Miscellaneous

183Urology Journal    Vol 7    No 3    Summer 2010

Effects of Isosorbide Dinitrate on the Urinary Flow 
Rate in Patients with Benign Prostatic Hyperplasia
Ali Roshani,1 Iraj Khosropanah,1 Mohammad Salehi,1 Alireza Noshad Kamran2

Purpose: To compare the immediate effects of a systemic nitric oxide (NO) 
donor with placebo on the uroflowmetric parameters in patients with benign 
prostatic hyperplasia (BPH).
Materials and Methods: Eighty patients with the mean age of 61.5 years 
(range, 49 to 74 years) who suffered from BPH were enrolled in the study. 
We examined peak flow rate, average flow rate, and residual urine in all the 
patients. Then, patients were randomized to receive either 20 mg sublingual 
isosorbide dinitrate (ISDN) (n = 40) or placebo (n = 40) 20 minutes prior to 
the second uroflowmetry, which was performed one day after the first test.
Results: The mean peak flow rate increased from 7.6 ± 0.41 mL/s to 10.2 ± 
0.54 mL/s (P = .013) in the ISDN group, while it increased +0.40 mL/s in the 
placebo group (P > .05). Mean residual urine volume decreased significantly 
from 51 ± 3.1 mL to 29 ± 2.9 mL and from 56 ± 4.1 to 51 ± 2.6 in the ISDN 
(P = .02) and the placebo groups (P > .05), respectively. At baseline, the 
mean arterial pressure was 95 ± 2.1 mmHg and under the influence of the 
NO-donor, it decreased to 83 ± 1.9 mmHg, which was significant (P < .001). 
No significant changes of micturition parameters were found in the placebo 
group.
Conclusion: Organic nitrates influence micturition parameters in patients 
with BPH. This new approach could offer a potential pharmacological option 
to treat obstructive lower urinary tract symptoms.

Urol J. 2010;7:183-7.
www.uj.unrc.ir

Keywords: benign prostatic 
hyperplasia, isosorbide dinitrate, 

flowmetry

1Guilan Urology Research Center, 
Rasht, Iran

2Valiasr Hospital, Arak University of 
Medical Sciences, Arak, Iran

Corresponding Author:
Alireza Noshad Kamran, MD

Valiasr Hospital, Arak University of 
Medical Sciences, Arak, Iran 

Tel: +98 861 223 1104
Fax: +98 861 222 0224

E-mail: Alireza_noshad@yahoo.com

Received January 2009
Accepted March 2010

INTRODUCTION
Benign prostatic hyperplasia 
(BPH) is a significant health-care 
problem affecting millions of 
men worldwide. Apart from the 
bothersome lower urinary tract 
symptoms (LUTS), BPH can 
lead to the detrusor overactivity, 
urinary retention, recurrent 
urinary tract infections, bladder 
stone formation, and even renal 
insufficiency.

Medical therapy is usually 
administered for bothersome LUTS 
due to BPH. Alpha-blockers and 

5α- reductase inhibitors are the only 
agents recommended by different 
guidelines.(1,2) New pharmaceutical 
agents with acceptable cost and 
safety profile would be very 
welcome.(3)

During the past few years, nitric 
oxide (NO) has been found to be 
a fundamental biologic messenger 
mediating neurotransmission, 
smooth muscle relaxation, and 
vasodilation in various organs. (4-6) In 
the male genital tract, the bladder 
neck, the prostate, the vas deferens, 
the seminal vesicle, and the corpus 



Isosorbide Dinitrate in BPH—Roshani et al

184 Urology Journal    Vol 7    No 3    Summer 2010

cavernosum were found to have high levels of 
calcium dependent nitric oxide synthase (NOS) 
activity.(7) Nitric oxide plays an important role 
in the autonomic innervation of all parts of the 
prostate tissue.(4,8)

There is some evidence that drugs acting on NO/
cyclic guanosine monophosphate (cGMP) pathway 
might have a potential role in treating subvesical 
obstruction caused by BPH. (9-12) The hypothesis 
relies on the relaxing effect of NO on the prostate 
smooth muscle cells that potentially decreases 
subvesical obstruction and improves both voiding 
and bothersome LUTS. Phosphodiesterase-5 
inhibitors, which increase cGMP levels in the 
lower urinary tract, have already been shown to 
have a beneficial influence on LUTS.(9)

Functional in vivo studies assessing the direct 
effect of NO on the human lower urinary tract 
are rare. However, after oral administration in 
healthy humans, an NO-donor had a functionally 
relevant effect on the resting tone and contractile 
properties of the human external urethral 
sphincter in vivo.(10) In a functional study on 
humans with spinal cord injury, subvesical 
obstruction caused by detrusor-sphincter 
dyssynergia was successfully reduced by oral 
administration of an NO-donor.(11) Recently, 
using pressure-flow studies, a significant reduction 
was reported in the bladder outlet resistance in 
healthy men within 20 minutes of sublingual 
administration of an NO-donor.(12)

Some studies have investigated NO-donors in 
men with BPH, but the results are conflicting. 
The aim of our study was to evaluate the 
immediate effect of a sublingual administration of 
isosorbide dinitrate (ISDN), as an NO-donor, on 
the infravesical resistance in patients with BPH.

