Endourology and Stone Disease

149Urology Journal    Vol 5    No 3    Summer 2008

Effect of Thymoquinone on Ethylene Glycol-Induced 
Kidney Calculi in Rats
Mousa-Al-Reza Hadjzadeh,1 Nama Mohammadian,2 Zeynab Rahmani,1  
Fatemeh Behnam Rassouli1

Introduction: The aim of this study was to investigate the effects of 
thymoquinone, a major component of Nigella Sativa seeds on ethylene glycol-
induced kidney calculi in rats.   
Materials and Methods: Sixty male Wistar rats were randomly divided into 
6 groups (intact control, ethylene glycol control, and 4 experimental groups) 
and treated for 28 days according to the protocol of the study. The rats in 
experimental groups received ethylene glycol and intraperitoneal injection 
of thymoquinone either from the first day of the study or the 15th day, 
with either doses of 5 mg/kg or 10 mg/kg. Blood and 24-hour urine samples 
were collected at baseline and on day 28. Urine oxalate and citrate and serum 
electrolytes were also measured. On day 29, all rats were decapitated and 
their kidney specimens were studied. 
Results: On day 28, urine oxalate concentration significantly decreased in 
the experimental groups compared to the ethylene glycol group (P < .001). 
Also, serum calcium levels were significantly higher in the experimental 
groups (P = .001). Calcium oxalate deposits were smaller in the experimental 
groups than the ethylene glycol group. The mean number of deposits was 
lower in these groups, too (P < .001). Treatment with the lower dose of 
thymoquinone was associated with fewer deposits.  
Conclusion: Thymoquinone significantly decreased the number and size 
of calcium oxalate deposits in the renal tubules. The dose and duration of 
treatment, however, does not have a linear relation with the outcomes. 
Further studies on thymoquinone as a preventive and therapeutic drug for 
kidney calculi are suggested.

Urol J. 2008;5:149-55. 
www.uj.unrc.ir

Keywords: urinary calculi, rats, 
thymoquinone, calcium oxalate, 

ethylene glycol

1Department of Physiology, 
Mashhad University of Medical 

Sciences, Mashhad, Iran
2Departemnt of Pathology, Ghaem 

Hospital, Mashhad University of 
Medical Sciences, Mashhad, Iran

Corresponding Author:
Mousa-Al-Reza Hadjzadeh, MD, PhD

Department of Physiology, Ghaem 
Hospital, Mashhad University of 

Medical Sciences, Mashhad, Iran
Tel:  +98 511 844 0350 
Fax: +98 511 844 0350

E-mail: hajzadehmr@mums.ac.ir

Received January 2008 
Accepted May 2008

INTRODUCTION
Invasive procedures for the 
treatment of urinary calculi may 
cause serious complications and 
they also impose a great load of 
costs to the healthcare system.
(1,2) In traditional medicine, there 
are noninvasive treatment options 
for urinary calculi that are worth 
to undergo scientific evaluation. 
Nigella Sativa L (NS) seeds (known 

as black seed in Iran) have been used 
for this purpose in folk medicine 
for centuries.(3,4) We have previously 
shown the preventive effect of 
ethanolic extract of NS seeds on 
calculus formation,(5) and other 
investigators have demonstrated 
its increasing effect on glutathione 
content in the kidney and also its 
anti-inflammatory, antioxidant, 
and analgesic activities.(6-8) As a 



Thymoquinone and Ethylene Glycol-Induced Kidney calculi—Hadjzadeh et al

150 Urology Journal    Vol 5    No 3    Summer 2008

major component of NS seeds, thymoquinone 
was reported to reduce blood pressure and heart 
rate, prevent chromosomal aberrations, and act 
as anticonvulsant, antioxidant, and a scavenger of 
free radicals and superoxide anions.(9-13) Of other 
effects of thymoquinone are hepatoprotective 
activity, improvement of cisplatin-induced 
nephrotoxicity, inhibition of cyclooxygenase 
pathway and eicosaniod generation in leukocytes, 
and inhibition of 5-lipooxygenase products.(14-18) 

In our previous study, we used ethylene glycol 
(EG) to induce kidney calculus formation in 
rats and found that NS can inhibit this effect. 
Metabolites of EG such as glycolaldehyde, 
glycolate, and oxalate can induce tissue damage, 
hyperoxaluria, and calcium oxalate (CaOx) 
calculi.(19,20) To scrutinize the exact mechanism 
of NS effect on the kidney, we decided to test 
its components on the kidneys of rats who 
were fed by EG. The aim of this study was to 
investigate the effects of thymoquinone as a major 
component of NS seeds on EG-induced CaOx 
kidney calculi in rats.   

