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Abdelaziz H et al, 2014: The usefulness of stone density and patient stoutness in predicting extracorporeal shock wave efficiency: Results in a North African ethnic group.

AbdelRazek M et al, 2018: SWL outcome in artificial hydronephrotic vs. non-hydronephrotic kidney for preschool children with high-density renal stones.

Abid N et al, 2015: Decreased Radiation Exposure and Increased Efficacy in Extracorporeal Lithotripsy Using A New Ultrasound Stone Locking System.

Aboumarzouk OM et al, 2011: Extracorporeal shock wave lithotripsy (ESWL) versus ureteroscopic management for ureteric calculi

Aboumarzouk OM et al, 2017: Analgesia for patients undergoing shockwave lithotripsy for urinary stones - a systematic review and meta-analysis.

Aboutaleb H et al, 2016: Management of upper ureteral stones exceeding 15 mm in diameter: Shock wave lithotripsy versus semirigid ureteroscopy with holmium:yttrium-aluminum-garnet laser lithotripsy.

Acar A et al, 2013: The Effect of EMLA Cream on Patient-Controlled Analgesia with Remifentanil in ESWL Procedure: A Placebo-Controlled Randomized Study

Acar C et al, 2012: Impact of Residual Fragments following Endourological Treatments in Renal Stones

Acland G et al, 2015: Contemporary trends in urinary tract stone surgery, a regional perspective: Auckland, New Zealand.

Adanur S et al, 2014: Extracorporeal shockwave lithotripsy under sedoanalgesia for treatment of kidney stones in infants: a single-center experience with 102 cases.

Adanur S et al, 2014: Percutaneous nephrolithotomy for the treatment of radiolucent renal stones in children: is it different opaque stone treatment?

Adanur S et al, 2014: What should be the ideal time interval between repeated extracorporeal shock wave lithotripsy sessions for renal stone treatment?

Ahmed AF et al, 2015: Diuresis and inversion therapy to improve clearance of lower caliceal stones after shock wave lithotripsy: A prospective, randomized, controlled, clinical study.

Ahmed AF et al, 2016: Role of Tamsulosin Therapy after Extracorporeal Shockwave Lithotripsy for Renal Stones: Randomized Controlled Trial.

Ahmed MH et al, 2012: Renal stone disease and obesity: what is important for urologists and nephrologists?

Ahn JS et al, 2017: National Imaging Trends After Ureteroscopic or Shockwave Lithotripsy For Nephrolithiasis

Ahn SH et al, 2015: Can a dual-energy computed tomography predict unsuitable stone components for extracorporeal shock wave lithotripsy?

Akbas A et al, 2015: The effect of music therapy during shockwave lithotripsy on patient relaxation, anxiety, and pain perception.

Akbulut F et al, 2015: A Rare Complication of Extracorporeal Shock Wave Lithotripsy: Intrarenal Hematoma Mimicking Pelvis Renalis Tumor.

Akça O et al, 2013: Obesity might not be a disadvantage for SWL treatment in children with renal stone

Akelma H et al, 2018: Comparison of Ketamine with Midazolam versus Ketamine with Fentanyl for Pediatric Extracorporeal Shock Wave Lithotripsy Procedure: A Randomized Controlled Study.

Akin Y et al, 2014: Long-term effects of pediatric extracorporeal shockwave lithotripsy on renal function.

Al Edwan GM et al, 2017: Long term efficacy of extracorporeal shock wave therapy [ESWT] for treatment of refractory chronic abacterial prostatitis.

Al Ghazal A et al, 2014: Capsulotomy for treatment of compartment syndrome in patients with post extracorporeal shock wave lithotripsy renal hematomas: safe and effective, but also advisable?

Al-Abadi E et al, 2013: Extracorporal shock wave lithotripsy in the management of stones in children with oxalosis-still the first choice?

Al-Marhoon MS et al, 2013: Extracorporeal Shock-wave Lithotripsy Success Rate and Complications: Initial Experience at Sultan Qaboos University Hospital

Alavi Tamaddoni H et al, 2016: Enhanced High-Rate Shockwave Lithotripsy Stone Comminution in an In Vivo Porcine Model Using Acoustic Bubble Coalescence.

Albino G et al, 2017: Who "apparently" more spends, "in reality" spends less. Spending "a little" more for the rental of the extracorporeal lithotripter can save "a lot" about the days of hospitalization for urinary stones.

Alenezi H et al, 2015: The Effect of Renal Cysts on the Fragmentation of Renal Stones During Shockwave Lithotripsy: A Comparative In Vitro Study.

Alexander CE et al, 2016: Routine Antibiotic Prophylaxis Is Not Required for Patients Undergoing Shockwave Lithotripsy: Outcomes from a National Shockwave Lithotripsy Database in New Zealand.

Ali M et al, 2018: Shock wave lithotripsy versus endoscopic cystolitholapaxy in the management of patients presenting with calcular acute urinary retention: a randomised controlled trial.

Alibakhshi MA et al, 2013: Single-shot measurements of the acoustic field of an electrohydraulic lithotripter using a hydrophone array

Alken P., 2017: Intracorporeal lithotripsy.

Alp BF et al, 2014: Inhibition of inducible nitric oxide synthase prevents shock wave therapy induced renal injury

Alsagheer G et al, 2017: Extracorporeal shock wave lithotripsy (ESWL) monotherapy in children: Predictors of successful outcome.

Alsaikhan B et al, 2011: Shock wave lithotripsy in patients requiring anticoagulation or antiplatelet agents

Altok M et al, 2016: Comparison of shockwave frequencies of 30 and 60 shocks per minute for kidney stones: a prospective randomized study.

Altok M et al, 2016: Do anxiety, stress, or depression have any impact on pain perception during shock wave lithotripsy?

Aminsharifi A et al, 2018: Shock Wave Lithotripsy is More Effective for Residual Fragments after Percutaneous Nephrolithotomy than for Primary Stones of the Same Size: A Matched Pair Cohort Study.

Andonian S, 2015: Is shockwave lithotripsy on the verge of extinction?

Anglada-Curado et al, 2012: Extracorporeal shock wave lithotripsy for distal ureteral calculi: Improved efficacy using low frequency

Angulo JC et al, 2016: Efficacy of low-intensity shock wave therapy for erectile dysfunction: A systematic review and meta-analysis.

Angulo JC et al, 2017: Trends in the management of urolithiasis in Latin America, Spain and Portugal: results of a survey in the Confederación Americana de Urología (CAU).

Arcaniolo D et al, 2017: Emergent versus delayed lithotripsy for obstructing ureteral stones: a cumulative analysis of comparative studies.

Argüelles-Salido E et al, 2014: Prediction of the energy required for extracorporeal shock wave lithotripsy of certain stones composition using simple radiology and computerized axial tomography

Argüelles-Salido E et al, 2014: The usefulness of densitometry in predicting the composition and fragility of urolithiasis.

