This article has an erratum available at: http://dx.doi.org/10.21037/atm-2024-4 the article has been update on 2024-03-13 at here.
Preoperative prediction of gastrointestinal stromal tumors with high Ki-67 proliferation index based on CT features
Introduction
Gastrointestinal stromal tumors (GISTs) are the most common mesenchymal tumors, originating from interstitial Cajal cells in the abdominal cavity or retroperitoneum (1). Immunohistochemical tests have demonstrated that GISTs are usually positive for CD117 and DOG1 proteins (2). The formation of GISTs is mainly due to mutations in the genes encoding the tyrosine kinase receptor KIT and platelet-derived growth factor receptor alpha (PDGFRA), resulting in the corresponding tyrosine kinase receptors becoming proto-oncogene drivers (3,4). Some GISTs may develop distant metastases, with the most frequent sites of metastases being the peritoneum and the liver (5). It would be useful to assess the biological behaviors of GISTs before and after surgery, in order to make decisions regarding adjuvant therapy and treatment regimens for individual patients (5).
The cell proliferation index, also known as the Ki-67 proliferation index (Ki-67 PI), is the percentage of Ki-67-positive staining cells in each cell population. Ki-67 PI is a crucial immunohistochemical marker for evaluating tumor heterogeneity and cell growth (6). The Ki-67 nucleoprotein is highly expressed in proliferating cells during the G1, S, and G2 phases based on mitotic count, and is downregulated in the G0 phase, implying involvement in cell proliferation, invasive aggressiveness, and malignant potential (6).
According to previous studies, a high level of Ki-67 PI is an independent predictive indicator for high-malignancy GISTs and poor survival prognosis (7-12). A high Ki-67 PI GIST indicated a reduced survival time and a poorer therapeutic response with molecular targeted treatment (13-17). Moreover, Ki-67 PI is significantly correlated with KIT or PDGFRA mutations of GISTs, which may assist individual multidisciplinary planning of gene-targeted therapy (18,19). Therefore, preoperative non-invasive prediction of Ki-67 PI in GISTs would be very valuable. A previous study demonstrated that the Ki-67 PI is correlated with risk stratification and prognosis prediction of GISTs, and that computed tomography (CT) features are valuable in preoperative evaluation (20). However, the diagnostic performance and predictability of CT features is unknown and uncertain when determining high Ki-67 PI patients.
Therefore, our study was designed to explore the potential predictive ability of CT features. The purpose of this study is to determine whether enhanced CT features can be used for the preoperative prediction of GISTs with high Ki-67 PI. Our study initially assesses the diagnostic performance and predictive ability of detailed CT quantitative and morphological imaging features in determining high Ki-67 PI GISTs.
We present the following article in accordance with the STARD reporting checklist (available at https://dx.doi.org/10.21037/atm-21-4669).
Methods
Patients
This retrospective study was approved by the institutional review board at West China Hospital, Sichuan University (No. 2020-249). All procedures performed in this study involving human participants were in accordance with the Declaration of Helsinki (as revised in 2013). Because of the retrospective nature of the research, the requirement for informed consent was waived. Our institutional pathological databases were searched using the following terms: “GISTs or gastrointestinal stromal tumors”, from September 2010 to June 2019. A total of 794 patients were initially included. The inclusion criteria were as follows: (I) surgical specimens of GISTs were pathologically analyzed; (II) patients without any history of preoperative targeted therapy; (III) patients with only one single primary tumor (note: this study only evaluated the primary lesion for tumors with metastases); and (IV) cases where preoperative contrast-enhanced CT images were available, and the interval between the CT acquisition time and surgical time of GISTs was within 2 weeks. The exclusion criteria were as follows: (I) patients who were unavailable or had incomplete enhanced CT images in our hospital; and (II) GISTs without Ki-67 PI identifications in immunochemistry. Finally, 198 GISTs were included in this study (the study flowchart is displayed in Figure 1).
CT scanning parameters
Bowel cleansing was a precondition for CT examination, which involved a low-residue diet or ample fluids the day before the examination and fasting 10 hours prior to the examination. The patients were requested to drink 600–1,000 mL of water within 40–60 min before the examination.
All patients were examined using Brilliance 64 (Philips Medical System, Eindhoven, the Netherlands), 128-slice scanner (SOMATOM Definition AS+, Siemens Healthcare), or dual-source CT system (SOMATOM Definition Flash, Siemens Healthcare). The scanning range covered the entire abdomen. The scanning parameters were as follows: tube voltage, 120 kV; tube current, 145–200 mAs; slice thickness, 2–5 mm; slice interval, 2 mm; field of view, 35–50 cm; matrix, 512×512; rotation time, 0.5 s; and pitch 1.0. With the trigger threshold of the aorta reaching 170 HU, enhanced images were obtained with the arterial phase at the trigger, and the portal vein phase at 30 s after the trigger. Iodinated contrast agent (1.2–1.5 mL/kg, Iopamiro, Bracco, Italy; Ultravist, Bayer, Germany) was injected intravenously at a flow rate of 2.5–3.0 mL/s using a high-pressure syringe (Medrad Stellant CT Injector System, Medrad Inc.).
