Sexual Dysfunction and Infertility

255Urology Journal    Vol 5    No 4    Autumn 2008

Effect of Saffron on Semen Parameters of Infertile Men
Mohammad Heidary,1 Jahanbakhsh Reza Nejadi,2 Bahram Delfan,2 Mehdi Birjandi,2 
Hossein Kaviani,3 Soudabeh Givrad4

Introduction: We conducted this study to determine the effects of saffron 
(Crocus sativus) on the results of semen analysis in men with idiopathic 
infertility.
Materials and Methods: In this clinical trial, 52 nonsmoker infertile men 
whose problem could not be solved surgically were enrolled. They were 
treated by saffron for 3 months. Saffron, 50 mg, was solved in drinking milk 
and administered 3 times a week during the study course. Semen analysis was 
done before and after the treatment and the results were compared.
Results: The mean percentage of sperm with normal morphology was 26.50 
± 6.44% before the treatment which increased to 33.90 ± 10.45%, thereafter 
(P < .001). The mean percentage of sperm with Class A motility was  
5.32 ± 4.57% before and 11.77 ± 6.07% after the treatment (P < .001). Class B 
and C motilities were initially 10.09 ± 4.20% and 19.79 ± 9.11% which increased 
to 17.92 ± 6.50% (P < .001) and 25.35 ± 10.22% (P < .001), respectively. 
No significant increase was detected in sperm count; the mean sperm count 
was 43.45 ± 31.29 × 106/mL at baseline and 44.92 ± 28.36× 106/mL after the 
treatment period (P = .30). 
Conclusion: Saffron, as an antioxidant, is positively effective on sperm 
morphology and motility in infertile men, while it does not increase sperm 
count. We believe further studies on larger sample sizes are needed to elucidate 
the potential role and mechanism of action of saffron and its ingredient in the 
treatment of male infertility.

Urol J. 2008;5:255-9. 
www.uj.unrc.ir

Keywords: male infertility, Crocus 
sativus, antioxidants, sperm motility, 

sperm count

1Department of Urology, Lorestan 
University of Medical Sciences, 

Khorramabad, Iran
2Department of Anesthesiology, 

Lorestan University of Medical 
Sciences, Khorramabad, Iran

3Shohada-e-Ashayer Hospital, 
Lorestan University of Medical 
Sciences, Khorramabad, Iran

4Urology and Nephrology Research 
Center, Shahid Beheshti University 

(MC), Tehran, Iran

Corresponding Author: 
Mohammad Heidary, MD

Urology and Nephrology Research 
Center, No 44, 9th Boustan St, 

Pasdaran Ave, Tehran, Iran
Phone: +98 21 2256 7222

Fax:  +98 21 2256 7282
E-mail: drheidary@yahoo.com

Received February 2008 
Accepted July 2008

INTRODUCTION
Approximately, 8% of the Iranian 
couples suffer from infertility after 
2 years of attempting conception.(1) 
Where the issue lies with the male 
partner, 2 groups of patients are 
seeking treatment, namely those 
suffering from idiopathic infertility 
and those in whom the etiology 
of infertility is known. Various 
therapeutic agents including 
clomiphene citrate, tamoxifen, 
kallikreins, and antioxidant agents 
such as vitamin E and glutathione 
are used to help these patients; 
nevertheless, none is a definite 

treatment.(2-4) This necessitates 
utilization of other alternative 
agents. 

Recent studies have investigated 
the role of reactive oxygen species 
(ROS) on sperm. Even though, small 
amounts of ROS are necessary for 
sperm activation, these agents can 
cause damage to the sperm in higher 
concentrations.(5-7) Increased levels 
of ROS are related to decreased 
motility of the spermatozoa and 
DNA damage, and may even lead 
to germ cell apoptosis.(8-12) In fact, 
studies have shown that more than 



Saffron and Semen Parameters of Infertile Men—Heidary et al

256 Urology Journal    Vol 5    No 4    Autumn 2008

40% of infertile men have augmented levels of 
ROS in their seminal plasma.(13) Therefore, many 
studies have focused on antioxidant agents in order 
to prevent this damage on sperm metabolism, 
motility, morphology, and as a consequence, 
fertilizing capacity. 

Crocus sativus (saffron) is a perennial herb of the 
Iridaceae family with antioxidative prosperities.(14-16)  
It is widely cultivated in Iran, India, Greece, 
Spain, and France. Its dried red stigma is 
commercially used as a food spice. Saffron has 
also been widely used in folk medicine as an 
antispasmodic, eupeptic, pain killer, anticatarrhal, 
carminative, diaphoretic, expectorant, stimulant, 
stomachic, aphrodisiac, and emmenagogue.(17,18)  In 
some countries such as India, Spain, and China, 
saffron has been used to treat infertility and 
impotence from long ago.(19,20) We undertook this 
study to investigate the effect of saffron on semen 
parameters and infertility.