Arpali E et al, 2014: The efficacy of radiographic anatomical measurement methods in predicting success after extracorporeal shockwave lithotripsy for lower pole kidney stones.

Arrabal-Polo MA et al, 2012: Value of focal applied energy quotient in treatment of ureteral lithiasis with shock waves

Asgari SA et al, 2011: Is extracorporeal shockwave lithotripsy safe in patients with chronic bleeding tendency?

Askari A et al, 2012: Patient information leaflets for extracorporeal shock wave lithotripsy: questionnaire survey

Ateş F et al, 2012: Does the use of doxazosin influence the success of SWL in the treatment of upper ureteral stones? A multicenter, prospective and randomized study

Aydin HR et al, 2015: The Application of Kidney Injury Molecule-1 to Determine the Duration Between Shockwave Lithotripsy Sessions.

Aydogdu O et al, 2015: Recent management of urinary stone disease in a pediatric population.

Azili MN et al, 2015: Management of stone disease in infants.

Bach C et al, 2011: Drugs for pain management in shock wave lithotripsy

Badalato GM et al, 2011: Treatment of upper urinary lithiasis in patients who have undergone urinary diversion

Badawy AA et al, 2012: Extracorporeal shock wave lithotripsy as first line treatment for urinary tract stones in children: outcome of 500 cases

Bader MJ et al, 2012: Contemporary management of ureteral stones

Bahílo Mateu P et al, 2017: Is extracorporeal shock wave lithotripsy a current treatment for urolithiasis? A systematic review.

Bai Y et al, 2016: Extracorporeal shock wave lithotripsy and ERCP to remove a fractured guidewire in the pancreatic duct in a patient with chronic pancreatitis and pancreatic duct stones.

Bailey M et al, 2015: Shockwave lithotripsy with renoprotective pause is associated with renovascular vasoconstriction in humans.

Baishya R et al, 2012: Management of nephrolithiasis in autosomal dominant polycystic kidney disease - A single center experience

Bakoyiannis C et al, 2012: Superior mesenteric artery dissection after extracorporeal shockwave lithotripsy

Balawender K et al, 2017: The impact of pelvicalyceal anatomy on the stone formation in patients with lower pole renal stones.

Bantis A et al, 2015: Can tumor necrosis factor a (TNF-a) and interleukin 6 (IL-6) be used as prognostic markers of infection following ureteroscopic lithrotripsy and extracorporeal shock wave lithotripsy for ureteral stones?

Barbosa PV et al, 2011: Shock Wave Lithotripsy Associated With Greater Prevalence of Hypertension

Barreto L et al, 2018: Medical and surgical interventions for the treatment of urinary stones in children.

Bas O et al, 2013: Comparison of shock wave lithotripsy, flexible ureterorenoscopy and percutaneous nephrolithotripsy on moderate size renal pelvis stones

Basiri A et al, 2010: A multicenter, randomized, controlled trial of transureteral and shock wave lithotripsy - which is the best minimally invasive modality to treat distal ureteral calculi in children?

Basri C et al, 2013: The effect of tamsulosin on pain and clearance according to ureteral stone location after shock wave lithotripsy

Bechara A et al, 2015: Effectiveness of low-intensity extracorporeal shock wave therapy on patients with Erectile Dysfunction (ED) who have failed to respond to PDE5i therapy. A pilot study.

Beilan J et al, 2014: The Postoperative Morbidity Index: a quantitative weighing of postoperative complications applied to urological procedures

Ben Khalifa B et al, 2016: Predictive factors of extracorporeal shock wave lithotripsy success for urinary stones.

Benes J et al, 2012: Biological effects of tandem shock waves demonstrated on magnetic resonance

Berte N et al, 2011: Ischemic lesions in kidneys after extracorporeal shock wave lithotripsy demonstrated by Proton NMR spectroscopy of urine samples

Beshliev DA et al, 2018: [The first domestic lithotripter URAT-: to the 30th anniversary of introduction].

Beyna T et al, 2017: Endoscopic treatment of pancreatic duct stones under direct vision. Revolution or resignation? A systematic review.

Bhandari S et al, 2016: Extracorporeal shock wave lithotripsy: the cornerstone of pancreatic endotherapy.

Bhojani N et al, 2013: Shockwave lithotripsy-new concepts and optimizing treatment parameters

Bhojani N et al, 2015: Lithotripter Outcomes in a Community Practice Setting: Comparison of an Electromagnetic and an Electrohydraulic Lithotripter.

Bianchi G et al, 2018: Ultrasound follow up: Is an undetected spontaneous expulsion of stone fragments a sign of extracorporeal shock wave treatment failure in kidney stones?

Bjazevic J et al, 2018: Stones in pregnancy and pediatrics.

Blackburne AT et al, 2016: Endoscopic Management of Urolithiasis in the Horseshoe Kidney.

Bohris C et al, 2012: Monitoring the coupling of the lithotripter therapy head with skin during routine shock wave lithotripsy with a surveillance camera

Bohris C et al, 2015: Improvement of SWL Efficacy: Reduction of the Respiration-Induced Kidney Motion by Using an Abdominal Compression Plate.

Bostanci Y et al, 2011: Single session removal of forgotten encrusted ureteral stents: combined endourological approach

Bourdoumis A et al, 2014: Thromboprophylaxis and bleeding diathesis in minimally invasive stone surgery

Bourdoumis A et al, 2016: The evolution of urolithiasis management in the new millennium.

Bozkurt A et al, 2018: Does extracorporeal shockwave lithotripsy therapy affect thiol-disulfide homeostasis?

Bozzini G et al, 2017: A prospective randomized comparison among SWL, PCNL and RIRS for lower calyceal stones less than 2 cm: a multicenter experience: A better understanding on the treatment options for lower pole stones.

Branchereau J et al, 2017: Management of renal transplant urolithiasis: a multicentre study by the French Urology Association Transplantation Committee.

Bres-Niewada E et al, 2015: Predicting stone composition before treatment - can it really drive clinical decisions?

Bres-Niewada E et al, 2018: A stone pushed back to the collecting system - long therapeutic path in centers with limited access to flexible instruments.

Brown JA et al, 2013: Effect of High Shock Number on Acute Complication Development Following Extracorporeal Shock Wave Lithotripsy

Brown RD et al, 2014: Best practices in shock wave lithotripsy: a comparison of regional practice patterns.

Bucci S et al, 2018: Emergency extracorporeal shockwave lithotripsy (eSWL) as opposed to delayed SWL (dSWL) for the treatment of acute renal colic due to obstructive ureteral stone: a prospective randomized trial.

Budía Alba A et al, 2015: Analysis of the safety profile of treatment with a large number of shock waves per session in extracorporeal lithotripsy

Burr J et al, 2015: Is flexible ureterorenoscopy and laser lithotripsy the new gold standard for lower pole renal stones when compared to shock wave lithotripsy: Comparative outcomes from a University hospital over similar time period.