CT image analysis
All imaging feature assessments were independently interpreted by two radiologists (Lian Zhao and Xi-Jiao Liu, with 4 and 15 years of diagnostic experience in abdominal imaging, respectively) on Syngo Imaging Workplaces (VersionVB35A, Siemens AG, Erlangen, Germany). Precise quantitative imaging data were also recorded and calculated. The two radiologists were blinded to the clinical data and pathological results. Inconsistencies between the observers in the initial evaluation were settled by additional discussion to make a final determination.
The following qualitative CT features of the lesions were recorded: (I) locations, which were recorded as stomach, duodenum, intestine, rectum, or extra-gastrointestinal tract (including omentum, mesentery, and peritoneum); (II) borders, which were classified as ill-defined or well-defined; (III) contours, which were classified as round, ovoid [egg shaped with long diameter (LD)/short diameter (SD) ratio ≤1.5], dumbbell (shaped like two larger parts joined by a thinner neck), bell (shaped like an inverted cup and with a wider base), flat (growing in a certain axis and with LD/SD ratio >1.5), or irregular (no specific shape); (IV) growth types, which were classified into endoluminal, exophytic, or mixed (including intraluminal and extraluminal sections of the gastrointestinal tract contour) (21); (V) enhancement patterns, which were evaluated as homogeneous or heterogeneous; (VI) enhancement degrees, which were classified as mild, intermediate, or marked on the basis of tumor CT attenuation difference between the arterial and unenhanced phases [differences ≤20 Hounsfield unit (HU) were defined as mild; 20–40 HU were defined as intermediate; and ≥40 HU were defined as marked] (22); (VII) tumor enhancement levels, which were graded as slight, moderate, or serious, compared to the paraspinal muscle and the liver at the same level in the arterial phase (if the CT value of the tumor was less than the muscle, it was defined as slight; if it was between that of the muscle and the liver, it was defined as moderate; and if it was greater than that of the liver, it was defined as severe); (VIII) calcification; (IX) air density in mass (intraluminal air density connected to the gastrointestinal lumen); (X) ulceration (a focal discontinuity or break on the endoluminal surface of the tumor); (XI) enlarged vasculature feeding or draining the mass (EVFDM) (detectably enlarged or engorged veins or arteries near the tumor) (23); (XII) necrosis (an area with CT attenuation ≤20 HU in each phase and enhancement difference of this area ≤10 HU between the unenhanced and enhanced phases (24); (XIII) cystic degeneration (a thin-walled region within the tumor with CT attenuation ranging from 0 to 10 HU and without enhancement in the venous phase); (XIV) hemorrhage; (XV) hyperenhancement of the overlying mucosa (HYOM, a hyper-enhanced mucosal line delineating the tumor) (25); (XVI) adjacent organ invasion (an unclear boundary of the tumor with blurred outline relative to adjacent structures); (XVII) lymphadenopathy, which was defined as an enlarged lymph node SD ≥1 cm; (XVIII) metastasis; (IXX) peritonitis; (XX) ascites; and (XXI) rupture, which was defined as a focal tissue defect on the extraluminal region of the tumor surface with secondary peritonitis, peritoneal effusion, peritoneal abscess, or hemoperitoneum (26). Identification disputes of rupture were finally decided by pathological determination.
The quantitative parameters of these tumors were also measured. The LD and SD of each lesion were recorded, and the LD/SD ratio was then calculated. For CT attenuation-related measurements, a circular region of interest (ROI) in the tumor (approximate size 15–18 mm2) was applied in HU. For the enhancement degree, CT attenuation of each tumor and the aorta at the same layer in each phase was recorded, while the enhancement level of the paraspinal muscle and liver at the same level in each phase was measured. To avoid tumor heterogeneity, tumor attenuation in three phases was measured by three circular ROIs placed on different parts of the tumor, avoiding adjacent tumor vessels, cystic degeneration, necrosis, air density, calcification, and contiguous gastrointestinal tract wall. The average of the three ROIs was then recorded as tumor attenuation in the plain phase (Tp), tumor attenuation in the arterial phase (Ta), and tumor attenuation in the venous phase (Tv). To normalize the individual circulation level of each patient with different injection rates and doses, the CT values of Tp, Ta, and Tv were divided by the aorta CT values at the same layer and phase (Ap, Aa, and Av), which were recorded as standard tumor attenuation in the plain phase (Sp, Tp/Ap), standard tumor attenuation in the arterial phase (Sa, Ta/Aa), and standard tumor attenuation in the venous phase (Sv, Tv/Av), respectively. For tumors with EVFDM, the diameter of the tumor feeding artery or drainage vein was carefully observed in the enhanced phase. For tumors with necrosis, the necrosis degree was the estimated ratio of the necrotic component to parenchymal part of the tumor using percentage count. Similarly, the wall thickness of necrosis was measured by the thickest distance between the solid tumor wall and necrotic component of the tumor in the enhanced phase.
