:
Personalized radiomics signature to screen for KIT-11 mutation genotypes among patients with gastrointestinal stromal tumors: a retrospective multicenter study
Journal of Translational Medicine volume 21, Article number: 726 (2023)
Abstract
Objectives
Gastrointestinal stromal tumors (GISTs) carrying different KIT exon 11 (KIT-11) mutations exhibit varying prognoses and responses to Imatinib. Herein, we aimed to determine whether computed tomography (CT) radiomics can accurately stratify KIT-11 mutation genotypes to benefit Imatinib therapy and GISTs monitoring.
Methods
Overall, 1143 GISTs from 3 independent centers were separated into a training cohort (TC) or validation cohort (VC). In addition, the KIT-11 mutation genotype was classified into 4 categories: no KIT-11 mutation (K11-NM), point mutations or duplications (K11-PM/D), KIT-11 557/558 deletions (K11-557/558D), and KIT-11 deletion without codons 557/558 involvement (K11-D). Subsequently, radiomic signatures (RS) were generated based on the arterial phase of contrast CT, which were then developed as KIT-11 mutation predictors using 1408 quantitative image features and LASSO regression analysis, with further evaluation of its predictive capability.
Results
The TC AUCs for K11-NM, K11-PM/D, K11-557/558D, and K11-D ranged from 0.848 (95% CI 0.812–0.884), 0.759 (95% CI 0.722–0.797), 0.956 (95% CI 0.938–0.974), and 0.876 (95% CI 0.844–0.908), whereas the VC AUCs ranged from 0.723 (95% CI 0.660–0.786), 0.688 (95% CI 0.643–0.732), 0.870 (95% CI 0.824–0.918), and 0.830 (95% CI 0.780–0.878). Macro-weighted AUCs for the KIT-11 mutant genotype ranged from 0.838 (95% CI 0.820–0.855) in the TC to 0.758 (95% CI 0.758–0.784) in VC. TC had an overall accuracy of 0.694 (95%CI 0.660–0.729) for RS-based predictions of the KIT-11 mutant genotype, whereas VC had an accuracy of 0.637 (95%CI 0.595–0.679).
Conclusions
CT radiomics signature exhibited good predictive performance in estimating the KIT-11 mutation genotype, especially in prediction of K11-557/558D genotype. RS-based classification of K11-NM, K11-557/558D, and K11-D patients may be an indication for choice of Imatinib therapy.
Introduction
Subepithelial cancers of the gastrointestinal system are most common in the form of gastrointestinal stromal tumors (GISTs) [1, 2]. Malignant and noncancerous GISTs may be diagnosed, with surgery being the treatment of choice [1, 2]. In addition, small molecule tyrosine kinase inhibitors (TKIs), particularly Imatinib, are known to significantly boost the prognosis of GISTs [3].
Gain-of-function mutations in c-kit (KIT) or platelet-derived growth factor receptor alpha (PDGFRA) receptor tyrosine kinase genes are frequent in individuals with GISTs [4,5,6,7]. The 95% of adult GIST patients have abnormally high levels of KIT protein, and 80% of GIST patients have mutations in the KIT gene [4,5,6,7]. Exon 11, which codes for the intracellular juxtamembrane region of the KIT receptor, is the most common site for mutations in the KIT gene [4,5,6,7]. Interestingly, Point mutations (PM), deletions (D), and insertions (I) in KIT exon 11 have all been observed, which is rather intriguing (I). Most GISTs have been linked to a gain-of-function mutation in the tyrosine kinase function of c-kit, suggesting a role for this mutation in the etiology of this tumor [8, 9].
Given its strong prevalence and poor prognosis with late detection, it is essential to identify GIST mutation biomarkers which can aid in diagnosis and personalized treatment planning. It was previously revealed that the GIST response to targeted therapy and its disease progression is highly dependent on the location and form of genetic mutation [9,10,11,12]. According to one research, GIST with a mutation in the main KIT exon 11 had the best response to Imatinib [13]. However, GIST with mutations in exon 17 of the KIT gene or exon 18 of the PDGFRA gene is resistant to Imatinib [14, 15].
