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    Investig Clin Urol. 2017 Sep;58(5):346-352. English.
    Published online Aug 03, 2017.
    https://doi.org/10.4111/icu.2017.58.5.346
    © The Korean Urological Association, 2017
    Original Article

    Ultrasound-guided percutaneous nephrolithotomy: Advantages and limitations

    Foo Cheong Ng, Wai Loon Yam, Tze Ying Benjamin Lim, Jin Kiat Teo, Kok Kit Ng and Sey Kiat Lim
      • Department of Urology, Changi General Hospital, Changi, Singapore.
    • Corresponding Author: Wai Loon Yam. Department of Urology, Changi General Hospital, 2 Simei Street 3, Changi, Singapore 529889. TEL: +65-68503944, FAX: +65-67880933, Email: wai_loon_yam@cgh.com.sg
    Received January 24, 2017; Accepted May 14, 2017.

    This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

    Abstract

    Purpose

    The use of ultrasound in percutaneous nephrolithotomy (PCNL) has not been shown to translate to better clinical and stone outcomes. To compare the operative outcomes, postoperative outcomes and complication rates of ultrasound-guided access PCNL (USGA-PCNL) versus fluoroscopy-guided access PCNL (FGA-PCNL).

    Materials and Methods

    A total of 184 consecutive patients who underwent PCNL from July 2008 to September 2014 were identified from our PCNL database. Seventy-two patients underwent USGA-PCNL and 112 FGA-PCNL.

    Results

    The patients were similar in age, sex, race, American Society of Anesthesiologists physical status classification, mean largest stone diameters, side of PCNL, number of stones and the degree of hydronephrosis between both groups. There were higher rates of upper pole (5.6% vs. 3.6%), mid pole (8.3% vs. 2.7%) and multiple pole punctures (4.2% vs. 0%) in USGA-PCNL compared to FGA-PCNL (p=0.027). There was no difference in the stone free rates of both groups in univariate analysis. Those who had FGA-PCNL were 2.26 (95% confidence interval, 1.09–4.75; p=0.029) times more likely to require a second-look procedure compared to USGA-PCNL on univariate analysis but not on multivariate analysis. There were no differences in Clavien-Dindo complications. No patient in the USGA-PCNL group experienced organ injuries during puncture compared to 1 patient in the FGA-PCNL group who had pneumothorax requiring urgent chest tube insertion.

    Conclusions

    The use of ultrasonography to guide access puncture during PCNL eliminates the risk of inadvertent organ injuries. Similar operative and stone outcomes show that the learning curve for USGA is minimal compared to conventional FGA.

    Keywords
    Fluoroscopy; Interventional ultrasonography;; Percutaneous nephrostomy; Staghorn calculi; Urolithiasis

    INTRODUCTION

    Percutaneous nephrolithotomy (PCNL) is the treatment of choice for staghorn stones and large renal stones. It is traditionally guided by fluoroscopy and may pose a risk of radiation to patient and staff especially in a high workload center [1, 2]. The use of ultrasonography in PCNL was first described as early as the 1970s [3]. In the recent years, its popularity has grown with multiple case series being published, demonstrating its feasibility, safety and efficacy [4, 5, 6, 7]. These have led to 2 randomised clinical trials that showed a more accurate puncture and less radiation exposure for the patients and staff in ultrasound-guided PCNL [8, 9].

    To perform a successful PCNL, accurate puncture into the desired calyx is of paramount importance. Although fluoroscopy allows accurate identification of the desired calyx for puncture, it does not allow for real-time simultaneous bi-plane fluoroscopy, making the process of obtaining accurate puncture into the desired calyx more difficult. In addition, important adjacent organs such as the pleura and the bowels are not visualised during the puncture, posing the risk of accidental injury to these organs [10, 11, 12]. Access with ultrasound-guided puncture during PCNL allows real-time simultaneous bi-plane tracking of the route of puncture into the desired calyx, while avoiding accidental injuries to vital adjacent organs. A less optimal entry into the collecting system will therefore lead to increased bleeding complications and decreased postoperative stone free rates [13].

    To our knowledge, there had been only one publication focusing on the complications and stone f ree rates between ultrasound-guided access PCNL (USGA-PCNL) and fluoroscopy-guided access PCNL (FGA-PCNL) [14]. In this study, we aimed to compare the operative outcomes, postoperative outcomes and complication rates of USGAPCNL versus FGA-PCNL during PCNL.