Histological evaluation and immunohistochemical assessment
Surgically resected sections for histology and immunohistochemistry were matched to the significant parenchyma of GISTs as much as possible, where the calcification, and air density of the tumor was carefully avoided. Next, the predominant cell type (including spindle cells, epithelioid cells, or mixed spindle cells and epithelioid component) and mitotic count were recorded. All mitotic cells counted in 50 high-power fields (HPF) were recorded as <5/50, 5–10/50, or ≥10/50 HPF. Ki-67 PI expression was assessed by immunohistochemistry within 7 days after surgery. The pathologist was blinded to clinical data and imaging assessments. Monoclonal rabbit antihuman Ki-67 antibody (Rabbit monoclonal, SP6, Abcam Shanghai) was used to detect the Ki-67 PI. GISTs were categorized into two groups: a high Ki-67 PI group (Ki-67 PI ≥10%) and a low Ki-67 PI group (Ki-67 PI <10%) based on previous research (7-9,27). Risk stratification of modified National Institute of Health (mNIH) classification was eventually determined using histological evaluation (mitotic count) and clinical records (tumor site, tumor size, and presence of rupture).
Statistical analysis
Categorical data were calculated using Pearson’s chi-square test or Fisher’s exact test, and quantitative data were calculated using the Student’s t-test or Mann-Whitney-Wilcoxon test. Continuous data were analyzed using the normality test and presented as means ± standard deviations, while categorical data were presented as numbers with percentages. Spearman’s correlation analysis with correlation coefficient rho (r) was conducted to assess the strength of connection between significant qualitative or quantitative parameters and Ki-67 PI groups. Diagnostic performance was evaluated by the receiver operating characteristic (ROC) analysis, and the area under the ROC curve (AUC) was calculated. The comparison of different AUCs was performed using DeLong’s test (28). The Youden index decided the corresponding sensitivity and specificity at the optimal cut-off value.
The interobserver agreement for qualitative features was evaluated using the kappa test. The intraclass correlation coefficient (ICC) was used to assess the inter-observer and intra-observer agreement of the quantitative parameters (29). In multivariate logistic regression analysis, variables with a P value less than 0.05 determined by univariate analysis were selected as an independent indicator, and the odds ratio (OR) as the relative risk estimates with 95% confidence interval (CI) of each risk factor was obtained.
Statistical tests were performed using the Statistical Package for Social Sciences software version 25.0 (IBM, Chicago, IL, USA) and MedCalc statistical software (version 15.8; https://www.medcalc.org). A P value <0.05 (two-tailed) was considered as statistically significant for each statistical test.
Results
Patient demographics and pathological results
In total, 198 GISTs patients (89 men and 109 women; average age: 56.83±12.46 years) were included, with a median CT acquisition and surgical time interval of 9 days (range, 1–14 days). The detailed patient characteristics are presented in Table 1. Clinical symptoms included digestive tract hemorrhage (n=76, 38.4%), abdominal discomfort or pain (n=83, 41.9%), and asymptomatic patients (n=39, 19.7%). All gastric GISTs patients (n=140) underwent different surgical resections, including partial gastrectomy (n=96, 68.6%), wedge resection (n=28, 20.0%), and total gastrectomy (n=16, 11.4%).
Table 1
Characteristics | Total GISTs (n=198) | High Ki-67 PI GISTs group (n=58) | Low Ki-67 PI GISTs group (n=140) | P value* |
---|---|---|---|---|
Age (mean ± SD) | 56.83±12.46 | 58.57±13.35 | 56.11±12.04 | 0.208 |
Gender (male/female) | 89/109 | 32/26 | 57/83 | 0.063 |
Male (mean ± SD) | 57.61±12.31 | 58.69±13.95 | 57.00±11.37 | 0.538 |
Female (mean ± SD) | 56.20±12.60 | 58.42±12.85 | 55.51±12.51 | 0.305 |
Clinical symptom (n/%) | 0.969 | |||
Digestive tract hemorrhage | 76/38.4 | 23/39.7 | 53/37.9 | |
Abdominal discomfort or pain | 83/41.9 | 24/41.3 | 59/42.1 | |
Asymptomatic | 39/19.7 | 11/19.0 | 28/20.0 | |
Type of gastric surgery (n=140, n/%) | 0.746 | |||
Partial gastrectomy | 96/68.6 | 29/67.4 | 67/69.1 | |
Wedge resection | 28/20.0 | 10/23.3 | 18/18.5 | |
Total gastrectomy | 16/11.4 | 4/9.3 | 12/12.4 |
*, between the high and low Ki-67 PI GISTs groups, categorical data were calculated using Pearson’s chi-square or Fisher’s exact tests, and quantitative data were calculated with the Student t-test or Mann-Whitney-Wilcoxon test. Ki-67 PI, Ki-67 proliferation index; GISTs, gastrointestinal stromal tumors.
A majority of the GISTs were spindle-cell tumors (156, 78.8%), while epithelioid type and mixed type GISTs were seen in 17 (8.6%) and 15 (7.6%) patients, respectively. Mitotic counts ranged from 0 to 110 per 50 HPF (mean, 6.2 mitoses per 50 HPF). There were ≤5 per 50 HPF in 124 (62.6%) patients, 5–10 per 50HPF in 41 (20.7%) patients, ≥10 per 50 HPF in 33 (16.7%) patients. In terms of mNIH risk stratification, very low-risk, low-risk, intermediate-risk, and high-risk classifications were counted as 14 (7.1%), 70 (35.4%), 50 (25.3%), 64 (32.3%), respectively. Based on immunohistochemical assessment, 58 (29.3%) tumors were identified as high Ki-67 PI (Figure 2), while 140 (70.7%) were classified as the low Ki-67 PI group (Table 2).
