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Quantitative differentiation of non-invasive bladder urothelial carcinoma and inverted papilloma based on CT urography
BMC Urology volume 24, Article number: 73 (2024)
Abstract
Purpose
To investigate the value of CT urography (CTU) indicators in the quantitative differential diagnosis of bladder urothelial carcinoma (BUC) and inverted papilloma of the bladder (IPB).
Material and methods
The clinical and preoperative CTU imaging data of continuous 103 patients with histologically confirmed BUC or IPB were retrospectively analyzed. The imaging data included 6 qualitative indicators and 7 quantitative measures. The recorded clinical information and imaging features were subjected to univariate and multivariate logistic regression analysis to find independent risk factors for BUC, and a combined multi-indicator prediction model was constructed, and the prediction model was visualized using nomogram. ROC curve analysis was used to calculate and compare the predictive efficacy of independent risk factors and nomogram.
Results
Junction smoothness, maximum longitudinal diameter, tumor-wall interface and arterial reinforcement rate were independent risk factors for distinguishing BUC from IPB. The AUC of the combined model was 0.934 (sensitivity = 0.808, specificity = 0.920, accuracy = 0.835), and its diagnostic efficiency was higher than that of junction smoothness (AUC=0.667, sensitivity = 0.654, specificity = 0.680, accuracy = 0.660), maximum longitudinal diameter (AUC=0.757, sensitivity = 0.833, specificity = 0.604, accuracy = 0.786), tumor-wall interface (AUC=0.888, sensitivity = 0.755, specificity = 0.808, accuracy = 0.816) and Arterial reinforcement rate (AUC=0.786, sensitivity = 0.936, specificity = 0.640, accuracy = 0.864).
Conclusion
Above qualitative and quantitative indicators based on CTU and the combination of them may be helpful to the differential diagnosis of BUC and IPB, thus better assisting in clinical decision-making.
Key points
1. Bladder urothelial carcinoma (BUC) and inverted papilloma of the bladder (IPB) exhibit similar clinical symptoms and imaging presentations.
2. The diagnostic value of CT urography (CTU) in distinguishing between BUC and IPB has not been documented.
3. BUC and IPB differ in lesion size, growth pattern and blood supply.
4. The diagnostic efficiency is optimized by integrating multiple independent risk factors into the prediction model.
Introduction
Bladder tumors are the most prevalent neoplasms of the urinary system, of which epithelial tumors accounting for over 90%, including urothelial carcinoma, low-grade malignant uroepithelial papilloma, adenocarcinoma and squamous cell carcinoma [1]. Bladder urothelial carcinoma (BUC) is the most common pathological type of bladder cancer, representing about 90% or more, which is easy to metastasize and has a high recurrence rate, leading to an unfavorable prognosis [2]. Inverted papilloma of the bladder (IPB) is a scarce benign tumor characterized by inverted growth pattern, accounting for approximately 6% of bladder tumors, with a significantly lower risk of recurrence and progression than BUC [3]. However, due to their similar clinical symptoms (such as gross or microscopic hematuria, frequent urination, dysuria), and tendency to occur in the bladder neck and triangle, distinguishing them through imaging findings can be challenging when the lesions do not invade surrounding structures, so preoperative misdiagnosis arose frequently.
The surgical approaches of BUC are classified into two categories according to the existence of muscular infiltration. Transurethral resection of the bladder tumor (TURBT) is commonly employed for non-muscle-invasive bladder cancer (NMIBC), whereas radical cystectomy is preferred for muscle-invasive bladder cancer (MIBC) [4, 5]. No matter which grade of BUC, postoperative infusion chemotherapy or systemic chemotherapy is required depending on the situation [6]. The standard surgical procedure for IPB involves TURBT, in addition to electrocauterization of bladder tumor, while preserving the bladder. Postoperative chemotherapy is not routinely administered, but regular monitoring is necessary [7]. Cystoscopy and pathological examination is the essential diagnostic tool for bladder tumors. Patients with confirmed BUC through flexible cystoscopic biopsy should undergo evaluation for myometrial invasion, often followed by re-examination using cystoscopy to extend the depth of excised tissue. If the suspicious lesion is identified as IPB by a pre-treatment imaging method before flexible cystoscopy, rigid cystoscopy and TURBT can be performed directly, and without the need for a second biopsy. In terms of prognosis, TURBT has limitations in completely removing lesions at once and often underestimates the tumor grade, resulting in a high recurrence rate of BUC. About 50%~70% of patients will redevelop tumor nodules, with most occurring within two years after surgery [8]. In contrast to BUC, IPB cells differentiating maturely, demonstrating localized growth with non-invasion of the muscular layer. The recurrence rate is pretty low, only about 1% [9]. Given the certain degree of difference in treatment options and prognosis, preoperative differentiation between BUC and IPB is quite important.