Cakiroglu B et al, 2015: The effect of inclined position on stone free rates in patients with lower caliceal stones during SWL session.

Cakmak O et al, 2017: Listening to music during shock wave lithotripsy decreases anxiety, pain, and dissatisfaction: A randomized controlled study.

Cannata F et al, 2013: Total Intravenous Anesthesia using Remifentanil in Extracorporeal Shock Wave Lithotripsy (ESWL). Comparison of two dosages: a randomized clinical trial

Canseco G et al, 2011: Modified shock waves for extracorporeal shock wave lithotripsy: A simulation based on the Gilmore formulation

Cárcamo JJ et al, 2011: Raman study of the shockwave effect on collagens

Carpentier X et al, 2014: [Update for the management of kidney stones in 2013. Stone group comity of the French association of Urology]

Carrasco A Jr et al, 2015: Surgical management of stone disease in patients with primary hyperoxaluria.

Carrasco J et al, 2013: The protective role of coenzyme Q10 in renal injury associated with extracorporeal shockwave lithotripsy: a randomised, placebo-controlled clinical trial

Carvalho M et al, 2016: Effect of potassium citrate supplement on stone recurrence before or after lithotripsy: systematic review and meta-analysis.

Ceban E, 2012: The treatment of the reno-ureteral calculi by extracorporeal shockwave lithotripsy (ESWL)

Cecen K et al, 2015: Flexible Ureterorenoscopy versus Extracorporeal Shock Wave Lithotripsy for the treatment of upper/middle calyx kidney stones of 10-20 mm: a retrospective analysis of 174 patients.

Cecere N et al, 2015: Renovascular acute renal failure precipitated by extracorporeal shock wave lithotripsy for pancreatic stones.

Celik S et al, 2015: Evaluation of computed tomography findings for success prediction after extracorporeal shock wave lithotripsy for urinary tract stone disease.

Cevik B et al, 2017: Procedural sedation and analgesia for pediatric shock wave lithotripsy: a 10 year experience of single institution.

Ceylan C et al, 2013: Evaluation of the Process of Recycling and Renal Parenchymal Injury after ESWL with Metabolites Excreted in the Urine

Ceylan Y et al, 2017: The effect of SWL and URS on health-related quality of life in proximal ureteral stones.

Chabannes É et al, 2013: [Management of adult's renal and ureteral stones. Update of the Lithiasis Committee of the French association of urology (CLAFU). General considerations]

Chabannes E et al, 2014: Management of adult's renal and ureteral stones. Update of the Lithiasis Committee of the French association of urology (CLAFU). General considerations

Chan LH et al, 2017: 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.

Chandrasekar T et al, 2015: Internet-Based Patient Survey on Urolithiasis Treatment and Patient Satisfaction.

Chang CC et al, 2012: In Vitro Study of the Revised Ultrasound Based Real-Time Tracking of Renal Stones for Shock Wave Lithotripsy: Part 1

Chang H et al, 2017: Melamine Poisoning Pediatric Urolithiasis Treatment in Gansu, China 5-Year Follow-up Analysis.

Chang KD et al, 2017: Impact of Pretreatment Hydronephrosis on the Success Rate of Shock Wave Lithotripsy in Patients with Ureteral Stone.

Chaudhary R et al, 2017: Perspectives on hypertension outcomes after single-stage clearance of a complete staghorn renal calculus.

Chaussy C et al, 2016: First Clinical Experience with Extracorporeally Induced Destruction of Kidney Stones by Shock Waves.

Chaussy CG et al, 2015: Engineering Better Lithotripters.

Chaussy CG et al, 2017: How can and should we optimize extracorporeal shockwave lithotripsy?

Chen K et al, 2015: The Efficacy and Safety of Tamsulosin Combined with Extracorporeal Shockwave Lithotripsy for Urolithiasis: A Systematic Review and Meta-Analysis of Randomized Controlled Trials.

Chen KH et al, 2018: A Young Man With Epigastric Pain After Extracorporeal Shock Wave Lithotripsy.

Chen TT et al, 2015: Radiation Exposure during the Evaluation and Management of Nephrolithiasis.

Chen WT et al, 2014: An Evaluation of Electroacupuncture at the Weizhong Acupoint (BL-40) as a Means of Relieving Pain Induced by Extracorporeal Shock Wave Lithotripsy.

Chen X et al, 2018: [Focused low-intensity extracorporeal shock wave therapy for erectile dysfunction: Preliminary observation of 32 cases].

Chen YZ et al, 2017: Comparison of safety and outcomes of shock wave lithotripsy between elderly and non-elderly patients.

Chew BH et al, 2011: Twenty-year prevalence of diabetes mellitus and hypertension in patients receiving shock-wave lithotripsy for urolithiasis

Chiang BJ et al, 2017: The efficacy of extracorporeal shockwave lithotripsy for symptomatic ureteral stones: Predictors of treatment failure without the assistance of computed tomography.

Childs MA et al, 2012: Factors Influencing Urologist Treatment Preference in Surgical Management of Stone Disease

Cho HJ et al, 2013: Efficacy of alfuzosin after shock wave lithotripsy for the treatment of ureteral calculi

Cho KS et al, 2015: Optimal Skin-to-Stone Distance Is a Positive Predictor for Successful Outcomes in Upper Ureter Calculi following Extracorporeal Shock Wave Lithotripsy: A Bayesian Model Averaging Approach.

Choi HJ et al, 2012: Usefulness of early extracorporeal shock wave lithotripsy in colic patients with ureteral stones

Choi JW et al, 2012: Predictive factors of the outcome of extracorporeal shockwave lithotripsy for ureteral stones

Chongruksut W et al, 2011: Kidney stones recurrence and regrowth after extracorporeal shock wave lithotripsy and percutaneous nephrolithotomy

Chongruksut W et al, 2011: Prognostic factors for success in treating kidney stones by extracorporeal shock wave lithotripsy

Chongruksut W et al, 2012: Predictors for kidney stones recurrence following extracorporeal shock wave lithotripsy (ESWL) or percutaneous nephrolithotomy (PCNL)

Choo MS et al, 2018: A Prediction Model using Machine Learning Algorithm for Assessing Stone-Free Status after Single-Session Shockwave Lithotripsy to Treat Ureteral Stones.

Choo MS et al, 2018: The transgluteal approach to shockwave lithotripsy to treat distal ureter stones: a prospective, randomized, and multicenter study.

Christiansen FE et al, 2015: Internal Structure of Kidney Calculi as a Predictor for Shockwave Lithotripsy Success.

Chuang YC et al, 2017: Urodynamic and molecular characteristics of detrusor underactivity in a rat cryoinjury model and effects of low energy shock wave therapy.

Chung DY et al, 2015: Impact of colic pain as a significant factor for predicting the stone free rate of one-session shock wave lithotripsy for treating ureter stones: a Bayesian logistic regression model analysis.

Chung E, Alkhayal A and Carrier S: Pro and Con

Chung JM et al, 2017: Impact of repeated extracorporeal shock wave lithotripsy on prepubertal rat kidney.

