Abstract
Background
The unique property of sodium fluorescein has made it ideal for use in medical applications such as diagnostic ophthalmology and intravenous angiography. It is mainly excreted via the renal system and although extensively used in these diagnostic applications, it has not been widely used to aid in the visualization of the ureters. It is possible to visualize the urinary tract by shining a source of light and studying the fluorescence using a special filter. The goal of our study was to assess the real-time visualization of ureters using intravenous sodium fluorescein under the stimulus of a 530 nm wavelength light.
Materials and methods
Nine 250 gm Wister rats were given an intravenous dose of 0.01 ml of sodium fluorescein. A laparotomy was immediately performed following the administration of dye. Anesthesia was performed with an intraperitoneal dose of ketamine–xylazine. The retroperitoneum was exposed and observed under an alternating white xenon and a 530 nm excitation light with an objective to visualize the organs captured within the fluorescence of the compound (sodium fluorescein).
Results
Under xenon light, the location of the kidneys and urinary bladder were visualized, but not the ureters. The light was then changed to a 530 nm wavelength mode when the location and orientation of the ureters was visualized along with the peristaltic movements. Fluorescence visualization of the ureters was noted 5–10 min following kidney visualization. In addition, the vascular structures in close proximity to the ureters were also visualized. None of the rats underwent any retroperitoneal dissection, and in one case, partial mobilization of a kidney was undertaken. All rats were euthanized at the completion of the procedure.
Conclusion
Intravenous administration of sodium fluorescein enables fluorescence visualization of the ureters in a rat model, after activation with a 530 nm light transmitter.
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References
Goodno JA, Powers TW, Harris VD (1995) Ureteral injury in gynecologic surgery: a ten-year review in a community hospital. AmJ Obstet Gynecol 172(6):1817–1820 discussion 1820–1822
Symmonds RE (1976) Ureteral injuries associated with gynecologic surgery: prevention and management. Clin Obstet Gynecol 19(3):623–644
Schols RM, Bouvy ND, Van Dam RM, Stassen LPS (2013) Advanced intraoperative imaging methods for laparoscopic anatomy navigation: an overview. Surg Endosc 27(6):1851–1859. doi:10.1007/s00464-012-2701-x
Delacroix SE, Winters JC (2010) Urinary tract injures: recognition and management. Clin Colon Rectal Surg 23(2):104–112
Salvatierra O, Tunkey DD, Blaisdell FW (1975) Management of urologic injuries. West J Med 122(3):257–261
Parpala-Spårman T, Paananen I, Santala M, Ohtonen P, Hellström P (2008) Increasing numbers of ureteric injuries after the introduction of laparoscopic surgery. Scand J Urol Nephrol 42(5):422–427. doi:10.1080/00365590802025857
da Silva G, Boutros M, Wexner SD (2012) Role of prophylactic ureteric stents in colorectal surgery. Asian J Endosc Surg 5(3):105–110
Picozzi S, Carmignani L (2010) A knotted ureteral stent: A case report and review of the literature. Urol Ann 2(2):80–82
Lange D, Chew BH (2009) Update on ureteral stent technology. Ther Adv Urol 1(3):143–148. doi:10.1177/1756287209341306
Sheikh FA, Khubchandani IT (1990) Prophylactic ureteric catheters in colon surgery—how safe are they? Report of three cases. Dis Colon Rectum 33(6):508–510
Ishizawa T, Bandai Y, Ijichi M, Kaneko J, Hasegawa K, Kokudo N (2010) Fluorescent cholangiography illuminating the biliary tree during laparoscopic cholecystectomy. Br J Surg 97(9):1369–1377
Matsui A, Tanaka E, Choi HS, Winer JH, Kianzad V, Gioux S et al (2010) Real-time intra-operative near-infrared fluorescence identification of the extrahepatic bile ducts using clinically available contrast agents. Surgery 148(1):87–95
Verbeek FPR, Van der Vorst JR, Schaafsma BE, Swijnenburg R-J, Gaarenstroom KN, Elzevier HW et al (2013) Intraoperative near-infrared fluorescence-guided identification of the ureters using low-dose methylene blue: a first-in-human experience. J Urol 190(2):574–579. doi:10.1016/j.juro.2013.02.3187
FDA drug database. dailymed.nlm.nih.gov
Acknowledgments
The authors thank Karl Storz GmbH & Co. KG (Tuttlingen, Germany) for technical services and for providing the laparoscopic fluorescence imaging system for animal experiments, and Alejandro Damonte, MD, Lisandro Alpe, MD, and Hernan Todeschini, MD, for their assistance.
Disclosures
Dr Fernando D. Dip has received the equipment for performing this experiment from KARL STORZ Endoskope, Tuttlingen, Germany, but has not received any financial assistance for the same. Drs Mario Nahmod, Francisco Suarez Anzorena, Alejandro Moreira, Luis Sarotto, Carolina Ampudia, Sudhir N Kalaskar, Pedro Ferraina, Raul J Rosenthal have no conflicts of interest or financial ties to disclose. Dr. Steven Wexner is a consultant and received royalty income for intellectual property license from Karl Storz Endoscopy.
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Dip, F.D., Nahmod, M., Anzorena, F.S. et al. Novel technique for identification of ureters using sodium fluorescein. Surg Endosc 28, 2730–2733 (2014). https://doi.org/10.1007/s00464-014-3519-5
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DOI: https://doi.org/10.1007/s00464-014-3519-5