e805cca3fea76d5242aee7c904b63caa.ppt
- Количество слайдов: 36
PCNL A Global Perspective Dr CW Wong Division of Urology Department of Surgery Pamela Youde Nethersole Eastern Hospital
l l l l l Introduction and history PCNL: what is it? Indications Imaging modalities for percutaneous access Dilatation of the nephrostomy tract Mini-perc technique Mode of stone fragmentation Chinese MPCNL: PYNEH experience Conclusion
Introduction and history l 1865 Thomas Hillier described first percutaneous nephrostomy l 1955 Willard Goodwin & associates reported their experience with percutaneous nephrostomies in 16 patients l 1976 Fernstrom & Johansson described a procedure through which a renal pelvic calculus could be extracted through a percutaneous tract l Early 80 s Percutaneous nephrolithotomy gained widespread popularity
PCNL & ESWL l With the advent of ESWL in the mid 80 s, the indications for percutaneous stone extraction were narrowed l As the limitations of ESWL were recognised, percutaneous surgery once again rose in popularity with a redefined role in stone management
PCNL: what is it? Percutaneous nephrolithotripsy l Retrograde pyelogram l Tract formation for renal access l
PCNL: what is it? l Stone fragmentation & retrieval
Indications l PCNL is the preferred treatment for l l l l Large stone burden 2 cm or 1. 5 cm for lower calyceal stones Staghorn stones Stones that are difficult to disintegrate by ESWL (calcium-oxalate monohydrate, brushite, cystine) Stones refractory to ESWL or ureteroscopy Urinary tract obstructions that need simultaneous correction (e. g. PUJ obstruction) Malformations with reduced probability of fragment passage after ESWL (e. g. horseshoe or dystopic kidneys, calyceal diverticula) Obesity EAU Guidelines on Urolithiasis 2001
Imaging modalities for percutaneous access l Image guided l Fluoroscopy l USG
Imaging modalities for percutaneous access l Fluoroscopy l Most commonly employed l Use of 2 -plane fluoroscopy to achieve accurate needle entry l Radiation safety: patient, surgeons, staff
Imaging modalities for percutaneous access l Ultrasonography: l The simplest & most direct l Minimises radiation exposure l Allows imaging of intervening structures between skin and kidney l Sonographic identification of the puncture needle may be technically demanding l Inability to clearly visualise and manipulate a guidewire once it is placed through the percutaneous access tract
Dilatation of the nephrostomy tract Progressive fascial dilators l Metal coaxial dilators l Balloon dilation catheters l
Dilation of the nephrostomy tract l Fascial dilators l Progressively larger Teflon tubes designed to slide over a 0. 038 inch GW l Size ranging from 8 to 36 Fr l Inserted in a rotating, screw-type fashion l Advantages: l Safe l Ideal for dilation of fibrous tracts l Disadvantages: l Dependence on the integrity of the GW
Dilation of the nephrostomy tract l Metal coaxial dilators l l l Stainless steel, mounted together in a telescopic fashion 8 Fr hollow guide rod that slides over a GW A set of six metal tubes ranging in diameter from 9 to 24 Fr, each adapting exactly to the lumen of the next dilators
Dilation of the nephrostomy tract l Balloon dilation catheters l To achieve tract dilation in a single step l Avoid the need for serial dilation l Generate lateral compressive forces, theoretically less traumatic l Drawback: relative inability to dilate dense fascial tissue or scar tissue
Mini-perc technique Use of 13 to 20 Fr tract l Smaller volume of renal parenchyma dilated, leading to decrease in blood loss and post-op pain l Lahme et al Eur Urol. 40(6): 619 -24
Stone fragmentation l Electrohydraulic Lithotripsy l Fragments stones with shock waves generated by an underwater electrical discharge l Narrow margin of safety owing to the risk of damage to ureteral mucosa and ureteral perforation