GIST prognosis determination depends on responses to targeted therapy. Prior reports suggested that GISTs carrying varying primary KIT exon 11 mutations give rise to distinct patient prognoses. Although there is no general consensus regarding gene mutation and prognosis association, several clinical trials demonstrated that D, particularly, KIT exon 11 codon 557-558 D (K11-557/558D) is linked to disease progression and the largest postsurgical recurrence rate among GIST patients. However, these patients respond well to Imatinib [9, 11, 16]. Given this evidences, longer postsurgical targeted therapy was recommend for these patients [10, 17].
Typically, surgically removed tissue samples are used for GIST gene mutation analysis. Unfortunately, some patients with GIST are diagnosed with tumor metastases or rather big tumors, making surgical excision impossible. It is possible to use fine-needle aspiration to acquire tissue for pathological assessment. However, the extracted sample is generally insufficient for genotyping. Moreover, routine genotyping is also avoided owing to its relatively high cost, even among surgical resection patients.
Medical imaging is a robust tool with multiple applications, including, disease diagnosis and treatment guidance [18]. It is commonly used owing to its non-invasive nature and relatively thorough assessment of the internal tissues and organs. GIST is frequently identified using computed tomography (CT) [3]. Radiomics allows the conversion of CT scans into high-throughput quantitative data, which may be used to characterize intra-tumor heterogeneity and its possible connections with genetic profiles. The higher effectiveness of radiomics in predicting malignancy and the ki-67 profile among GIST patients has been shown in recent papers [19, 20]. Radiogenomics integrates clinical imaging information with molecular and genomic imaging [21]. Multiple recent investigations reported strong correlations between tumor radiomics and gene profiles belonging to renal cell carcinoma, breast cancer, gliomas, neck tumors and GISTs [18, 22,23,24]. Few studies also examined the feasibility of employing radiogenomics to study KIT-11 mutation among GIST patients [25, 26]. However, these studies only investigated whether radiomics can estimate KIT-11 mutation among GIST patients, and they did not differentiate between varying KIT-11 mutation genotypes, which, as we mentioned earlier, produces distinct disease progressions, postoperative recurrence rates, and responses to Imatinib [9, 11, 16].
Herein, we separated eligible GIST patients into 4 categories: no mutation (K11-NM), K11-PM/D, K11-557/558D, and KIT-11 D not involving codons 557/558 (K11-D). We explored the predictive performance of our radiomics signature extracted from the arterial phase of contrast-corrected CT to predict varying KIT-11 mutation genotypes.
Methods
Patient population
The institutional review board approved the study protocol, and the study was conducted in accordance with ethical principles of the 1975 Declaration of Helsinki and subsequent revisions (KY2023-002-B). Consent requirement have been waved by institutional review board due to its retrospective study. Overall, 1143 GIST patients were enrolled from 3 medical centers for this retrospective investigation. The following patients were selected for analysis: (1) those who received surgery; (2) standard contrast-enhanced CT (CE-CT) < 2 weeks prior to treatment; (3) histology- and immunohistochemistry-based GIST diagnosis; (4) available previously analyzed clinical and pathological variables. Among those that were eliminated from analysis were patients with prior Imatinib treatment or numerous GISTs or cases involving inadequate image quality (e.g., missing contrast-enhanced CT portal phase, severe motion artifact).
The study subjects were separated into two distinct cohorts, namely, training (TC) and validation cohorts (VC). Between January 2011 and June 2022, 617 patients were chosen from the one hospital for the TC. We chose GIST patients from the remaining two facilities between January 2015 and June 2022 for the VC. The detail of inclusion of GIST patients and radiomcis extraction was shown in the Fig. 1.
CT assessment
The CT protocol is presented in detail in Additional file 1: A1 and Table S1, which have been validated in the assessment of prediction of Ki-67 expression and maligiant potential in GISTs [19, 27].
