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DOI: 10.1055/s-0035-1556880
Planning and Execution of Access for Percutaneous Renal Stone Removal in a Community Hospital Setting
Publikationsverlauf
Publikationsdatum:
18. August 2015 (online)
There have been several reports on the feasibility and safety of the superior pole approach to the kidney for percutaneous renal stone removal. To the author's knowledge, no one has published on the huge advantages this approach affords, owing to the rigid nature of the nephroscope/ultrasonic lithotripter, and due to the usually oblique position of the kidney as it lies upon the psoas. Between July 1986 and June 2014, the author has performed more than 500 percutaneous renal access procedures for stone removal at a single community hospital. Procedural technique is reviewed in detail, including the usual supremacy of the superior pole approach, the value of preprocedural sagittal computed tomographic reconstructions in forming a tentative plan of approach to the kidney, and the value of an intraprocedural partial-air nephrostogram in finalizing the plan. The importance of collaboration with the involved urologist, and knowledge of the tools available to the urologist, is emphasized.
In the first half of the 1980s, with the introduction of extracorporeal shock-wave lithotripsy and percutaneous nephrolithotomy, there was an abrupt advance in the treatment of renal calculi. Prior to that time the only option for treatment of large renal calculi, particularly staghorns, had been surgery. For these stones, a combined percutaneous–extracorporeal technique quickly evolved.[1]
The author's first exposure to these techniques was in 1985, at the University of Virginia in Charlottesville. Here two or three “staghorn percs” were performed each week. These cases were very much team efforts; interventional radiologists created the initial access tract or tracts, and then the stone was addressed by a urologist. Decision making on subsequent maneuvers was collaborative.
Since 1986, in a single community hospital private practice setting, these methods have continued to serve well. Over the years, in a personal series of more than 500 cases, a few modifications have been made. Below are practical and technical points intended to help anyone starting out doing these procedures.[2] [3]
The team approach has proven successful and efficient in the author's community hospital setting, as it makes best use of the skill and time of the radiologist, urologist, and anesthesiologist, and also of the available equipment. Procedures are staged such that the access is created in the morning, in the Department of Radiology's Special Procedure suite. Conscious sedation is used for the access procedure. The patient is then returned to the outpatient surgery nursing unit until the afternoon, when he or she is taken to the operating room (OR), where general anesthesia is induced, the tract dilated, and the stone removed. Proceeding this way we take advantage of the superb fluoroscopy available in the Department of Radiology (as opposed to the mobile C-arms used in the ORs), and the urologist and anesthesiologist need not waste time while the percutaneous access is being obtained.
Funding
No financial support has been received.
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References
- 1 Miller RA. Role of endoscopic surgery in management of renal and ureteric calculi: a review. J R Soc Med 1985; 78 (12) 1034-1038
- 2 Preminger GM, Assimos DG, Lingeman JE, Nakada SY, Pearle MS, Wolf Jr JS ; AUA Nephrolithiasis Guideline Panel). Chapter 1: AUA guideline on management of staghorn calculi: diagnosis and treatment recommendations. J Urol 2005; 173 (6) 1991-2000
- 3 Vicentini FC, Gomes CM, Danilovic A, Neto EA, Mazzucchi E, Srougi M. Percutaneous nephrolithotomy: current concepts. Indian J Urol 2009; 25 (1) 4-10
- 4 Golijanin D, Katz R, Verstandig A, Sasson T, Landau EH, Meretyk S. The supracostal percutaneous nephrostomy for treatment of staghorn and complex kidney stones. J Endourol 1998; 12 (5) 403-405
- 5 Munver R, Delvecchio FC, Newman GE, Preminger GM. Critical analysis of supracostal access for percutaneous renal surgery. J Urol 2001; 166 (4) 1242-1246
- 6 Wong C, Leveillee RJ. Single upper-pole percutaneous access for treatment of > or = 5-cm complex branched staghorn calculi: is shockwave lithotripsy necessary?. J Endourol 2002; 16 (7) 477-481
- 7 Gupta R, Kumar A, Kapoor R, Srivastava A, Mandhani A. Prospective evaluation of safety and efficacy of the supracostal approach for percutaneous nephrolithotomy. BJU Int 2002; 90 (9) 809-813
- 8 Rais-Bahrami S, Friedlander JI, Duty BD, Okeke Z, Smith AD. Difficulties with access in percutaneous renal surgery. Ther Adv Urol 2011; 3 (2) 59-68
- 9 Labate G, Modi P, Timoney A , et al. The percutaneous nephrolithotomy global study: classification of complications. J Endourol 2011; 25 (8) 1275-1280
- 10 Song SH, Hong B, Park HK, Park T. Paradoxical air embolism during percutaneous nephrolithotomy: a case report. J Korean Med Sci 2007; 22 (6) 1071-1073
- 11 Springer III RM. Precise placement of tract anesthesia for percutaneous biliary drainage and nephrostomy. J Vasc Interv Radiol 2000; 11 (7) 938-939
- 12 Krambeck AE, Lingeman JE. Percutaneous management of caliceal diverticuli. J Endourol 2009; 23 (10) 1723-1729
- 13 Srivastava A, Chipde SS, Mandhani A, Kapoor R, Ansari MS. Percutaneous management of renal caliceal diverticular stones: Ten-year experience of a tertiary care center with different techniques to deal with diverticula after stone extraction. Indian J Urol 2013; 29 (4) 273-276
- 14 Shah HN, Hegde S, Shah JN, Mohile PD, Yuvaraja TB, Bansal MB. A prospective, randomized trial evaluating the safety and efficacy of fibrin sealant in tubeless percutaneous nephrolithotomy. J Urol 2006; 176 (6, Pt 1): 2488-2492, discussion 2492–2493
- 15 Nemoy NJ, Staney TA. Surgical, bacteriological, and biochemical management of “infection stones”. JAMA 1971; 215 (9) 1470-1476