Stone fragmentation l Holmium: YAG laser lithotripsy l Occurs primarily through a photothermal mechanism that causes stone vaporisation l Highly absorbed by water l Zone of thermal injury associated with laser ablation ranges from 0. 5 to 1. 0 mm l Able to fragment all stones regardless of composition
Stone fragmentation l Ballistic Lithotripsy l l A “jackhammer” effect Swiss Litho. Clast Effective means for stone fragmentation in the entire urinary tract with wide margin of safety Relatively high rate of stone propulsion
Stone fragmentation l Ultrasonic lithotripsy l Probe tip causes the stone to resonate at high frequency and break l When placing it on compliant tissues such as the urothelium, damage is minimal because the tissue does not resonate with the vibrational energy
Minimally Invasive PCNL (MPCNL) according to the Chinese Method: A Comparison with Traditional PCNL CW Wong, TC Fung, CW Fan, SM Hou, SK Li Division of Urology, Department of Surgery Pamela Youde Nethersole Eastern Hospital Hong Kong
Chinese MPCNL l Minimally invasive PCNL, according to the Chinese method l MPCNL l First described by Lahme, Germany in 2001 Eur Urol. 40(6): 619 -24 l The term Chinese MPCNL l l Coined by Dr SK Li, PYNEH at ELSA 2005 Based on the approach described by Professor Li Xun, Guangzhou, China
Essential features l Puncture: l Kidney puncture based on pre-op imaging and tactile feedback l Minimal use of fluoroscopy l Size Fr 18 tract l Stone fragmentation: l Litho. Clast® l (using 1 mm probe) Stone removal: l Mainly by retrograde saline flushing
Puncture & tract dilatation 12 th rib 11 th rib puncture site in 11 th intercostal space Patient in prone position
Miniaturized endoscope Olympus® slim compact cystoscope
Pressurized irrigation 350 mm. Hg
Access to all calyces & ureter
MPCNL: the technique
Method l Patients l 16 consecutive cases of staghorn stones l Underwent Chinese MPCNL by one single Surgeon l Statistical analysis l Results were retrospectively compared to that of the last 20 cases of traditional PCNL using Fr 24 -28 sheath
Results – stone characteristics Chinese MPCNL 3. 79 1. 3 3. 36 0. 94 784. 8 926. 3 Borderline 5 (31) 13 (65) Partial 9 (56) 5 (25) Complete 2 (13) 2 (10) Stone diameter (cm) Stone area (mm²) Type n (%)
Results – operative parameters & outcome Chinese MPCNL OR time (minutes) 94. 7 122 Length of stay (day) 6. 7 7. 6 8 (50) 12 (60) Residual ≤ 4 mm 2 (12. 5) 2 (10) Residual > 4 mm 6 (37. 5) 6 (30) 5 6 Stone clearance n (%) Complete Auxiliary treatment
Results - complications Chinese MPCNL Transfusion UTI 1 (6. 3) 5 (25) 2 (10) Pleural effusion 1 (6. 3) 0 TOTAL 3 (18. 9) 7 (35) Complications n (%)
Advantages of Chinese MPCNL l Miniaturised endoscope allows good calyceal and ureteric access even with middle calyceal puncture l Middle calyceal puncture at 11 th intercostal space avoids risk associated with supra-11 th upper pole calyceal puncture l A Fr 18 percutaneous tract minimises trauma with less blood loss
Conclusion l l l PCNL is a good and valuable method for removal of renal calculi Different techniques of percutaneous renal access, tract dilation and stone fragmentation have been developed Mini-perc is an evolving PCNL technique l l l An effective treatment option even for staghorn stone Good stone clearance Good calyceal and ureteric access A safe option Reducing trauma Less transfusion requirement
eedle is being advanced with the C-arm at 30 degrees. A, Use of a clamp to reduce radiatio gist. B, The C-arm is rotated back to the vertical position, and the depth of the needle is asc
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