Treatment of renal lower pole stones: an update

Mazzucchi, Eduardo; Berto, Fernanda C.G.; Denstedt, John; Danilovic, Alexandre; Batagello, Carlos Alfredo; Torricelli, Fabio C.M.; Vicentini, Fabio C.; Marchini, Giovanni S.; Srougi, Miguel; Nahas, William C.

doi:10.1590/S1677-5538.IBJU.2020.1023

INTRODUCTION

The prevalence of urinary lithiasis ranges from 8% to 19% in males and 3% to 5% in females in Western countries and varies greatly worldwide (¹1 Trinchieri A. Epidemiology of urolithiasis: an update. Clin Cases Miner Bone Metab. 2008; 5:101-6.). These numbers are rising particularly due to changes in lifestyle including a higher intake of animal protein and carbohydrates and less physical activity, leading to an increased prevalence of obesity and diabetes (¹1 Trinchieri A. Epidemiology of urolithiasis: an update. Clin Cases Miner Bone Metab. 2008; 5:101-6.

2 Taylor EN, Stampfer MJ, Curhan GC. Obesity, weight gain, and the risk of kidney stones. JAMA. 2005; 293:455-62.-³3 Stamatelou KK, Francis ME, Jones CA, Nyberg LM, Curhan GC. Time trends in reported prevalence of kidney stones in the United States: 1976-1994. Kidney Int. 2003; 63:1817-23.). These changes also reflect in the gender gap and stone composition (⁴4 Wang S, Zhang Y, Zhang X, Tang Y, Li J. Upper urinary tract stone compositions: the role of age and gender. Int Braz J Urol. 2020; 46:70-80.). Clinical symptoms, mainly renal pain, develop in approximately 50% of urinary stone patients and require intervention (⁵5 Burgher A, Beman M, Holtzman JL, Monga M. Progression of nephrolithiasis: long-term outcomes with observation of asymptomatic calculi. J Endourol. 2004; 18:534-9.). Additionally, 50% of the affected patients will experience a recurrence during their lifetime (⁶6 Bihl G, Meyers A. Recurrent renal stone disease-advances in pathogenesis and clinical management. Lancet. 2001; 358:651-6.). Lower pole stones (LPS) account for approximately 35% of renal calculi and may remain asymptomatic in many patients. On the other hand, treatment of such stones is challenging due to the difficulty in eliminating fragments and anatomical access to the inferior renal calyx (⁷7 Tiselius HG, Ackermann D, Alken P, Buck C, Conort P, Gallucci M: Working Party onLithiasis, European Association of Urology. Guidelines on urolithiasis. Eur Urol. 2006. [Internet]. Available at. <https://uroweb.org/guideline/urolithiasis/>
https://uroweb.org/guideline/urolithiasi... ). A great debate has arisen regarding the best management of LPS and many controversies still exist since large randomized studies are scarce in the literature. Some reviews and metanalysis have been published and made a significant contribution for a better understanding of this issue but, unfortunately, many of these reviews are based in heterogeneous and low-quality studies. Currently, the management of lower pole stones includes watchful waiting, extracorporeal lithotripsy (SWL), flexible ureterorenoscopy (FURS) and percutaneous nephrolithotripsy (PCNL) with its variations including mini, ultramini, micro and supermini PCNL. The success rates for each of these treatment modalities is related to stone burden and composition, patient’s body habitus and anatomy as well as the surgeon’s experience. The main differences among these modalities is related to their different degrees of invasiveness, anesthetic requirement, stone clearance, complications and costs (⁸8 McClinton S, Starr K, Thomas R, MacLennan G, Lam T, Hernandez R, et al. The clinical and cost effectiveness of surgical interventions for stones in the lower pole of the kidney: the percutaneous nephrolithotomy, flexible ureterorenoscopy and extracorporeal shockwave lithotripsy for lower pole kidney stones randomised controlled trial (PUrE RCT) protocol. Trials. 2020; 21:479.).

The aim of this article is to review the results of each of these treatment modalities according to the stone burden and patient’s characteristics in order to help urologists decide what is the optimal approach to manage lower pole stones in each patient.

MATERIALS AND METHODS

A PubMed database search was conducted in August-September 2020 using the following Medical Subject Heading (MeSH) terms in several combinations: lower pole, lower calyx, inferior calyx, renal stones, urinary stones, urinary lithiasis, renal anatomy, treatment, extracorporeal lithotripsy, flexible ureteroscopy, percutaneous nephrolithotripsy, costs. We included original articles published between 1990 and 2020, in English or Spanish languages. Studies involving children, review articles, and case reports were not included. Initially 152 articles were reviewed, 81 studies were not analyzed due to reasons shown in the flowchart, 71 articles were included in the final analysis. The flowchart of the study is shown in Figure-1.

Figure 1
Flowchart of the study.

We aimed to present, in a summarized way, the optimal treatment for lower pole calculi according to the stone burden, taking into consideration the stone-free rates, hospitalization and complications of each type of procedure.

Renal anatomy-The inferior calyx

The anatomy of the collecting system may influence the treatment outcome for kidney stones (⁹9 Sampaio FJ. Renal collecting system anatomy: its possible role in the effectiveness of renal stone treatment. Curr Opin Urol. 2001; 11:359-66.). Sampaio and Aragão, in 1992, described the lower pole spatial calyceal anatomy using an endocast and suggested that some anatomic features could impact fragment clearance (¹⁰10 Sampaio FJ, Aragao AH. Inferior pole collecting system anatomy: its probable role in extracorporeal shock wave lithotripsy. J Urol. 1992; 147:322-4.). Sampaio et al. showed that the angle between the calyx where the stone is located and the renal pelvis (infundibulopelvic angle) influences stone elimination (¹¹11 Sampaio FJ, D’Anunciação AL, Silva EC. Comparative follow-up of patients with acute and obtuse infundibulum-pelvic angle submitted to extracorporeal shockwave lithotripsy for lower caliceal stones: preliminary report and proposed study design. J Endourol. 1997; 11:157-61.). Among 146 endocasts obtained from 73 adult cadavers, 74% presented an obtuse infundibulopelvic angle in the lower pole, 60.3% had lower pole infundibula with diameters ≥4mm and 56.8% of the lower poles drained multiple calyces (¹²12 Sampaio FJ, Aragao AH. Limitations of extracorporeal shockwave lithotripsy for lower caliceal stones: anatomic insight. J Endourol. 1994; 8:241-7.). In a study published in 1997 (¹¹11 Sampaio FJ, D’Anunciação AL, Silva EC. Comparative follow-up of patients with acute and obtuse infundibulum-pelvic angle submitted to extracorporeal shockwave lithotripsy for lower caliceal stones: preliminary report and proposed study design. J Endourol. 1997; 11:157-61.), the authors described a technique to measure the infundibulopelvic angle. The first line (line I) links the central axis of the superior ureter with the central axis of the ureteropelvic junction and the second line (line II) follows the orientation of the main infundibulum in the lower calyx where the stone is located. The infundibulopelvic angle is measured between lines I and II. In another study with 74 patients submitted to SWL for LPS, 52 presented an infundibulopelvic angle >90° (obtuse) and 75% of them eliminated the fragments within 3 months while in patients with an infundibulopelvic angle <90° (acute) the clearance rate was 23% (¹²12 Sampaio FJ, Aragao AH. Limitations of extracorporeal shockwave lithotripsy for lower caliceal stones: anatomic insight. J Endourol. 1994; 8:241-7.). Although Elbahnasy et al. (¹³13 Elbahnasy AM, Shalhav AL, Hoenig DM, Elashry OM, Smith DS, McDougall EM, et al. Lower caliceal stone clearance after shock wave lithotripsy or ureteroscopy: the impact of lower pole radiographic anatomy. J Urol. 1998; 159:676-82.) used a slightly different method to measure the infundibulopelvic angle, in their cohort with 34 patients, significant larger infundibulopelvic angles were identified in stone-free patients following SWL (75 vs. 51 degrees, p=0.009). A retrospective study with 116 patients comparing five different anatomic characteristics, demonstrated that infundibulopelvic angle was the only significant factor to predict stone-free rates after SWL (34% in patients with an acute angle vs. 66% for obtuse angle, p=0.012) (¹⁴14 Keeley FX Jr, Moussa SA, Smith G, Tolley DA. Clearance of lower-pole stones following shock wave lithotripsy: effect of the infundibulopelvic angle. Eur Urol. 1999; 36:371-5.).