CT urography (CTU) is widely utilized in the clinical diagnosis and monitoring bladder tumor [10]. By observing pre- and post-contrast medium injection CT images, location of the tumor, number and size of lesions, relationship with surrounding tissue, as well as lymph node metastasis or distant metastasis can be accurately displayed. Studies have demonstrated that although CTU has limited value in distinguishing MIBC from NMIBC, it serves as a reference standard for staging MIBC by revealing the invasion of fat around the bladder or adjacent organs [11]. To our knowledge, there is currently no comparative study on CTU characteristics of BUC and IPB, and their role in identifying the two remains unclear.
Taken together, this study aims to analyze the differential characteristics of BUC and IPB based on CTU and to quantitatively identify them.
Materials and methods
Study population
This study was a retrospective study and was approved by the ethics committee of the Zhejiang Cancer Hospital. Institutional Review Board approval was obtained (202308241652000135978). Written informed consent was waived by the Institutional Review Board. The requirement for informed consent was waived by the ethics committee of the Zhejiang Cancer Hospital.
We retrieved the roster of patients who underwent CTU between January 2019 and December 2022 via the PACS platform, and procured clinical (such as age, gender, urine erythrocyte) and pathological information from the electronic medical record database. The inclusion criteria comprised: (1) initial consultation for bladder lesions; (2) TURBT or radical cystectomy within 15 days after CTU examination; (3) pathologically confirmed as BUC or IPB. A total of 227 eligible patients were found. Then, some cases were further excluded according to the following criteria: (1) absence of positive CTU findings or lesions too small to measure quantitative indices; (2) incomplete clinical or imaging data; (3) lesions with diffuse bladder wall thickening; (4) peri-bladder tissue invasion or regional lymph node metastasis observed on CTU. The incidence of IPB being relatively low, we conducted a continuous collection of BUC cases from January 2019 to December 2019 and IPB cases from January 2019 to December 2022 in order to minimize the disparity in their numbers. Ultimately, 103 cases were included for successive analysis. Figure 1 shows the flow chart of this study.
Devices and scanning methods
Image capture was performed with a special Siemens 64-layer spiral CT (Siemens SOMATOM Definition Flash, Germany). Drank 500~600ml water before examination until the patient felt the bladder was full. Patients were placed in the supine position with their foot placed anteriorly. The entire abdomen and pelvis were covered. The parameters of CT plain scan were: tube voltage 120kV, tube current was automatic with a reference value of 300mA, pitch 0.6, matrix 512 × 512, gantry rotation speed of 0.50s, collimation 128 × 0.6mm, reconstructed layer thickness 1mm, reconstructed layer spacing 1mm. Subsequently, the non-ionic contrast agent (Ultraist370, Bayer Schering, Germany) was injected intravenously with a rate of 3~3.5mL/s, and then the saline tracer 100ml was injected intravenously. The arterial, venous, and excretory phases were collected at 35s, 65s and 600~900s post-contrast injection using contrast medium tracking technique.
Imaging interpretation
Four-stage CTU images of all cases were independently and randomly reviewed by two radiologists with 4-year and 10-year specializing in the urological subgroup. These radiologists were not involved in the case selection process, and clinical information as well as pathological results were concealed from them. The following specific indicators were assessed:
-
(1)
Number of lesion. A single lesion was designated as such, while the presence of two or more was considered multiple.
-
(2)
Location. According to the bladder wall where the base of the tumor was located, the growth site was divided into lateral wall, posterior wall, parietal wall, bottom wall and anterior wall.
-
(3)
Morphology. The shape of the lesion includes cauliflower, hilly, lobulation, and papillary (Fig. 2).
-
(4)
Calcification. Dense nodules exceeding 100HU on plain scan were defined as having calcification, and vice versa as not having calcification.
-
(5)
Cystic degeneration. A more hypointense area without definite enhancement within the enhanced lesion.
-
(6)
Junction smoothness. Depending on whether the bladder wall at the junction of the lesion and the bladder is elevated, thickened or rough, it was classified as smooth and non-smooth (Fig. 2).
