ENDOUROLOGY AND STONE DISEASES Combined Use of Pyelolithotomy and Endoscopy: An Alternative Surgical Treatment for Staghorn Urolithiasis in Children Beata Jurkiewicz,1* Tomasz Ząbkowski,2 Katarzyna Jobs,3 Joanna Samotyjek,1 Anna Jung3 Purpose: To present a combining pyelolithotomy and endoscopy, an alternative approach for treating staghorn calculi in children. Materials and Methods: We treated 1414 children (age, 10 months to 17 years) with urolithiasis between 2009 and 2013 in the Pediatric Surgery Department and in the Pediatrics and Nephrology Department, Military Institute of Medicine in Warsaw. Most patients were treated conservatively. In 162 cases, an extracorporeal shockwave lithotripsy (SWL) procedure was needed. Surgery was only used in patients who had failed SWL. We performed minimally invasive procedures, ureterolithotripsy using semi-rigid and flexible ureterorenoscopes or percutaneous nephrolithotomy (PCNL) in 126 patients. Results: In the most serious cases of staghorn or multifocal calculi, we performed a combined operation of pye- lolithotomy with endoscopic removal of concrements from all calyces of the diseased kidney. In 15 out of the 18 combination treatments (83.3%), concrements were completely removed from the kidney in a single procedure. In three cases, fine concrements (5 to 6 mm) remained after the procedure, and these were candidate for SWL. In one case, a boy aged 4 years, symptoms of infection in the urinary tract occurred 2 days after the procedure. Conclusion: Combining pyelolithotomy with endoscopy to remove concrements clears the diseased kidney with- out causing parenchymal damage in one procedure. The method is safe in children, does not require blood transfu- sion, and helps maintain kidney function. Keywords: child; kidney calculi; surgery; treatment outcome; urologic surgical procedures. INTRODUCTION Urolithiasis is a well-known and widespread dis-ease. The prevalence in Europe is 5–10% in adults and approximately 2% in children. The number of new cases has increased over the past few years, especially in much younger patients, particularly those aged < 1 year.(1,2) The disease is chronic, and regression occurs within 15 years in 30 –50% of affected patients.(1,3) The management of cases with new concrement formation is especially very problematic. According to data from the medical literature, approximately 80% of concrement created in the urinary system can be excreted sponta- neously.(1,4) Such stones are typically 4–5 mm in diame- ter; however, in children, the spontaneous excretion of stones that are 9–10 mm of diameter is possible, pos- sibly as a result of the greater elasticity of the urinary tract.(2) The duration that the concrement is present in the same location is a factor that determines its passage; after 4 weeks, the probability of spontaneous excretion is low.(5) The procedure for active concrement remov- al may obstruct the flow of urine from the kidney and make an individual susceptible to infection, obstruction of urine outflow from only one kidney, urinary system defects, stymied urine outflow, and inefficient analge- sic treatment.(1) Therefore, the need for concrement re- moval using one of available method performs in about 25% of all group of patients and until in half of these patients with clinical symptoms.(1) The most severe form of urolithiasis is staghorn urolithiasis with meta- bolic disorders which results in concrements in urinary tracts. Typical stones include all calyces of the kidney and renal pelvis creating a typical ‘cast’ of tracts carry- ing urine from the kidney. The treatment of this type of urolithiasis is a challenge for a surgeon. The aim of the study was to present an alternative, ef- ficient method of concrement removal from the kidney 1Department of Pediatric Surgery, Children's Hospital, Marii Konopnickiej Street 65, 05-092 Dziekanów Lesny, Warsaw, Poland. 2Department of Urology, Military Medical Institute, Szaserów Street, 128,04-349 Warsaw, Poland. 3Department of Pediatric and Nephrology, Military Medical Institute, Szaserów Street, 128,04-349 Warsaw, Poland. *Correspondence: Department of Urology, Military Medical Institute, Szaserów Street 128,04-349, Warsaw, Poland. Tel:+48 791 533555. E-mail: urodent@wp.pl. Received September 2015 & Accepted March 2016 Endourology and Stone Diseases 2599 Vol 13 No 02 March-April 2016 2600 which is possible to use within staghorn urolithiasis in children. MATERIALS AND METHODS Study Population A total of 1414 patients aged 10 months to 17 years with urolithiasis were treated in the Pediatric Surgery Department and Pediatrics and Nephrology Department of the Military Institute of Medicine between 2009 and 2013. Of whom 1111 (78.57%) patients were treated conservatively. Procedures An extracorporeal