Chung SD et al, 2014: Percutaneous nephrolithotomy increases the risk of diabetes: A 5-year follow-up study

Chung VY et al, 2016: The success of shock wave lithotripsy (SWL) in treating moderate-sized (10-20 mm) renal stones.

Cicerello E et al, 2012: Management of Clinically Insignificant Residual Fragments following Shock Wave Lithotripsy

Cicerello E et al, 2015: Urolithiasis in renal transplantation: diagnosis and management.

Clark DL et al, 2011: Pretreatment with low-energy shock waves reduces the renal oxidative stress and inflammation caused by high-energy shock wave lithotripsy

Clavijo RI et al, 2016: Effects of Low-Intensity Extracorporeal Shockwave Therapy on Erectile Dysfunction: A Systematic Review and Meta-Analysis.

Clifton MM et al, 2014: The change in upper tract urolithiasis composition, surgical treatments and outcomes of para and quadriplegic patients over time.

Cone EB et al, 2014: Cost-Effectiveness Comparison of Renal Calculi Treated with Ureteroscopic Laser Lithotripsy Versus Shockwave Lithotripsy

Cone EB et al, 2016: Cost-effectiveness comparison of ureteral calculi treated with ureteroscopic laser lithotripsy versus shockwave lithotripsy.

Connors BA et al, 2012: Evaluation of shock wave lithotripsy injury in the pig using a narrow focal zone lithotriptor

Connors BA et al, 2013: Comparison of Tissue Injury from Focused Ultrasonic Propulsion of Kidney Stones Versus Extracorporeal Shock Wave Lithotripsy

Connors BA et al, 2016: Using 300 Pretreatment Shock Waves In A Voltage Ramping Protocol Can Significantly Reduce Tissue Injury During Extracorporeal Shock Wave Lithotripsy.

Connors BA et al, 2018: Preliminary Report on Stone Breakage and Lesion Size Produced by a New Extracorporeal Electrohydraulic (Sparker Array) Discharge Device.

Cortes JA et al, 2011: Update on technological and selection factors influencing shockwave lithotripsy of renal stones in adults and children

Cranfield A et al, 2015: Goodpasture's disease following extracorporeal shock wave lithotripsy: a case report & literature review.

Cui H et al, 2013: Efficacy of the lithotripsy in treating lower pole renal stones

Cui HW et al, 2017: CT Texture Analysis of Ex Vivo Renal Stones Predicts Ease of Fragmentation with Shockwave Lithotripsy.

Cui X et al, 2015: Comparison Between Extracorporeal Shock Wave Lithotripsy and Ureteroscopic Lithotripsy for Treating Large Proximal Ureteral Stones: A Meta-analysis.

Cui Y et al, 2014: Comparison of ESWL and Ureteroscopic Holmium Laser lithotripsy in Management of Ureteral Stones

Cunitz BW et al, 2017: Characterizing the Acoustic Output of an Ultrasonic Propulsion Device for Urinary Stones.

D'A Honey RJ et al, 2012: A Prospective Study Examining the Incidence of Bacteriuria and Urinary Tract Infection After Shock Wave Lithotripsy with Targeted Antibiotic Prophylaxis

D'Addessi A et al, 2012: Complications of extracorporeal shock wave lithotripsy for urinary stones: to know and to manage them-a review

Dai J et al, 2013: Critical Analysis of a New Generation Electrohydraulic Lithotripter: A Single Institution Experience with the Medispec E3000TM

Davis RB et al, 2018: Contemporary practice patterns in the treatment of pediatric stone disease.

de Cógáin M et al, 2012: Shock wave lithotripsy and diabetes mellitus: a population-based cohort study

de Icaza-Herrera M et al, 2015: Combined short and long-delay tandem shock waves to improve shock wave lithotripsy according to the Gilmore-Akulichev theory.

De Nunzio C et al, 2016: Tamsulosin or Silodosin Adjuvant Treatment Is Ineffective in Improving Shockwave Lithotripsy Outcome: A Short-Term Follow-Up Randomized, Placebo-Controlled Study.

Dede O et al, 2015: Does morbid obesity influence the success and complication rates of extracorporeal shockwave lithotripsy for upper ureteral stones?

Deem S et al, 2011: Percutaneous Nephrolithotomy Versus Extracorporeal Shock Wave Lithotripsy for Moderate Sized Kidney Stones

Dell'Atti L et al, 2016: Ten-year experience in the management of distal ureteral stones greater than 10 mm in size.

Dellis AE et al, 2014: Role of α-blockers in the Treatment of Stent-related Symptoms: A Prospective Randomized Control Study

Demir A et al, 2015: Pain control using pethidine in combination with diazepam compared to diclofenac in combination with hyoscine-n-butyl bromide: in patients undergoing extracorporeal shock wave lithotripsy.

Demir A et al, 2015: The histomorphological findings of kidneys after application of high dose and high-energy shock wave lithotripsy.

Demir E et al, 2014: Immediate and long-term high levels of plasma homocysteine after extracorporeal shock wave lithotripsy in patients with renal stone disease.

Demirbas M et al, 2012: Extracorporeal shockwave lithotripsy for ureteral stones: twelve years of experience with 2836 patients at a single center

Denburg MR et al, 2015: Assessing the risk of incident hypertension and chronic kidney disease after exposure to shockwave lithotripsy and ureteroscopy.

Deng T et al, 2015: New-onset diabetes mellitus after shock wave lithotripsy for urinary stone: a systematic review and meta-analysis.

Deng T et al, 2018: Systematic review and cumulative analysis of the managements for proximal impacted ureteral stones.

Desai M et al, 2017: Treatment selection for urolithiasis: percutaneous nephrolithomy, ureteroscopy, shock wave lithotripsy, and active monitoring.

Desai MR, 2012: Urolithiasis: newer trends and practice

Desoky EA et al, 2016: Immediate versus delayed shockwave lithotripsy for inaccessible stones after uncomplicated percutaneous nephrolithotomy.

Dincel N et al, 2013: Are small residual stone fragments really insignificant in children?

Ding J et al, 2015: Tailored minimally invasive management of complex calculi in horseshoe kidney.

Dogan HS et al, 2012: Minimally invasive surgical approaches to kidney stones in children

Dogan HS et al, 2015: A new nomogram for prediction of outcome of pediatric shock-wave lithotripsy.

Donaldson JF et al, 2015: Systematic Review and Meta-analysis of the Clinical Effectiveness of Shock Wave Lithotripsy, Retrograde Intrarenal Surgery, and Percutaneous Nephrolithotomy for Lower-pole Renal Stones.

Donaldson JF, 2015: Difference of opinion - In the era of flexible ureteroscopy is there still a place for Shock-wave lithotripsy? Opinion: YES.

Drake T et al, 2017: What are the Benefits and Harms of Ureteroscopy Compared with Shock-wave Lithotripsy in the Treatment of Upper Ureteral Stones? A Systematic Review.