MATERIALS AND METHODS
We randomly divided 60 male Wistar rats into 
6 groups of 10 (groups A to F). They weighted 
190 ± 20 g. All groups of rats were kept at 25 ± 
2˚C with a standard diet and tap drinking water 
and were treated according to the protocol of 
the study for 28 days. Rats in group A (intact 
controls) received tap drinking water, and 
those in group B (EG controls) received 1% 
EG (Merck KGaA, Darmstadt, Germany) in 
drinking water for 28 days. Rats in groups C to 
F received thymoquinone (Aldrich, WI, USA) 
with different protocols as well as the same dosage 
of EG as those in group B; in groups C and D, 
thymoquinone, 5 mg/kg/d, was administered 
as intraperitoneal injection from day 1 and day 
15 to the end of the experiment, respectively. 
Rats in groups E and F were treated by 10 mg/
kg/d of thymoquinone from day 1 and day 
15, respectively. The animal procedures were 
complied with the international guidelines and 
national laws, and the study was approved by 
Mashhad University of Medical Sciences.

Twenty-four-hour urine samples were collected 

on the first and 28th days of the study, while 
each rat was kept in a separate metabolic cage. 
Blood was also collected from the cavernous 
sinus on the same days. Serum levels of calcium, 
potassium, and magnesium were measured by 
enzymatic method, flame photometer, and 
xylidyl blue reaction, respectively. Urine oxalate 
and citrate were measured by enzymatic methods 
(Darman Kaw, Tehran, Iran) with an auto-
analyzer. All rats survived until day 29 when they 
were decapitated by guillotine. Their kidneys 
were removed, weighed, and kept in formalin 
for histological studies. Five-μm sections were 
prepared from both kidneys, and the slides were 
stained with hematoxylin-eosin method. The 
slides were examined under light microscope and 
CaOx deposits were determined. Aggregations of 
CaOx deposits (tubules containing deposits) were 
counted in 10 microscope fields. 

Data were expressed as mean ± standard deviation 
and were analyzed by the Kruskal-Wallis test to 
find the differences among all groups, and Mann-
Whitney U test for comparison between each two 
groups. A P value less than .05 was considered 
significant.

RESULTS
No CaOx deposits or other pathological defects 
were found in different segments of the nephrons 
of the rats in group A (intact controls; Figure 1).  
On the other hand, many CaOx deposits were 
found in the proximal tubules, loops of Henle, 
distal tubules, collecting ducts, and calyxes of 
the rats in group B (EG controls; Figure 2). 
Aggregations were composed of 3 to 4 large 
polygonal crystals in different parts of the 
tubules. Renal tubular dilation with epithelial 
damage and leukocyte reaction were also observed 
on pathology examination (Figure 3). The mean 
number of CaOx deposits in 10 microscopic 
fields was 28.0 ± 3.2 in group B, which was 
significantly more than that in group A (P = .001; 
Figure 4). 

In the kidney specimens of group C, a few thin 
and tiny crystals of CaOx were detected in 
different parts of the tubules (mean, 1.4 ± 0.9;  
P = .001, compared with group B). Tiny calcium 
oxalate crystals were also detected in different 



Thymoquinone and Ethylene Glycol-Induced Kidney calculi—Hadjzadeh et al

Urology Journal    Vol 5    No 3    Summer 2008 151

segments of the nephrons in group D (with 
thymoquinone started on day 15). The rats in this 
group had less deposits than those in group B, 
too (mean, 2.2 ± 1.0; P = .001). Thymoquinone 

was administered with a higher dose in groups 
E and F. Crystals in different parts of nephrons 
in the kidney specimens of these groups were 
also thin, small, and fewer compared with those 
in group B (mean, 5.2 ± 1.6 and 14.6 ± 3.0, 
respectively; P = .001 and P = .03). The number 
of CaOx crystals in experimental groups C and D 
was not statistically different from that in group 
A. The number of the deposits in group D was 
significantly less than that in group F (P = .008); 
however, the difference between groups C and E 
was not significant. 

Urine oxalate concentration of the rats was higher 
in group B than in group A on day 28 (P < .001). 
Also, its concentration was higher in group B 
than in any of the experimental groups (C to F) 
on day 28 (Figure 5). Urine samples of the rats in 
group C had a lower levels of oxalate than those 

Figure 1. Left, Normal medullary and papillary tubules in the kidney of a Wistar rat (hematoxylin-eosin, × 20). Right, Normal tubular and 
collecting ducts (hematoxylin-eosin, × 40).

Figure 2. Left, Tubular calcium oxalate deposits (arrows) in a rat treated with ethylene glycol (hematoxylin-eosin, × 40). Right, Multiple 
tabular calculi (arrows) in the same rat (hematoxylin-eosin, × 40). 