shockwave lithotripsy (SWL) pro- cedure was needed in 162 (11.45%) cases. A total of 141 (9.97%) patients with different types of urolithiasis were treated using other surgical procedures. Surgical treatment was used only in the patients who were not suitable to undergo SWL procedure for many different reasons. In most of these patients, minimally invasive procedures (ureterolithotripsies) were performed using semi-rigid and flexible ureterorenoscopes (URS); per- cutaneous nephrolithotomy (PCNL) procedures were performed in 126 (17.82%) patients. In certain serious cases of staghorn or multifocal urolithiasis including re- nal pelvis and at least 3 calyces (most of concrements were from 11 mm to 50 mm), we performed a com- bination of pyelolithotomy and endoscopic removal of concrements from all calyces of each diseased kidney (Figures 1-4). Inclusion and Exclusion Criteria The inclusion criteria were: a lack of renal stones evac- uation using minimally invasive procedures, or concre- ments in major and distal calyces including renal pelvis. In 2009–2013, 15 (1.06%) patients aged 1.5–10 years (mean age, 6.7 years; 10 boys, 5 girls) with staghorn urolithiasis underwent pyelolithotomy with endoscopic concrement removal. There were 4 children aged under 2 years of life. Twelve of these patients had unilateral urolithiasis, whereas the other three had bilateral uro- lithiasis (Figure 2). Evaluations The dominant symptom of these patients was pain in the lumbar area. Recurrent urinary tract infections, uro- sepsis, and urinary retention were also common. Be- fore a decision on the surgical approach was made, the patients’ conditions were precisely evaluated and as- sessed to detect metabolic changes that may be related to the cause of the urolithiasis. The diagnoses included hyperoxaluria type I in three cases, cystinuria in four cases, and hypercalciuria in the remaining cases. The patients with cystinuria were initially qualified to con- servative treatment using Tiopronin and Captopril with urine alkalization by potassium citrate over 7.5 pH. The children with hyperoxaluria were given vitamin B6 with high fluid intake, the urine alkalization was also used. Unfortunately, this management did not protect the patients against the new concrements formation. The following basic examinations were performed in all patients: blood cell count, ionogram, urea and cre- atinine concentration test, urinalysis and urine culture, and assessment of urinary crystalloid excretion in urine collection samples. The presence of concrements within the urinary tract was assessed using ultrasonography. The radiological examinations included plain abdomi- nal radiography, urography, or computed tomography with contrast. Before the procedure, dynamic scintig- raphy was performed to determine the excretory and secretory function of the kidneys. The conducted history results that in the majority of Figure 1. The treatment’s methods used in children with urolithiasis (n =1414). Abbreviations: ESWL, extracorporeal shockwave lithotripsy; PCNL, percutaneous nephrolithotomy; URSL, ureterorenoscopy with lithotripsy. Combined Use of Pyelolithotomy and Endoscopy-Jurkiewicz et al. children the minimally invasive procedures were ear- lier performed. In 9 children, SWL procedures were repeatedly performed (from 2 to 5 times), in 3 cases PCNL was performed, in 4 cases retrograde intrarenal surgery (RIRS) was performed. In 4 children, different possibilities of minimally invasive treatment’s ways were used, from SWL procedures to URS lithotripsy (URSL), RIRS and PCNL. Unfortunately, these proce- dures were ineffective, and in the kidneys were still big concrements. The size of the concrements ranged from 11 mm to 3 -5 cm, and the concrements were numer- ous, varied in size, and were located in several calyces and in the pelvis. In 3 cases, staghorn urolithiasis was accompanied by hydronephrosis as well as obstruction of the urine outlet in the ureteropelvic junction. In the case of sub-pelvic stenosis, the stenosis was excised us- ing the Hynes-Anderson method and pyelotomy, during which the nephroscope was introduced into the kidney. After concrement removal, plastic reconstruction of the ureteropelvic junction was performed. The pyelolithotomy procedure with endoscopic concre- ment removal consisted of several stages. Stage 1: The kidney was accessed using lumbotomy and exposure of the renal pelvic and ureteropelvic junc- tion. The entire kidney was not released from concre- tions with surrounding tissues; instead, a slanted 1–1.5 cm long incision was made in the renal pelvis to expose the concrements (Figure 3). Stage 2: A staghorn concrement within the renal pel- vis was crushed by a pneumatic lithotripter Wolf and the fragments of the concrement were removed