Clinical variable and primary endpoint
We assessed clinical and pathological information, namely, age, gender, tumor site, mitotic count, tumor size, and KIT-11 mutation genotype. The maximum diameter on axial CT scans was used to determine the tumor size. There were four distinct categories for the KIT-11 mutant genotype: K11-NM, K11-PM/D, K11-557/558D, and K11-D. Our primary endpoint was the accuracy in KIT-11 mutation genotype prediction.
Radiomic signature (RS) construction
ITK-SNAP (version 2.2.0; www.itksnap.org) was used to manually pick the area of interest from all contrast-corrected CT images for each GIST that were downloaded from the Picture Archiving and Communication System. Each patient's CE-CT arterial phase slice pictures were reviewed, and the slice with the most tumor was selected for further examination. After that, for each individual being studied, a 2D region of interest (ROI) with largest area was selected. Our research methodology is shown in Fig. 1.
Each GIST's radiomic profile was obtained using the aforementioned ROI using PyRadiomics in Python (version 3.7), and the resulting profile included first-order statistics, 2D shape features, a grey-level co-occurrence matrix (GLCM), a grey-level run-length matrix (GLRLM), a grey-level size-zone matrix (GLSZM), a gray-level dependence matrix (GLDM), and a neighboring gray-tone difference matrix (NGTDM) [28]. In-depth summaries of these radiomic profiles are provided in Table S2 of the Additional file 1. After that, we followed these steps (Additional file 1: A3) to pick a radiomic profile and build an RS: The ICCs (intra- and inter-class correlation coefficients) [29] are used to assess the repeatability of a profile, whereas the LASSO technique is used to build a RS [30]. In GIST patients, the RS produced the genotype of the KIT-11 mutation. The LASSO coefficients were used to assign relative importance to each radiomics profile, and then RS was calculated as: Rad-score = a1X1 + a2X2 + ⋯ + anXn + b.
Statistical analysis
Categorical variables are stated as raw numbers or percentages, whereas continuous variables are shown as means ± standard deviations or medians and ranges. The t- or Mann–Whitney test for continuous data, and the chi-square test or Fisher's exact test for categorical data, were used to find statistically significant differences in TC and VC across several groups.
Cohen's k statistic was used for both inter- and intra-observer ICCs to assess the level of agreement amongst CT profile readers. Values of kappa over 0.80 indicated very strong agreement, while values between 0.40 and 0.80 indicated moderate correlation, and values below 0.40 indicated minimal consensus.
Receiver operating characteristic (ROC) curves and area under the ROC curve (AUC) with 95% confidence interval (CI) were used to evaluate the precision of the RS predictions, as has been previously reported [31, 32]. In addition, we calculated and showed the TC and VC's prediction accuracy, sensitivity, specificity, negative predictive value (NPV), and positive predictive value (PPV). Micro- and macro-averages are also provided. The micro-average value represents the average instance-level performance. As such, it can form a bias toward the label with the largest frequency count. This is likely why the associated values are relatively high. The macro-averaged value represents the mean performance across all labels. Hence, it provides an enhanced understanding of a model’s performance across different labels [33]. Moreover, the bootstrap technique (N = 1000) was employed for the macro- and micro-averaged value calculations.
R (3.5.0) and Python (3.7) were used for all statistical analyses. The cutoff point for significance was determined to be a P value of 0.05 or below.
Results
Clinical baseline profiles of the TC and VC
Overall, 1143 GISTs patients with definitive KIT-11 mutation genotype testing results from 3 centers were separated into TC and VC. TC consisted of 617 GIST patients from one hospital, and VC consisted of 526 GIST patients from the remaining two hospitals. Patients in both groups showed similar demographics (Table 1), including gender, age, geographic region, aggressive behavior risk, and KIT-11 mutant genotype. However, a higher percent of high mitotic count (> 10/50 HPF) was observed in the VC, compared to the TC.
