Randomized clinical trial on the use of IMAGE1 S LIGHT (SPIES) vs. white light in the prevention of recurrence during transurethral resection of bladder tumors: Analysis after 12-month follow-up.

INTRODUCTION: The improved image resolution of IMAGE1 S technology will increase tumor detection, achieve a greater number of complete resections, and would probably have an impact on the reduction of recurrences. AIM: The primary objective was to compare the recurrence rates of IMAGE1 S vs. white light during transurethral resection of the bladder (TUR); the secondary objective was to compare the complication rates according to Clavien-Dindo (CD) at 12 months of follow-up. METHODS: Prospective, randomized 1:1, blinded clinical trial. Recurrence and complication rates according to CD were analyzed using chi-square/U Mann-Whitney tests and recurrence-free survival (RFS) using Kaplan-Meier curves. The European Association of Urology (EAU) 2021 scoring model was used. RESULTS: The analysis included 103 participants; 49 were assigned to the IMAGE1 S group and 54 to the white light group. Recurrence rates were 12.2% and 25.9%, respectively (P = .080). The low and intermediate risk group had a lower recurrence rate with IMAGE1 S (7.7% vs. 30.8%, P = .003) and a higher RFS with IMAGE1 S (85.2% vs. 62.8% Log Rank: 0.021), with a Hazard Ratio of 0.215 (95% CI: 0.046-0.925). No differences were observed in the high and very high-risk groups. Complications were mostly grade I and rates were similar between both groups (IMAGE1 S 20.4% vs. white light 7.4% P = .083). CONCLUSIONS: There were no differences in the recurrence rates between groups. However, the low and intermediate risk group had a lower recurrence rate with IMAGE1 S. In addition, perioperative complication rates were not higher.

Modelo impreso en 3D para entrenamiento en ureteroscopia flexible, una opción de bajo coste para el entrenamiento quirúrgico / 3D printed model for flexible ureteroscopy training, a low-cost option for surgical training

Introducción La práctica en modelos experimentales es una opción válida que mejora los resultados y acorta las curvas de aprendizaje de las técnicas quirúrgicas.Nuestro objetivo fue desarrollar un modelo en plástico, impreso en 3D para la docencia, el entrenamiento y la formación en ureteroscopia flexible, analizando costes e idoneidad para la práctica de esta técnica quirúrgica.Métodos Se elaboró un modelo impreso en 3D a partir de una tomografía axial computarizada de una vía urinaria superior de un paciente real. La segmentación se llevó a cabo mediante el software HorosTM y la impresión mediante una impresora FDM-Ultimaker.Se numeró los cálices renales para ser identificados, como en el plan de formación de tratamiento endoscópico de litiasis, ejercicio 4, de la Asociación Europea de Urología.Se utilizaron: un ureteroscopio flexible desechable Innovex (Palex) y cestillas de nitinol (Coloplast).Resultados El tiempo de impresión fue de 19h, con un coste total de 8,77€.El modelo tridimensional permitió la introducción del ureteroscopio flexible y la exploración de los cálices renales por parte de urólogos tanto en formación como en ejercicio actual de la especialidad sin dificultad.El modelo también permitió la utilización de cestillas y la movilización y extracción de litiasis previamente colocadas.Conclusión Damos a conocer un modelo tridimensional válido para ejercicios de formación en ureteroscopia flexible con unos costes razonables, que permitirá adquirir la destreza y la confianza necesaria para iniciar el procedimiento en un escenario real (AU)

Introduction Training in experimental models is a valid option that improves the outcomes and shortens surgical learning curves.Our objective was to develop a 3D printed plastic model for teaching, training and education in flexible ureteroscopy, analyzing costs and suitability for the practice of this surgical technique.Methods A 3D printed model was developed based on a CT scan from a real-life patient's upper urinary tract. HorosTM software was used for segmentation and an FDM-Ultimaker for 3D printing.Renal calyces were numbered to be identified, as in the European Association of Urology Endoscopic Stone Treatment training curriculum, Task 4.The following were used: Innovex single-use flexible ureteroscope (Palex) and nitinol baskets (Coloplast).Results Printing time was 19hours, with a total cost of €8.77.The three-dimensional model allowed the insertion of the flexible ureteroscope and the exploration of the renal calyces by urologists in training as well as in current practice of the specialty without difficulty.The model also allowed the use of baskets and the mobilization and removal of previously placed stones.Conclusion We unveil a valid three-dimensional model for flexible ureteroscopy training exercises with reasonable costs, which will allow acquiring the necessary skills and confidence to initiate the procedure in a real-life scenario (AU)

3D printed model for flexible ureteroscopy training, a low-cost option for surgical training.

INTRODUCTION: Training in experimental models is a valid option that improves the outcomes and shortens surgical learning curves. Our objective was to develop a 3D printed plastic model for teaching, training and education in flexible ureteroscopy, analyzing costs and suitability for the practice of this surgical technique. METHODS: A 3D printed model was developed based on a CT scan from a real-life patient's upper urinary tract. Horos™ software was used for segmentation and an FDM-Ultimaker for 3D printing. Renal calyces were numbered to be identified, as in the European Association of Urology Endoscopic Stone Treatment training curriculum, Task 4. The following were used: Innovex single-use flexible ureteroscope (Palex) and nitinol baskets (Coloplast). RESULTS: Printing time was 19 h, with a total cost of €8.77. The three-dimensional model allowed the insertion of the flexible ureteroscope and the exploration of the renal calyces by urologists in training as well as in current practice of the specialty without difficulty. The model also allowed the use of baskets and the mobilization and removal of previously placed stones. CONCLUSION: We unveil a valid three-dimensional model for flexible ureteroscopy training exercises with reasonable costs, which will allow acquiring the necessary skills and confidence to initiate the procedure in a real-life scenario.