Table 2
Variables | High Ki-67 PI GISTs group (n=58) | Low Ki-67 PI GISTs group (n=140) | Total GISTs (n=198) | P value* | r value# |
---|---|---|---|---|---|
Risk stratification, n (%) | <0.001 | 0.425 | |||
Very low risk | 0 (0) | 14 (10.0) | 14 (7.1) | ||
Low risk | 10 (17.2) | 60 (42.9) | 70 (35.4) | ||
Intermediate risk | 11 (19.0) | 39 (27.9) | 50 (25.3) | ||
High risk | 37 (63.8) | 27 (19.3) | 64 (32.3) | ||
Mitotic count, n (%) | <0.001 | 0.504 | |||
≤5 | 19 (32.8) | 105 (75.0) | 124 (62.6) | ||
5–10 | 12 (20.7) | 29 (20.7) | 41 (20.7) | ||
≥10 | 27 (46.6) | 6 (4.3) | 33 (16.7) |
*, between the high and low Ki-67 PI GISTs groups, variables were calculated using Pearson’s chi-square or Fisher’s exact tests. #, between the high and low Ki-67 PI GISTs groups, meaningful variables were analyzed with correlation analyses. Data are numbers of positive patients (with percentage of positive/total numbers in parentheses). Percentages may not add up to 100% because of rounding. Ki-67 PI, Ki-67 proliferation index; GISTs, gastrointestinal stromal tumors; mNIH, modified National Institute of Health.
There were no significant differences in gender, age, clinical symptom, and type of gastric surgery between the two groups of GIST patients (P>0.05).
The correlation between Ki-67 PI GIST groups and clinical indexes
The correlation between Ki-67 PI GIST groups and mNIH risk stratification or mitotic count is shown in Table 2. The incidence of intermediate- and high-risk stratification in the high Ki-67 PI group was markedly higher than that in the low Ki-67 PI group, with a percentage ratio of 1.93 (82.79% vs. 47.14%). Risk stratification and mitotic count were significantly different between the two groups (P<0.001). The Ki-67 PI GIST groups were positively correlated with risk stratification and mitotic count, and the rank correlation coefficients (r) were 0.425 and 0.524, respectively.
Imaging findings
Of the qualitative CT features, an ill-defined border, heterogeneous enhancement pattern, air density in mass, ulceration, EVFDM, necrosis (Figures 3,4), cystic degeneration (Figure 4), hemorrhage, HYOM (Figure 4), adjacent organ invasion, lymphadenopathy, metastasis, peritonitis, ascites, and rupture were found to be significantly different between the low and high Ki-67 PI groups (P<0.05, Table 3). As for the quantitative CT features, LD, SD, LD/SD ratio, Tp, necrosis degree, wall thickness of necrosis, and diameter of EVFDM were found to be significantly different between the two groups (P<0.05, Table 4). The Ta and Tv were not associated with low or high Ki-67 PI classifications (P>0.05). The standard tumor attenuation in the unenhanced and enhanced phases (Sp, Sa, Sv) showed no statistical differences between the two groups (P>0.05). These meaningful qualitative and quantitative features were correlated with the Ki-67 PI groups positively, except for Tp (r=−0.181). As shown in Table 3 and Table 4, the rank correlation coefficient (r) values ranged from 0.164 to 0.625.
Table 3
Variables | Total GISTs (n=198), n (%) | High Ki-67 PI GISTs group (n=58), n (%) | Low Ki-67 PI GISTs group (n=140), n (%) | P value*1 | r value*2 | Kappa value*3 |
---|---|---|---|---|---|---|
Location | 0.261 | – | 0.946 | |||
Stomach | 140 (70.7) | 43 (74.1) | 97 (69.3) | |||
Duodenum | 21 (10.6) | 3 (5.2) | 18 (12.9) | |||
Intestine | 25 (12.6) | 7 (12.1) | 18 (12.9) | |||
Rectum | 5 (2.5) | 1 (1.7) | 4 (2.9) | |||
Extra-gastrointestinal tract*4 | 7 (3.5) | 4 (6.9) | 3 (2.1) | |||
Borders | 0.021 | 0.164 | 0.906 | |||
Ill-defined | 62 (31.3) | 25 (43.1) | 37 (26.4) | |||
Well-defined | 136 (68.7) | 33 (56.9) | 103 (73.6) | |||
Contours | 0.281 | – | 0.908 | |||
Round | 24 (12.1) | 5 (8.6) | 19 (13.6) | |||
Ovoid | 101 (51.0) | 27 (46.6) | 74 (52.9) | |||
Dumbbell | 50 (25.3) | 19 (32.8) | 31 (22.1) | |||
Bell | 7 (3.5) | 1 (1.7) | 6 (4.3) | |||
Flat | 1 (0.5) | 1 (1.7) | 0 | |||
Irregular | 15 (7.6) | 5 (8.6) | 10 (7.1) | |||
Growth types | 0.059 | – | 0.904 | |||
Endoluminal | 53 (26.8) | 11 (19.0) | 42 (30.0) | |||
Exophytic | 48 (24.2) | 11 (19.0) | 37 (26.4) | |||
Mixed | 97 (49.0) | 36 (62.1) | 61 (43.6) | |||
Enhancement patterns | 0.001 | 0.227 | 0.868 | |||