Development of RS in prediction of KIT-11 mutation subtyping in TC
Overall, 726 radiomics characteristics with ICC values > 0.8 in the intra- and inter-individual comparisons were employed for model construction. Using LASSO regression, 46, 55, 50, and 39 radiomics were employed for RS construction to predict K11-NM, K11-PM/D, K11-557/558D, and K11-D, respectively. The detailed LASSO coefficients for each radiomics are described in Table S2.
Our newly constructed RS showed a high AUC in predicting each KIT-11 mutation, as shown in Fig. 2A. The AUCs for K11-NM, K11-PM/D, K11-557/558D, and K11-D predictions were 0.848 (95% CI 0.812–0.884), 0.759 (95% CI 0.722–0.797), 0.956 (95% CI 0.938–0.974), and 0.876 (95% CI 0.844–0.908) respectively. Figure 3A depicts the TC RS confusion matrix. We found that the RS correctly predicted 73 of 114 instances of K11-NM, 194 of 243 cases of K11-PM/D, 79 of 132 cases of K11-557/558D, and 82 of 108 cases of K11-D. We also calculated the diagnostic accuracy of RS for identifying different types of KIT-11 mutations. Table 2 shows the RS specificity ranged from 0.706 (95% CI 0.660–0.752) to 0.965 (95% CI 0.949–0.981), sensitivity ranged from 0.545 (95% CI 0.460–0.629) to 0.798 (95% CI 0.748–0.849), accuracy ranged from 0.742 (95% CI 0.708–0.777) to 0.930 (95% CI 0.910–0.950), NPV ranged from 0.843 (95% CI 0.803–0.884) to 0.965 (95% CI 0.949–0.981) and PPV ranged from 0.638 (95% CI 0.584–0.692) to 0.822 (95% CI 0.747–0.896).
Validation of RS in prediction of KIT-11 mutation subtyping in VC
We next validated our newly developed RS in the VC from two medical centers. The AUCs were 0.723 (95% CI 0.660–0.786), 0.688 (95% CI 0.643–0.732), 0.870 (95% CI 0.824–0.918), and 0.830 (95% CI 0.780–0.878) for K11-NM, K11-PM/D, K11-557/558D, and K11-D prediction, respectively. The RS confusion matrix for VC is depicted in Fig. 3B. Based on our observation, there were 70 (52.2%) cases of K11-NM, 150 (78.1%) cases of K11-PM/D, 61 (55.0%) cases of K11-557/558D, and 54 (60.7%) cases of K11-D which were accurately predicted by the RS in VC. We also computed the RS diagnostic efficacy in predicting each KIT-11 mutation class in the VC. As depicted in Table 2, the RS specificity ranged from 0.737 (95% CI 0.689–0.784) to 0.929 (95% CI 0.905–0.953), sensitivity ranged from 0.522 (95% CI 0.438–0.607) to 0.781 (95% CI 0.723–0.840), NPV ranged from 0.854 (95% CI 0.813–0.895) to 0.921 (95% CI 0.895–0.946), PPV ranged from 0.598 (95% CI 0.503–0.693) to 0.693 (95% CI 0.603–0.783), and accuracy ranged from 0.637 (95% CI 0.595–0.610) to 0.875 (95% CI 0.846–0.903).
As depicted in Fig. 2, the micro-averaging AUCs were 0.860 (95% CI 0.845–0.873) and 0.778 (95% CI 0.752–0.803) in the TC and VC. The macro-averaging AUCs were 0.838 (95% CI 0.820–0.855) and 0.758 (95% CI 0.758–0.784) in the TC and VC. In terms of the macro- and micro-averaging diagnostic efficacies, the micro-averaging accuracies were 0.781 (95% CI 0.755–0.808), and 0.694 (95% CI 0.660–0.729) in the TC and VC, respectively. The macro-averaging accuracies were 0.694 (95% CI 0.660–0.729), and 0.637 (95% CI 0.595–0.679) in the TC and VC, respectively. The micro- and macro-averaging values are detailed in Table 2.