-
(7)
Diameter measurement. The largest cross-section of the lesion was found on any orientation image during the excretion phase, the maximum transverse diameter (parallel to the base of the lesion) and the maximum longitudinal longitude (perpendicular to the base of the lesion) were measured, and the ratio of transverse to longitudinal diameter was calculated.
-
(8)
Tumor-wall interface. Defined as the length of the curved contact between the bladder wall and tumor, which was measured using the free curve caliper tool in PACS.
-
(9)
Density and enhancement. The largest level of the lesion was selected, and a 15~20mm2 circular ROI was placed in the solid part of the lesion with relatively uniform density in the non-enhanced and arterial phases, avoiding necrotic and calcified regions. Three consecutive measurements were averaged, and the size, plane and position of the ROI in the 2 phases were kept as consistent as possible. The arterial reinforcement rate was defined as (arterial phase CT value - non-enhanced CT value)/non-enhanced CT value.
When multiple lesions were present, the lesion with the largest area was selected as the index lesions for evaluation. The intraclass correlation coefficient (ICC) was used to evaluate the inter-rater reliability between two radiologists' measurements. If the ICC for each index exceeds 0.75, it indicated qualified inter-reader agreement, and the measurement results of 4-year experience radiologist were used for succeeding analysis.
Construction of quantitative prediction model
Firstly, clinical characteristics including age, gender, urine erythrocyte and all quantitative and qualitative imaging features were subjected to univariate logistic regression analysis. Subsequently, variables with P < 0.05 were taken as related factors and multivariate logistic regression analysis was performed to determine independent risk factors for BUC and construct a combined multi-indicator model. Finally, a nomogram was created to visually display the combined model.
Statistical analysis
The statistical analysis was conducted using SPSS 25.0 and R language 4.1.0 software. The Kolmogorov-Smirnov test was first used to check the normality of the quantitative data, and those who conformed to the normal distribution were expressed as mean ± standard deviation and compared between the two groups using the independent samples t-test; those who did not conform to the normal distribution were expressed as interquartile range (IQR) and compared between the two groups using the Mann-Whitney U test. Categorical variables were expressed as frequencies and rates, and the chi-square test or Fisher's exact test was used for comparison between two groups. The area under the curve (AUC) of the receiver operating characteristic (ROC) curve was used to evaluate the efficacy of independent risk factors and combined model to identify BUC and IPB. Sensitivity, specificity and accuracy were calculated through the Youden index. The Delong test was used to compare the differences in AUC. The nomogram underwent internal validation via 1000 bootstrap resamplings and the accuracy was assessed by Hosmer-Lemeshow test and calibration curve. A statistically significant difference was defined as P < 0.05.
Results
Baseline information of the patient
Seventy-nine (76.7%) of the 103 patients were male and 24 (23.3%) were female. Based on pathological results, 78 (75.7%) BUC and 25 (24.3%) IPB were defined. Following preliminary inter-group analysis, BUC and IPB were statistically different in terms of location, morphology, junction smoothness, age and urine erythrocyte. Additionally, the maximum transverse diameter and longitudinal diameters and their ratio of BUC were larger than those of IPB (P≤0.001). The contact range between BUC and bladder wall was longer than that of IPB (P<0.001). The arterial phase CT and arterial reinforcement rate were also higher in BUC compared to IPB (P < 0.001). Table 1 for details. Figures 3 and 4 illustrate the characteristic CTU findings of BUC and IPB.
Inter-observer agreement
The two radiologists essentially exhibited the same perception of morphology (ICC=0.777), with strong agreement on fundamental characteristics, assessment of the intersection, tumor-wall interface, diameter and density measurements (ICC range: 0.817-0.889). These results suggested that the evaluation method of this study was highly reproducible (Table 2).
Logistic regression analysis
Univariate analysis showed that gender, morphology, number of lesions, calcification, cystic degeneration and non-enhanced CT value were not significantly associated with BUC (all P > 0.05). After excluding these indicators, the remaining features were included in multivariate logistic regression equation, which identified junction smoothness, maximum longitudinal diameter, tumor-wall interface and arterial reinforcement rate as independent risk factors for BUC (OR range 0.11- 35.68, all P < 0.05). Lastly, these independent risk factors were used to construct a nomogram prediction model to discriminate BUC from IPB (Table 3, Figs. 5 and 6).