using forceps via a small perforation made in the renal pelvis (Figure 3). Stage 3: After the concrements were removed from the renal pelvis, their locations within the calyces were de- termined using a 9 French (F) nephroscope Wolf or 4.5 F ureteroscope (Figure 3). Stage 4: These concrements were then crushed in stages using a pneumatic, laser and ultrasound waves. The cal- yces were sequentially ‘cleaned’ until all of the concre- ments were removed from the diseased kidney. Stage 5: All calyces were assessed using a nephroscope, and the catheter pig -tail was placed from the renal pel- vis to the urinary bladder to ensure appropriate outflow from the kidney. The incisions made in the renal pelvis were closed by using a running suture. A drainage tube was left near the kidney. The integuments were closed lamellarly. After the procedure, the patients received second- gen- eration cephalosporin within 3 days. The pig-tail cath- eter was removed 10 days after the procedure with the patient receiving brief intravenous anesthesia. After the procedures, blood cell count, ionogram, creatinine con- centration test were performed. After the procedures, ultrasonography and plain abdominal radiography were repeated performed. These follow-up examinations were performed 1 week, 2 weeks, and 1 month after the procedure. In all children, renoscintigraphy was performed after 3 months to assess renal function after procedure. Statistical Analysis For the statistical analysis, the number of procedures was calculated for the retrospective (before the per- Figure 2. Bilateral cystine urolithiasis in boy aged 2.5 years of life. Figure 3. Stage 1: Pyelolithotomy and concrement’s removal from renal pelvis. Stage 2: Concrement’s removal from upper and interior calyces. Stage 3: Concrement’s removal from lower calyces. Combined Use of Pyelolithotomy and Endoscopy-Jurkiewicz et al. Endourology and Stone Diseases 2601 Vol 13 No 02 March-April 2016 2602 formance of this procedure) and prospective (after the performance of this procedure) phases of the study. Continuous variables were compared using the Wilcox- on rank-sum test. The number of procedures in resid- ual concrements was analyzed using a Kaplan-Meier survival function. Differences in continuous variables were expressed as mean difference (MD) with 95% confidence intervals (CI). RESULTS In 15 (83.3%) cases, the concrements were complete- ly removed from the kidney within a single procedure. The duration of procedures ranged from 90 to 300 minutes (mean, 160 minutes). In the other 3 (16.7%) cases, concrements of 5–6-mm in size remained after the procedure and required SWL. Symptoms of gener- ic infection in the urinary tract occurred in only 1 pa- tient, a 4-year-old boy, on the second day after proce- dure. Escherichia coli was detected during culture of a urine sample. Pharmacological therapy consisted of an aminoglycoside (amikacin) and a carbapenem (merope- nem). None of the patients required a blood transfusion because of blood loss within surgical procedure or after it. Follow-up after procedures ranged from 1 year to 5 years. At the same time, in all children, isotopic exam- inations of kidneys, creatinine concentration test and blood pressure were performed (Table). Renoscintigraphy revealed that the renal function had Figure 4. Intraoperative photos, the concrements in calyces of the kid- neys. No. Type of Urolithiasis 1 Day Before Procedure 3 Months after Procedure Urosepsis Procedures in Follow-up after Diagnosed in Creatinine Blood Pressure Creatinine Blood Pressure Residual Concrements Procedure (months) Metabolic Examinations (mg/dL) (mmHg) (mg/dL) (mmHg) 1 Hypercalciuria 0.22 94/60 0.2 90/60 (-) None 27 2 Cystinuria 0.3 103/69 0.3 110/70 (-) None 21 3 Hypercalciuria 0.32 95/60 0.42 110/65 (-) None 61 4 Hypercalciuria 0.49 120/75 0.47 117/70 (-) None 29 5 Hyperoxaluria 0.6 120/60 0.65 124/65 (-) None 62 6 Cystinuria 0.6 125/70 0.7 115/70 (-) None 50 Cystinuria 0.75 120/75 0.9 109/72 (-) SWL 22 7 Hyperoxaluria 0.3 90/60 0.22 92/60 E. coli None 29 8 Hyperoxaluria 0.7 90/60 0.5 100/65 (-) None 58 9 Cystinuria 0.5 124/82 0.6 122/80 (-) None 28 Cystinuria 0.92 108/65 0.79 127/75 (-) None 23 10 Hypercalciuria 0.39 92/64 0.3 90/60 (-) None 63 Hypercalciuria 0.39 94/60 0.36 97/60 (-) None 29 11 Hypercalciuria 0.8 127/70 0.77 125/72 (-) SWL 18 12 Hypercalciuria 0.23 90/63 0.26 92/63 (-) None 16 13 Hypercalciuria 0.5 109/70 0.6 100/60 (-) SWL 58 14 Hypercalciuria 0.6 115/78 0.5 115/82 (-) None 16 15 Cystinuria 0.31 110/65 0.34 110/70 (-) None 23 Abbreviation: SWL, extracorporeal shockwave lithotripsy. Table. Clinical characteristics of study patient. Combined Use of Pyelolithotomy and Endoscopy-Jurkiewicz et al. not worsened in any of the children 3 months after the procedure. In ultrasound examinations, it was not diag- nosed any concrements in the urinary tracts. All patients are under the care of nephrology clinic. DISCUSSION SWL is the most minimally invasive surgical procedure for urolithiasis at present.