Discussion
Herein, we explored the feasibility of the radiomics profile to predict varying KIT exon 11 K11-Mutations in GISTs using various contrast-corrected CT images from large-scale imaging data. We established a four-level classification model with satisfactory performance to probe the KIT-11 mutation genotype profiles of GISTs, based on contrast CT images. We further demonstrated that our newly developed RS can accurately predict the KIT-11 mutation genotype.
Historically, the application of medical imaging was primarily driven by necessity. The advent of radiomics has revolutionized this approach, enabling the conversion of medical images into high-throughput quantitative data that may be linked to factors such as intra-tumor heterogeneity and individual patient genetics (radiogenomics). In 2018, Xu et al. conducted a study that showcased the potential of CT texture analysis of enhanced CT images to differentiate between GIST without K11-mutation and GIST with K11-mutation [25]. They further proposed that the standard deviation of tumor texture parameters could serve as a unique indicator of GIST without K11-D. While this study was a significant contribution to the field, it should be noted that it was conducted with a relatively small patient population, consisting of 69 cases in TC and 17 cases in VC. Additionally, the VC group only included 4 cases of GIST without K11-mutation, which could potentially have influenced the results. The study also limited its retrieval to 30 radiomics characteristics from CT images for texture analysis [25]. These limitations were addressed in a subsequent study by Liu et al. [26]. However, it's important to note that this was a single-center study, and its primary focus was to predict whether the GIST involved K11-mutation or not. It's crucial to appreciate the contributions of each study while also acknowledging their limitations. These limitations do not detract from the value of the research but rather provide avenues for further exploration and improvement in future studies.
The current investigation does not have the deficiencies described in the above two studies, and it shows significant progress. First, we employed a significantly larger patient population. We trained RS using 617 GIST patients, and externally validated the RS in two independent medical centers. Second, we analyzed 1408 radiomics features for radiogenomics, which is considerably more than the above two studies. Third, unlike the aforementioned studies, we predicted a four-level KIT-11 mutation genotype classification using RS, and produced satisfactory results.
We demonstrated that our newly developed RS may be economical for usage in clinics to guide Imatinib treatment planning and outcome monitoring. Of note, in terms of an RS-based classification of GIST with K11-PM/D, clinicians must be cautious about starting standard Imatinib therapy, as only 63.6% of estimated K11-PM/D in the TC and 63.0% in the VC was histologically confirmed to be true KIT-11 K11-PM/D. Thus, for these patients, selective genotype testing may be a better choice to guide targeted treatment rather than unselective standard Imatinib therapy. Moreover, it is suggested that patients initially classified as GISTs without K11-mutation using RS are also sent for genotype testing for the identification of other potential mutations, for example, KIT-9, 13, 17 mutation or PDGFRA-12, 18 mutation [9,10,11,12]. Alternately, the RS-based classification of K11-NM, K11-557/558D, and K11-D patients can be treated with Imatinib therapy and prognosis monitoring can occur according to the predicted KIT-11 mutation type using RS.
This study encountered certain limitations. First, being a retrospective research and with our strict exclusion criteria, the study may have introduced unintentional selection bias. Second, owing to the relatively small patient population in certain KIT or PDGFRA mutation, we were unable to explore the RS feasibility in predicting KIT-9, KIT-12 and PDGFRA mutation. Thus, we only grouped GISTs KIT-11 mutation into four-level classification. However, we are aware that it is imperative to distinguish between some of these mutations, for example, small intestinal GIST with K11-mutation from the KIT exon 9 (K9) mutation, which may be associated with poorer response to targeted therapy and worse prognosis. This must be addressed in future well-designed investigations with large population cohort. Third, we assessed and demonstrated a correlation between GIST with K11-D and contrast-corrected CT imaging. However, the underlying biochemical and clinical mechanisms of this correlation were not explored in this study. In addition, the mitotic count of GISTs was different in the TC and the VC, and we used scanners from three separate locations to determine this. Our aim is that this would lead to widespread use of our models since they are replicable and reliable. Forth, though segmentation was done by an experienced radiologist in 2D to ensure accuracy of segmentation, but this process could be really time-consuming which may again limit the clinical implementation. In the future, automatic segmentation and automatic calculation of probality of different KIT-11 mutation could be tested. Finally, the ROIs were chosen in a single slice (2D), which may not provide an accurate depiction of the complete tumor. Moreover, certain radiomics characteristics, for instance, the texture profile, may be impacted when retrieved from 2D, and not 3D, imaging. Hence, it is critical to perform the 3D analyses of the entire GIST in the future.