MATERIALS AND METHODS
Between 2006 and 2007, we evaluated infertile 
men referring to the urology clinic of Shohada-
e-Ashayer Hospital in Khorramabad, Iran. All 
patients were initially interviewed and questioned 
about their sexual behavior, history of prior 
surgical interventions or childhood diseases such 
as cryptorchidism that affect fertility, and family 
history of infertility. Complete drug history 
was obtained; the patients were specifically 
asked about administration of sulfasalazine, 
cimetidine, marijuana, cocaine, and tobacco. 
Moreover, history of contact with chemicals 
and ionizing radiation was acquired. All patients 
were then assessed for systemic diseases such 
as fever, viremia, and acute infections (eg, 
mumps). Finally, the participants underwent 
full urologic examination. Smokers and patients 
whose problems could be solved surgically were 
excluded. Eligible patients provided informed 
consent and entered the study. The study 
protocol was approved by the ethics committee 
of the Urology and Nephrology Research Center, 
Shahid Beheshti University (MC).

Before initiating the treatment with saffron, 
semen analysis was performed. Samples were 
obtained 48 to 72 hours after the patient’s last 

sexual contact. Analyses were performed by the 
aid of the Computer-Assisted Sperm Analysis in 
less than 1 hour after sample collection. Using 
this method, sperm motility was determined 
in 4 classes defined by the World Health 
Organization.(21) These 4 classes are characterized 
as follows: class A, fast progressively motile sperm 
(4th degree); class B, progressively motile sperm 
(3rd degree); class C, nonprogressively motile 
sperm (2nd degree); and class D, immotile sperm 
(1st degree). 

By the end of initial evaluation and semen 
analysis, the patients were asked to administer 50 
mg of saffron solved in milk, 3 times a week for 3 
months. A specific brand of the available saffron 
in Khorramabad was obtained for all the patients. 
The amount to be used was weighed and divided 
in separate doses by the trained research assistants. 
No other treatment options were considered 
during the study period. After finishing the 
treatment course, semen analysis was again 
carried out by Computer-Assisted Sperm Analysis 
method. Results were compared and analyzed by 
paired t test.

RESULTS
A total of 52 eligible patients were enrolled in the 
study, all of whom finished the study course and 
underwent a secondary semen analysis. The mean 
age of the patients was 31.0 ± 4.6 years (range, 21 
to 48 years). The mean percentage of sperm with 
normal morphology was 26.50 ± 6.44% before 
the treatment which increased to 33.90 ± 10.45%, 
thereafter (P < .001), which corresponded to 
a 7.4% improvement in this index. Significant 
increases were also seen in the percentages of class 
A to class C morphology of the sperm. The mean 
percentage of sperm with Class A motility was 
5.32 ± 4.57% before and 11.77% ± 6.07% after 
the treatment (P < .001). Class B and C motilities 
were initially 10.09 ± 4.20% and 19.79 ± 9.11% 
which increased to 17.92 ± 6.50% (P < .001) and 
25.35 ± 10.22% (P < .001), respectively. Overall, 
6.4%, 7.8%, and 5.6% increases were detected 
in the percentage of sperm with class A, B, and 
C motility, respectively. We could not detect 
a significant increase in terms of sperm count 
with saffron therapy; the mean sperm count was 



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Urology Journal    Vol 5    No 4    Autumn 2008 257

initially 43.45 ± 31.29 × 106/mL which changed 
to 44.92 ± 28.36× 106/mL, afterwards (P = .30). 

DISCUSSION
About 8% of the Iranian couples are infertile, and 
male factor accounts for nearly 40% of infertility 
cases.(1,22) Recent advances in fertility medicine are 
indicative of ROS, which impairs sperm function, 
as one of the reasons behind this dilemma.(1,8-13,23) 
As mentioned earlier, in contrast to the semen 
of a healthy man, seminal plasma of up to 40% 
of infertile men shows increased amounts of 
ROS.(13) Thus, reducing the ROS may help in 
the treatment of male-factor infertility. Pursuing 
this hypothesis, we examined saffron stigma as 
an antioxidant and found that semen parameters 
improved after a period of saffron administration.