Diagnostic performance of independent risk factors and combined model
According to ROC curve analysis, the diagnostic efficacy of individual independent risk factor was 0.667 (junction smoothness), 0.757 (maximum longitudinal diameter), 0.888 (tumor-wall interface) and 0.786 (arterial reinforcement rate), while the AUC of the nomogram was as high as 0.934 (95%CI: 0.887-0.981), with sensitivity, specificity and accuracy were 0.808, 0.920 and 0.835, respectively (Table 4, Fig. 7). Delong test demonstrated that the diagnostic efficiency of the nomograml was significantly higher than that of junction smoothness, maximum longitudinal diameter and arterial reinforcement rate (all P<0 05). Although it also surpassed the AUC of tumor-wall interface, this difference did not reach statistical significance (P=0.139). The Hosmer-Lemeshow test yielded x2=5.620, P=0.690, indicating that the nomogram's prediction probability did not significantly differ from that of the ideal model, thus demonstrating high accuracy. Additionally, the calibration curve demonstrated excellent agreement between predicted and actual risks for BUC occurrence (Fig. 8).
Discussion
BUC is the most common malignant tumor of the bladder, characterized by strong invasiveness that facilitates infiltration into muscular layer and invade surrounding tissues. This makes complete removal the tumor via TURBT challenging, resulting in a significantly higher recurrence rate and lower survival rate for patients [12]. IPB is the most common benign tumor of the bladder, generally showing limited growth and not invading the muscular layer [13]. However, due to its unclear pathogenesis and low incidence rate, clinical symptoms and imaging manifestations often overlap with BUC, many radiologists lack sufficient experience in diagnosing it accurately unless peripheral abnormalities or signs of metastasis are observed, which is not conducive to guiding treatment and assessing patient prognosis. In this study, we examined the disparities in multiple qualitative and quantitative indicators present in CTU images between BUC and IPB, and finally searched for 4 easy-to-use quantifiable features, all of which demonstrated satisfactory diagnostic efficacy. The nomogram, constructed by the combination of 4 independent risk factors, further improved the discrimination between BUC and IPB, achieving the highest AUC and specificity. This suggests that CTU-based quantitative features may aid improve the accuracy in distinguishing between BUC and IPB preoperatively, thereby contributing to enhancing the reliability of imaging diagnostic reports.
In this study, there were no significant inter-group differences observed in terms of gender, morphology, number of lesion, calcification, cystic degeneration, or plain CT values, indicating that distinguishing BUC from IPB based solely on basic qualitative characteristics observed by the naked eye is difficult. Both of them are prevalent among men and way present with calcification, cystic degeneration, and multiple lesions are not uncommon, which appear as limited bladder wall thickening or soft tissue nodules on non-enhanced CT [14, 15]. In clinical practice, both BUC and IPB are generally considered to be prevalent in middle-aged and elderly. In all participants enrolled in this study, the mean age of BUC was higher than the that of IPB (63.51±12.23 years vs. 55.00±11.80 years, P=0.003), suggesting that age may serve as a potential predictive factor for differentiating them. However, the multivariate analysis failed to identify age as an independent risk factor. We postulated there were two reasons: first, the sample size was small, particularly in IPB with only 25 cases, which was insufficient to fully reflect age differences. Second, there may have been selection bias as this study included BUC that did not invade structures outside the bladder, with slower cell proliferation and smaller overall lesion size, resulting in late onset of clinical symptoms and delaying detection. However, these speculations need validation through larger-scale studies with more comprehensive staging of BUC.
Among the 4 independent risk factors, the junction smoothness was the only subjective qualitative indicator, which indirectly reflects image features around tumors. The inter-observer agreement between two radiologists' measurements was high with an ICC of 0.841. 65.4% (51/78) BUC had junction abnormalities, whereas only 32.0% (8/25) IPB caused non-smoothness at the junction. This may be attributed to their biological behavior. The tumor cells of BUC grow at different rates in all directions, resulting in irregular or lobulated tumor shapes, which promotes the precipitation and adsorption of urate crystals around the focus [16]. Moreover, about 25% of BUC infiltrates downward into the muscular layer, causing thickening and stiffening of the basal bladder wall, while the adjacent normal bladder wall was soft and mobile, creating a junction bulge or disruption of continuity [17]. IPB exhibits slow growth and regular morphology, with its surface being covered by normal urinary tract epithelium and without involving the muscle layer. There, there is no significant difference between the lesion margin and the adjacent bladder wall [18].