Conclusion
It is indicated that contrast-corrected CT imaging may be useful for prediction of KIT-11 mutation genotype given further evaluation, especially in prediction of K11-557/558D genotype. Our automated feature algorithms could facilitate further investigation using the image-based quantitative features. Given that CT imaging is widely employed all over the world, tapping into its rich data for GIST stage diagnoses and treatment can be extremely beneficial for clinicians and patients, and it can potentially enhance Imatinib therapy and GIST monitoring. RS-based classification of K11-NM, K11-557/558D, and K11-D patients may be an indication for choice of Imatinib therapy.
Availability of data and materials
The data generated in this study are available upon request from the corresponding author.
References
Lim YJ, Son HJ, Lee JS, Byun YH, Suh HJ, Rhee PL, Kim JJ, Rhee JC. Clinical course of subepithelial lesions detected on upper gastrointestinal endoscopy. World J Gastroenterol. 2010;16:439–44.
Joensuu H. Risk stratification of patients diagnosed with gastrointestinal stromal tumor. Hum Pathol. 2008;39:1411–9.
Casali PG, Blay JY, Abecassis N, Bajpai J, Bauer S, Biagini R, Bielack S, Bonvalot S, Boukovinas I, Bovee J, et al. Gastrointestinal stromal tumours: ESMO-EURACAN-GENTURIS Clinical Practice Guidelines for diagnosis, treatment and follow-up. Ann Oncol. 2022;33:20–33.
Corless CL. Gastrointestinal stromal tumors: what do we know now? Mod Pathol. 2014;27(Suppl 1):S1-16.
Hirota S, Isozaki K, Moriyama Y, Hashimoto K, Nishida T, Ishiguro S, Kawano K, Hanada M, Kurata A, Takeda M, et al. Gain-of-function mutations of c-kit in human gastrointestinal stromal tumors. Science. 1998;279:577–80.
Heinrich MC, Corless CL, Duensing A, McGreevey L, Chen CJ, Joseph N, Singer S, Griffith DJ, Haley A, Town A, et al. PDGFRA activating mutations in gastrointestinal stromal tumors. Science. 2003;299:708–10.
Blay JY, Kang YK, Nishida T, von Mehren M. Gastrointestinal stromal tumours. Nat Rev Dis Primers. 2021;7:22.
Martin J, Poveda A, Llombart-Bosch A, Ramos R, Lopez-Guerrero JA, Garcia del Muro J, Maurel J, Calabuig S, Gutierrez A, Gonzalez de Sande JL, et al. Deletions affecting codons 557–558 of the c-KIT gene indicate a poor prognosis in patients with completely resected gastrointestinal stromal tumors: a study by the Spanish Group for Sarcoma Research (GEIS). J Clin Oncol. 2005;23:6190–8.
Martin-Broto J, Gutierrez A, Garcia-Del-Muro X, Lopez-Guerrero JA, Martinez-Trufero J, de Sande LM, Lainez N, Maurel J, De Juan A, Losa F, et al. Prognostic time dependence of deletions affecting codons 557 and/or 558 of KIT gene for relapse-free survival (RFS) in localized GIST: a Spanish Group for Sarcoma Research (GEIS) Study. Ann Oncol. 2010;21:1552–7.
Joensuu H, Wardelmann E, Sihto H, Eriksson M, Sundby Hall K, Reichardt A, Hartmann JT, Pink D, Cameron S, Hohenberger P, et al. Effect of KIT and PDGFRA mutations on survival in patients with gastrointestinal stromal tumors treated with adjuvant imatinib: an exploratory analysis of a randomized clinical trial. JAMA Oncol. 2017;3:602–9.