Figure 3. Renal tubular dilation with epithelial damage and 
leukocyte reaction, producing granular and leukocytic cast 
(hematoxylin-eosin, × 40).



Thymoquinone and Ethylene Glycol-Induced Kidney calculi—Hadjzadeh et al

152 Urology Journal    Vol 5    No 3    Summer 2008

in group E (P = .003), but the difference between 
groups D and F was insignificant. Table 1 shows 
urine citrate concentrations at baseline and the 
end of the study. Urine citrate of the rats in group 
A was significantly higher than those in group B 
and the experimental groups except for group D. 
No difference was found between group B and the 
experimental groups in urine citrate concentration.  

Serum potassium concentrations in group B and 
group A were not significantly different, but it was 
lower in all the experimental groups than in group 
B (Table 2). Concerning serum calcium levels, rats 

in group B had a lower concentration on day 28 
than those in any of the other groups (Table 3).  
However, no significant difference was found 
between serum magnesium levels of the studied 
groups on day 28 (P = .74; Kruskal-Wallis test). 

Finally, the extracted kidneys were weighed and 
compared between the groups. The kidneys in 
group B was 62% heavier than those in group 
A (mean, 2.81 ± 0.26 g versus 1.73 ± 0.07 g, 
respectively). The kidneys in the experimental 
groups, although had a lower weight, were not 
significantly different from those in group B. The 

Figure 4. The number of calcium oxalate crystal deposits (in 10 microscopic fields) in the kidneys of the rats at the end of the 
experiment. Data are expressed as mean ± standard deviation. The Kruskal-Wallis test demonstrated a significant difference between 
the six groups (P < .001). 

Figure 5. The 24-hour urine oxalate concentration in different groups of rats on day 28. The Kruskal-Wallis test showed a significant 
difference between the six groups (P < .001).



Thymoquinone and Ethylene Glycol-Induced Kidney calculi—Hadjzadeh et al

Urology Journal    Vol 5    No 3    Summer 2008 153

mean weight of the kidneys were 1.86 ± 0.08 g, 
1.63 ± 0.09 g, 1.76 ± 0.09 g, and 1.94 ± 0.11 g in 
groups C, D, E, and F, respectively.

DISCUSSION 
According to our results, thymoquinone 

has a preventive effect on CaOx calculi 
formation in the kidneys of rats. In a similar 
way, thymoquinone has a disruptive effect on 
CaOx crystals formed by EG, demonstrating a 
therapeutic effect on kidney calculi in rats (Figure 4). 
To our best knowledge, this is the first report on 
the effects of thymoquinone on kidney calculi. 
Thymoquinone, as a major component of NS 
seeds, has been reported to reduce blood pressure 
and heart rate, prevent chromosomal aberrations, 
and act as anticonvulsant, antioxidant, and 
a scavenger of free radicals and superoxide 
anions.(9-13) Of other effects of thymoquinone 
are hepatoprotective activity, improvement of 
cisplatin-induced nephrotoxicity, inhibition 
of cyclooxygenase pathway and eicosaniod 
generation in leukocytes, and inhibition of 
5-lipooxygenase products.(14-18)

We found that with a dose of 5 mg/kg, 
thymoquinone had a potent preventive effect on 
calculus formation and a highly disruptive effect 
on CaOx kidney calculi. We also tried 10 mg/
kg of thymoquinone and documented its potent 
preventive effect on kidney calculus formation 
and a moderate effect on disruption of the kidney 
calculi. These data suggest that lower doses of 
thymoquinone might be more effective on the 
treatment of CaOx kidney calculi. In a study on 
the effect of thymoquinone on lipid profile of 
rats, Bamosa and colleagues tested intraperitoneal 
injection of thymoquinone with varying doses 
of 0.4 mg/kg to 8 mg/kg. They found that 
there was no linear association of the dose and 
lowering effect of thymoquinone on serum lipids. 
The highest dose they used (8 mg/kg) had toxic 
effects.(21) This is in accordance with our findings. 
Unpublished data at our university have shown 
that oral thymoquinone with a dose of 0.4 mg/kg 
could disrupt CaOx calculi in rats’ kidney.(22) 

It has been reported that an ethyl-acetate phase 
remnant fraction and N-butanol fraction from 
aqueous-ethanolic extract of NS seeds had 
preventive effects on EG-induced kidney calculi.(22) 
Both polar and nonpolar components are present 
in ethyl-acetate phase remnant fraction and only 
nonpolar components are present in N-butanol 
phase of the extract. Thymoquinone is the major 
nonpolar compound in the extracts of NS seeds; it 