Reactive oxygen species consist of a wide range 
of molecules including radicals, nonradicals, and 
oxygen derivatives.(22) A small amount of ROS 
is necessary for the function of cells including 
germ cells. However, in increased levels, 
these molecules are capable of damaging cell 
membranes and genetic content. Polyunsaturated 
fatty acids found in the sperm cell membrane are 
one of the primary targets of ROS due to their 
lipid nature. Reactive oxygen species cause lipid 
peroxidation in the sperm cell membrane, and as 
a result, impair sperm motility and its ability to 
fuse with the oocyte.(24,25) Moreover, ROS may 
induce DNA damage, which in turn will result 
in poor fertilization. This DNA damage happens 
through modification of all bases, production 
of base-free sites, deletions, frame shifts, DNA 
cross links, and chromosomal re-arrangements. 
Also, they may induce high frequencies of single-
strand and double-strand DNA breaks.(11,12,24) 
Finally, high levels of ROS disrupt the inner 
and outer membranes of the mitochondria; as 
a consequence, cytochrome c is released and 
caspases are activated which lead to apoptosis.(24) 

Antioxidants preserve fatty acids from oxidation, 
and therefore, may play an important role in 
male fertility.(25) Many studies have investigated 
the role of different antioxidants on infertility. In 
an investigation by Lenzi and colleagues, it was 
shown that utilizing glutathione (600 mg/d for 
2 months) had a significant effect on increasing 

sperm motility and morphology.(26)  They carried 
out another study in 1993 on 20 infertile men 
and re-established the role of glutathione in 
improving sperm motility and morphology.(27) 
In 1996, Suleiman and coworkers determined 
the role of vitamin E in the treatment of infertile 
men. They treated 82 infertile men with vitamin 
E and demonstrated that sperm motility increased 
from 31.1% to 48.9%, compared to a slighter 
increase from 30.6% to 35.9% in the control 
group of infertile men.(28) In the group receiving 
vitamin E, 11 pregnancies took place, 9 of which 
led to birth; however, no pregnancies happened 
in the control group. In another research project, 
Martin-Du Pan and Sakkas treated 14 infertile 
men with vitamin E and gave another 20 infertile 
men glutathione.(29) They concluded that vitamin 
E improved sperm count, while glutathione 
increased sperm motility. Five years later, 
Ibrahim and colleagues investigated the effect of 
vitamin E on 65 infertile men.(30) Sperm motility 
and sperm count increased from 32.46% and  
11.9 × 106/mL to 37.2% and 12.15 × 106/mL  
in their patients, respectively. Eskenazi 
and associates performed another study on 
96 healthy male participants in California 
University in 2005.(31) They established the fact 
that using antioxidants (vitamin E, vitamin C, 
L-carnitine, and beta carotene) had beneficial 
effects on concentration and motility of the 
sperm; especially, class A motility. Increased 
absorption of antioxidants led to increased effect 
on concentration and motility of the sperm. 
Therefore, those with higher absorption, had  
80 × 106/mL more sperm than those with lower 
absorption; furthermore, the number of sperm 
with class A motility was 36 × 106/mL more in 
those with a high absorption rate.(32)

Crocetin and dimethylcrocetin are derived from 
crocin which is a water-soluble carotenoid found 
in the stigmas of saffron.(16) Their antioxidant 
effect has been documented in several studies.(14-16)  
We tested this effect on the sperm of infertile 
men and found no significant change in sperm 
count after a period of treatment with saffron; 
however, significant alterations were observed 
in sperm morphology and motility. The normal 
morphology of the sperm increased from a mean 
of 26.5% to 33.9%; class A motility was initially 



Saffron and Semen Parameters of Infertile Men—Heidary et al

258 Urology Journal    Vol 5    No 4    Autumn 2008

5.3% that later increased to 11.8%. As for class 
B and C motility, the preliminary amounts of 
10.1% and 19.8% changed to 17.9% and 25.4% 
after the treatment course, respectively. Overall, 
the introductory amount of motile sperm 
(35.2%) increased to the final amount of 55.1%. 
Although the study did not have the strength 
of a randomized controlled trial, results were 
promising and the effect of saffron on semen 
parameters was documented. This can be a basis 
of further investigation on saffron ingredients in 
infertility research.

CONCLUSION
Saffron has a positive effect on semen parameters 
in terms of sperm motility in men suffering 
from idiopathic infertility. It comprises several 
ingredients and even though its antioxidative 
effect may be the reason behind its positive 
value on spermatic parameters, further studies 
are required to define its exact mechanism of 
action. Moreover, we acknowledge the need for 
further studies on larger groups of patients. We 
also believe that a longer period of follow-up, 
possibly up to 1 year, will be more beneficial in 
determining the role of saffron on seminal fluid.

CONFLICT OF INTEREST
None declared.

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