Durmuş G et al, 2017: Assessment of electrocardiographic parameters in adult patients undergoing extracorporeal shockwave lithotripsy.

Duryea AP et al, 2011: In vitro comminution of model renal calculi using histotripsy

Duryea AP et al, 2013. Controlled cavitation to augment SWL stone comminution: mechanistic insights in vitro

Duryea AP et al, 2013: Acoustic Bubble Removal to Enhance SWL Efficacy at High Shock Rate: An In Vitro Study

Duryea AP et al, 2015: Removal of residual cavitation nuclei to enhance histotripsy erosion of model urinary stones.

Duryea AP et al, 2015: Removal of residual nuclei following a cavitation event using low-amplitude ultrasound.

Dzięgała M et al, 2018: Evaluation and physiopathology of minor transient shock wave lithotripsy - induced renal injury based on urinary biomarkers levels.

Eker HE et al, 2012: IV paracetamol effect on propofol-ketamine consumption in paediatric patients undergoing ESWL

el-Assmy A et al, 2011: Multidetector computed tomography: role in determination of urinary stones composition and disintegration with extracorporeal shock wave lithotripsy--an in vitro study

El-Assmy A et al, 2013: Kidney stone size and hounsfield units predict successful shockwave lithotripsy in children

El-Assmy A et al, 2015: Clinically Insignificant Residual Fragments: Is It an Appropriate Term in Children?

El-Assmy A et al, 2015: Risk factors for formation of steinstrasse after extracorporeal shock wave lithotripsy for pediatric renal calculi: a multivariate analysis model.

El-Assmy A et al, 2016: Does lithotripsy increase stone recurrence? A comparative study between extracorporeal shockwave lithotripsy and non-fragmenting percutaneous nephrolithotomy.

El-Halwagy S et al, 2013: Shock wave lithotripsy of vesical stones in patients with infravesical obstruction: an underused noninvasive approach

El-Nahas AR et al, 2012: Flexible ureterorenoscopy versus extracorporeal shock wave lithotripsy for treatment of lower pole stones of 10-20 mm

El-Nahas AR et al, 2013: Extracorporeal shockwave lithotripsy for renal stones in pediatric patients: A multivariate analysis model for estimating the stone-free probability

El-Nahas AR et al, 2016: A randomized controlled trial evaluating renal protective effects of selenium with vitamins A, C, E, verapamil, and losartan against extracorporeal shockwave lithotripsy-induced renal injury.

El-Nahas AR et al, 2017: Hospital admission for treatment of complications after extracorporeal shock wave lithotripsy for renal stones: a study of risk factors.

El-Nahas et al, 2012: Are there long-term effects of extracorporeal shockwave lithotripsy in paediatric patients?

Elawdy MM et al, 2018: Extracorporeal shock wave lithotripsy for bilateral renal stones: A case report with serious complications that could be avoided.

Elderwy AA et al, 2014: Dissolution Therapy versus Shock Wave Lithotripsy for Radiolucent Renal Stones in Children: A Prospective Study

Elkholy MM et al, 2015: Efficacy of extracorporeal shockwave lithotripsy using Dornier SII in different levels of ureteral stones.

Elkoushy MA et al, 2011: Factors Determining Stone-free Rate in Shock Wave Lithotripsy Using Standard Focus of Storz Modulith SLX-F2 Lithotripter

Elkoushy MA et al, 2012: Impact of Radiological Technologists on the Outcome of Shock Wave Lithotripsy

Ellison JS et al, 2017: Patient-Reported Outcomes in Nephrolithiasis: Can We Do Better?

Ellison JS et al, 2018: Risk factors for repeat surgical intervention in pediatric nephrolithiasis: A Pediatric Health Information System database study.

Elmansy HE et al, 2016: Recent advances in lithotripsy technology and treatment strategies: A systematic review update.

Elnabtity AM et al, 2015: Is unilateral transversus abdominis plane block an analgesic alternative for ureteric shock wave lithotripsy?

Elnabtity AM et al, 2016: Unilateral versus bilateral ultrasound-guided transversus abdominis plane blocks during ureteric shock wave lithotripsy: A prospective randomized trial.

ElSheemy MS et al 2016: Lower calyceal and renal pelvic stones in preschool children: A comparative study of mini-percutaneous nephrolithotomy versus extracorporeal shockwave lithotripsy.

Elsheemy MS, 2013: Editorial Comment from Dr ElSheemy to Extracorporeal shockwave lithotripsy for renal stones in pediatric patients: A multivariate analysis model for estimating the stone-free probability

Emiliani E et al, 2018: Over 30-yr Experience on the Management of Graft Stones After Renal Transplantation.

Ergin G et al, 2018: Shock wave lithotripsy or retrograde intrarenal surgery: which one is more effective for 10-20-mm renal stones in children.

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Sarica K et al, 2017: Super-mini percutaneous nephrolithotomy for renal stone less than 25mm in pediatric patients: Could it be an alternative to shockwave lithotripsy?

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Saxena S et al, 2013: Treating stones in transplanted kidneys

Scales CD Jr et al, 2014: Comparative Effectiveness of Shock Wave Lithotripsy and Ureteroscopy for Treating Patients With Kidney Stones.

Scales CD Jr, 2013: Practice patterns in the management of urinary lithiasis

Schnabel MJ et al, 2014: Antiplatelet and anticoagulative medication during shock wave lithotripsy.

Schnabel MJ et al, 2014: Incidence and risk factors of renal hematoma: a prospective study of 1,300 SWL treatments

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Schregel C et al, 2017: Influence of acetylsalicylic acid and low-molecular weight heparins on the formation of renal hematoma after shock wave lithotripsy.

Schults AJ et al, 2017: Combination of Extracorporeal Shockwave Lithotripsy and Ureteroscopy for Large Staghorn Calculi in a Pediatric Patient: Case Report.

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Sener NC et al, 2015: Asymptomatic lower pole small renal stones: shock wave lithotripsy, flexible ureteroscopy, or observation? A Prospective randomized trial.

Senyucel MF et al, 2013: Evaluation of contralateral kidney, liver and lung after extracorporeal shock wave lithotripsy in rabbits

Sermeus L et al, 2017: Hypovolemic Shock Caused by Massive Renal Hematoma After a Third Consecutive Extracorporeal Shockwave Lithotripsy Session: A Case Report.

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Sfoungaristos S et al, 2015: Do we really need kidneys-ureters-bladder radiography to predict stone radiopacity before treatment with shockwave lithotripsy? Development and internal validation of a novel predictive model based on computed tomography parameters.

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Shafi H et al, 2018: Antibiotic prophylaxis in the prevention of urinary tract infection in patients with sterile urine before extracorporeal shock wave lithotripsy.

Shahat A et al, 2016: Is Tamsulosin Effective after Shock Wave Lithotripsy for Pediatric Renal Stones? A Randomized, Controlled Study.

