Pediatrics: UPJO & Megaureter

Ureteropelvic Junction Obstruction (UJPO)[edit | edit source]

• See Ureteropelvic Junction Obstruction Chapter Notes

Differential Diagnosis of Hydronephrosis in Child[edit | edit source]

1. Ureteropelvic junction obstruction
2. Multicyclic dysplastic kidney
3. Ureteral stone
4. Extrarenal pelvis
5. Malignant ureteral obstruction
6. Megaureter
7. Peripelvic cyst
8. Retrocaval ureter
9. Vesicoureteral reflux (VUR)
10. Fibroepithelial polyp
11. Calyceal diverticulum

Management[edit | edit source]

Options (2):[edit | edit source]

1. Observation
2. Surgical intervention
   1. Endoscopic
   2. Pyeloplasty

Observation[edit | edit source]

• Only ≈1/3 of affected children will need surgical intervention

Intervention[edit | edit source]

Indications (4):[edit | edit source]

1. Symptoms
2. Infections while on prophylactic antibiotics
3. Increasing hydronephrosis
4. Low or decreasing differential renal function

Pyeloplasty[edit | edit source]

• Dismembered Pyeloplasty
  • Improved outcomes over non-dismemembered approach in the repair of a UPJO
    • Anderson-Hynes dismembered pyeloplasty is the preferred technique  
    • Advantages of dismembering the UPJ (3):
      1. A vessel crossing the lower pole can be preserved
      2. The adynamic part of the ureter excised
      3. Redundant pelvic tissue reduced
      • Main steps of the Anderson-Hynes dismembered pyeloplasty:
        • After opening the Gerota fascia, the anterior or posterior aspect of the UPJ is dissected (depending on the access used). The lower pole of the kidney is freed to avoid overlooking an accessory vessel. Electrocautery should be used with caution to minimize damage to the blood supply of both the pelvis and the ureter, with preference given to bipolar diathermy.
        • A stay suture is placed in the pelvis proximal to the anticipated line of dismemberment; another stay suture can be placed in the ureter at the level of the stenosis.
        • The UPJ is dismembered, and the pelvis reduced if indicated. A tensely dilated pelvis should be decompressed with a 21-gauge needle before dismembering, to avoid excessive pelvic reduction.
        • The ureter is then spatulated along its lateral border, well beyond the dysplastic stenotic segment and carried through adequately into healthy ureteral tissue. At this stage, the stenotic part of the ureter should not be removed, because it can serve as a handle that minimizes ureteral tissue manipulation while performing the anastomosis, reducing the risk for mucosal edema.
        • The anastomosis can be completed with interrupted or continuous suturing. Suture size depends on the prevailing anatomy, but most often a 6-0 or 5-0 resorbable monofilament suture on a round needle is used. Care should be taken at the tip of the V of the anastomosis, which has to be assembled precisely and in a tension-free manner. Placing inadvertent excessive tension on the stay sutures while aligning the anastomosis should be avoided because it can lead to kinking of the ureter once tension is relieved.
        • Just before completing the anastomosis, the stenotic part of the ureter is removed and the pelvis is irrigated with saline to avoid blood clots obstructing the ureter.
        • Stenting the anastomosis is a matter of choice
        • The kidney is brought back to its native position, and the anastomosis can be covered with perinephric fat if available.
        • Usually the use of external drainage in the form of a Penrose is not indicated
• Non-dismembered Pyeloplasty
  • Techniques: Heineke-Mikulicz, Foley Y-V plasty
• Laparoscopic vs. open pyeloplasties
  • Laparoscopic pyeloplasties provide excellent visualization of the anatomy, enhance cosmesis, and duplicate the results of open pyeloplasties with short-term follow-up.
    • During laparoscopy monopolar cautery increases the risk of unrecognized lesions to intra-abdominal organs, particularly the bowel.
    • The technical challenges of this approach have been facilitated by the use of a robotic-assisted procedure that improves the anastomotic repair
    • Trocars should not be removed before the intra-abdominal pressure is close to normal. Lowering the pressure before removing the trocars will reveal that the hemostasis is under control and prevents intra-abdominal (bowel, omentum) content from entering the port holes.
    • The peritoneal lining mirrors the light from the telescope, giving the transperitoneal approach better visibility than in the retroperitoneal route.
    • Horseshoe kidneys are a relative contraindication to the retroperitoneal approach as access to the UPJ from the posterior aspect is extremely difficult
    • Hypothermia during laparoscopy in all infants is caused by insufflation of a large amount of CO2 due to port leakage.
    • Bladeless optical trocars or open access for the camera port might be helpful for pediatric minimally invasive surgery in obese patients
  • Newborns may be more suitable for open pyeloplasty since access to the ureteropelvic junction (UPJ) requires only a very small incision.
• Complications (3):
  1. Prolonged urinary drainage postoperatively
  2. Lack of improvement in renal function or improvement in washout
  3. Occasionally, worsening hydronephrosis and diminished renal function post-operatively
     • Such a situation may lend itself to a repair using endoscopic procedures or a repeat dismembered pyeloplasty

Endoscopic[edit | edit source]

• Preoperative screening for accessory vessels is required by CT, MRI, or transluminal US, so as to avoid vascular injury
• Endopyelotomy may have a place in the management of failed primary open or laparoscopic procedures followed by the placement of a double-pigtail catheter for 6 weeks. A repeat pyeloplasty, either open or laparoscopically, is the best choice in most cases.

