Introduction

Of patients with pelvic fractures, 4% to 14% also

have posterior urethral rupture (PUR), which is

associated with considerable morbidities such as

incontinence, erectile dysfunction, and urethral

stricture.(1)

Management of PUR continues to evolve. Some

urologists advise initial placement of a

suprapubic cystostomy followed by delayed

urethroplasty 3 to 6 months later, while others

suggest immediate realignment.(2) The definition

of primary realignment of urethral distraction

injury has changed over the years. The current

definition of primary realignment refers to

immediate stenting of urethral distraction with a

catheter without pelvic dissection or suture.(3) In

the present study, we review our experience with

primary realignment of PUR and report its

outcome and complications. 

Materials and Methods

Between March 2002 and August 2004, there

were 25 men (mean age, 33.5 ± 14.5 years; range,

18 to 70 years) with PUR due to injury who

underwent primary realignment in our medical

center. Posterior urethral ruptures were

diagnosed and confirmed by history, physical

examination, and retrograde urethrography. We

prospectively selected those patients with no

visceral injuries to undergo primary realignment.

Surgical technique. A lower midline

abdominal incision is made. If the patient is

hemodynamically stable with no other

genitourinary tract injuries, a vertical cystotomy

incision is made under direct vision, and a

urethral Foley catheter is gently passed in a

retrograde fashion. If the catheter is easily

Primary Realignment of Posterior Urethral Rupture

Mehdi Salehipour, Abdolaziz Khezri, Rashid Askari,* Parham Masoudi

Department of Surgery, Division of Urology, Faghihi Hospital, Shiraz University of 

Medical Sciences, Shiraz, Iran

ABSTRACT

Introduction: We report the results of treatment of posterior urethral rupture (PUR)

by primary realignment with some modifications of the technique.

Materials and Methods: In this prospective study, 25 patients (mean age, 33.5

years; range, 18 to 70 years) in whom PUR had been proved underwent primary

urethral realignment. All patients were evaluated postoperatively for urinary

incontinence, erectile dysfunction, and urethral stricture. They were followed for a

mean of 20 months (range, 9 to 27 months).

Results: In 20 of 25 patients (80%), posterior urethral rupture was associated with

pelvic fractures and in 2 (8%), bladder rupture was also present. None of the patients

had urinary incontinence. Six patients (24%) had evidence of postoperative stricture

that required urethral dilatation and/or direct vision internal urethrotomy in 2 or 3

procedures under local anesthesia. Erectile dysfunction was reported by 4 patients

(16%) as a decreased quality of erection, all of whom responded to sildenafil. 

Conclusion: We believe that primary realignment of PUR is a simple procedure

associated with low morbidity. It is recommended for patients who are stable and have

no other significant intra-abdominal and pelvic organ injuries. 

KEY WORDS: urethra, urethral distraction, urethroplasty, injuries, primary realignment 

211

Urology Journal

UNRC/IUA

Vol. 2, No. 4, 211-215 Autumn 2005

Printed in IRAN

Received January 2005

Accepted July 2005

*Corresponding Author: Department of Urology,

Faghihi Hospital, Zand Ave, Shiraz, Iran.

Tel: ++98 711 233 0724, ++98 711 235 5397,

Fax: ++98 711 233 0724

E-mail: rashidaskari@yahoo.com



Primary Realignment of Posterior Urethral Rupture

brought into the bladder, its tip is sewn to the tip

of a Nelaton catheter using a nonabsorbable

suture, and the latter catheter is brought out

from the bladder and the anterior abdominal wall

and fixed to the abdominal wall. A suprapubic

tube is placed in the dome of the bladder and the

bladder is closed in 2 layers using a standard

technique (Figure 1A). 

If retrograde catheter placement fails, a 20-F

Nelaton catheter is gently passed from the

urethral meatus to the urethral disrupted area

and the space of Retzius. A second 18-F Nelaton

catheter is also gently passed from the bladder

neck and the prostatic urethra to the disrupted

area and the space of Retzius, in an antegrade

fashion. The ends of these catheters are tied

together, and the antegrade catheter is

manipulated through the anterior urethra by

pulling the retrograde catheter back to the

urethral meatus. Subsequently, the antegrade

catheter is secured to a Foley catheter by a

nonabsorbable suture, which is then pulled back

into the bladder. The antegrade catheter is

brought out the anterior wall of the bladder and

abdominal wall and fixed to the skin. The Foley

catheter balloon is filled with 20 mL fluid. A

suprapubic cystostomy tube is placed using a

standard technique as previously described. No

traction is applied on the Foley catheter. 