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Sharma R et al, 2017: Can a brief period of double J stenting improve the outcome of extracorporeal shock wave lithotripsy for renal calculi sized 1 to 2 cm?

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Shen L et al, 2011: Comparison of Efficacy of German and Chinese Electromagnetic Shock Wave Lithotripters: Dornier Compact S vs Huikang MZ-SWL-V

Shen P et al, 2011: Use of ureteral stent in extracorporeal shock wave lithotripsy for upper urinary calculi: a systematic review and meta-analysis

Sheng B et al, 2010: The protective effects of the traditional Chinese herbs against renal damage induced by extracorporeal shock wave lithotripsy: a clinical study

Shim M et al, 2014: Multimodal treatments of cystine stones: an observational, retrospective single-center analysis of 14 cases.

Shim M et al, 2017: The efficacy of performing shockwave lithotripsy before retrograde intrarenal surgery in the treatment of multiple or large (≥1.5 cm) nephrolithiasis: A propensity score matched analysis.

Shinde S et al, 2018: Factors Affecting the Outcome of Extracorporeal Shockwave Lithotripsy in Urinary Stone Treatment.

Shoar K et al, 2017: Tracking kidney stones in a homogeneous medium using a trilateration approach.

Silay MS et al, 2017: Update on Urinary Stones in Children: Current and Future Concepts in Surgical Treatment and Shockwave Lithotripsy.

Silbert BS et al, 2014: Incidence of postoperative cognitive dysfunction after general or spinal anaesthesia for extracorporeal shock wave lithotripsy.

Simal I et al, 2016: Therapeutic possibilities for urolithiasis in childhood.

Singh BP et al, 2014: Retrograde Intrarenal Surgery vs Extracorporeal Shock Wave Lithotripsy for Intermediate Size Inferior Pole Calculi: A Prospective Assessment of Objective and Subjective Outcomes

Singh SK et al, 2011: Role of tamsulosin in clearance of upper ureteral calculi after extracorporeal shock wave lithotripsy: a randomized controlled trial

Sivalingam S et al, 2015: Contemporary Practice Patterns in the Management of Acute Obstructing Ureteral Stones.

Skinner TA et al, 2012: Variables influencing the likelihood of cardiac dysrhythmias during extracorporeal shock wave lithotripsy

Skolarikos A et al, 2015: Manuscript Title: the Efficacy of Medical Expulsive Therapy (MET) in Improving Stone-Free Rate and Stone Expulsion Time, after Extracorporeal Shock Wave Lithotripsy (SWL) for Upper Urinary Stones: a Systematic Review and Meta-Analysis.

Skuginna V et al, 2015: Does Stepwise Voltage Ramping Protect the Kidney from Injury During Extracorporeal Shockwave Lithotripsy? Results of a Prospective Randomized Trial.

Smith HE et al, 2017: Extracorporeal shockwave lithotripsy without radiation: Ultrasound localization is as effective as fluoroscopy.

Smith NB et al, 2013: A heuristic model of stone comminution in shock wave lithotripsy

Smrkolj T et al, 2015: Endoscopic Removal of a Nitinol Mesh Stent from the Ureteropelvic Junction after 15 Years.

Soliman T et al, 2016: Miniperc versus shockwave lithotripsy for average sized radiopaque lower pole calculi: A prospective randomized study.

Sorensen MD et al, 2012: Quantitative Assessment of Shockwave Lithotripsy Accuracy and the Effect of Respiratory Motion

Soydan H et al, 2012: Postshockwave Lithotripsy Outcome Evaluation in Ureteral Stones: Comparison Between Noncontrast Computed Tomography and Plain Abdominal Radiography

Sridharan K et al, 2017: Medical expulsive therapy in urolithiasis: a mixed treatment comparison network meta-analysis of randomized controlled clinical trials.

Sridharan K et al, 2018: Efficacy and safety of alpha blockers in medical expulsive therapy for ureteral stones: a mixed treatment network meta-analysis and trial sequential analysis of randomized controlled clinical trials.

Srini VS et al, 2015: Low intensity extracorporeal shockwave therapy for erectile dysfunction: a study in an Indian population.

Srisubat A et al, 2015: Extracorporeal shock wave lithotripsy (ESWL) versus percutaneous nephrolithotomy (PCNL) or retrograde intrarenal surgery (RIRS) for kidney stones.

Srivastava A et al, 2012: Percutaneous nephrolithotomy in polycystic kidney disease: is it safe and effective?

Srivastava A et al, 2013: Management of 1-2 cm renal stones

Stasinou T et al, 2015: Re: Antiplatelet and Anticoagulative Medication During Shockwave Lithotripsy.

Stravodimos KG et al, 2012: Renal transplant lithiasis: analysis of our series and review of the literature

Streeper NM, 2018: Asymptomatic Renal Stones-to Treat or Not to Treat.

Sugihara T et al, 2012: Renal haemorrhage risk after extracorporeal shockwave lithotripsy: Results from the Japanese Diagnosis Procedure Combination Database

Tailly GG et al, 2014: Optical Coupling Control: An Important Step Toward Better Shockwave Lithotripsy.

Tailly GG, 2013: Extracorporeal shock wave lithotripsy today

Takahara K et al, 2012: Predictors of success for stone fragmentation and stone-free rate after extracorporeal shockwave lithotripsy in the treatment of upper urinary tract stones

Tanaka N et al, 2013: Stone attenuation value and cross-sectional area on computed tomography predict the success of shock wave lithotripsy

Tandan M et al, 2016: Management of Pancreatic Calculi: An Update.

Tao T et al, 2017: Outcome of a session of extracorporeal shock wave lithotripsy before endoscopic retrograde cholangiopancreatography for problematic and large common bile duct stones.

Taşdemir S et al, 2015: Meralgia paresthetica after the fragmentation of renal stone using extracorporeal shock wave lithotripsy: a case report.

Tauber V et al, 2015: Efficacy Management of Urolithiasis: Flexible Ureteroscopy versus Extracorporeal Shockwave Lithotripsy.

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Tejwani R et al, 2016: Increased pediatric sub-specialization is associated with decreased surgical complication rates for inpatient pediatric urology procedures.

Tekgül S, 2011: Ureteroscopy versus shock wave lithotripsy for renal calculi in children

Telegrafo M et al, 2016: Diagnostic and prognostic role of computed tomography in extracorporeal shock wave lithotripsy complications.

Telli O et al, 2015: Does previous stone treatment in children generate a disadvantage or just the opposite?

Telli O et al, 2015: What is the best option for 10-20mm renal pelvic stones undergoing ESWL in the pediatric population: stenting, alpha blockers or conservative follow-up?

Telli O et al, 2017: What happens to asymptomatic lower pole kidney stones smaller than 10 mm in children during watchful waiting?

Thiel DD et al, 2011: Evaluation of pancreatic damage after extracorporeal shock wave lithotripsy, percutaneous stone surgery, and ureteroscopy

Thomas K, 2015: Evolution of extracorporeal shockwave lithotripsy (ESWL).