The infundibular length, measured from the bottom of the infundibulum to the lower lip of the renal pelvis (¹³13 Elbahnasy AM, Shalhav AL, Hoenig DM, Elashry OM, Smith DS, McDougall EM, et al. Lower caliceal stone clearance after shock wave lithotripsy or ureteroscopy: the impact of lower pole radiographic anatomy. J Urol. 1998; 159:676-82.), is also related to stone clearance. In a study with 13 patients who underwent ureteroscopy and 21 submitted to SWL, shorter infundibular lengths (≤3cm) were related to better stone clearance following SWL (¹³13 Elbahnasy AM, Shalhav AL, Hoenig DM, Elashry OM, Smith DS, McDougall EM, et al. Lower caliceal stone clearance after shock wave lithotripsy or ureteroscopy: the impact of lower pole radiographic anatomy. J Urol. 1998; 159:676-82.). Another study with 151 patients comparing SWL, PCNL and FURS also demonstrated higher SFR in patients submitted to SWL with an infundibular length <3cm (¹⁵15 Elbahnasy AM, Clayman RV, Shalhav AL, Hoenig DM, Chandhoke P, Lingeman JE, et al. Lower-pole caliceal stone clearance after shockwave lithotripsy, percutaneous nephrolithotomy, and flexible ureteroscopy: impact of radiographic spatial anatomy. J Endourol. 1998; 12:113-9.).

Narrow infundibula (<4mm) (¹⁰10 Sampaio FJ, Aragao AH. Inferior pole collecting system anatomy: its probable role in extracorporeal shock wave lithotripsy. J Urol. 1992; 147:322-4.) and complex lower pole calyceal anatomy are also related to lower SFR in several studies (¹1 Trinchieri A. Epidemiology of urolithiasis: an update. Clin Cases Miner Bone Metab. 2008; 5:101-6., ¹¹11 Sampaio FJ, D’Anunciação AL, Silva EC. Comparative follow-up of patients with acute and obtuse infundibulum-pelvic angle submitted to extracorporeal shockwave lithotripsy for lower caliceal stones: preliminary report and proposed study design. J Endourol. 1997; 11:157-61., ¹³13 Elbahnasy AM, Shalhav AL, Hoenig DM, Elashry OM, Smith DS, McDougall EM, et al. Lower caliceal stone clearance after shock wave lithotripsy or ureteroscopy: the impact of lower pole radiographic anatomy. J Urol. 1998; 159:676-82., ¹⁶16 Sabnis RB, Naik K, Patel SH, Desai MR, Bapat SD. Extracorporeal shock wave lithotripsy for lower calyceal stones: can clearance be predicted? Br J Urol. 1997; 80:853-7.) although another study with a large number of patients did not demonstrate significant difference in SFR when analyzing these specific characteristics (¹⁴14 Keeley FX Jr, Moussa SA, Smith G, Tolley DA. Clearance of lower-pole stones following shock wave lithotripsy: effect of the infundibulopelvic angle. Eur Urol. 1999; 36:371-5.). The presence of two or more favorable or unfavorable characteristics, though, was more significant than any isolate factor (¹⁵15 Elbahnasy AM, Clayman RV, Shalhav AL, Hoenig DM, Chandhoke P, Lingeman JE, et al. Lower-pole caliceal stone clearance after shockwave lithotripsy, percutaneous nephrolithotomy, and flexible ureteroscopy: impact of radiographic spatial anatomy. J Endourol. 1998; 12:113-9.).

An acute infundibulopelvic angle is related to a decreased stone clearance following treatment. Longer lower pole infundibulum length with narrow diameters and complex calyceal anatomy seem to be related to lower SFR in LPS.

General overview of the current available methods of LPS treatment

SWL is a non-invasive method of stone treatment introduced in 1980, performed under sedation and in an outpatient setting with a low complication rate (¹⁷17 Chaussy C, Schmiedt E, Jocham D, Brendel W, Forssmann B, Walther V. First clinical experience with extracorporeally induced destruction of kidney stones by shock waves. J Urol. 1982; 127:417-20.). The success of SWL is highly affected by:

Stone burden-the likelihood of success decreases for stones >20mm.
Stone composition-cystine, brushite and very soft stones (struvite) with a high amount of organic matrix (¹⁸18 Elmansy HE, Lingeman JE. Recent advances in lithotripsy technology and treatment strategies: A systematic review update. Int J Surg. 2016; 36(Pt D):676-80.).

When stone composition is unknown, stone density (as measured by Hounsfield units on CT) can predict stone fragility and response to SWL.

According to Joseph et al., the stone-free rate (SFR) for stones with less than 500HU, between 500-1000HU and more than 1000HU is 100%, 87.5% and 54.5%, respectively (¹⁹19 Joseph P, Mandal AK, Singh SK, Mandal P, Sankhwar SN, Sharma SK. Computerized tomography attenuation value of renal calculus: can it predict successful fragmentation of the calculus by extracorporeal shock wave lithotripsy? A preliminary study. J Urol. 2002; 167:1968-71.).

Stone location-LPS represent a challenge to SWL especially when the infundibulopelvic angle is acute; results are poorer when compared to stones located in the upper pole or renal pelvis. In the multicentric trial study Lower Pole I, conducted by Albala et al., postoperatively SFR at 3 months for LPS treated with SWL in comparison to PCNL was 95% for PCNL versus 37% for SWL (²⁰20 Albala DM, Assimos DG, Clayman RV, Denstedt JD, Grasso M, Gutierrez-Aceves J, et al. Lower pole I: a prospective randomized trial of extracorporeal shock wave lithotripsy and percutaneous nephrostolithotomy for lower pole nephrolithiasis-initial results. J Urol. 2001; 166:2072-80. Erratum in: J Urol 2002; 167:1805.).
Obesity-obese patients represent a challenge for SWL, first because there are weight limitations on the lithotripter table or gantry, the second challenge is positioning patients with high body mass index (BMI) to target the stone as the focal length of most lithotripters varies from 12-16cm (¹⁸18 Elmansy HE, Lingeman JE. Recent advances in lithotripsy technology and treatment strategies: A systematic review update. Int J Surg. 2016; 36(Pt D):676-80.), and third, the excess adipose tissue dampens energy from the shock wave as it travels to the focal point (²¹21 Pareek G, Armenakas NA, Panagopoulos G, Bruno JJ, Fracchia JA. Extracorporeal shock wave lithotripsy success based on body mass index and Hounsfield units. Urology. 2005; 65:33-6.).

FURS is a minimally invasive method that gained popularity among urologists due to its high success rates and low incidence of complications. The method is not affected by obesity and can be performed in anticoagulated patients or during pregnancy, under general or spinal anesthesia and in outpatient or short hospitalization settings. The major drawback of FURS is its costs; many disposables such as guide wires, baskets, access sheaths and laser fibers might be needed in a regular procedure, although they are not mandatory in all situations.

PCNL is the most efficient method in terms of stone-free rates but is also the one with the highest morbidity among all the above cited methods, and the complications include bleeding, lesion of adjacent organs and urinary extravasation. PCNL has passed through changes in recent years especially regarding miniaturization of the tracts and new sources of energy aiming the reduction of complications while maintaining the same SFR. Currently, miniperc (16-18/20Fr), ultramini perc (11-14Fr), the microperc (<10Fr) and other variations are described in the literature. Generally, miniaturized PCNL is indicated for stones <30mm. Kirac et al. published a comparison between miniperc and FURS for LPS <15mm and found 91% SFR for both methods with a shorter operative time but longer hospital stay for miniperc (²²22 Kirac M, Bozkurt ÖF, Tunc L, Guneri C, Unsal A, Biri H. Comparison of retrograde intrarenal surgery and mini-percutaneous nephrolithotomy in management of lower-pole renal stones with a diameter of smaller than 15mm. Urolithiasis. 2013; 41:241-6.).

Despite the known advantages and disadvantages of each method, controversies on the treatment of lower pole stones arise and many of them are still not resolved in the literature. Some of the advantages and disadvantages of each method are summarized in Table-1 (²³23 Moore SL, Bres-Niewada E, Cook P, Wells H, Somani BK. Optimal management of lower pole stones: the direction of future travel. Cent European J Urol. 2016; 69:274-9.).