The Foley catheter is left in place for 4 weeks

and replaced by another one based on the

guidance of the antegrade catheter. The Foley

catheter is retracted until the tip of the

antegrade catheter are seen via the urethral

meatus. The suture is removed from tips of both

catheters, and a new Foley catheter is sewn to

the tip of the antegrade catheter. The antegrade

catheter is retracted through the bladder and the

abdominal wall and removed by cutting the

sutures (Figure 1B). The new Foley catheter is

retracted gently while its balloon is filled with 20

mL fluid (Figure 1C). The new Foley catheter is

left in place for another 4 weeks and removed

when a retrograde urethrography around the

Foley catheter shows no extravasation of contrast

medium. The suprapubic cystostomy is clamped,

but left in place. If the patient voids normally and

without difficulty, the cystostomy tube may be

removed 2 weeks later. 

Follow-up. After the removal of catheters, the

patients were followed at 3, 6, and 12

postoperative months with physical examination,

uroflowmetry studies, and, if needed, retrograde

urethrography and/or a voiding cystourethrography.

Potency and continence were evaluated

subjectively by interviews with the patients.

Patients were considered potent if they were able

to have intercourse with vaginal penetration. If

the patients had decreased firmness of erection

compared with the preinjury status, this was

considered decreased potency. Continence was

defined as no requirement to use a pad to protect

against urine loss. Eventually, the need for

additional urologic procedures was assessed. 

212

FIG. 1. Primary realignment of posterior urethral rupture, A. A 20-F Foley catheter is inserted, its tip is sewn to a Nelaton

catheter, and cystostomy is placed. B and C. After 4 weeks, the Foley catheter is exchanged with another one, and the

Nelaton catheter is retracted from the bladder and abdominal wall and removed. A Foley catheter is placed for another 4

weeks. 



Salehipour et al

Results

Mean follow-up was 20.0 ± 5.6 months (range,

9 to 27 months). Twenty patients (80%) had pelvic

fractures, and 2 (8%) had both pelvic fracture and

bladder rupture. They had no visceral injury. All

patients underwent surgical operation within 12

hours after injury. Twenty-one patients were

followed for more than 12 months. The most

common mechanisms of injury in our patients, in

order of frequency, are shown in Table 1. 

On follow-up, 19 patients (76%) had no

symptoms or radiologic evidence of urethral

stricture. All patients reported good urinary

continence with no need for a pad. Six (24%) had

strictures that were treated with urethral

dilatation and/or direct vision internal

urethrotomy. Of these, 3 patients required 3

procedures, and 3 required 2 procedures. None

required open urethroplasty. 

Twenty-one (84%) patients reported a normal

erection, while 4 (16%) had decreased firmness of

erection (all of which responded to sildenafil, 50

mg to 100 mg, daily).

The mean operative time for primary

realignment was 50 ± 3 minutes (range, 45 to 60

minutes). The estimated blood loss was 300 mL

to 700 mL, and 3 patients received 500 mL blood

transfusion.

Discussion

The PUR is one of the worst types of

genitourinary trauma with 3 significant

complications: erectile dysfunction, urethral

stricture, and urinary incontinence. Management

of PUR remains controversial. In the present

study, we showed that primary realignment was

associated with no urinary incontinence, a low

rate of erectile dysfunction, and a relatively low

rate of urinary tract strictures that were treated

successfully. Some studies have shown that initial

suprapubic cystostomy and delayed urethroplasty,

3 to 6 months later produces less complication

than does primary realignment, while other

studies have shown the opposite. 

In 1972, Morehouse and colleagues(4) reported

high impotence and incontinence rates in

patients treated with primary realignment.

Webster and coworkers(5) have compared delayed

urethroplasty and primary realignment in the

treatment of PUR and noted a significant

advantage with delayed urethroplasty. On the

other hand, Follis and colleagues(6) have

compared the operative outcomes of complete

prostatomembranous disruptions in 20 men with

delayed repair and 13 with immediate

realignment. They reported potency rates of 50%

and 80%, respectively, and an increased need for

a secondary operation when the repair was

delayed. Elliott and Barrett(3) analyzed the long-

term (10-year) results of treatment of PUR with

primary realignment in 57 men and showed that

primary realignment resulted in low incidence of

erectile dysfunction (21%, mostly mild),

incontinence (3.7%), and stricture (34%, but with

no requirement for intervention). 

The main disadvantages of delayed

urethroplasty are urethral stricture (in

approximately 100% of patients(1)) and the need

for a second operation with its potential

complications such as impotence and

incontinence. Conversely, primary realignment

reduces the requirement for secondary open

urethroplasty, and in addition, the majority of

strictures can be treated with urethral dilatation

and/or direct vision internal urethrotomy as an

outpatient procedure. Compared with other

studies,(3,6) the rate of urethral stricture in our

study was relatively low. We think that the low

urethral stricture rate is probably due to the

minor modifications we made in our procedure.