Urine Citrate, mg/dL
Group Baseline Day 28 P†

A 31.75 ± 3.25 32.27 ± 3.35 …
B 29.37 ± 3.12 19.37 ± 2.52 .04
C 32.90 ± 3.51 12.90 ± 3.51 .01
D 29.34 ± 2.82 21.34 ± 2.22 .13
E 33.96 ± 3.83 13.96 ± 4.83 .01
F 32.18 ± 3.23 12.18 ± 1.93   .002

Table 1. Urine Citrate Concentrations Before and After the Study 
Period in Control and Experimental Groups*

*Data are expressed as mean ± standard deviation. No difference 
was found between the groups on day 0 (baseline); however, 
the Kruskal-Wallis test showed a significant difference between 
the groups (P = .007) on day 28. The differences between the 
experimental groups (C to F) and group B were insignificant.
†P values are related to comparisons of the values on day 28 
between group A and other groups (Mann-Whitney U test).

Serum Potassium, mg/dL
Group Baseline Day 28 P†

A 4.94 ± 0.20 6.22 ± 0.62  .09
B 5.04 ± 0.18 4.94 ± 0.22 …
C 5.24 ± 0.25 0.80 ± 8.20  .008
D 5.04 ± 0.26 0.60 ± 8.40  .008
E 5.34 ± 0.29 0.47 ± 7.02  .008
F 5.26 ± 0.25 0.93 ± 6.30  .03

Table 2. Serum Potassium Concentrations Before and After the 
Study Period in Control and Experimental Groups*

*Data are expressed as mean ± standard deviation. No difference 
was found between the groups on day 0 (baseline); however, the 
Kruskal-Wallis test showed a significant difference between the 
groups (P = .006) on day 28.
†P values are related to comparisons of the values on day 28 
between group B and other groups (Mann-Whitney U test).

Serum Calcium, mg/dL
Group Baseline Day 28 P†

A 9.16 ± 0.16  9.18 ± 0.18 .008
B 9.26 ± 0.22  8.28 ± 0.30 ...
C 9.26 ± 0.16  11.66 ± 0.89 .008
D 9.04 ± 0.16  11.20 ± 0.31 .008
E 9.14 ± 0.20  10.08 ± 0.26 .008
F 9.04 ± 0.24  10.58 ± 0.52 .008

Table 3. Serum Calcium Concentrations Before and After the 
Study Period in Control and Experimental Groups*

*Data are expressed as mean ± standard deviation. No difference 
was found between the groups on day 0 (baseline); however, the 
Kruskal-Wallis test showed a significant difference between the 
groups (P = .001) on day 28.
†P values are related to comparisons of the values on day 28 
between group B and other groups (Mann-Whitney U test).



Thymoquinone and Ethylene Glycol-Induced Kidney calculi—Hadjzadeh et al

154 Urology Journal    Vol 5    No 3    Summer 2008

was concluded by researchers that thymoquinone 
might be the main compound with preventive 
effect on kidney calculus formation in these 
studies.(22) These reports are in agreement with 
our data in the present study. 

Calcium oxalate crystals in tubules may damage 
epithelial cells that leads to production of 
superoxide anions and free radicals and induction 
of hetrogenic crystal nucleation.(23-25) On the other 
hand, thymoquinone, as an active quinine, has 
antioxidant effect, scavenges free radicals and 
superoxide anions, and inhibits cyclooxygenase 
and 5-lipoxygenase pathways; therefore, it inhibits 
inflammatory products.(17,18) Consequently, it 
can be suggested that a part of its effects on 
prevention and disruption of CaOx calculi is 
due to these roles.(13,18,26) Thymoquinone has an 
antibacterial effect, and therefore, calculi with 
a bacterial origin such as struvite calculi may 
be prevented by thymoquinone.(27,28) Urine 
oxalate concentration was also decreased by 
thymoquinone which is in agreement with its 
preventive effects on the CaOx kidney calculi. 
However, thymoquinone had no significant effect 
on the weight of the kidney which in part may be 
due to very short period of the treatment.

CONCLUSION
According to our results, intraperitoneal injection 
of thymoquinone was effective for prevention 
and treatment of CaOx kidney calculi in rats. A 
dose of 5 mg/kg of thymoquinone significantly 
decreased the number and size of CaOx deposits 
in different segments of the renal tubules. A 
higher dose of thymoquinone had also preventive 
and therapeutic effects on CaOx kidney calculi, 
although the therapeutic effect of thymoquinone 
with a dose of 5 mg/kg was more potent. Further 
studies to determine the same effects on human 
beings are recommended.

CONFLICT OF INTEREST
None declared. 

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