The maximum longitudinal diameter and tumor-wall interface quantitatively reflect the lesion size. The findings of this study showed an inverse correlation between tumor height and the likelihood of presenting with BUC. IPB typically appear as narrow basal strips or sphere-like shapes on CT images, with a longitudinal diameter similar to the transverse diameter. Previous research have shown that tipped is a specific presentation of IPB [14, 19, 20]. In contrast, the transverse diameter of BUC was significantly larger than its longitudinal diameter, indicating that the tumor show more of a broad base and the growth direction spread mainly to the bladder wall on both sides. The author posits that the aspect ratio may be a superior indicator for evaluating morphological characteristics of tumors compared to basal and height measurements, even if it was not included as a reference standard in the nomogram. For example, the aspect ratio is frequently utilized in predicting BUC staging, and one study have shown that when the aspect ratio is <0.605, it suggests a heightened likelihood of myofilament infiltration [21]. Tumor-wall interface, when used along, is the most effective independent risk factor for identifying BUC and IPB. There was no statistically different from the AUC of nomogram. This easily observable and measurable metric performed nearly perfectly in terms of inter-reader agreement. Combined use with other indicators in a multivariate logistic regression equation significantly improved the predictive efficacy, suggesting that other indicators are complementary to tumor-wall interface in predicting tumor benignity and malignancy. Previous studies have shown that the tumor-wall interface of lesions without stick was wider than that of tipped lesions, and the risk of myometrial invasion is higher [22, 23]. Ahn et al. measured the length of tumor-bladder contact on T2WI, DWI and ADC images in combination with the Vesical Imaging-Reporting and Data System (VI-RADS) to predict muscular invasion of BUC, and showed that the tumor-wall interface was an independent risk factor (OR range 1.9-2.0) for differentiating MIBC from NMIBC, compensating for the lack of VI-RADS as a qualitative indicator [24]. A variety of derived quantitative indicators have been used for staging other tumors that were similar to tumor-wall interface. For example, the extent of contact with the pleura has been used as a criterion for judging pleural invasion in lung cancer [25]. Similarly, the length of contact with the envelope has been used to predict extracapsular extension of prostate cancer [26].
Since tumor growth depends is dependent on angiogenesis, varying degrees of neovascularization and malformation can reflect different levels of tumor differentiation [27]. The presence or absence of arteriovenous fistula, vascular tortuosity, distribution, vessel size and interstitial edema can affect the perfusion of contrast medium within the lesion. The arterial reinforcement rate represents the blood supply characteristics of the lesion. The results demonstrated that the arterial reinforcement rate of BUC was significantly higher than that of IPB, indicating that the blood supply of BUC was richer than that of IPB, and the heterogeneity of tumor vessels was higher, which is consistent with the pathological manifestations [28, 29]. The hyperplastic epithelial nests of IPB are parallel arranged epithelial cells with minimal fibrovascular structures, and derive their blood supply primarily from the surrounding vasculatures of the tumor cell mass. By comparison, BUC is a malignant neoplasm characterized by extensive neovascularization and rapid growth, and most vessels extend to the interior of the tumor in the shape of dendrites at the base of the tumor. Therefore, typical BUC shows obvious enhancement in arterial phase, with maximum enhancement in venous phase and diminished enhancement in delayed phase. Conversely, the typical IPB shows moderate to severe delayed intensification. When describing the enhancement characteristics, we only analyzed the difference between arterial phase CT and non-enhanced CT value, but did not measure venous phase and delayed CT value. The reason is that the dynamic changes of the enhancement degree of lesions analyzed by simultaneous measurement of arterial and venous CT values are closely related to contrast medium injection time and individual differences such as cycle period, which may increase the error of measurement results. In addition, the contrast medium was excreted into the bladder through the urinary tract during the delayed phase, resulting in a "jet" image that interfered with accurate CT value measurement of adjacent lesions.