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Table 1
Advantages and Disadvantages of methods for LPS treatment (modified from Moore SL et al.) (²³23 Moore SL, Bres-Niewada E, Cook P, Wells H, Somani BK. Optimal management of lower pole stones: the direction of future travel. Cent European J Urol. 2016; 69:274-9.).

Asymptomatic lower pole stones <10mm-active surveillance

The natural history of asymptomatic renal stones is controversial. Glowacki et al. (²⁴24 Glowacki LS, Beecroft ML, Cook RJ, Pahl D, Churchill DN. The natural history of asymptomatic urolithiasis. J Urol. 1992; 147:319-21.) evaluated the outcome of asymptomatic calyceal stones and estimated the risk of a symptomatic stone episode or need for intervention to be approximately 10% per year with a cumulative 5-year event probability of 48.5%. Inci et al., in a prospective study evaluating the outcome of asymptomatic lower pole stones, reported 33% disease progression (defined as pain experienced during follow-up, stone growth or need for intervention) and 11% intervention rates during a 52-month follow-up period (²⁵25 Inci K, Sahin A, Islamoglu E, Eren MT, Bakkaloglu M, Ozen H. Prospective long-term followup of patients with asymptomatic lower pole caliceal stones. J Urol. 2007; 177:2189-92.). Koh et al. reported overall incidences of spontaneous stone passage, progression and intervention for asymptomatic calyceal stones of 20%, 45.9% and 7.1%, respectively (²⁶26 Koh LT, Ng FC, Ng KK. Outcomes of long-term follow-up of patients with conservative management of asymptomatic renal calculi. BJU Int. 2012; 109:622-5.). Based on the current literature, the American Urological Association (AUA) recommends watchful waiting as a valid option for asymptomatic lower pole stones (²⁷27 Assimos D, Krambeck A, Miller NL, Monga M, Murad MH, Nelson CP, et al. Surgical Management of Stones: American Urological Association/Endourological Society Guideline, PART II. J Urol. 2016; 196:1161-9., ²⁸28 Assimos D, Krambeck A, Miller NL, Monga M, Murad MH, Nelson CP, et al. Surgical Management of Stones: American Urological Association/Endourological Society Guideline, PART I. J Urol. 2016; 196:1153-60.). The European Association of Urology (EAU) extends this recommendation to patients with lower pole stones up to 15mm (²⁹29 Türk C, Neisius A, Petrik A, Seitz C, Skolarikos A, Thomas K et al.: EAU Guidelines on Urolithiasis. Eur Urol. 2020. [Internet]. Available at. <http://uroweb.org/guidelines/compilations-of-all-guidelines/>
http://uroweb.org/guidelines/compilation... ). The exceptions to these recommendations are patients with a solitary kidney, those with poor access to medical assistance, airline pilots and military personnel. Additionally, treatment should be recommended if urinary infection develops (²⁷27 Assimos D, Krambeck A, Miller NL, Monga M, Murad MH, Nelson CP, et al. Surgical Management of Stones: American Urological Association/Endourological Society Guideline, PART II. J Urol. 2016; 196:1161-9., ²⁸28 Assimos D, Krambeck A, Miller NL, Monga M, Murad MH, Nelson CP, et al. Surgical Management of Stones: American Urological Association/Endourological Society Guideline, PART I. J Urol. 2016; 196:1153-60.).

In patients under active surveillance for asymptomatic stones, imaging studies are highly recommended every six or 12 months in order to assess stone growth, hydrocalyx or the formation of new calculi (³⁰30 Pearle MS, Goldfarb DS, Assimos DG, Curhan G, Denu-Ciocca CJ, Matlaga BR, et al. Medical management of kidney stones: AUA guideline. J Urol. 2014; 192:316-24.).

Interventional treatment of lower pole stones <10mm

There are two main treatment modalities for stones <10mm located in the lower pole: SWL and FURS. PCNL is considered a second line treatment.

Extracorporeal shockwave lithotripsy is a good choice for small caliceal stones due to its noninvasive nature. SWL is more acceptable by patients when compared to FURS (³¹31 Pearle MS, Lingeman JE, Leveillee R, Kuo R, Preminger GM, Nadler RB, et al. Prospective, randomized trial comparing shock wave lithotripsy and ureteroscopy for lower pole caliceal calculi 1 cm or less. J Urol. 2005; 173:2005-9.). Results depend greatly on stone characteristics, especially stone burden and density, body habitus and on renal anatomy, including infundibulum-pelvic angle, length and diameter of the infundibulum. Torricelli et al. reported overall fragmentation, success and stone-free rates of 76%, 54% and 37%, respectively in a prospective study with non-contrast CT performed 90 days after the procedure (³²32 Torricelli FC, Marchini GS, Yamauchi FI, Danilovic A, Vicentini FC, Srougi M, et al. Impact of renal anatomy on shock wave lithotripsy outcomes for lower pole kidney stones: results of a prospective multifactorial analysis controlled by computerized tomography. J Urol. 2015; 193:2002-7.). The authors reported better results for patients with BMI <30kg/m2, stones ≤10mm, stone density <900HU and an infundibular length of 25mm or less. Hoag et al. reported a success rate of 57% (residual fragments less than 3mm) after SWL for LPS <10mm (³³33 Hoag CC, Taylor WN, Rowley VA. The efficacy of the Dornier Doli S lithotripter for renal stones. Can J Urol. 2006; 13:3358-63.). Similarly, in the 3-month follow-up, Pearle et al. reported a stone-free rate of 35% for a single-session SWL and 50% for FURS. The operative time was shorter for SWL when compared to FURS (66 minutes x 90 minutes). Minor intra and post-operative complications were 25% for SWL and 40% for FURS. Patients submitted to SWL reported better quality of life when compared to FURS (³¹31 Pearle MS, Lingeman JE, Leveillee R, Kuo R, Preminger GM, Nadler RB, et al. Prospective, randomized trial comparing shock wave lithotripsy and ureteroscopy for lower pole caliceal calculi 1 cm or less. J Urol. 2005; 173:2005-9.). The influence of lower pole anatomy on fragment clearance and better SFR after SWL is controversial: Elbhanasy et al., reported in 1998 that a wide infundibulopelvic angle or short infundibular length and broad infundibular width are significant favorable factors for stone clearance following ESWL (¹³13 Elbahnasy AM, Shalhav AL, Hoenig DM, Elashry OM, Smith DS, McDougall EM, et al. Lower caliceal stone clearance after shock wave lithotripsy or ureteroscopy: the impact of lower pole radiographic anatomy. J Urol. 1998; 159:676-82.). Sener et al. reported 91.5% success (residual fragments <3mm) for SWL and 100% for FURS in a prospective study where results were checked with KUB+ultrasound performed three months after procedure, but patients treated by SWL needed a mean of 2.7 procedures to achieve these results (³⁴34 Sener NC, Imamoglu MA, Bas O, Ozturk U, Goktug HN, Tuygun C, et al. Prospective randomized trial comparing shock wave lithotripsy and flexible ureterorenoscopy for lower pole stones smaller than 1 cm. Urolithiasis. 2014; 42:127-31.). The stone-free rate for FURS reported by Orywall et al. was 89% in the first post-operative day, evaluation was performed by KUB+ultrasound (³⁵35 Orywal AK, Knipper AS, Tiburtius C, Gross AJ, Netsch C. Temporal Trends and Treatment Outcomes of Flexible Ureteroscopy for Lower Pole Stones in a Tertiary Referral Stone Center. J Endourol. 2015; 29:1371-8.), similar to the results obtained by Jessen and colleagues with a SFR of 88.3% in 111 patients with a total mean stone size of 7.47±3.95mm (³⁶36 Jessen JP, Honeck P, Knoll T, Wendt-Nordahl G. Flexible ureterorenoscopy for lower pole stones: influence of the collecting system’s anatomy. J Endourol. 2014; 28:146-51.), and Perlmutter et al. who reported a SFR of 90.9% in 44 patients with LPS of median 6.89mm (³⁷37 Perlmutter AE, Talug C, Tarry WF, Zaslau S, Mohseni H, Kandzari SJ. Impact of stone location on success rates of endoscopic lithotripsy for nephrolithiasis. Urology. 2008; 71:214-7.).