    MATERIALS AND METHODS

    1. Patient selection

    A total of 184 consecutive patients who underwent PCNL between July 2008 and September 2014 were identified from our database. We included all patients who were older than 18 years with size of renal stone ≥10 mm. We excluded patients with congenital kidney anomalies, uncorrected coagulopathy and previous open surgery for renal stones. All patients underwent routine blood investigations and anesthesia assessment prior to operation. Preoperative computed tomography (CT) urogram or plain CT KUB (kidney, ureter, and bladder) were routinely performed to evaluate the anatomy of kidney, the locations of stones and the positions of adjacent structures in relation to the desired route of puncture. Every case was performed either by an associate consultant/consultant/senior consultant or a registrar-in-training under direct supervision by a consultant/senior consultant.

    2. Surgical techniques

    Under general anesthesia, the patient was first positioned in lithotomy when a ureteric catheter was inserted, if possible, past the stone into the upper calyx of the kidney. This was to allow infusion of methylene blue and radiographic contrast, diluted in normal saline, during needle puncture into the collecting system. The patient was then repositioned in prone. In the USGA-PCNL group, an ultrasound was used to identify the anatomy of the calyces, the position of the stones and the route of puncture. The adjacent structures i.e., lung, large bowel, liver, spleen were then surface-marked. The selected calyx to be punctured was then visualized with ultrasound and the puncture was made with Initial Puncture Needle 18 G/12 cm or 18 G/20 cm (Cook Medical, Bloomington, IN, USA) under ultrasound guidance. In the FGA-PCNL group, the needle puncture was performed with the triangulation method under fluoroscopic guidance.

    Once the desired calyx was punctured, the subsequent steps were identical in the 2 approaches. Fluoroscopy was used for the subsequent steps. An Amplatz Super Stiff straight tip 0.035 inch guide-wire (Boston Scientific, Spencer, IN, USA) was inserted into the collecting system. Attempt was made to direct this guide-wire down the ureter into the bladder whenever possible. With the guide-wire in place, the skin incision was made and the tract was dilated with either the coaxial dilator 8F/10F (Boston Scientific) or the Super Arrow-Flex PSI Set (Arrow International, Reading, PA, USA). A second guide wire, 0.038-inch PTFE Amplatz Extra Stiff guide-wire (Cook Medical) (used for subsequent dilatation) was then inserted down the ureter into the bladder if possible. A NephroMax balloon dilator (Boston Scientific) was then used to dilate the tract to 30F. A 30F Amplatz sheath was then directed over the balloon into the selected calyx under fluoroscopy. Stone fragmentation was performed using an ultrasonic lithotripter (Olympus LUS-2, Tokyo, Japan) or CyberWand (Olympus, South borough, MA, USA). Flexible nephroscopy may be performed to identify and fragment residual stones with Holmium laser or retrieve stone fragments with dormia basket. None of the cases required the use of flexible ureteroscopy. At the end of operation, a double J stent may be inserted antegradely or retrogradely and a Jacque catheter was inserted. Finally an on-table check nephrostogram was performed to ascertain positions of the DJ stent and Jacque catheter.

    3. Statistical analysis

    We compared patients' demographics, stone characteristics, operative and postoperative outcomes in patients who underwent USGA-PCNL or FGA-PCNL using the Student t-test for continuous variables and the Pearson chi-square test for categorical variables. Multivariate analysis was performed with logistic regression for the need for second-look procedure and linear regression for the mean length of hospital stay. Statistical analysis was conducted using IBM SPSS Statistics ver. 21.0 (IBM Co., Armonk, NY, USA); p<0.05 from use of 2-side statistical tests was considered statistically significant.

    RESULTS

    There were 72 patients in the USGA-PCNL group versus 112 patients in the FGA-PCNL group. The baseline patient demographics are presented in Table 1. The major parameters for both USGA-PCNL and FGA-PCNL groups were similar at baseline. As USGA-PCNL was a newer technique that we more recently adopted, the mean follow-up duration was shorter in USGA-PCNL than in FGA-PCNL (14.8±16.1 months vs. 24.7±21.3 months, p=0.001).

    Table 1
    Patient demographics

    The operative outcomes are shown in Table 2. There were higher rates of upper pole (5.6% vs. 3.6%), mid pole (8.3% vs. 2.7%) and multiple pole punctures (4.2% vs. 0%) in USGA-PCNL compared to FGA-PCNL (p=0.027). The mean size of Jacques catheter used was smaller in USGA-PCNL than in FGA-PCNL (17.6F vs. 22.0F, p=0.053). There were no statistically significant differences in duration of surgery or types of ureteric stents used.