Megaureter[edit | edit source]

• Definition of megaureter: dilatation of the ureter irrespective of cause

Classification[edit | edit source]

• Classified as primary vs. secondary
  • Primary obstructed megaureters (POM)
    • A condition intrinsic to the ureter itself; obstruction results from the presence of an abnormal adynamic segment at the terminal end of the ureter near or at the ureterovesical junction (UVJ)
      • Insufficient peristalsis at the UVJ leads to obstruction and upstream dilatation
  • Secondary to bladder pathologic processes, such as neurogenic bladder dysfunction, bladder outlet obstruction, and/or infection
• Subclassified based on cause (4):
  1. Obstructed
  2. Refluxing
  3. Non-obstructed non-refluxing
  4. Refluxing with obstruction

Management[edit | edit source]

• The goal is to prevent renal functional deterioration with either conservative or surgical treatment
• Conservative
  • > 90% of antenatally detected non-refluxing, non-obstructing megaureters will improve with conservative management within the first few years of life
  • Patients with ureteral diameters > 10 mm were more prone to complications
• Surgery
  • Indications for surgery of POM (5):
    1. Symptoms
    2. Infections (recurring UTIs)
    3. Increasing hydronephrosis/hydroureter
    4. < 40% differential renal function
    5. ≥ 5% decrease in differential renal function of on sequential “comparable” nuclear functional studies
       • The T 1/2, or Lasix washout time, especially in neonatal megaureters is not a reliable indicator of obstruction
         • Washout curves in neonates and infants can be affected by many factors other than restriction of flow.
         • A normal creatinine and symmetric renal function support initial observation in a child
  • Options (3):
    1. Decompression
       • Indications for prompt decompression:
         1. Neonate with a megaureter and sepsis
         2. Ipsilateral reduced function (< 35% in a neonate)
         3. Marked or increasing hydroureteronephrosis
       • Options (2):
         1. Distal cutaneous ureterostomy (preferred)
         2. Nephrostomy tube
            • Nephrostomy tubes are difficult to keep in place
    2. Endoscopic
       • Endoscopic dilatation and stenting of the UVJ in POM is an alternative that is less invasive than formal open or laparoscopic surgical intervention, with short- to medium-term success rates ≈70%
    3. Surgical repair
       • Excision and tapered re-implant
         • The stenotic distal part of the ureter is excised
         • The megaureter is straightened and then tapered to facilitate reimplantation in a nonrefluxing fashion with adequate ratio of length to diameter of 5:1 to improve coaptation of the ureteral lumen, whereby effective peristalsis and urine transportation are achieved
           • Ureteral tailoring is usually necessary to achieve the proper length-to-diameter ratio required of successful reimplants. Especially in small children, the reimplant can be otherwise impossible.
           • Folding techniques for ureteral tailoring are not applicable in ureters >1.75 cm in diameter.
           • The most serious complication to ureteral tailoring is compromise of the distal vasculature of the ureter with subsequent fibrosis.
             • Fibrosis can lead to recurrent obstruction and require a redo. However, when performed with care, the risk of vascular compromise should be minimal
         • Most surgeons advocate temporary postoperative stenting
       • Complications: obstruction, vesicoureteric reflux, and persistent dilatation
       • A concomitant reimplantation and dismembered pyeloplasty should be discouraged, as the ureteral blood supply may be compromised.

Congenital ureteral strictures[edit | edit source]

• Rare anomalies causing hydroureteronephrosis
• Management entails excision of the stenotic ureteral segment and reanastomosis by ureteroureterostomy
• Excised segments range in length from 1-3 cm and histologically are characterized by increased collagen deposition and muscular hypertrophy

Ureteral Polyps[edit | edit source]

• Rare anomaly that may lead to obstruction and dilatation
• Most often found in the proximal third of the ureter.
• Management options include dismembered pyeloplasty with resection of the afflicted part of the ureter when polyps are near the UPJ or ureteral resection and ureteroureterostomy by open and even laparoscopic surgery. In cases of smaller polyps, ureteroscopic excision might be a feasible alternative

Questions[edit | edit source]

1. List congenital renal malformations common seen with UPJO. Which is most common?
2. What are indications for surgical intervention of UPJO?
3. What is the natural history of antenatally detected megaureter?
4. What are indications for surgery of primary obstructive megaureter?

Answers[edit | edit source]

1. List congenital renal malformations common seen with UPJO. Which is most common?
   1. Contralateral UPJO (most common anomalyv)
   2. Renal dysplasia
   3. Multicystic dysplastic kidneys
   4. Renal agenesis
   5. Horseshoe kidneys
   6. VUR
   7. Ectopic kidney
   8. Duplex kidney
2. What are indications for surgical intervention of UPJO?
   1. Symptoms
   2. Infections while on prophylactic antibiotics
   3. Increasing hydronephrosis
   4. Low or decreasing differential renal function
3. What is the natural history of antenatally detected megaureter?
   • > 90% of antenatally detected megaureters will improve with conservative management within the first few years of life
4. What are indications for surgery of primary obstructive megaureter?
   1. Symptoms
   2. Infections
   3. Increasing hydronephrosis/hydroureter
   4. < 40% differential renal function
   5. ≥ 5% decrease in differential renal function of on sequential “comparable” nuclear functional studies

References[edit | edit source]

• Wein AJ, Kavoussi LR, Partin AW, Peters CA (eds): CAMPBELL-WALSH UROLOGY, ed 11. Philadelphia, Elsevier, 2015, chap 133