We connect the tip of the retrograde catheter to

the tip of the antegrade Nelaton catheter for 2

reasons: first, because it can prevent unwanted

disconnection of the retrograde catheter that acts

as a stent and is important to the healing

processes; and second, because passage of the

Nelaton catheter after 4 weeks (when we change

the retrograde Foley catheter with another one,

while the antegrade catheter is connected to it)

213

TABLE 1. Mechanisms of posterior urethral rupture

in 25 patients 

Mechanisms of injury  Number of patients (%) 

Car accident  12 (48) 

Falling  5 (20) 

Crushing  4 (16) 

Motorcycle accident  3 (12) 

Tractor rollover 1 (4) 

Total 25 (100) 

 



Primary Realignment of Posterior Urethral Rupture

may result in mild urethral dilatation.

Urinary continence depends on intact internal

and external urethral sphincters. In PUR, the

bladder neck is separated from the urethra, and

so it seems that continence is dependant on the

external sphincter function. During

urethroplasty, the possibility of damage to the

external urethral sphincter is high. Consequently,

the rate of incontinence is higher than that in

primary realignment. The reported rate of

urinary incontinence with delayed urethroplasty

has been 2% to 8%.(4-6) In 2 studies on primary

realignment, urinary incontinence was present in

0% and 3.7% of the patients, and none of the

patients in the latter study needed treatment.(3,6)

We had no cases of incontinence. Thus, is seems

that primary realignment can be done with no

serious impact on the patient's continence. We

speculate that this is due to less manipulation of

the external sphincter during primary

realignment and repair of bladder neck and

prostatic urethra with a good exposure. In

addition, we used no traction on the urethral

Foley catheter, which prevents ischemic damage

to the internal urethral sphincter, which is very

important in maintaining continence.(7)

Causes of erectile dysfunction following PUR

are not understood. Dhabuwala and associates

have noted that impotence is caused by the

original injury and is not due to the urethral

repair.(8) In a report by Tunc and colleagues,(9)

erectile dysfunction was attributed to delayed

urethral reconstruction in 16.2% of patients. It is

likely that injury to the autonomic plexus in

patients with pelvic fractures, or injury to the

nervi erigentes in the neurovascular bundles

dorsolateral to the prostatomemberanous urethra

contributes to erectile dysfunction.(6) In our

study, no patient developed permanent erectile

dysfunction, and 4 patients with decreased

firmness of erection responded to sildenafil and

gradually improved significantly. We suppose that

minimal manipulation of pelvic viscera and a low

incidence of hematomas contributed to the low

rate of erectile dysfunction in our study. The

complication rates of primary realignment in our

study and some other studies are shown in Table 2.

Conclusion

We believe that primary realignment of PUR is

a simple procedure associated with low morbidity.

This technique is useful for patients who are

stable with no other significant intra-abdominal

or pelvic organ injuries. 

Acknowledgement

We gratefully acknowledge Ms. Mersedeh

Feradoni for her drawings in this article. We

would also like to thank the Office of Research

Development of Nemazee Hospital and Dr.

Hooman Yarmohammadi for his editorial

assistance.

References

1. McAninch JW, Santucci RA. Genitourinary trauma, In:

Walsh PC, Retik AB, Vaughan ED Jr, et al, editors.

Campbell's urology. 8th ed. Philadelphia: WB Saunders;

2002. p. 3707-44. 

214

TABLE 2. Results of primary realignment versus delayed urethroplasty of posterior urethral rupture in

different studies

Study Technique 
Number of 

patients 

Stricture No. 

       (%) 

Incontinence No. 

          (%) 

Erectile dysfunction No. 

                 (%) 

Elliott and Barrett
(3)

 PR 57 18 (34) 2 (3.7) 12 (21) 

Webster and colleagues
(5)

 PR 19 18 (95) 1 (5.2) 10 (53) 

Follis and colleagues
(6)

 PR/DU 20/13 3/11 (15/85) 0/1 (0/8) 4/5 (20/39) 

Tunc and colleagues
(9)

 DU 77 77 (100) 7 (9.1) 7/58 (16.2) 

Patterson and 

colleagues
(10)

 
PR 29 11(38) 1 (3.4) 4 (14) 

Husmann and 

colleagues
(11)

 
DU 17 16 (94) 2 (12) 8 (47) 

The present study PR 25 6 (24) 0 (0) 4 (16) 



Salehipour et al

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215