Treatment of lower pole stones 10-20mm

Patients with medium sized LPS, between 10 and 20mm, can be treated with SWL, FURS and PCNL, especially in its variants including miniperc, ultraminiperc, super mini PCNL, and microperc. Miniperc refers to all percutaneous surgeries performed with a tract that has a diameter smaller than 20Fr. This way, there are variants like mini-perc (16-20Fr), ultra-mini perc (12-14Fr), super-mini perc (12Fr) and micro-perc (4.8Fr-All-seeing-needle^®). There are no studies comparing these modalities in the treatment of LPS.

SWL stone-free rates are more influenced by stone burden and composition and by patient’s body habitus, overall obesity as well as renal anatomy as previously stated (³⁸38 Torricelli FCM, Monga M, Yamauchi FI, Marchini GS, Danilovic A, Vicentini FC, et al. Renal Stone Features Are More Important Than Renal Anatomy to Predict Shock Wave Lithotripsy Outcomes: Results from a Prospective Study with CT Follow-Up. J Endourol. 2020; 34:63-7.). Many studies comparing the results of SWL, FURS and PCNL have been published and some of them are summarized in Table-2 (³⁹39 Bozkurt OF, Resorlu B, Yildiz Y, Can CE, Unsal A. Retrograde intrarenal surgery versus percutaneous nephrolithotomy in the management of lower-pole renal stones with a diameter of 15 to 20mm. J Endourol. 2011; 25:1131-5.

40 El-Nahas AR, Ibrahim HM, Youssef RF, Sheir KZ. Flexible ureterorenoscopy versus extracorporeal shock wave lithotripsy for treatment of lower pole stones of 10-20mm. BJU Int. 2012; 110:898-902.

41 Kumar A, Vasudeva P, Nanda B, Kumar N, Das MK, Jha SK. A Prospective Randomized Comparison Between Shock Wave Lithotripsy and Flexible Ureterorenoscopy for Lower Caliceal Stones ≤2 cm: A Single-Center Experience. J Endourol. 2015; 29:575-9.

42 Vilches RM, Aliaga A, Reyes D, Sepulveda F, Mercado A, Moya F, et al. Comparison between retrograde intrarenal surgery and extracorporeal shock wave lithotripsy in the treatment of lower pole kidney stones up to 15 mm. Prospective, randomized study. Actas Urol Esp. 2015; 39:236-42.

43 Kumar A, Kumar N, Vasudeva P, Kumar Jha S, Kumar R, Singh H. A prospective, randomized comparison of shock wave lithotripsy, retrograde intrarenal surgery and miniperc for treatment of 1 to 2 cm radiolucent lower calyceal renal calculi: a single center experience. J Urol. 2015; 193:160-4.

44 Chan LH, Good DW, Laing K, Phipps S, Thomas BG, Keanie JY, et al. Primary SWL Is an Efficient and Cost-Effective Treatment for Lower Pole Renal Stones Between 10 and 20 mm in Size: A Large Single Center Study. J Endourol. 2017; 31:510-6.

45 Zeng G, Zhang T, Agrawal M, He X, Zhang W, Xiao K, et al. Super-mini percutaneous nephrolithotomy (SMP) vs retrograde intrarenal surgery for the treatment of 1-2 cm lower-pole renal calculi: an international multicentre randomised controlled trial. BJU Int. 2018; 122:1034-40.

46 Ozgor F, Sahan M, Yanaral F, Savun M, Sarilar O. Flexible ureterorenoscopy is associated with less stone recurrence rates over Shockwave lithotripsy in the management of 10-20 millimeter lower pole renal stone: medium follow-up results. Int Braz J Urol. 2018; 44:314-22.-⁴⁷47 Jin L, Yang B, Zhou Z, Li N. Comparative Efficacy on Flexible Ureteroscopy Lithotripsy and Miniaturized Percutaneous Nephrolithotomy for the Treatment of Medium-Sized Lower-Pole Renal Calculi. J Endourol. 2019; 33:914-9.).

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Table 2
Stone-free rates for LPS 10-20 mm at two or three months after treatment.

Stone-free rates, which means the complete absence of residual fragments, are higher for patients submitted to PCNL (and its variations) and FURS when compared to SWL in most of the studies. Regarding micro-perc, the reported stone-free rate is 85% but there is only one retrospective article published on this modality of treatment for lower-pole stones (⁴⁸48 Tepeler A, Armagan A, Sancaktutar AA, Silay MS, Penbegul N, Akman T, et al. The role of microperc in the treatment of symptomatic lower pole renal calculi. J Endourol. 2013; 27:13-8.).

The re-treatment rate (63.4% vs. 2.1% and 2.2%, p <0.001) and the need for auxiliary procedures (20.2% vs. 8.8% and 6.6%, p <0.02) are significantly higher for patients submitted to SWL when compared to those treated with FURS or miniperc (⁴³43 Kumar A, Kumar N, Vasudeva P, Kumar Jha S, Kumar R, Singh H. A prospective, randomized comparison of shock wave lithotripsy, retrograde intrarenal surgery and miniperc for treatment of 1 to 2 cm radiolucent lower calyceal renal calculi: a single center experience. J Urol. 2015; 193:160-4.). The mean number of SWL sessions required to reach good results is 2.8 (⁴⁶46 Ozgor F, Sahan M, Yanaral F, Savun M, Sarilar O. Flexible ureterorenoscopy is associated with less stone recurrence rates over Shockwave lithotripsy in the management of 10-20 millimeter lower pole renal stone: medium follow-up results. Int Braz J Urol. 2018; 44:314-22.).

Operative time ranges from 26 to 49 minutes for SWL, 39 to 52 minutes for FURS and 60 minutes for PCNL with no significant differences among the three modalities (⁴¹41 Kumar A, Vasudeva P, Nanda B, Kumar N, Das MK, Jha SK. A Prospective Randomized Comparison Between Shock Wave Lithotripsy and Flexible Ureterorenoscopy for Lower Caliceal Stones ≤2 cm: A Single-Center Experience. J Endourol. 2015; 29:575-9.). Although in a study including stones in different renal locations, supine miniperc presented shorter operative and fluoroscopy times compared to procedures performed in prone position (58.1±45.9 vs. 80.1±40.0 min, p=0.025 and 3.0±1.7 vs. 4.9±4.5 min, p=0.01, respectively) (⁴⁹49 Ozdemir H, Erbin A, Sahan M, Savun M, Cubuk A, Yazici O, et al. Comparison of supine and prone miniaturized percutaneous nephrolithotomy in the treatment of lower pole, middle pole and renal pelvic stones: A matched pair analysis. Int Braz J Urol. 2019; 45:956-64.).

Mean hospital stay ranged between 2.1 and 3.1 hours for SWL, 21.1 and 31.1 hours for FURS and 74.4 hours for miniperc (⁴³43 Kumar A, Kumar N, Vasudeva P, Kumar Jha S, Kumar R, Singh H. A prospective, randomized comparison of shock wave lithotripsy, retrograde intrarenal surgery and miniperc for treatment of 1 to 2 cm radiolucent lower calyceal renal calculi: a single center experience. J Urol. 2015; 193:160-4., ⁵⁰50 Soliman T, Sherif H, Sebaey A, Mohey A, Elmohamady BN. Miniperc vs Shockwave Lithotripsy for Average-Sized, Radiopaque Lower Pole Calculi: A Prospective Randomized Study. J Endourol. 2016. Online ahead of print.).

One of the advantages of FURS, is the possibility of treating patients submitted to anticoagulation therapy and during pregnancy. Also, there is no influence of obesity on its results. For stones with >15mm, though, fatigue could impact in the results and Hui et al. suggests that this can be minimized by a two-shift operation which also would increase the clearance rates (⁵¹51 Hui S, Qingya Y, Xinbao Y, Ming L, Gonghui L, Jun C. Two-shift operation mode can improve the efficiency and comfort of flexible ureteroscopic holmium laser lithotripsy for the treatment of renal calculi larger than 1.5cm. Int Braz J Urol. 2019; 45:1161-6.).