Heterogeneous | 147 (74.2) | 6 (10.3) | 45 (32.1) | |||
Homogeneous | 51 (25.8) | 52 (89.7) | 95 (67.9) | |||
Enhancement degrees | 0.857 | – | 0.970 | |||
Mild | 82 (41.4) | 23 (39.7) | 59 (42.1) | |||
Intermediate | 56 (28.3) | 18 (32.1) | 38 (27.1) | |||
Marked | 60 (30.3) | 17 (28.3) | 43 (30.7) | |||
Enhancement levels | 0.963 | – | 0.954 | |||
Slight | 66 (33.3) | 20 (34.5) | 46 (32.9) | |||
Moderate | 68 (34.3) | 20 (34.5) | 48 (34.3) | |||
Severe | 64 (32.3) | 18 (31.0) | 46 (32.9) | |||
Calcification | 24 (12.1) | 11 (19.0) | 13 (9.3) | 0.058 | – | 0.953 |
Air density in mass | 36 (18.2) | 23 (39.7) | 13 (9.3) | <0.001 | 0.358 | 0.966 |
Ulceration | 48 (24.2) | 26 (44.8) | 22 (15.7) | <0.001 | 0.309 | 0.918 |
EVFDM | 134 (67.7) | 52 (89.7) | 82 (58.6) | <0.001 | 0.302 | 0.931 |
Necrosis | 52 (26.3) | 40 (69.0) | 12 (8.6) | <0.001 | 0.625 | 0.922 |
Cystic degeneration | 13 (6.6) | 9 (15.5) | 4 (2.9) | 0.001 | 0.233 | 0.923 |
Hemorrhage | 16 (8.1) | 10 (17.2) | 6 (4.3) | 0.002 | 0.216 | 0.901 |
HYOM | 101 (51.0) | 52 (89.7) | 49 (35.0) | <0.001 | 0.498 | 0.96 |
Adjacent organ invasion | 17 (8.6) | 17 (29.3) | 0 | <0.001 | 0.476 | 0.936 |
Lymphadenopathy | 13 (6.6) | 7 (12.1) | 6 (4.3) | 0.044 | 0.430 | 0.881 |
Metastasis | 4 (2.0) | 4 (6.9) | 0 | 0.002 | 0.223 | 0.659 |
Peritonitis | 11 (5.6) | 9 (15.5) | 2 (1.4) | <0.001 | 0.280 | 0.878 |
Ascites | 17 (8.6) | 14 (24.1) | 3 (2.1) | <0.001 | 0.357 | 0.911 |
Rupture | 19 (9.6) | 17 (29.3) | 2 (1.4) | <0.001 | 0.431 | 0.884 |
*1, between the high and low Ki-67 PI GISTs groups, variables were calculated using Pearson’s chi-square or Fisher’s exact tests; *2, between the high and low Ki-67 PI GISTs groups, meaningful variables were analyzed using correlation analyses; *3, the inter-observer agreement for qualitative features was evaluated using the kappa test; *4, extra-gastrointestinal tract included omentum, mesentery, and peritoneum. Data are numbers of positive patients (with percentage of positive/total numbers in parentheses). Percentages may not add up to 100% because of rounding. Ki-67 PI, Ki-67 proliferation index; GISTs, gastrointestinal stromal tumors; EVFDM, enlarged vasculature feeding or draining the mass; HYOM, hyperenhancement of the overlying mucosa.
Table 4
Variables | Total GISTs (n=198), (mean ± SD) | High Ki-67 PI GISTs group (n=58), (mean ± SD) | Low Ki-67 PI GISTs group (n=140), (mean ± SD) | P value*1 | r value*2 | ICC value*3 |
---|---|---|---|---|---|---|
LD (mm) | 53.56±34.79 | 68.31±37.87 | 47.45±31.61 | <0.001 | 0.274 | 0.991 |
SD (mm) | 41.99±25.24 | 51.69±25.95 | 37.98±23.90 | <0.001 | 0.248 | 0.984 |
LD/SD | 1.28±0.31 | 1.35±0.47 | 1.24±0.20 | 0.028 | 0.157 | 0.922 |
Tp (HU) | 32.72±8.66 | 30.29±8.45 | 33.72±8.58 | 0.011 | −0.181 | 0.842 |
Ta (HU) | 71.32±36.42 | 67.67±36.40 | 72.83±36.45 | 0.366 | 0.946 | |
Tv (HU) | 81.68±30.85 | 77.03±26.97 | 83.60±32.32 | 0.174 | 0.969 | |
Sp (HU) | 0.87±0.23 | 0.85±0.25 | 0.88±0.22 | 0.523 | 0.913 | |
Sa (HU) | 0.27±0.12 | 0.25±0.12 | 0.28±0.13 | 0.16 | 0.884 | |
Sv (HU) | 0.25±0.81 | 0.23±0.08 | 0.25±0.08 | 0.079 | 0.911 | |
Necrosis degree (%) | 9.3±18.9 | 23±23.07 | 3.5±13.1 | <0.001 | 0.476 | 0.947 |
Wall thickness of necrosis (mm) | 5.87±4.21 | 7.77±4.02 | 3.40±3.13 | 0.01 | 0.526 | 0.947 |
Diameter of EVFDM (mm) | 2.20±1.91 | 2.93±1.71 | 1.89±1.92 | <0.001 | 0.248 | 0.855 |
*1, between the high and Ki-67 PI GISTs groups, quantitative variables were calculated using the Student’s t-test or Mann-Whitney-Wilcoxon test; *2, between the high and low Ki-67 PI GISTs groups, meaningful quantitative variables were analyzed using correlation analyses; *3, the ICC was used to assess the inter-observer and intra-observer agreement of quantitative parameters. Ki-67 PI, Ki-67 proliferation index; GISTs, gastrointestinal stromal tumors; LD, long diameter; SD, short diameter; Tp, tumor attenuation in plain phase; Ta, tumor attenuation in arterial phase; Tv, tumor attenuation in venous phase; Sp, standard tumor attenuation in plain phase; Sa, standard tumor attenuation in arterial phase; Sv, standard tumor attenuation in venous phase; EVFDM, enlarged vasculature feeding or draining the mass; ICC, intraclass correlation coefficient.