Tiselius HG et al, 2012: Aspects on how extracorporeal shockwave lithotripsy should be carried out in order to be maximally effective

Tiselius HG et al, 2015: Arguments for choosing extracorporeal shockwave lithotripsy for removal of urinary tract stones.

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Tiselius HG, 2012: Words of wisdom: Re: Alkaline citrate reduces stone recurrence and regrowth after shockwave lithotripsy and percutaneous nephrolithotomy

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Torbati SS et al, 2014: Renal rupture following extracorporeal shockwave lithotripsy.

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Tsai CC et al, 2017: Low-Intensity Extracorporeal Shockwave Therapy Can Improve Erectile Function in Patients Who Failed to Respond to Phosphodiesterase Type 5 Inhibitors.

Tsakaldimis G et al, 2015: Tumor necrosis factor A and interleucin 6 serum values in patients undergoing extracorporeal shock wave lithotripsy for ureteral stones.

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Uğuz S et al, 2016: Medical ozone therapy reduces shock wave therapy-induced renal injury.

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Vicentini FC et al, 2011: Adjuvant Tamsulosin or Nifedipine After Extracorporeal Shock Wave Lithotripsy for Renal Stones: a Double Blind, Randomized, Placebo-controlled Trial

Vicentini FC, 2015: Difference of opinion - In the era of flexible ureteroscopy is there still a place for Shock-wave lithotripsy? Opinion: NO

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Vilches RM et al, 2015: Comparison between retrograde intrarenal surgery and extracorporeal shock wave lithotripsy in the treatment of lower pole kidney stones up to 15mm. Prospective, randomized study.

Vittori M et al, 2016: Neutrophil gelatinase-associated lipocalin (NGAL) value changes before and after shock wave lithotripsy.

Vivaldi B et al, 2011: Single-Session Extracorporeal Shock Wave Lithotripsy for Urinary Calculi: Factors Predicting Success after Three Weeks of Follow-Up

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Vogt B et al, 2016: MiniJFil®: A New Safe and Effective Stent for Well-Tolerated Repeated Extracorporeal Shockwave Lithotripsy or Ureteroscopy for Medium-to-Large Kidney Stones?

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Wang D et al, 2018: Extracorporeal Shock Wave Lithotripsy for Chronic Pancreatitis Patients With Stones After Pancreatic Surgery.

Wang H et al, 2017: Meta-Analysis of Stenting versus Non-Stenting for the Treatment of Ureteral Stones.

Wang HH et al, 2012: Shock wave lithotripsy vs ureteroscopy: variation in surgical management of kidney stones at freestanding children's hospitals

Wang HS et al, 2018: Delayed Low-Intensity Extracorporeal Shock Wave Therapy Ameliorates Impaired Penile Hemodynamics in Rats Subjected to Pelvic Neurovascular Injury.

Wang JC et al, 2014: Suppressing bubble shielding effect in shock wave lithotripsy by low intensity pulsed ultrasound.

Wang JC, Zhou Y. 2016: Shifting the Split Reflectors to Enhance Stone Fragmentation of Shock Wave Lithotripsy.

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Wang YB et al, 2018: Efficacies of Various Surgical Regimens in the Treatment of Renal Calculi Patients: a Network Meta-Analysis in 25 Enrolled Controlled Clinical Trials.

Wankhade NH et al, 2014: Comparative Study of Lithotripsy and PCNL for 11-15 mm Lower Caliceal Calculi In Community Health Hospital.

Waqas M et al, 2017: Comparison of Different Analgesia Drug Regimens for Pain Control During Extracorporeal Shock Wave Lithotripsy for Renal Stones: A Randomized Control Study.

Waqas M et al, 2017: Non-Contrast Computed Tomography Scan Based Parameters of Ureteric Stones Affecting the Outcome of Extracorporeal Shock Wave Lithotripsy.

Waqas M et al, 2018: Evaluating the importance of different computed tomography scan-based factors in predicting the outcome of extracorporeal shock wave lithotripsy for renal stones.

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Welk B et al, 2012: Renal Stone Disease in Spinal-Cord-Injured Patients

Welk B et al, 2013: The surgical management of upper tract stone disease among spinal cord-injured patients

Weng CH et al, 2013: Severe acute pancreatitis with abscess after extracorporeal shock wave lithotripsy: a rare complication

Wiesenthal JD et al, 2011: A clinical nomogram to predict the successful shock wave lithotripsy of renal and ureteral calculi

Wiesenthal JD et al, 2011: A comparison of treatment modalities for renal calculi between 100 and 300 mm2: are shockwave lithotripsy, ureteroscopy, and percutaneous nephrolithotomy equivalent?

Williams JC Jr et al, 2012: Fragility of brushite stones in shock wave lithotripsy: absence of correlation with computerized tomography visible structure

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Woźniak P et al, 2017: Evaluation of hemostasis parameters and the role of the oxidative damage to plasma proteins in the modulation of hemostasis in patients with nephrolithiasis before and after extracorporeal shock wave lithotripsy.

Wu H et al, 2015: Treatment of Renal Stones ≥20 mm with Extracorporeal Shock Wave Lithotripsy.

Wu W et al, 2017: How to accelerate the upper urinary stone discharge after extracorporeal shockwave lithotripsy (ESWL) for bole (EPVL).

Xing Y et al, 2017: Comparison of Broad vs Narrow Focal Width Lithotripter Fields.

Xu G et al, 2015: A comparative study to analyze the efficacy and safety of flexible ureteroscopy combined with holmium laser lithotripsy for residual calculi after percutaneous nephrolithotripsy.

Xu Y et al, 2014: A meta-analysis of the efficacy of ureteroscopic lithotripsy and extracorporeal shock wave lithotripsy on ureteral calculi.

Ya Wei B et al, 2017: Hepatic Subcapsular Hematoma Breaking into the Abdominal Cavity after Extracorporeal Shock Wave Lithotripsy for Pancreatic Stones.

Yamaçake KGR et al, 2018: Low-intensity shockwave therapy for erectile dysfunction in kidney transplant recipients. A prospective, randomized, double blinded, sham-controlled study with evaluation by penile Doppler ultrasonography.

Yamashita S et al, 2017: Upper urinary tract stone disease in patients with poor performance status: active stone removal or conservative management?

Yamashita S et al, 2017: Variation Coefficient of Stone Density: A Novel Predictor of the Outcome of Extracorporeal Shockwave Lithotripsy.

Yanaral F et al, 2018: Shock-wave Lithotripsy for Pediatric Patients: Which Nomogram Can Better Predict Postoperative Outcomes?

Yang C et al, 2016: Comparison of YAG Laser Lithotripsy and Extracorporeal Shock Wave Lithotripsy in Treatment of Ureteral Calculi: A Meta-Analysis.