At present, routine examinations for the diagnosis of bladder tumors include ultrasound, CT, MRI and cystoscopy. However, due to the low soft tissue separation rate and limited scanning range of ultrasound, it is difficult to make qualitative diagnosis only according to sonogram. MRI offers clear advantages in evaluating myometrial invasion and lymph node metastasis [30], its imaging time is lengthy and image quality can be affected by intestinal peristalsis. Furthermore, the conventional scan image is thicker, and the display effect of micro-lesion and calcification is not distinct. Cystoscopy is subject to operator-dependent variability and incomplete sampling, which may lead to inaccurate pathological results. In addition, the possibility of damaging the urethra and causing urinary tract infection limits its frequent use in diagnosing and postoperative monitoring bladder tumors. In this study, CTU was used to identify BUC and IPB because of its 5 major advantages: (1) non-invasive, fast imaging and economical cost; (2) relatively objective data acquisition that is not influenced by operator level; (3) the target vessels are reconstructed using MIP mode, which can show the vascular structures within and around the lesion; (4) the excretion phase images provided clearer lesion morphology and contour details, as well as more precise diameter measurements; (5) the ability to quantitatively measure multiple features of the lesion.
The human papillomavirus (HPV) hinders the function of tumor suppressor proteins by means of its viral oncogenic proteins E6 and E7, disrupting the regulation of cell cycle and DNA repair mechanisms. Consequently, this impairs genomic stability in cells, thereby elevating the risk of cellular malignancy and tumor recurrence. The study conducted by Sarier et al. [31] involved a 2-year regular follow-up of patients with BUC, revealing that the recurrence rate was higher in HPV-positive patients (47.3%) compared to HPV-negative patients (36.8%). These findings suggest that HPV infection could potentially serve as a valuable tool for distinguishing BUC from IPB prior to surgery and assessing tumor prognosis, warranting further investigation.
Several limitations of this study are noteworthy. First, this was a single-center retrospective study, and selection bias is inevitable. Second, the sample size was small and unbalanced; therefore further studies require an increased sample size. Third, the assessment involved only a limited number of readers and did not analyze the intra-reader reproducibility of quantitative indicators. Finally, the index lesions were classified according to lesion size, which means that they may not necessarily by the highest grade lesions pathologically and could have caused some misleading results. A follow-up study will stratify the different grades of BUC and explore the differences in imaging performance with IPB.
Conclusions
The quantitative indicators based on CTU measurement have credible consistency among readers, reflecting the variations in growth pattern, size and blood supply between BUC and IPB. In addition, the composite nomogram incorporating multiple variables may holds some benefit in helping imaging differential diagnosis of BUC and IPB, thus worth further investigation.
Availability of data and materials
The imaging studies and clinical data used for model development are not publicly available, because they contain private patient health information. Interested users may request access to these data, where institutional approvals along with signed data use agreements and/or material transfer agreements may be needed/negotiated. Derived result data supporting the findings of this study are available upon reasonable requests.
References
Antoni S, Ferlay J, Soerjomataram I, et al. Bladder cancer incidence and mortality: a global overview and recent trends. Eur Urol. 2017;71(1):96–108. https://0-doi-org.brum.beds.ac.uk/10.1016/j.eururo.2016.06.010.
Richters A, Aben KKH, Kiemeney LALM. The global burden of urinary bladder cancer: an update. World J Urol. 2020;38(8):1895–904. https://0-doi-org.brum.beds.ac.uk/10.1007/s00345-019-02984-4.
Ho L, Jones E, Kavanagh A. Benign inverted papilloma at bladder neck causing acute urinary retention. J Surg Case Rep. 2018;6:125. https://0-doi-org.brum.beds.ac.uk/10.1093/jscr/rjy125.
Taylor J, Becher E, Steinberg GD. Update on the guideline of guidelines: non-muscle-invasive bladder cancer. BJU Int. 2020;125(2):197–205. https://0-doi-org.brum.beds.ac.uk/10.1111/bju.14915.
Mitra AP, Cai J, Miranda G, et al. Management trends and outcomes of patients undergoing radical cystectomy for urothelial carcinoma of the bladder: evolution of the University of Southern California Experience over 3,347 Cases. J Urol. 2022;207(2):302–13. https://0-doi-org.brum.beds.ac.uk/10.1097/JU.0000000000002242.
Rouprêt M, Seisen T, Birtle AJ, et al. European association of urology guidelines on upper urinary tract urothelial carcinoma: 2023 update. Eur Urol. 2023;S0302–2838(23):02652. https://0-doi-org.brum.beds.ac.uk/10.1016/j.eururo.2023.03.013.
Baarimah A, El Helaly A, Al Ghanbar M, et al. Inverted urothelial papilloma: a rare pathology in young girl. A case report and literature review. Urol Case Rep. 2020;35:101543. https://0-doi-org.brum.beds.ac.uk/10.1016/j.eucr.2020.101543.