ROC curve analyses results showed that the wall thickness of necrosis, LD, HYOM, necrosis, and necrosis degree had good AUC values (AUC >0.7, P<0.05, Table 5). Of these, wall thickness of necrosis demonstrated the highest predictive value, with an AUC of 0.838 (95% CI: 0.627–0.957), sensitivity of 76.9% (95% CI: 46.2–95.0%), and specificity of 80.0% (95% CI: 44.4–97.5%), followed by necrosis, necrosis degree, HYOM, and LD with AUCs of 0.802 (95% CI: 0.740–0.855), 0.795 (95% CI: 0.732–0.849), 0.773 (95% CI: 0.709–0.830), and 0.705 (95% CI: 0.637–0.768), respectively (Figure 5). DeLong’s test demonstrated that the AUCs did not differ significantly between different features. Multinomial logistic regression analyses showed that the presence of necrosis (OR =2.987, 95% CI: 1.328–6.718), cystic degeneration (OR =14.057, 95% CI: 1.016–194.527), HYOM (OR =30.037, 95% CI: 5.707–158.106), and Tp ≤32 HU (OR =4.650, 95% CI: 1.378–15.695) were determined to be independent predictors for the high Ki-67 PI GISTs group (P<0.05, Table 6).
Table 5
Variables | AUC (95% CI) | Sensitivity (95% CI) | Specificity (95% CI) | P value | Cut-off value |
---|---|---|---|---|---|
Borders | 0.583 (0.511–0.653) | 43.1% (30.2–56.8%) | 73.6% (65.5–80.7%) | 0.027 | – |
Enhancement patterns | 0.609 (0.537–0.677) | 89.7% (78.8–96.1%) | 32.1% (24.5–40.6%) | 0.0001 | – |
Air density in mass | 0.652 (0.581–0.718) | 39.7% (27.0–53.4%) | 90.7% (84.6–90.7%) | <0.0001 | – |
Ulceration | 0.646 (0.575–0.712) | 44.8% (31.7–58.5%) | 84.3% (77.2–89.9%) | 0.0001 | – |
EVFDM | 0.655 (0.585–0.721) | 89.7% (78.8–96.1%) | 41.4% (33.2–50.1%) | <0.0001 | – |
Necrosis | 0.802 (0.740–0.855) | 69.0% (55.5–80.5%) | 91.4% (85.5–95.5%) | <0.0001 | – |
Cystic degeneration | 0.563 (0.491–0.633) | 15.5% (7.3–27.4%) | 97.1% (92.8–99.2%) | 0.011 | – |
Hemorrhage | 0.565 (0.493–0.635) | 17.2% (8.6–29.4%) | 95.7% (90.9–98.4%) | 0.014 | – |
HYOM | 0.773 (0.709–0.830) | 89.7% (78.8–96.1%) | 65.0% (56.5–72.9%) | <0.0001 | – |
Adjacent organ invasion | 0.647 (0.576–0.713) | 29.3% (18.1–42.7%) | 100.0% (97.4–100.0%) | <0.0001 | – |
Lymphadenopathy | 0.539 (0.467–0.610) | 12.1% (5.0–23.3%) | 95.7% (90.9–98.4%) | 0.094 | – |
Metastasis | 0.534 (0.462–0.606) | 6.9% (1.9–16.7%) | 100.0% (97.4–100.0%) | 0.039 | – |
Peritonitis | 0.570 (0.498–0.640) | 15.5% (7.3–27.4%) | 98.6% (94.9–99.8%) | 0.004 | – |
Ascites | 0.610 (0.538–0.678) | 24.1% (13.9–37.2%) | 97.7% (93.9–99.6%) | 0.0001 | – |
Rupture | 0.639 (0.568–0.706) | 29.3% (18.1–42.7%) | 98.6% (94.9–99.8%) | <0.0001 | – |
LD (mm) | 0.705 (0.637–0.768) | 86.2% (74.6–93.9%) | 50.0% (41.4–58.6%) | <0.0001 | >38 |
SD (mm) | 0.684 (0.614–0.748) | 75.9% (62.8–82.1%) | 57.9% (49.2–66.1%) | <0.0001 | >36 |
LD/SD | 0.576 (0.504–0.645) | 43.1% (30.2–56.8%) | 73.6% (65.5–80.7%) | 0.105 | >1.33 |
Tp (HU) | 0.639 (0.568–0.706) | 65.5% (51.9–77.5%) | 60.7% (52.1–68.9%) | 0.001 | ≤32 |
Necrosis degree (%) | 0.795 (0.732–0.849) | 69.0% (55.5–80.5%) | 92.1% (86.3–96.0%) | <0.0001 | >0 |
Wall thickness of necrosis (mm) | 0.838 (0.627–0.975) | 76.9% (46.2–95.0%) | 80.0% (44.4–97.5%) | 0.0002 | >4 |
Diameter of EVFDM (mm) | 0.656 (0.586–0.722) | 89.7% (78.8–96.1%) | 41.4% (33.2–50.1%) | 0.0001 | >0 |
AUC, area under the curve; CI, confidential interval; EVFDM, enlarged vasculature feeding or draining the mass; HYOM, hyperenhancement of the overlying mucosa; LD, long diameter; SD, short diameter; Tp, tumor attenuation in plain phase.