Complications of these procedures are, in general, minor, and are classified as grades 1, 2 or 3 (6%, 12% and 5% respectively) by the Clavien-Dindo modified classification (⁵²52 Dindo D, Demartines N, Clavien PA. Classification of surgical complications: a new proposal with evaluation in a cohort of 6336 patients and results of a survey. Ann Surg. 2004; 240:205-13.). The most common complications are pain, gross hematuria, fever, urinary tract infection and sepsis. Urinary tract infection and gross hematuria are more frequent in patients submitted to mini PCNL (⁴³43 Kumar A, Kumar N, Vasudeva P, Kumar Jha S, Kumar R, Singh H. A prospective, randomized comparison of shock wave lithotripsy, retrograde intrarenal surgery and miniperc for treatment of 1 to 2 cm radiolucent lower calyceal renal calculi: a single center experience. J Urol. 2015; 193:160-4.) and pain is more frequent in those treated by SWL (⁴¹41 Kumar A, Vasudeva P, Nanda B, Kumar N, Das MK, Jha SK. A Prospective Randomized Comparison Between Shock Wave Lithotripsy and Flexible Ureterorenoscopy for Lower Caliceal Stones ≤2 cm: A Single-Center Experience. J Endourol. 2015; 29:575-9.). Steinstrasse after SWL is reported to occur in 4% of patients with stones less than 20mm, rising to 5-10% for stones >20mm (⁵³53 Bierkens AF, Hendrikx AJ, Lemmens WA, Debruyne FM. Extracorporeal shock wave lithotripsy for large renal calculi: the role of ureteral stents. A randomized trial. J Urol. 1991; 145:699-702.). Sepsis is the most serious complication and occurs between 0.9% and 5% of the cases (⁴⁷47 Jin L, Yang B, Zhou Z, Li N. Comparative Efficacy on Flexible Ureteroscopy Lithotripsy and Miniaturized Percutaneous Nephrolithotomy for the Treatment of Medium-Sized Lower-Pole Renal Calculi. J Endourol. 2019; 33:914-9.). Severe complications like ureteral avulsion, arteriovenous fistulae and severe kidney injuries have been described after FURS but are rare (⁵⁴54 Cindolo L, Castellan P, Primiceri G, Hoznek A, Cracco CM, Scoffone CM, et al. Life-threatening complications after ureteroscopy for urinary stones: survey and systematic literature review. Minerva Urol Nefrol. 2017; 69:421-31.). Complications are higher for miniperc when compared to SWL and FURS but not significantly (⁴³43 Kumar A, Kumar N, Vasudeva P, Kumar Jha S, Kumar R, Singh H. A prospective, randomized comparison of shock wave lithotripsy, retrograde intrarenal surgery and miniperc for treatment of 1 to 2 cm radiolucent lower calyceal renal calculi: a single center experience. J Urol. 2015; 193:160-4., ⁴⁴44 Chan LH, Good DW, Laing K, Phipps S, Thomas BG, Keanie JY, et al. Primary SWL Is an Efficient and Cost-Effective Treatment for Lower Pole Renal Stones Between 10 and 20 mm in Size: A Large Single Center Study. J Endourol. 2017; 31:510-6.).

Transfusion is rarely needed in patients submitted to SWL or FURS, but for patients treated by miniperc, the rate is around 4% (⁵⁰50 Soliman T, Sherif H, Sebaey A, Mohey A, Elmohamady BN. Miniperc vs Shockwave Lithotripsy for Average-Sized, Radiopaque Lower Pole Calculi: A Prospective Randomized Study. J Endourol. 2016. Online ahead of print.). Mortality is low in FURS and six cases have been described in the literature until 2016, four of them due to sepsis, one due to hemorrhagic complications and another one because of anesthetic complications. In three of the four cases of sepsis, non-treated UTI was present before surgery (⁵⁵55 Cindolo L, Castellan P, Scoffone CM, Cracco CM, Celia A, Paccaduscio A, et al. Mortality and flexible ureteroscopy: analysis of six cases. World J Urol. 2016; 34:305-10.). The mortality rate among patients submitted to PCNL is reported to be 0.03% generally due to sepsis and hemorrhage (⁵⁶56 de la Rosette J, Assimos D, Desai M, Gutierrez J, Lingeman J, Scarpa R, et al. The Clinical Research Office of the Endourological Society Percutaneous Nephrolithotomy Global Study: indications, complications, and outcomes in 5803 patients. J Endourol. 2011; 25:11-7.).

In the author’s view, choosing between FURS and miniperc for the treatment of 10-20mm LPS will depend on several factors including stone burden, patient’s body habitus, clinical condition and expectations, type of equipment the surgeon has access to (laser, scopes, fibers, etc.) and his expertise in one or the other method.

Repositioning of LPS

The technique of lower calyx displacement to an upper or medium calyx where the access is easier was first described by Kourambas and colleagues (⁵⁷57 Kourambas J, Delvecchio FC, Munver R, Preminger GM. Nitinol stone retrieval-assisted ureteroscopic management of lower pole renal calculi. Urology. 2000; 56:935-9.) and more details were discussed by Auge et al. in 2001 (⁵⁸58 Auge BK, Dahm P, Wu NZ, Preminger GM. Ureteroscopic management of lower-pole renal calculi: technique of calculus displacement. J Endourol. 2001; 15:835-8.). The aim of this maneuver is to improve stone-free rate and reduce ureteroscope damage. Schuster et al. reported an improvement in the success rate for LPS 10-20mm from 29% to 100% in cases where repositioning was used (⁵⁹59 Schuster TG, Hollenbeck BK, Faerber GJ, Wolf JS Jr. Ureteroscopic treatment of lower pole calculi: comparison of lithotripsy in situ and after displacement. J Urol. 2002; 168:43-5.). There are still controversies on this issue once the literature is scarce with small numbers of studied cases, but a recent survey showed that 56% of urologists reposition lower pole stones during flexible ureteroscopy (⁶⁰60 Dauw CA, Simeon L, Alruwaily AF, Sanguedolce F, Hollingsworth JM, Roberts WW, et al. Contemporary Practice Patterns of Flexible Ureteroscopy for Treating Renal Stones: Results of a Worldwide Survey. J Endourol. 2015; 29:1221-30.).

Influence of scope type on results of FURS for lower-pole stones

With the advent of digital flexible ureteroscopes and, more recently, single-use digital scopes, a question arises: do these new devices improve results and reduce complications of lower-pole stone treatment? One study compared prospectively the Polyscope^®, a first generation single-use flexible ureteroscope with the Olympus P5^®, a re-usable optical flexible scope. The single session SFR, for lower calyceal stones, was significantly better for URF-P5^®than Polyscope^® (82.0% vs. 69.2%, p=0.022) and the complication rate presented no difference (15.3% vs. 15%, p=0.3) (⁶¹61 Ding J, Xu D, Cao Q, Huang T, Zhu Y, Huang K, et al. Comparing the Efficacy of a Multimodular Flexible Ureteroscope With Its Conventional Counterpart in the Management of Renal Stones. Urology. 2015; 86:224-9.). A more recent study compared the Olympus P6^®, a last generation re-usable fiberoptic scope with the Lithovue^®, a first-generation single-use digital scope and reported a lower complication rate for the single-use scope (5.4% vs. 18.0%, p <0.05) (⁶²62 Usawachintachit M, Isaacson DS, Taguchi K, Tzou DT, Hsi RS, Sherer BA, et al. A Prospective Case-Control Study Comparing LithoVue, a Single-Use, Flexible Disposable Ureteroscope, with Flexible, Reusable Fiber-Optic Ureteroscopes. J Endourol. 2017; 31:468-75.). In another study, not addressed for LPS only, but for stones located in all calyces, there was no difference in SFR and complications when comparing the Lithovue^® with the Storz Flex X2S^® (last generation fiberoptic) and the Flex XC^® (digital) (⁶³63 Mager R, Kurosch M, Höfner T, Frees S, Haferkamp A, Neisius A. Clinical outcomes and costs of reusable and single-use flexible ureterorenoscopes: a prospective cohort study. Urolithiasis. 2018; 46:587-93.).