Paner GP, Montironi R, Amin MB. Challenges in pathologic staging of bladder cancer: proposals for fresh approaches of assessing pathologic stage in light of recent studies and observations pertaining to bladder histoanatomic variances. Adv Anat Pathol. 2017;24(3):113–27. https://0-doi-org.brum.beds.ac.uk/10.1097/PAP.0000000000000152.
Akgul M, MacLennan GT, Cheng L. Distinct mutational landscape of inverted urothelial papilloma. J Pathol. 2019;249(1):3–5. https://0-doi-org.brum.beds.ac.uk/10.1002/path.5307.
Van Der Molen AJ, Cowan NC, Mueller-Lisse UG, et al. CT urography: definition, indications and techniques. A guideline for clinical practice. Eur Radiol. 2008;18(1):4–17. https://0-doi-org.brum.beds.ac.uk/10.1007/s00330-007-0792-x.
Flaig TW, Spiess PE, Agarwal N, et al. Bladder Cancer, Version 3.2020, NCCN Clinical Practice Guidelines in Oncology. J Natl Compr Canc Netw. 2020;18(3):329–54. https://0-doi-org.brum.beds.ac.uk/10.6004/jnccn.2020.0011.
Cumberbatch MGK, Foerster B, Catto JWF, et al. Repeat Transurethral Resection in Non-muscle-invasive Bladder Cancer: A Systematic Review. Eur Urol. 2018;73(6):925–33. https://0-doi-org.brum.beds.ac.uk/10.1016/j.eururo.2018.02.014.
Picozzi S, Casellato S, Bozzini G, et al. Inverted papilloma of the bladder: a review and an analysis of the recent literature of 365 patients. Urol Oncol. 2013;31(8):1584–90. https://0-doi-org.brum.beds.ac.uk/10.1016/j.urolonc.2012.03.009.
Takeuchi M, Sasaguri K, Naiki T, et al. MRI findings of inverted urothelial papilloma of the bladder. AJR Am J Roentgenol. 2015;205(2):311–6. https://0-doi-org.brum.beds.ac.uk/10.2214/AJR.14.13879.
Trinh TW, Glazer DI, Sadow CA, et al. Bladder cancer diagnosis with CT urography: test characteristics and reasons for false-positive and false-negative results. Abdom Radiol (NY). 2018;43(3):663–71. https://0-doi-org.brum.beds.ac.uk/10.1007/s00261-017-1249-6.
Li L, Na R, Mi T, et al. Medical image diagnostic value of computed tomography for bladder tumors. Comput Math Methods Med. 2021;2021:3781028. https://0-doi-org.brum.beds.ac.uk/10.1155/2021/3781028.
Raman SP, Fishman EK. Bladder malignancies on CT: the underrated role of CT in diagnosis. AJR Am J Roentgenol. 2014;203(2):347–54. https://0-doi-org.brum.beds.ac.uk/10.2214/AJR.13.12021.
Jørgensen PH, Vainer B, Hermann GG. A clinical and molecular review of inverted papilloma of the urinary tract: how to handle? APMIS. 2015;123(11):920–9. https://0-doi-org.brum.beds.ac.uk/10.1111/apm.12456.
Asano K, Miki J, Maeda S, et al. Clinical studies on inverted papilloma of the urinary tract: report of 48 cases and review of the literature. J Urol. 2003;170(4 Pt 1):1209–12. https://0-doi-org.brum.beds.ac.uk/10.1097/01.ju.0000085342.15918.d7.
Sweeney MK, Rais-Bahrami S, Gordetsky J. Inverted urothelial papilloma: a review of diagnostic pitfalls and clinical management. Can Urol Assoc J. 2017;11(1–2):66–9. https://0-doi-org.brum.beds.ac.uk/10.5489/cuaj.4136.
Ozden E, Turgut AT, Yesil M, et al. A new parameter for staging bladder carcinoma: ultrasonographic contact length and height-to-length ratio. J Ultrasound Med. 2007;26(9):1137–42. https://0-doi-org.brum.beds.ac.uk/10.7863/jum.2007.26.9.1137.
Huele EH, Veenboer PW, Wessels FJ, et al. Value of multiparametric magnetic resonance imaging for local staging of invasive urinary bladder tumours. Urol Oncol. 2023;41(1):49.e7-49.e12. https://0-doi-org.brum.beds.ac.uk/10.1016/j.urolonc.2022.09.026.