Yang TK et al, 2013: Body mass index and buttock circumference are independent predictors of disintegration failure in extracorporeal shock wave lithotripsy for ureteral calculi

Yang TX et al, 2017: A network meta-analysis on the beneficial effect of medical expulsive therapy after extracorporeal shock wave lithotripsy.

Yazici O et al, 2015: Shock Wave Lithotripsy in Ureteral Stones: Evaluation of Patient and Stone Related Predictive Factors.

Yee CH et al, 2014: Extracorporeal shockwave therapy in the treatment of erectile dysfunction: A prospective, randomized, double-blinded, placebo controlled study.

Yencilek E et al, 2015: The Daily Resistive Index measurement useful tool in the estimation of the optimal time interval between two Shock Wave Lithotripsy sessions.

Yesil S et al, 2013: Previous Open Renal Surgery Increased Vascular Complications in Percutaneous Nephrolithotomy (PCNL) Compared with Primary and Secondary PCNL and Extracorporeal Shock Wave Lithotripsy Patients: A Retrospective Study

Yesil S et al, 2015: Effect of different analgesics on pain relief during extracorporeal shock wave lithotripsy.

Yildirim K et al, 2018: Trends in the treatment of urinary stone disease in Turkey.

Yilmaz B et al, 2012: An FDTD-based computer simulation platform for shock wave propagation in electrohydraulic lithotripsy

Yilmaz E et al, 2013: Ways in which SWL affects oxidant/antioxidant balance

Yong DZ et al, 2011: Optimization of treatment strategy used during shockwave lithotripsy to maximize stone fragmentation efficiency

Yoo DE et al, 2012: Removal of kidney stones by extracorporeal shock wave lithotripsy is associated with delayed progression of chronic kidney disease

Yoshimura K, 2012: Editorial Comment to Extracorporeal shock wave lithotripsy for distal ureteral calculi: Improved efficacy using low frequency

Younesi Rostami M et al, 2012: Treatment of Kidney Stones Using Extracorporeal Shock Wave Lithotripsy (ESWL) and Double-J Stent in Infants

Yu C et al, 2013: A systematic review and meta-analysis of new onset hypertension after extracorporeal shock wave lithotripsy

Yuan HJ et al, 2015: Minimally invasive treatment of renal transplant nephrolithiasis.

Yucel MO et al, 2017: The Respiratory Induced Kidney Motion: Does It Really Effect the Shock Wave Lithotripsy?

Yucel S et al, 2012: Complications and associated factors of pediatric extracorporeal shock wave lithotripsy

Yuri P et al, 2018: Meta-analysis of Optimal Management of Lower Pole Stone of 10 - 20 mm: Flexible Ureteroscopy (FURS) versus Extracorporeal Shock Wave Lithotripsy (ESWL) versus Percutaneus Nephrolithotomy (PCNL).

Yuruk E et al, 2015: Comparison of Shockwave Lithotripsy and Flexible Ureteroscopy for the Treatment of Kidney Stones in Patients with a Solitary Kidney.

Yürük E et al, 2015: Previous shock-wave lithotripsy treatment does not impact the outcomes of flexible ureterorenoscopy.

Zafar S et al, 2018: Bilateral Psoas Abscess After Extracorporeal Shock Wave Lithotripsy: Reminder Of A Rare Complication.

Zanetti G, 2011: Ureteral stones: SWL treatment

Zang ZJ et al, 2018: The impact of low-intensity extracorporeal shock wave therapy on testicular function in adult rats.

Zavitsanos PJ et al, 2013: Low Methodological and Reporting Quality of Randomized, Controlled Trials of Devices to Treat Urolithiasis

Zaytoun OM et al, 2011: Tamsulosin and doxazosin as adjunctive therapy following shock-wave lithotripsy of renal calculi: randomized controlled trial

Zehnder P et al, 2011: A prospective randomised trial comparing the modified HM3 with the MODULITH® SLX-F2 lithotripter

Zekey F et al, 2012: Evaluation of the Impact of Shock Wave Lithotripsy on Kidneys Using a New Marker: How Do Neutrophil Gelatinese-associated Lypocalin Values Change After Shock Wave Lithotripsy?

Zeng G et al, 2012: Treatment of renal stones in infants: comparing extracorporeal shock wave lithotripsy and mini-percutaneous nephrolithotomy

Zewin TS et al, 2018: Efficacy and safety of low-intensity shock wave therapy in penile rehabilitation post nerve-sparing radical cystoprostatectomy: a randomized controlled trial.

Zhang H et al, 2018: Comparison of the Efficacy of Ultra-Mini PCNL, Flexible Ureteroscopy, and Shock Wave Lithotripsy on the Treatment of 1-2 cm Lower Pole Renal Calculi.

Zhang J et al, 2011: Cost-effectiveness analysis of ureteroscopic laser lithotripsy and shock wave lithotripsy in the management of ureteral calculi in eastern china

Zhang LJ, 2012: Shock-wave lithotripsy for renal calculi

Zhang X et al, 2016: Low-Energy Shockwave Therapy Improves Ischemic Kidney Microcirculation.

Zhang Y et al, 2016: Effects of Stone Size on the Comminution Process and Efficiency in Shock Wave Lithotripsy.

Zheng C et al, 2015: Extracorporeal shock wave lithotripsy versus retrograde intrarenal surgery for treatment for renal stones 1-2 cm: a meta-analysis.

Zhong W et al, 2013: Percutaneous nephrolithotomy for renal stones following failed extracorporeal shockwave lithotripsy: different performances and morbidities

Zhou SG et al, 2011: Comparing efficacy of α(1)D-receptor antagonist naftopidil and α1A/D-receptor antagonist tamsulosin in management of distal ureteral stones

Zhou Y et al, 2012: Characteristics of the secondary bubble cluster produced by an electrohydraulic shock wave lithotripter

Zhou Y, 2012: Reduction of bubble cavitation by modifying the diffraction wave from a lithotripter aperture

Zhu GQ et al, 2018: Efficient Promotion of Autophagy and Angiogenesis Using Mesenchymal Stem Cell Therapy Enhanced by the Low-Energy Shock Waves in the Treatment of Erectile Dysfunction.

Zhu X et al, 2013: Retrograde, Antegrade, and Laparoscopic Approaches to the Management of Large Upper Ureteral Stones After Shockwave Lithotripsy Failure: A Four-Year Retrospective Study

Ziaee SA et al, 2011: Impact of Sleep Position on Stone Clearance after Shock Wave Lithotripsy in Renal Calculi

Zodda D et al, 2017: A Novel Case of Splenic Injury After Shockwave Lithotripsy.

Zolfaghari A et al, 2013: Renal vascular Doppler resistance after extracorporeal shock wave lithotripsy

Zou ZJ et al, 2017: Low-intensity extracorporeal shock wave therapy for erectile dysfunction after radical prostatectomy: a review of preclinical studies.

Zou ZJ et al, 2017: Short-term efficacy and safety of low-intensity extracorporeal shock wave therapy in erectile dysfunction: a systematic review and meta-analysis.