Although a definite study proving the advantage of one type of flexible ureteroscope for treatment of stones located in the lower pole still does not exist, studies have been published showing that there is a correlation between the technical difficulty of the procedure, like treating lower-pole stones with a very acute infundibulo-pelvic angle, and a higher incidence of ureteroscope malfunction (⁶⁴64 White MD, Moran ME: Fatigability of the latest generation ureteropyeloscopes: Richard Wolf vs. Karl Storz [abstract]. J Endourol. 1998;12:S182.). The combination of aggressive active deflection of the flexible ureteroscope and simultaneous passage of the holmium laser probe may stress the fiberoptic system and result in fiber breakage (⁶⁵65 Marchini GS, Torricelli FC, Batagello CA, Monga M, Vicentini FC, Danilovic A, et al. A comprehensive literature-based equation to compare cost-effectiveness of a flexible ureteroscopy program with single-use versus reusable devices. Int Braz J Urol. 2019; 45:658-70.). Ozimek et al. evaluated the occurrence of damage in reusable flexible ureterorenoscopes and found that in 32 of 423 (7.5%) cases the scopes were defective after the procedures. Thirty-one of 32 cases (96.86%) with proven scope damage were related to exploration of the lower pole and in 20 of 23 cases (86.96%) it was for stone treatment in that location (⁶⁶66 Ozimek T, Schneider MH, Hupe MC, Wiessmeyer JR, Cordes J, Chlosta PL, et al. Retrospective Cost Analysis of a Single-Center Reusable Flexible Ureterorenoscopy Program: A Comparative Cost Simulation of Disposable fURS as an Alternative. J Endourol. 2017; 31:1226-30.).

Treatment of lower pole stones >20mm

Traditionally PCNL has been the most effective method for stones larger than 2cm. According to Pardalidis et al., a 98% SFR was observed after a single session treatment in 48 patients with LPS >2cm, using the conventional 26Fr rigid nephroscope. The mean hospital stay was 2.3 days. Fever was the most common complication, occurring in 6.9% of patients and no cases of hemorrhage were reported (⁶⁷67 Pardalidis NP, Andriopoulos NA, Sountoulidis P, Kosmaoglou EV. Should percutaneous nephrolithotripsy be considered the primary therapy for lower pole stones? J Endourol. 2010; 24:219-22.). New technologies, such as 3D printing have been recently described to facilitate the percutaneous access and reduce operative time, complications (⁶⁸68 Bianchi L, Schiavina R, Barbaresi U, Angiolini A, Pultrone CV, Manferrari F, et al. 3D Reconstruction and physical renal model to improve percutaneous punture during PNL. Int Braz J Urol. 2019; 45:1281-2.), and fluoroscopy time (⁶⁹69 Ozbir S, Atalay HA, Canat HL, Culha MG, Cakır SS, Can O, et al. Factors affecting fluoroscopy time during percutaneous nephrolithotomy: Impact of stone volume distribution in renal collecting system. Int Braz J Urol. 2019; 45:1153-60.). Microperc, a miniaturized version of the PCNL which uses a 4.8Fr “All-seeing needle^®” coupled to an 8Fr microsheath and a 360 micron fiber laser, has been used by some authors for treating LPS up to 29mm with a 85% SFR in the post-operative day30 CT scan (⁴⁸48 Tepeler A, Armagan A, Sancaktutar AA, Silay MS, Penbegul N, Akman T, et al. The role of microperc in the treatment of symptomatic lower pole renal calculi. J Endourol. 2013; 27:13-8.). Flexible ureteroscopy has been used as an alternative method for treating LPS >2cm. A SFR of 93.3% was reported in a study with 15 patients and stones 20-25mm not only located in the lower calyx. However, the mean number of sessions needed to reach these results was 2.3, ranging from two to four (⁷⁰70 Breda A, Ogunyemi O, Leppert JT, Lam JS, Schulam PG. Flexible ureteroscopy and laser lithotripsy for single intrarenal stones 2 cm or greater--is this the new frontier? J Urol. 2008; 179:981-4.). In another study, Takazawa et al. reported a 100% SFR (considering residual fragments <4mm) after a mean of 1.4 sessions per patient (range 2-4). No intra-operative complications occurred and fever was the only complication observed in three of the 20 studied patients (15%) (⁷¹71 Takazawa R, Kitayama S, Tsujii T. Successful outcome of flexible ureteroscopy with holmium laser lithotripsy for renal stones 2 cm or greater. Int J Urol. 2012; 19:264-7.). SWL is not recommended for treatment of lower pole stones >2cm according to the AUA and EAU guidelines (²⁷27 Assimos D, Krambeck A, Miller NL, Monga M, Murad MH, Nelson CP, et al. Surgical Management of Stones: American Urological Association/Endourological Society Guideline, PART II. J Urol. 2016; 196:1161-9.

28 Assimos D, Krambeck A, Miller NL, Monga M, Murad MH, Nelson CP, et al. Surgical Management of Stones: American Urological Association/Endourological Society Guideline, PART I. J Urol. 2016; 196:1153-60.-²⁹29 Türk C, Neisius A, Petrik A, Seitz C, Skolarikos A, Thomas K et al.: EAU Guidelines on Urolithiasis. Eur Urol. 2020. [Internet]. Available at. <http://uroweb.org/guidelines/compilations-of-all-guidelines/>
http://uroweb.org/guidelines/compilation... ).

CONCLUSIONS

Watchful waiting is recommended for asymptomatic LPS <10mm, except in cases of solitary kidneys and in other particular situations. SWL and FURS are both good options for symptomatic LPS <10mm, FURS has advantages in obese, pregnant and anticoagulated patients. For treating LPS 10 to 20mm, FURS has currently the best cost-benefit, but Miniperc has a higher SFR although with a higher morbidity. Repositioning LPS to a more favorable calyx probably improve results and decreases endoscope damage but more studies are needed. Single-use ureteroscopes are probably recommended for LPS located in calices with a very acute infundibulum-pelvic angle where the chance of endoscope damage is higher. PCNL is the best treatment modality for stones >20mm.