Arita Y, Shigeta K, Akita H, et al. Clinical utility of the Vesical Imaging-Reporting and Data System for muscle-invasive bladder cancer between radiologists and urologists based on multiparametric MRI including 3D FSE T2-weighted acquisitions. Eur Radiol. 2021;31(2):875–83. https://0-doi-org.brum.beds.ac.uk/10.1007/s00330-020-07153-5.
Ahn H, Hwang SI, Lee HJ, et al. Quantitation of bladder cancer for the prediction of muscle layer invasion as a complement to the vesical imaging-reporting and data system. Eur Radiol. 2021;31(3):1656–66. https://0-doi-org.brum.beds.ac.uk/10.1007/s00330-020-07224-7.
Feng SH, Yang ST. The new 8th TNM staging system of lung cancer and its potential imaging interpretation pitfalls and limitations with CT image demonstrations. Diagn Interv Radiol. 2019;25(4):270–9. https://0-doi-org.brum.beds.ac.uk/10.5152/dir.2019.18458.
Shieh AC, Guler E, Ojili V, et al. Extraprostatic extension in prostate cancer: primer for radiologists. Abdom Radiol (NY). 2020;45(12):4040–51. https://0-doi-org.brum.beds.ac.uk/10.1007/s00261-020-02555-x.
Fu W, Liu D, Xiong Y, et al. The comparison between contrast-enhanced ultrasound and contrast-enhanced magnetic resonance imaging in diagnosing bladder urothelial carcinoma. Int Urol Nephrol. 2023;55(5):1073–9. https://0-doi-org.brum.beds.ac.uk/10.1007/s11255-022-03410-2.
Zhu J, Huang X, Liu L, Wang N, Nie F. Can the Vesical Imaging Reporting and Data System (VI-RADS) score be applied in conventional ultrasound and contrast-enhanced ultrasound to differentiate muscle-invasive bladder cancer? Med Ultrason. 2023;25(1):22–8. https://0-doi-org.brum.beds.ac.uk/10.11152/mu-3841.
Kobayashi Y, Hashimoto S, Ishikawa S, et al. Nihon Hinyokika Gakkai Zasshi. 1992;83(12):2037-2043. https://0-doi-org.brum.beds.ac.uk/10.5980/jpnjurol1989.83.2037.
Panebianco V, De Berardinis E, Barchetti G, et al. An evaluation of morphological and functional multi-parametric MRI sequences in classifying non-muscle and muscle invasive bladder cancer. Eur Radiol. 2017;27(9):3759–66. https://0-doi-org.brum.beds.ac.uk/10.1007/s00330-017-4758-3.
Sarier M, Usta SS, Turgut H, et al. Prognostic value of HPV DNA in urothelial carcinoma of the bladder: a preliminary report of 2-year follow-up results. Urol J. 2021;19(1):45–9. https://0-doi-org.brum.beds.ac.uk/10.22037/uj.v18i.6429.
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This research was supported by Zhejiang Provincial Natural Science Foundation of China under Grant No.LGF22H220006, Medical Health Science and Technology Project of Zhejiang Province (2021KY549, 2022KY100).
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PJ: Conceptualization, Methodology, Writing - Original Draft, Visualization LY: Software, Investigation, Data curation YL: Supervision, Resources JH: Validation, Investigation XW: Writing - Review & Editing, Project administration, Funding acquisition. All authors approved the final version and agreed to publish the manuscript.
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This study was a retrospective study and was approved by the ethics committee of the Zhejiang Cancer Hospital. Institutional Review Board approval was obtained (202308241652000135978). Written informed consent was waived by the Institutional Review Board. The requirement for informed consent was waived by the ethics committee of the Zhejiang Cancer Hospital. Authors confirm that all methods were carried out in accordance with relevant guidelines and regulations. All procedures performed in studies involving human participants were in accordance with the ethical standards of the institutional and/or national research committee.
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Jin, P., Yang, L., Liu, Y. et al. Quantitative differentiation of non-invasive bladder urothelial carcinoma and inverted papilloma based on CT urography. BMC Urol 24, 73 (2024). https://0-doi-org.brum.beds.ac.uk/10.1186/s12894-024-01459-y
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DOI: https://0-doi-org.brum.beds.ac.uk/10.1186/s12894-024-01459-y