Table 6
Variables | β value | P value | OR value (95% CI) |
---|---|---|---|
Ill-defined border | 0.857 | 0.027 | 2.355 (0.519–10.681) |
Heterogeneous enhancement pattern | 0.210 | 0.787 | 1.233 (0.269–5.659) |
Air density in mass | −0.749 | 0.585 | 0.473 (0.032–6.949) |
Ulceration | 0.380 | 0.750 | 1.462 (0.142–15.099) |
EVFDM | 0.198 | 0.784 | 1.219 (0.296–5.008) |
Necrosis | −15.024 | <0.001 | 2.987 (1.328–6.718) |
Cystic degeneration | 2.643 | 0.049 | 14.057 (1.016–194.527) |
Hemorrhage | −1.324 | 0.551 | 0.266 (0.003–20.603) |
HYOM | 3.402 | <0.001 | 30.037 (5.707–158.106) |
Lymphadenopathy | 1.087 | 0.484 | 2.967 (0.141–62.354) |
Ascites | 2.096 | 0.173 | 8.134 (0.400–165.576) |
LD ≥38 mm | 0.819 | 0.487 | 2.269 (0.2245–22.987) |
SD ≥36 mm | −0.719 | 0.526 | 0.487 (0.053–4.509) |
LD/SD >1.33 | 0.303 | 0.653 | 1.354 (0.360–5.091) |
Tp ≤32 HU | 1.537 | 0.013 | 4.650 (1.378–15.695) |
Wall thickness of necrosis >4 mm | 0.671 | 0.704 | 1.956 (0.061–62.588) |
Ki-67 PI, Ki-67 proliferation index; GISTs, gastrointestinal stromal tumors; EVFDM, enlarged vasculature feeding or draining the mass; HYOM, hyperenhancement of the overlying mucosa; LD, long diameter; SD, short diameter; Tp tumor attenuation in plain phase.
Both intra- and inter-observer ICCs for CT features were good, with kappa values of qualitative parameters ranging from 0.659 to 0.970 and ICC values of quantitative parameters ranging from 0.842 to 0.991 (P<0.05, Table 3 and Table 4).
Discussion
The clinical signs of our study were consistent with the results of previous studies: the low and high Ki-67 PI GIST groups were not statistically different in terms of gender, age, clinical symptoms, and type of gastric surgery. The most common age range for GIST development was 55–60 years, with a tendency to occur in women (1,30,31). The most common clinical symptoms included abdominal discomfort or pain, digestive tract hemorrhage, and asymptomatic (in that order) (1,32). Also, for gastric stromal tumors, patients underwent partial gastrectomy, followed by wedge resection, and total gastrectomy (in that order).
Our univariate analyses results showed that high Ki-67 PI GISTs tended to have an ill-defined border, heterogeneous enhancement pattern, and more frequently presented with air density in mass, ulceration, EVFDM, necrosis, cystic degeneration, hemorrhage, HYOM, adjacent organ invasion, lymphadenopathy, metastasis, peritonitis, ascites, and rupture, which was similar to previous findings (33-36). Moreover, LD, SD, LD/SD ratio, Tp, necrosis degree, wall thickness of necrosis, and diameter of EVFDM were found to be significantly different between the low and high Ki-67 PI groups. Furthermore, our study demonstrated that the Ki-67 PI groups were correlated to mitotic count and mNIH risk classification, and these CT features were correlated to Ki-67 PI groups. In the present study, the differences of Sp, Sa, Sv, Ta, and Tv between the two groups were not significant. The same is true for the relationship between CT attenuation in the three phases and mNIH risk stratification of GISTs (24,37). The relationship between CT attenuation and Ki-67 PI levels of GISTs remains unclear and controversial.