    Table 2
    Comparison of operative outcome of USGA-PCNL vs. FGA-PCNL

    Table 3 summarizes the postoperative outcomes. We defined our stone free rate as level 4 according to Somani et al. [15] i.e., ≤4 mm on plain KUB X-ray. The stone free rate of USGA-PCNL was 66.7% vs. FGA-PCNL 43.7% on univariate analysis (p=0.159). USGA-PCNL was found to require fewer second-look procedures (16.7%) vs. FGA-PCNL (31.2%) on univariate analysis (p=0.027). Those who had FGA-PCNL were 2.26 (95% confidence interval, 1.09–4.75; p=0.029) times more likely to require a second-look procedure compared to USGA-PCNL. However, this is not significant on multivariate analysis (p=0.090). For those who needed a second-look procedure, 2 patients in the FGA-PCNL group had to undergo a repeat PCNL, 1 patient ureteroscopy and laser lithotripsy, and 32 (91.4%) required extracorporeal shockwave lithotripsy (ESWL); while 3 patients in the USGA-PCNL group required subsequent ureteroscopy and laser lithotripsy, 9 ESWL and none repeat PCNL (p=0.047). The mean duration of Jacques catheter was 3.9±6.1 days in USGA-PCNL and 3.7±3.8 in FGA-PCNL (p=0.823). The mean length of hospitalization was 2.9±2.8 days in USGA-PCNL vs. 4.6±5.7 days in FGA-PCNL on univariate analysis (p=0.008). Multivariate analysis also showed statistical significant reduction of hospital stay with p=0.024.

    Table 3
    Comparison of stone outcome of USGA-PCNL vs. FGA-PCNL

    The complication rates of the 2 approaches were shown in Table 4. There were no statistical differences in blood loss, postoperative acute renal impairment (defined as serum creatinine increased by 50% from baseline) as well as other complications according to Clavien-Dindo classifications. There was one patient who suffered a pleural injury requiring chest tube insertion and another patient had renal pelvis stenosis requiring open pyeloplasty in the FGA-PCNL group (Table 5). No patient in the USGA-PCNL group had accidental injury to the adjacent organs.

    Table 4
    Comparison of complications of USGA-PCNL vs. FGA-PCNL

    Table 5
    Detailed Clavien-Dindo classification grade III complications of USGA-PCNL vs. FGA-PCNL

    DISCUSSION

    Puncture during PCNL is traditionally carried out under the guidance of fluoroscopy. Exposure to radiation is an ongoing concern for the urologists, surgical assistants, nurses and patients [1, 16, 17]. The application of an alternative imaging technique is the best way to solve this problem. Basiri et al. [8] reported a mean duration of access of 11 minutes in a group of 50 patients undergoing USGA-PCNL whereas Agarwal et al. [9] quoted 1.8 minutes in his study involving 112 cases of USGA-PCNL. Both acknowledged that USGA-PCNL was highly accurate and duration of radiation exposure was significantly reduced. However, data comparing the outcomes and complications in both groups of USGA-PCNL and FGA-PCNL remains scarce and needs to be addressed. Our present study is one of the few designed to address this gap. We showed that USGA-PCNL was as safe as FGA-PCNL and with real-time ultrasound guidance during access puncture. Moreover, the risk of accidental puncture injury to adjacent organs like pleura or colon was eliminated.

    Majority of our PCNL were performed by a lower pole puncture, i.e., 81.9% in USGA-PCNL and 93.7% in FGA-PCNL. The main reasons are surgeons' preference and to avoid entering the pleura. Wong and Leveillee [11] and Raza et al. [12] reported 2.8% and 3% rate of hydrothorax respectively with upper pole puncture under standard FGA-PCNL. The magnitude of the concern of thoracic injury is evident with Finelli and Honey [18] describing thoracoscopy-assisted PCNL for upper pole puncture. When upper pole, mid pole puncture and multiple pole puncture were deemed necessary in our study, USGA-PCNL was favoured. Despite more upper pole punctures performed using USGA-PCNL, there was no lung or pleural injury reported in our study compared to one in FGA-PCNL. We believe that this was due to the improved visibility of renal calyces and surrounding anatomy by ultrasound. Positional changes of bowel in supine (during CT scan) and prone (on table) positions were well reported [19, 20]. With ultrasound guidance during access puncture, one will be able to more confidently avoid the bowel, thereby improving the accuracy of puncturing the desired calyx. In addition, fluoroscopic puncture via the triangulation method required a more lateral point of entry as opposed to ultrasound-guided puncture, increasing the risk of colonic injury [21].