(6) However, the success rates of complete concrement removal within the first proce- dure are 70–94%.(7) Other minimally invasive methods for achieving concrement removal include URS and PCNL. Concrement within the ureters can be removed via lithotripsy using rigid, semi-rigid, and flexible uret- erorenoscopes.(8) However, in certain cases, concrement in the kidneys are removed using PCNL and mini-PC- NL in children; the diameter of the nephroscope is 15 F. RIRS is a recently established urological procedure that removes concrements from the kidney using a flex- ible ureterorenoscope and the Holmium:Yag laser.(9) All health centers treating urolithiasis in children aim to minimalize the extent of the surgical procedures and the risk related to surgical treatment.(10) Nevertheless, in certain clinical situations, unconventional treatment might be required. Despite being efficient and safe, minimally invasive methods have certain limitations, including early or late post-surgical complications. However, there is some group of patients, for whom open surgery is only one appropriate and safe proce- dure. According to El-Husseiny and Buchholz, despite the fact that open surgery is currently rarely used, it is still one of the treatment’s way of urolithiasis in adults and children.(11) The more complicated type of urolithi- asis with anatomical anomalies, the more recommended is the use of surgical techniques.(11) In the health centers in the world provided with the right equipment, having a big experience and a team of experts, about 1-5.4% of patients with urolithiasis are operated.(12) According to Sumit and colleagues, 10% of children treated opera- tively required open surgery.(13,14) In the most recent European Urology Association guidelines (2011) prepared by Knoll and Pearle regard- ing the treatment of children with urolithiasis, surgical procedures are allowed in certain cases, primarily those involving staghorn urolithiasis and children at a very young age.(12) In some health centers, all children un- der 1 year of life are operated and efficiency of proce- dures ranges from 90% to 100%.(15) Bartoletti and Cai described very precisely indications for open surgery in adults and they also highlighted the necessity to use minimally invasive methods as a treatment of choice in most cases.(16) Complex procedure: Pyelolithotomy combined with en- doscopic concrement removal is able to remove all con- crements from a diseased kidney within a single proce- dure, but without causing parenchymal damage. In this procedure, all defects of the upper urinary tract may be fixed, and the inhibition of urine flow from the kidney may be resolved.(17) This method is safe for children, does not involve blood transfusions, and facilitates the preservation of kidney function. The identification of disorders such as cystinuria is es- pecially important in cases of severe chronic kidney failure, as certain metabolic disorders may damage the renal parenchyma (especially hyperoxaluria type I), or cases with a very high frequency of new concrement formation (for example in cystinuria). In the literature there are descriptions of “combined” methods used in adults.(18,19) These methods combine open surgery with minimally invasive methods at the same time. Howev- er, a described method was not used in children so far. CONCLUSIONS Primary surgical treatment of urolithiasis is minimally invasive endoscopic treatment. However, in complicat- ed, select cases there is an opportunity to use surgical methods. Open surgery is required only for the urolithi- asis which is difficult to treat. The new presented com- bination of open surgery and endoscopic technique used in complicated cases of staghorn urolithiasis is a safe and effective method, and it can be an alternative to the traditional methods. CONFLICT OF INTEREST None declared. REFERENCES 1. Akimoto M, Higashihara E, Kumon H, Masaki Z, Orikasa S. Treatment of Urolithiasis. Germany: Springer-Verlag; 2001. p. 12-6. 2. Straub M, Gschwend J, Zorn C. Pediatric urolithiasis: the current surgical management. Pediatr Nephrol. 2010;25:1239-44. 3. Bastug F, Dusunsel R. Pediatric urolithiasis: causative factors, diagnosis and medical management. Nat Rev Urol. 2012;9:138-46. 4. Dincel N, Resorlu B, Unsal A, et al. Are small residual stone fragments really insignificant in children? J Pediatr Surg. 2013;48:840-4. 5. Hesse A, Tiselius HG, Jachnen A. Urinary stones. General Aspects. In: Hesse A, Tiselius HG, Jahnen A: Urinary stones. 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