ROC curve analyses demonstrated that wall thickness of necrosis, necrosis, necrosis degree, HYOM, and LD achieved good AUC values (AUC >0.7). However, through multinominal logistic regression analyses, only necrosis, cystic degeneration, HYOM, and Tp ≤32 HU were determined to be independent predictors for the high Ki-67 PI GISTs group. Larger tumor LD could be a high-risk factor for GISTs based on the mNIH stratification (38). This is consistent with our study, where larger LD tended to occur in high Ki-67 PI GISTs. In terms of HYOM, which might be caused by mucosal disruption, invasion, or ulceration, patients presenting with HYOM tend to have high-risk stratification of gastric GISTs (25). Even if necrosis and its related parameters were not significant indicators for ruptured GISTs according to previous studies (26), they were demonstrated to be significant predictors in high-risk stratification GISTs (24,33,39). Previous studies have also shown that necrosis is one of the pathological predictors of malignant behavior of GISTs and is more important for evaluating the prognosis of GISTs (17,36,40-42). It is considered that necrosis is directly related to the severe proliferation of tumor portion; that is, necrosis will occur in the most invasive and aggressive area (42).
Ki-67 PI was previously used to predict the malignancy of GISTs (8,13,15,43,44), and was found to have prognostic value in GISTs (16). Zhao et al. reported that Ki-67 PI classifications (≤5%, 5–8%, and >8%) independently predict recurrence-free survival of GISTs, which could complement mNIH classification to differentiate various prognoses accurately and effectively in high-risk GIST patients. High-risk (Ki-67 PI >8%) GISTs showed poorer therapeutic responses with imatinib treatment (13). As a useful complement to mNIH classification, the preoperative prediction of high Ki-67 PI levels can provide additional and individual data for clinical treatment decision-making. Recent studies have explored the value of Ki-67 PI levels in the prognostic assessment of GISTs. A study concluded that high Ki-67 PI GISTs (≥10%) indicated reduced overall survival and disease-free survival (17). Belev et al. found that a high Ki-67 PI (≥6%) is statistically significant in terms of recurrence and identified that Ki-67 PI is an important prognostic predictor for recurrence and that is crucial for assessing the malignant potential of GISTs (14).
Another previous study investigated the correlation between Ki-67 PI, CT features, and risk stratification in GISTs, and explored the prognosis of CT features and the Ki-67 PI in GISTs (20). The results showed that the occurrence of GISTs of high mNIH risk classification or metastasis and the mitotic count were significantly higher in the Ki-67 PI >5% groups compared to the Ki-67 PI ≤5% group (P<0.001), with the Ki-67 PI found to be positively correlated with mNIH risk stratification (r=0.558) or mitotic count (r=0.619) (20). Moreover, the significance of preoperative Ki-67 PI and mNIH risk stratification evaluation was effectively confirmed by CT features, including tumor sizes, contours, borders, necrosis, cystic degeneration, and enhancement patterns (20). Thus, the correlation between CT features and Ki-67 PI was demonstrated to make decisions regarding follow-up care and disease management for GISTs before surgery. However, this study did not assess the diagnostic performance and predictive ability of CT features in determining high Ki-67 PI group. Our results indicated that necrosis, necrosis degree, wall thickness of necrosis, LD, and HYOM could effectively diagnoses high Ki-67 PI GISTs from low Ki-67 PI GISTs preoperatively. Furthermore, necrosis, cystic degeneration, HYOM, and Tp ≤32 HU could also reliably predict the high Ki-67 PI GISTs group.
There have been some studies investigated on conventional imaging features and radiomics to predict the gene mutations of GISTs, but there is no study explored between Ki-67 PI and KIT or PDGFRA mutations in GISTs. Our study did not perform the correlation between Ki-67 PI and gene mutations in GISTs, because we did not have the gene mutation results from the histological data. If we have a chance, we will continue to conduct further research.
Our study has some limitations that should be noted. Firstly, this was a retrospective study. Secondly, we only included GISTs patients with surgical resection and immunohistochemical assessment of Ki-67 PI, which may have caused selection bias. Finally, due to the lack of follow-up and prognosis-related data, we did not perform prognostic analyses.
In conclusion, CT imaging features, including necrosis, high necrosis degree, thick wall of necrosis, and HYOM were significant predictive indicators for the high Ki-67 PI GISTs group. Also, necrosis, cystic degeneration, HYOM, and Tp ≤32 HU could be independent predictive factors for high Ki-67 PI GISTs. Preoperative enhanced CT imaging features may help to predict the high Ki-67 PI GISTs and provide more information for clinicians. Contrast-enhanced CT could be a noninvasive substitute of GISTs for histological evaluation and immunohistochemical assessment in clinical practice.
Acknowledgments
Funding: This work was supported by the National Nature Science Foundations of China (grant number: 82001810) and the 1.3.5 project for disciplines of the Excellence-Clinical Research Incubation Project, West China Hospital, Sichuan University (grant number: 19HXFH054).
Footnote
Reporting Checklist: The authors have completed the STARD reporting checklist. Available at https://dx.doi.org/10.21037/atm-21-4669
Data Sharing Statement: Available at https://dx.doi.org/10.21037/atm-21-4669
Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at https://dx.doi.org/10.21037/atm-21-4669). Dr. BS serves as an unpaid Associate Editor-in-chief of Annals of Translational Medicine from Sept 2020 to Aug 2022. The other 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 retrospective study was approved by the institutional review board at West China Hospital, Sichuan University (No. 2020-249). All procedures performed in this study involving human participants were in accordance with the Declaration of Helsinki (as revised in 2013). Because of the retrospective nature of the research, the requirement for 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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