    Kalogeropoulou et al. [22] and Gamal et al. [23] revealed some dif f iculty in ultrasound-guided PCNL with a nondistended collecting system. Gamal et al. [23] reported 25 cases of moderate hydronephrosis and 9 cases of severe hydronephrosis, all with single stone. They concluded that USGA-PCNL can be performed safely by an experienced urologist for patients with a single stone at the renal pelvis in a moderately to markedly dilated pelvicalyceal system [23]. Li et al. [24] presented a series of successful ultrasound puncture in 132 cases after artificial retrograde dilatation of the collecting system. In our study, we did not find any statistical significance in the degree of hydronephrosis between the two arms. 66.6% of the USGA-PCNL arm had no or mild hydronephrosis compared to 60.7% of the FGA-PCNL arm (p=0.774). This showed that USGA-PCNL is safe and reproducible in general urology units. There was also no statistical significance in terms of the grades of surgeon performing the surgery (p=0.135). This further reinforces that USGA-PCNL is not difficult to learn. We think that with proper training, as well as the advancement in the technology of ultrasound providing sharp images, the lack of a moderate or severe hydronephrosis should not be a limiting factor to shy away from ultrasound-guided PCNL. The use of ultrasound puncture guide as suggested by Desai can be considered as a start to increase the surgeon's confidence [25].

    A recent 7-year single center study by Chi et al. [7] reported a high stone free rate of 90.5% in a group of 562 patients and 9.5% required auxiliary measures after one PCNL. Agarwal et al. [9] also claimed that all patients achieved stone free in his randomized trial. Basiri et al. [26] randomised 92 patients into 46 USGA-PCNL and 46 FGA-PCNL and found no difference in the stone free rate, with 79.0% and 65.2% in the USGA-PCNL and FGA-PCNL respectively, after one session of PCNL (p=0.485). In this study, we reported a statistically insignificant difference in the stone free rate with USGA-PCNL (49.1%) compared to FGA-PCNL (36.9%) (p=0.159). We also did not find any difference in the need for second-look procedure in these groups. As this is a retrospective study, the need for second-look procedure was not clear but likely to be influenced by the surgeons' and the patients' preference. A longer follow-up and a prospective study are needed to study the true impact of USGA-PCNL in the stone free rate.

    In this study, we also found that smaller nephrostomy tube was needed in the USGA-PCNL. We postulate that this may be due to the intra-operative use of color Doppler ultrasound to demonstrate a path of needle puncture to circumvent areas with dense vasculatures. As a result, this led to a less bloody intraoperative field observed by the surgeon, leading to the decision of placement of a smaller tube.

    Our study did not show a shorter total duration of operation for USGA-PCNL over FGA-PCNL as total operative duration was dependent on a multitude of factors. The overall duration of operation was influenced by the grades of surgeon, the size and composition of stones, the locations of stone fragments and the physical build of the patients among others. A separate timing taken for puncture would be ideal in demonstrating the benefit of USGA-PCNL over FGA-PCNL in this aspect. As this was a retrospective study, we did not routinely record the duration required for puncture separately from the total operative timings. There was indeed no study that showed a difference in the overall duration of USGA-PCNL and FGA-PCNL.

    There are several limitations in our study. As this is a retrospective study, the use of ultrasound in each PCNL was mainly dependent on the surgeon's training and preference. This was a heterogenous group of surgeons with varying level of expertise. There was scarce data regarding the stone composition and analysis. However, one of the strength of this study is that the definition of stone free status was clearly stated, i.e., <4 mm [15]. These could be the reasons for the relatively low stone free rate compared to other studies.

    CONCLUSIONS

    The use of ultrasonography to guide access puncture during PCNL eliminates the risk of inadvertent organ injuries. Similar operative and stone outcomes show that the learning curve for USGA is minimal compared to conventional FGA.

    Notes

    CONFLICTS OF INTEREST:The authors have nothing to disclose.

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    MeSH Terms
    Adult
    Aged
    Female
    Fluoroscopy/adverse effects
    Fluoroscopy/methods
    Humans
    Kidney Calculi/diagnostic imaging
    Kidney Calculi/pathology
    Kidney Calculi/surgery*
    Male
    Middle Aged
    Nephrolithotomy, Percutaneous/adverse effects
    Nephrolithotomy, Percutaneous/methods*
    Nephrostomy, Percutaneous/adverse effects
    Nephrostomy, Percutaneous/methods
    Radiography, Interventional/adverse effects
    Radiography, Interventional/methods
    Staghorn Calculi/diagnostic imaging
    Staghorn Calculi/pathology
    Staghorn Calculi/surgery
    Treatment Outcome
    Ultrasonography, Interventional/adverse effects
    Ultrasonography, Interventional/methods*
    Metrics
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