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Hui S, Qingya Y, Xinbao Y, Ming L, Gonghui L, Jun C. Two-shift operation mode can improve the efficiency and comfort of flexible ureteroscopic holmium laser lithotripsy for the treatment of renal calculi larger than 1.5cm. Int Braz J Urol. 2019; 45:1161-6.
⁵²
Dindo D, Demartines N, Clavien PA. Classification of surgical complications: a new proposal with evaluation in a cohort of 6336 patients and results of a survey. Ann Surg. 2004; 240:205-13.
⁵³
Bierkens AF, Hendrikx AJ, Lemmens WA, Debruyne FM. Extracorporeal shock wave lithotripsy for large renal calculi: the role of ureteral stents. A randomized trial. J Urol. 1991; 145:699-702.
⁵⁴
Cindolo L, Castellan P, Primiceri G, Hoznek A, Cracco CM, Scoffone CM, et al. Life-threatening complications after ureteroscopy for urinary stones: survey and systematic literature review. Minerva Urol Nefrol. 2017; 69:421-31.
⁵⁵
Cindolo L, Castellan P, Scoffone CM, Cracco CM, Celia A, Paccaduscio A, et al. Mortality and flexible ureteroscopy: analysis of six cases. World J Urol. 2016; 34:305-10.
⁵⁶
de la Rosette J, Assimos D, Desai M, Gutierrez J, Lingeman J, Scarpa R, et al. The Clinical Research Office of the Endourological Society Percutaneous Nephrolithotomy Global Study: indications, complications, and outcomes in 5803 patients. J Endourol. 2011; 25:11-7.
⁵⁷
Kourambas J, Delvecchio FC, Munver R, Preminger GM. Nitinol stone retrieval-assisted ureteroscopic management of lower pole renal calculi. Urology. 2000; 56:935-9.
⁵⁸
Auge BK, Dahm P, Wu NZ, Preminger GM. Ureteroscopic management of lower-pole renal calculi: technique of calculus displacement. J Endourol. 2001; 15:835-8.
⁵⁹
Schuster TG, Hollenbeck BK, Faerber GJ, Wolf JS Jr. Ureteroscopic treatment of lower pole calculi: comparison of lithotripsy in situ and after displacement. J Urol. 2002; 168:43-5.
⁶⁰
Dauw CA, Simeon L, Alruwaily AF, Sanguedolce F, Hollingsworth JM, Roberts WW, et al. Contemporary Practice Patterns of Flexible Ureteroscopy for Treating Renal Stones: Results of a Worldwide Survey. J Endourol. 2015; 29:1221-30.
⁶¹
Ding J, Xu D, Cao Q, Huang T, Zhu Y, Huang K, et al. Comparing the Efficacy of a Multimodular Flexible Ureteroscope With Its Conventional Counterpart in the Management of Renal Stones. Urology. 2015; 86:224-9.
⁶²
Usawachintachit M, Isaacson DS, Taguchi K, Tzou DT, Hsi RS, Sherer BA, et al. A Prospective Case-Control Study Comparing LithoVue, a Single-Use, Flexible Disposable Ureteroscope, with Flexible, Reusable Fiber-Optic Ureteroscopes. J Endourol. 2017; 31:468-75.
⁶³
Mager R, Kurosch M, Höfner T, Frees S, Haferkamp A, Neisius A. Clinical outcomes and costs of reusable and single-use flexible ureterorenoscopes: a prospective cohort study. Urolithiasis. 2018; 46:587-93.
⁶⁴
White MD, Moran ME: Fatigability of the latest generation ureteropyeloscopes: Richard Wolf vs. Karl Storz [abstract]. J Endourol. 1998;12:S182.
⁶⁵
Marchini GS, Torricelli FC, Batagello CA, Monga M, Vicentini FC, Danilovic A, et al. A comprehensive literature-based equation to compare cost-effectiveness of a flexible ureteroscopy program with single-use versus reusable devices. Int Braz J Urol. 2019; 45:658-70.
⁶⁶
Ozimek T, Schneider MH, Hupe MC, Wiessmeyer JR, Cordes J, Chlosta PL, et al. Retrospective Cost Analysis of a Single-Center Reusable Flexible Ureterorenoscopy Program: A Comparative Cost Simulation of Disposable fURS as an Alternative. J Endourol. 2017; 31:1226-30.
⁶⁷
Pardalidis NP, Andriopoulos NA, Sountoulidis P, Kosmaoglou EV. Should percutaneous nephrolithotripsy be considered the primary therapy for lower pole stones? J Endourol. 2010; 24:219-22.
⁶⁸
Bianchi L, Schiavina R, Barbaresi U, Angiolini A, Pultrone CV, Manferrari F, et al. 3D Reconstruction and physical renal model to improve percutaneous punture during PNL. Int Braz J Urol. 2019; 45:1281-2.
⁶⁹
Ozbir S, Atalay HA, Canat HL, Culha MG, Cakır SS, Can O, et al. Factors affecting fluoroscopy time during percutaneous nephrolithotomy: Impact of stone volume distribution in renal collecting system. Int Braz J Urol. 2019; 45:1153-60.
⁷⁰
Breda A, Ogunyemi O, Leppert JT, Lam JS, Schulam PG. Flexible ureteroscopy and laser lithotripsy for single intrarenal stones 2 cm or greater--is this the new frontier? J Urol. 2008; 179:981-4.
⁷¹
Takazawa R, Kitayama S, Tsujii T. Successful outcome of flexible ureteroscopy with holmium laser lithotripsy for renal stones 2 cm or greater. Int J Urol. 2012; 19:264-7.

Publication Dates

Publication in this collection
12 Jan 2022
Date of issue
Jan-Feb 2022

History

Received
21 Nov 2020
Accepted
19 Dec 2020
Published
20 Jan 2021

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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[39] ³⁹
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[40] ⁴⁰
El-Nahas AR, Ibrahim HM, Youssef RF, Sheir KZ. Flexible ureterorenoscopy versus extracorporeal shock wave lithotripsy for treatment of lower pole stones of 10-20mm. BJU Int. 2012; 110:898-902.

[41] ⁴¹
Kumar A, Vasudeva P, Nanda B, Kumar N, Das MK, Jha SK. A Prospective Randomized Comparison Between Shock Wave Lithotripsy and Flexible Ureterorenoscopy for Lower Caliceal Stones ≤2 cm: A Single-Center Experience. J Endourol. 2015; 29:575-9.

[42] ⁴²
Vilches RM, Aliaga A, Reyes D, Sepulveda F, Mercado A, Moya F, et al. Comparison between retrograde intrarenal surgery and extracorporeal shock wave lithotripsy in the treatment of lower pole kidney stones up to 15 mm. Prospective, randomized study. Actas Urol Esp. 2015; 39:236-42.

[43] ⁴³
Kumar A, Kumar N, Vasudeva P, Kumar Jha S, Kumar R, Singh H. A prospective, randomized comparison of shock wave lithotripsy, retrograde intrarenal surgery and miniperc for treatment of 1 to 2 cm radiolucent lower calyceal renal calculi: a single center experience. J Urol. 2015; 193:160-4.

[44] ⁴⁴
Chan LH, Good DW, Laing K, Phipps S, Thomas BG, Keanie JY, et al. Primary SWL Is an Efficient and Cost-Effective Treatment for Lower Pole Renal Stones Between 10 and 20 mm in Size: A Large Single Center Study. J Endourol. 2017; 31:510-6.

[45] ⁴⁵
Zeng G, Zhang T, Agrawal M, He X, Zhang W, Xiao K, et al. Super-mini percutaneous nephrolithotomy (SMP) vs retrograde intrarenal surgery for the treatment of 1-2 cm lower-pole renal calculi: an international multicentre randomised controlled trial. BJU Int. 2018; 122:1034-40.

[46] ⁴⁶
Ozgor F, Sahan M, Yanaral F, Savun M, Sarilar O. Flexible ureterorenoscopy is associated with less stone recurrence rates over Shockwave lithotripsy in the management of 10-20 millimeter lower pole renal stone: medium follow-up results. Int Braz J Urol. 2018; 44:314-22.

[47] ⁴⁷
Jin L, Yang B, Zhou Z, Li N. Comparative Efficacy on Flexible Ureteroscopy Lithotripsy and Miniaturized Percutaneous Nephrolithotomy for the Treatment of Medium-Sized Lower-Pole Renal Calculi. J Endourol. 2019; 33:914-9.

[48] ⁴⁸
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[49] ⁴⁹
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[50] ⁵⁰
Soliman T, Sherif H, Sebaey A, Mohey A, Elmohamady BN. Miniperc vs Shockwave Lithotripsy for Average-Sized, Radiopaque Lower Pole Calculi: A Prospective Randomized Study. J Endourol. 2016. Online ahead of print.

[51] ⁵¹
Hui S, Qingya Y, Xinbao Y, Ming L, Gonghui L, Jun C. Two-shift operation mode can improve the efficiency and comfort of flexible ureteroscopic holmium laser lithotripsy for the treatment of renal calculi larger than 1.5cm. Int Braz J Urol. 2019; 45:1161-6.

[52] ⁵²
Dindo D, Demartines N, Clavien PA. Classification of surgical complications: a new proposal with evaluation in a cohort of 6336 patients and results of a survey. Ann Surg. 2004; 240:205-13.

[53] ⁵³
Bierkens AF, Hendrikx AJ, Lemmens WA, Debruyne FM. Extracorporeal shock wave lithotripsy for large renal calculi: the role of ureteral stents. A randomized trial. J Urol. 1991; 145:699-702.

[54] ⁵⁴
Cindolo L, Castellan P, Primiceri G, Hoznek A, Cracco CM, Scoffone CM, et al. Life-threatening complications after ureteroscopy for urinary stones: survey and systematic literature review. Minerva Urol Nefrol. 2017; 69:421-31.

[55] ⁵⁵
Cindolo L, Castellan P, Scoffone CM, Cracco CM, Celia A, Paccaduscio A, et al. Mortality and flexible ureteroscopy: analysis of six cases. World J Urol. 2016; 34:305-10.

[56] ⁵⁶
de la Rosette J, Assimos D, Desai M, Gutierrez J, Lingeman J, Scarpa R, et al. The Clinical Research Office of the Endourological Society Percutaneous Nephrolithotomy Global Study: indications, complications, and outcomes in 5803 patients. J Endourol. 2011; 25:11-7.

[57] ⁵⁷
Kourambas J, Delvecchio FC, Munver R, Preminger GM. Nitinol stone retrieval-assisted ureteroscopic management of lower pole renal calculi. Urology. 2000; 56:935-9.

[58] ⁵⁸
Auge BK, Dahm P, Wu NZ, Preminger GM. Ureteroscopic management of lower-pole renal calculi: technique of calculus displacement. J Endourol. 2001; 15:835-8.