Wozniak A, Rutkowski P, Piskorz A, Ciwoniuk M, Osuch C, Bylina E, Sygut J, Chosia M, Rys J, Urbanczyk K, et al. Prognostic value of KIT/PDGFRA mutations in gastrointestinal stromal tumours (GIST): Polish Clinical GIST Registry experience. Ann Oncol. 2012;23:353–60.
Ramaswamy A, Bal M, Swami R, Shetty O, Bose S, Pai T, Gurav M, Gupta S, Ostwal V. Early outcomes of exon 11 mutants in GIST treated with standard dose Imatinib. Ann Transl Med. 2017;5:134.
Demetri GD, von Mehren M, Blanke CD, Van den Abbeele AD, Eisenberg B, Roberts PJ, Heinrich MC, Tuveson DA, Singer S, Janicek M, et al. Efficacy and safety of imatinib mesylate in advanced gastrointestinal stromal tumors. N Engl J Med. 2002;347:472–80.
Verweij J, Casali PG, Zalcberg J, LeCesne A, Reichardt P, Blay JY, Issels R, van Oosterom A, Hogendoorn PC, Van Glabbeke M, et al. Progression-free survival in gastrointestinal stromal tumours with high-dose imatinib: randomised trial. Lancet. 2004;364:1127–34.
Miettinen M, Sobin LH, Lasota J. Gastrointestinal stromal tumors of the stomach: a clinicopathologic, immunohistochemical, and molecular genetic study of 1765 cases with long-term follow-up. Am J Surg Pathol. 2005;29:52–68.
Bachet JB, Hostein I, Le Cesne A, Brahimi S, Beauchet A, Tabone-Eglinger S, Subra F, Bui B, Duffaud F, Terrier P, et al. Prognosis and predictive value of KIT exon 11 deletion in GISTs. Br J Cancer. 2009;101:7–11.
Joensuu H, Eriksson M, Sundby Hall K, Hartmann JT, Pink D, Schutte J, Ramadori G, Hohenberger P, Duyster J, Al-Batran SE, et al. One vs three years of adjuvant imatinib for operable gastrointestinal stromal tumor: a randomized trial. JAMA. 2012;307:1265–72.
Aerts HJ, Velazquez ER, Leijenaar RT, Parmar C, Grossmann P, Carvalho S, Bussink J, Monshouwer R, Haibe-Kains B, Rietveld D, et al. Decoding tumour phenotype by noninvasive imaging using a quantitative radiomics approach. Nat Commun. 2014;5:4006.
Zhang QW, Gao YJ, Zhang RY, Zhou XX, Chen SL, Zhang Y, Liu Q, Xu JR, Ge ZZ. Personalized CT-based radiomics nomogram preoperative predicting Ki-67 expression in gastrointestinal stromal tumors: a multicenter development and validation cohort. Clin Transl Med. 2020;9:12.
Zhang L, Kang L, Li G, Zhang X, Ren J, Shi Z, Li J, Yu S. Computed tomography-based radiomics model for discriminating the risk stratification of gastrointestinal stromal tumors. Radiol Med. 2020;125:465–73.
Kuo MD, Jamshidi N. Behind the numbers: decoding molecular phenotypes with radiogenomics–guiding principles and technical considerations. Radiology. 2014;270:320–5.
Karlo CA, Di Paolo PL, Chaim J, Hakimi AA, Ostrovnaya I, Russo P, Hricak H, Motzer R, Hsieh JJ, Akin O. Radiogenomics of clear cell renal cell carcinoma: associations between CT imaging features and mutations. Radiology. 2014;270:464–71.
Grimm LJ, Zhang J, Mazurowski MA. Computational approach to radiogenomics of breast cancer: Luminal A and luminal B molecular subtypes are associated with imaging features on routine breast MRI extracted using computer vision algorithms. J Magn Reson Imaging. 2015;42:902–7.