MATERIALS AND METHODS
This study was carried out on patients with LUTS 
suggestive of BPH who referred to urology clinic 
of Razi Hospital in Rasht between January 2007 
and December 2007. Eighty men with the mean 
age of 61.5 years (range, 49 to 74 years), who met 
the inclusion criteria, were enrolled in this study. 
The inclusion and exclusion criteria are listed in 
Table 1.

The study protocol was explained to all of the 
patients and written informed consents were 
obtained. The study was approved by the 
hospital’s ethics committee. We measured peak 
flow rate (Q-max), average flow rate (Q-ave), 
and voided volume using the Urodyn rotating 
Flowmeter (Dantec, Copenhagen, Denmark) 
and residual urine volume by transabdominal 
ultrasonography

After baseline evaluation, each patient was 
assigned in chronological order to one of the 
randomization numbers using a computer 
generated randomization list to receive either 20 
mg sublingual isosorbide dinitrate (Tolidarou 
Pharmaceutical co.) (group 1, n = 40) or identical 
sublingual placebo tablet (group 2, n = 40), 20 
minutes prior to the second uroflowmetry, which 
was performed with a one-day interval from the 
baseline test. Both patients and researchers were 
blind to the drug/placebo groups. Residual urine 
volume was measured again. Blood pressure was 
monitored at baseline and 1 hour after drug or 
placebo administration.

The urofowmetry strips were manually read in a 
blinded fashion by an independent investigator. 
To be considered valid, a flow reading required 
a total voided volume of at least 150 mL with 
the peak rate maintained for at least 2 seconds. 
Baseline values were compared to the values after 
intervention by the paired t test. P values less than 
.05 were considered statistically significant.

Inclusion criteria
Age < 75
Peak urinary flow ≤ 15mL/s
Total voided volume ≥ 150 mL
Prostate specific Antigen ≤ 4 ng/mL
International prostate symptom score (IPSS) ≥ 8
Prostate volume ≥ 20 cm3

Exclusion criteria
Age >75 years or < 49 years
Evidence and suspicion of prostate cancer
Acute prostatitis
Residual urine volume > 150 mL
Serum creatinine level > 1.5 mg/dL
Neurogenic bladder dysfunction
Inability to spontaneous voiding
History of prostate surgery or other transurethral procedures
Urinary tract infection
Contraindications of nitrates
Unstable cardiovascular disease
Maintenance nitroglycerin administration

Table 1. Inclusion and exclusion criteria



Isosorbide Dinitrate in BPH—Roshani et al

185Urology Journal    Vol 7    No 3    Summer 2010

RESULTS
The mean peak flow rate increased significantly 
from 7.6 ± 0.41 mL/s (range, 6.1 to 9.3 mL/s) 
to 10.2 ± 0.54 mL/s (range, 8.2 to 13.1 mL/s; 
P = .013) in the ISDN group, while the mean 
peak flow rate change in the placebo group was 
about +0.40 mL/s and statistically insignificant 
(P > .05). Mean residual urine volume decreased 
significantly from 51 ± 3.1 mL to 29 ± 2.9 mL 
and from 56 ± 4.1 to 51 ± 2.6 in the ISDN 
(P = .02) and the placebo groups (P > .05), 
respectively (Table 2).

At baseline, the mean arterial pressure of the 
patients was 95 ± 2.1 mmHg (range, 86 to 115 
mmHg) and under the influence of the NO-
donor, it decreased to 83 ± 1.9 mmHg (range, 74 
to 92 mmHg), which was significant (P < .001). 
The drop in blood pressure was symptomatic 
in 7 patients as they reported dizziness after the 
intake of ISDN in contrast to the placebo group, 
in which there was not any drop in the blood 
pressure. These symptoms, however, were mild 
and short lasting, and no subject was affected in 
a way that prevented him from completing the 
study. Five of the subjects reported a headache 
after ISDN administration.