[59] ⁵⁹
Schuster TG, Hollenbeck BK, Faerber GJ, Wolf JS Jr. Ureteroscopic treatment of lower pole calculi: comparison of lithotripsy in situ and after displacement. J Urol. 2002; 168:43-5.

[60] ⁶⁰
Dauw CA, Simeon L, Alruwaily AF, Sanguedolce F, Hollingsworth JM, Roberts WW, et al. Contemporary Practice Patterns of Flexible Ureteroscopy for Treating Renal Stones: Results of a Worldwide Survey. J Endourol. 2015; 29:1221-30.

[61] ⁶¹
Ding J, Xu D, Cao Q, Huang T, Zhu Y, Huang K, et al. Comparing the Efficacy of a Multimodular Flexible Ureteroscope With Its Conventional Counterpart in the Management of Renal Stones. Urology. 2015; 86:224-9.

[62] ⁶²
Usawachintachit M, Isaacson DS, Taguchi K, Tzou DT, Hsi RS, Sherer BA, et al. A Prospective Case-Control Study Comparing LithoVue, a Single-Use, Flexible Disposable Ureteroscope, with Flexible, Reusable Fiber-Optic Ureteroscopes. J Endourol. 2017; 31:468-75.

[63] ⁶³
Mager R, Kurosch M, Höfner T, Frees S, Haferkamp A, Neisius A. Clinical outcomes and costs of reusable and single-use flexible ureterorenoscopes: a prospective cohort study. Urolithiasis. 2018; 46:587-93.

[64] ⁶⁴
White MD, Moran ME: Fatigability of the latest generation ureteropyeloscopes: Richard Wolf vs. Karl Storz [abstract]. J Endourol. 1998;12:S182.

[65] ⁶⁵
Marchini GS, Torricelli FC, Batagello CA, Monga M, Vicentini FC, Danilovic A, et al. A comprehensive literature-based equation to compare cost-effectiveness of a flexible ureteroscopy program with single-use versus reusable devices. Int Braz J Urol. 2019; 45:658-70.

[66] ⁶⁶
Ozimek T, Schneider MH, Hupe MC, Wiessmeyer JR, Cordes J, Chlosta PL, et al. Retrospective Cost Analysis of a Single-Center Reusable Flexible Ureterorenoscopy Program: A Comparative Cost Simulation of Disposable fURS as an Alternative. J Endourol. 2017; 31:1226-30.

[67] ⁶⁷
Pardalidis NP, Andriopoulos NA, Sountoulidis P, Kosmaoglou EV. Should percutaneous nephrolithotripsy be considered the primary therapy for lower pole stones? J Endourol. 2010; 24:219-22.

[68] ⁶⁸
Bianchi L, Schiavina R, Barbaresi U, Angiolini A, Pultrone CV, Manferrari F, et al. 3D Reconstruction and physical renal model to improve percutaneous punture during PNL. Int Braz J Urol. 2019; 45:1281-2.

[69] ⁶⁹
Ozbir S, Atalay HA, Canat HL, Culha MG, Cakır SS, Can O, et al. Factors affecting fluoroscopy time during percutaneous nephrolithotomy: Impact of stone volume distribution in renal collecting system. Int Braz J Urol. 2019; 45:1153-60.

[70] ⁷⁰
Breda A, Ogunyemi O, Leppert JT, Lam JS, Schulam PG. Flexible ureteroscopy and laser lithotripsy for single intrarenal stones 2 cm or greater--is this the new frontier? J Urol. 2008; 179:981-4.

[71] ⁷¹
Takazawa R, Kitayama S, Tsujii T. Successful outcome of flexible ureteroscopy with holmium laser lithotripsy for renal stones 2 cm or greater. Int J Urol. 2012; 19:264-7.

Treatment method	Advantages	Disadvantages
SWL	Non-invasive; Outpatient setting; Performed under sedation;Low incidence of complications; Severe complications are rare	Highly dependent on stone burden; Low efficiency for stones > 900HU and obese patients (skin-stone distance >10 cm); Low SFR for LPS; Contraindicated for pregnant patients and coagulopathies; High capital equipment cost
FURS	Minimally invasive; Short hospital stay; Suitable for all types of stones; Low incidence of complications; Major complications are rare	Unable to reach lower pole in some cases; Residual fragments; High cost of disposables; Need for postoperative stent
PCNL	High SFR; Short procedural time; (compared to FURS); Good cost-benefit	Invasive; Contra-indicated in coagulopathies; Higher incidence of complications than SWL and FURS; Major complications possible (hemorrhage, colonic lesions, hemothorax); Longer hospitalization

	Type of study	N° of patients	SWL (%)	FURS (%)	Miniperc (%)	p-value
Bozkurt et al., 2011 (³⁹39 Bozkurt OF, Resorlu B, Yildiz Y, Can CE, Unsal A. Retrograde intrarenal surgery versus percutaneous nephrolithotomy in the management of lower-pole renal stones with a diameter of 15 to 20mm. J Endourol. 2011; 25:1131-5.)	Retrospective	79	-	89.2	92.8	0.571
El Nahas et al., 2012 (⁴⁰40 El-Nahas AR, Ibrahim HM, Youssef RF, Sheir KZ. Flexible ureterorenoscopy versus extracorporeal shock wave lithotripsy for treatment of lower pole stones of 10-20mm. BJU Int. 2012; 110:898-902.)	Retrospective	89	67.7	86.5	-	0.038
Kumar et al., 2015 (⁴¹41 Kumar A, Vasudeva P, Nanda B, Kumar N, Das MK, Jha SK. A Prospective Randomized Comparison Between Shock Wave Lithotripsy and Flexible Ureterorenoscopy for Lower Caliceal Stones ≤2 cm: A Single-Center Experience. J Endourol. 2015; 29:575-9.)	Prospective	180	78.4	85.4	-	0,34
Vilches et al., 2015 (⁴²42 Vilches RM, Aliaga A, Reyes D, Sepulveda F, Mercado A, Moya F, et al. Comparison between retrograde intrarenal surgery and extracorporeal shock wave lithotripsy in the treatment of lower pole kidney stones up to 15 mm. Prospective, randomized study. Actas Urol Esp. 2015; 39:236-42.)	Prospective		41.2	75.0	-	<0.05
Kumar et al., 2015 (⁴³43 Kumar A, Kumar N, Vasudeva P, Kumar Jha S, Kumar R, Singh H. A prospective, randomized comparison of shock wave lithotripsy, retrograde intrarenal surgery and miniperc for treatment of 1 to 2 cm radiolucent lower calyceal renal calculi: a single center experience. J Urol. 2015; 193:160-4.)	Prospective	126	73.8	86.1	95.1	0.01
Chan et al., 2017 (⁴⁴44 Chan LH, Good DW, Laing K, Phipps S, Thomas BG, Keanie JY, et al. Primary SWL Is an Efficient and Cost-Effective Treatment for Lower Pole Renal Stones Between 10 and 20 mm in Size: A Large Single Center Study. J Endourol. 2017; 31:510-6.)	Retrospective	225	48.5	42.9	66.7	0,59
Zeng et al., 2018 (⁴⁵45 Zeng G, Zhang T, Agrawal M, He X, Zhang W, Xiao K, et al. Super-mini percutaneous nephrolithotomy (SMP) vs retrograde intrarenal surgery for the treatment of 1-2 cm lower-pole renal calculi: an international multicentre randomised controlled trial. BJU Int. 2018; 122:1034-40.)	Prospective	160	-	82.5	93.8	0.028
Ozgor et al., 2018 (⁴⁶46 Ozgor F, Sahan M, Yanaral F, Savun M, Sarilar O. Flexible ureterorenoscopy is associated with less stone recurrence rates over Shockwave lithotripsy in the management of 10-20 millimeter lower pole renal stone: medium follow-up results. Int Braz J Urol. 2018; 44:314-22.)	Retrospective	241	77.9	89.0	-	0.029
Jin et al., 2019 (⁴⁷47 Jin L, Yang B, Zhou Z, Li N. Comparative Efficacy on Flexible Ureteroscopy Lithotripsy and Miniaturized Percutaneous Nephrolithotomy for the Treatment of Medium-Sized Lower-Pole Renal Calculi. J Endourol. 2019; 33:914-9.)^* * stone free considered as the occurrence of fragments <3mm	Prospective	220	-	97.3	99.1	0.622

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