Lu CF, Hsu FT, Hsieh KL, Kao YJ, Cheng SJ, Hsu JB, Tsai PH, Chen RJ, Huang CC, Yen Y, Chen CY. Machine learning-based radiomics for molecular subtyping of gliomas. Clin Cancer Res. 2018;24:4429–36.
Xu F, Ma X, Wang Y, Tian Y, Tang W, Wang M, Wei R, Zhao X. CT texture analysis can be a potential tool to differentiate gastrointestinal stromal tumors without KIT exon 11 mutation. Eur J Radiol. 2018;107:90–7.
Liu X, Yin Y, Wang X, Yang C, Wan S, Yin X, Wu T, Chen H, Xu Z, Li X, et al. Gastrointestinal stromal tumors: associations between contrast-enhanced CT images and KIT exon 11 gene mutation. Ann Transl Med. 2021;9:1496.
Zhang QW, Zhou XX, Zhang RY, Chen SL, Liu Q, Wang J, Zhang Y, Lin J, Xu JR, Gao YJ, Ge ZZ. Comparison of malignancy-prediction efficiency between contrast and non-contract CT-based radiomics features in gastrointestinal stromal tumors: A multicenter study. Clin Transl Med. 2020;10:e291.
van Griethuysen JJM, Fedorov A, Parmar C, Hosny A, Aucoin N, Narayan V, Beets-Tan RGH, Fillion-Robin JC, Pieper S, Aerts H. Computational radiomics system to decode the radiographic phenotype. Cancer Res. 2017;77:e104–7.
Shrout PE, Fleiss JL. Intraclass correlations: uses in assessing rater reliability. Psychol Bull. 1979;86:420.
Friedman J, Hastie T, Tibshirani R. Regularization paths for generalized linear models via coordinate descent. J Stat Softw. 2010;33:1.
Robin X, Turck N, Hainard A, Tiberti N, Lisacek F, Sanchez JC, Muller M. pROC: an open-source package for R and S+ to analyze and compare ROC curves. BMC Bioinform. 2011;12:77.
DeLong ER, DeLong DM, Clarke-Pearson DL. Comparing the areas under two or more correlated receiver operating characteristic curves: a nonparametric approach. Biometrics. 1988;44:837–45.
Van Asch V. Macro-and micro-averaged evaluation measures [[basic draft]]. Belgium: Clips. 2013;49:1–27.
Acknowledgements
The authors would like to thank all the reviewers who participated in the review and MJEditor (www.mjeditor.com) for its linguistic assistance during the preparation of this manuscript.
Funding
This study has received funding by the Health Technology Project of Pudong New District Health Commission (PW2020D-12), Science and Technology Commission of Shanghai Municipality (Grant No. 19411951606), and the Program for Promoting Advanced Appropriate Technology of Shanghai Health Commission (2019SY003).
Author information
Authors and Affiliations
Contributions
JL, HC, YZ, H-MC, X-BL, Q-WZ planning and/or conducting the study, Q-WZ, R-YZ, Z-BY, Y-XZ, X-YW, J-ZJ, Q-XQ, J-JC, and Z-HX collecting and/or interpreting data, Q-WZ, R-YZ, Z-BY drafting the manuscript, revised the manuscript. All authors has approved the final draft submitted.
Corresponding authors
Ethics declarations
Ethics approval and consent to participate
Institutional Review Board approval was obtained (KY2023-002-B). Written informed consent was waived by the Institutional Review Board.
Consent for publication
All authors has approved the final draft submitted.
Competing interests
The authors declare that they have no competing interests.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Additional file 1
: CT assessment and Radiomic signature development.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated in a credit line to the data.
About this article
Cite this article
Zhang, QW., Zhang, RY., Yan, ZB. et al. Personalized radiomics signature to screen for KIT-11 mutation genotypes among patients with gastrointestinal stromal tumors: a retrospective multicenter study. J Transl Med 21, 726 (2023). https://doi.org/10.1186/s12967-023-04520-w
Received:
Accepted:
Published:
DOI: https://doi.org/10.1186/s12967-023-04520-w