DISCUSSION
Nitric oxide produces smooth muscle relaxation 
by activating the soluble guanylate cyclase and 
hereby increasing the tissue levels of cGMP, 
which in turn interacts with various intracellular 
components that regulate activities of the 

contractile proteins.(13,14) Nitric oxide donors 
activate the soluble guanylate cyclase and increase 
the tissue levels of cGMP.(15) Exogenously applied 
NO in solution or NO-donors have been shown 
to cause relaxation in pre-contracted prostate 
tissue from rabbits, dogs, and humans.(8,16-18)

Several advantages of NO-donors make 
the clinical evaluation of their effect on the 
infravesical resistance worthwhile. First, 
many NO-donors are well-known drugs with 
good tolerability and long-established safety 
records .(19) Second, different formulations are 
available. This is especially notable for fast-acting 
formulations with an onset of action within 
seconds to minutes. They can be used alone or 
in combination with classical medical LUTS 
therapies, but the possibility of increased adverse 
events, eg, hypotension, has to be taken into 
consideratin.

Possibly, fast-acting NO-donors could also 
be used to treat acute urinary retention in 
an emergency setting. Since there is evidence 
that alterations in the NO-cGMP pathway are 
involved in the development of BPH and that 
NO has an antiproliferative effect on human 
prostate smooth muscle cells,(20) long-term use 
of NO-donors may also prevent or slow down 
BPH progression. Furthermore, the NO-cGMP 
pathway is suspected to be involved in the 
regulation of the threshold for afferent firing in 
the bladder.(21) Nitric oxide could, therefore, have 
a beneficial effect on LUTS beyond the decrease 
of the infravesical resistance.

Parameters
Baseline After ISDN

P 
Placebo Group ISDN Group Placebo Group ISDN Group

International Prostate Symptom Score (IPSS) 15.4 ± 2.1 15.8 ± 2.4 >0.05*
Prostate Volume (cm3) 28 ± 2.6 29 ± 2.1 >0.05*
Peak urinary flow rate (Qmax)(mL/s) 7.2 ± 0.61 7.6 ± 0.41 7.6 ± 0.44 10.2 ± 0.54 >0.05*

0.013†
>0.05‡

Residual Urine volume (cc) 56 ± 4.1 51 ± 3.1 51 ± 2.6 29 ± 2.9 >0.05*
0.02†

>0.05‡

Mean arterial Pressure (mmHg) 99 ± 1.6 95 ± 2.1 96 ± 2.2 83 ± 1.9 >0.05*
0.001†

>0.05‡

Table 2. Mean variations in parameters during study period in two groups

*Baseline ISDN group versus Placebo group
†ISDN group before and after intervention
‡Placebo group before and after intervention
§ISDN indicates isosorbide dinitrate



Isosorbide Dinitrate in BPH—Roshani et al

186 Urology Journal    Vol 7    No 3    Summer 2010

In this study, we administered only single dose 
of ISDN to assess immediate effects on urinary 
flow rate, but in a non-randomized non-placebo-
controlled study by Klotz and colleagues, patients 
with BPH with obstructive symptoms that 
were treated with oral ISDN with the dosage 
of 60 to 120 mg per day for 3 months exhibited 
improvement in the mean peak flow rates.(22)

Reitz and associates recently showed the relaxing 
effect of sublingual ISDN on the external urethral 
sphincter in spinal cord–injured patients as well 
as in healthy men within minutes after drug 
administration.(10,11) The most serious adverse 
effects of ISDN were pounding headache, 
flashing, vertigo, palpitation, and nausea or 
vomiting.(23)

In this study, we demonstrated a slight, but 
statistically significant increase of the peak 
urinary flow rate within 20 minutes after 
administration of an NO-donor in men with 
BPH. Whether this influence affected the outflow 
region of the lower urinary tract as a functional 
unit or individual segments (eg, the bladder neck, 
the prostate, or the urethra) to a variable extent 
cannot be determined with this study. We also 
chose to administer a relatively high dose of 
ISDN in this study to make sure that sufficient 
levels of the NO-donor were present systemically 
during the second uroflowmetry. In some studies, 
however, the administration of 10 mg instead of 
20 mg ISDN is reasonable, since other studies 
have shown significant adverse effects with this 
dose.(10,11)

Our study had some limitations. First we did 
not measure NO levels in the target region, 
namely the prostatic urethra and the bladder 
neck. Second, learning curve might have 
affected the results of the second uroflowmetry. 
Repeated uroflowmetry several hours after ISDN 
administration would have been a convincing 
evidence for the specificity and short-term 
efficacy of ISDN treatment when returning to 
pretreatment values.

It should be emphasized that this is a preliminary 
study about a novel option in medical treatment 
of BPH and any conclusion regarding the 
usefulness of this therapy can only be drawn from 

larger studies with long-term follow-up.

CONCLUSION
A clinical improvement was found in micturition 
parameters in patients with BPH after medication 
with nitrates. However, further controlled 
studies with larger sample are necessary to prove 
whether nitrates could eventually enrich the BPH 
treatment.

CONFLICT OF INTEREST
None declared.

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