Bangladesh Journal of Pharmacology

Research Article

Effect of semen sojae germinatum 
on experimental osteoarthritis in the 
rabbit knee  

BJP



Introduction 

Osteoarthritis (OA) characterized by progressive 
degeneration of the articular cartilage and accompanied 
by subchondral bone sclerosis and synovial inflamma-
tion is a degenerative joint disease afflicting an increa-
singly older population (Felson et al., 2000). Appro-
ximately 10% of adults aged 60 years or older suffer 
from OA of the knee (Scott and Kowalczyk, 2008). 
There is still no curative treatment for this disease 
despite availability of a large number of therapeutic 
options including nonpharmacological, pharmaco-
logical, and surgical therapies. Drug therapy includes 
non-opioid analgesics such as non-steroidal anti-
inflammatory drugs (NSAIDs), topical analgesics, opi-
oid analgesics and intra-articular steroid injection. Such 
treatments can only relieve some symptoms of OA, and 
may prove ineffective in some patients (Tramèr et al., 
2000). The most common therapy for treating OA is 
NSAIDs, but their use may be restricted by adverse 
gastrointestinal effects including serious occurrences of 

bleeding causing many deaths (Felson et al., 2000). 
Hence, there appears to be a need for drugs with good 
efficacy and low toxicity in the treatment of OA. 

Chinese medicine, such as herbal medicinal products, 
has been proved to be effective in the treatment of OA 
through slowing down cartilage degeneration, promo-
ting articular cartilage repair and inhibiting synovial 
inflammation (Wang et al., 2010a). Importantly, no 
serious side effects were reported with any herbal 
intervention (Cameron et al., 2009). In traditional 
Chinese medicine, the condition which is congruent 
with OA is called "Bi syndrome" (painful obstruction 
syndrome), and more specifically, “Bi syndrome of 
bone”. “Bi syndrome” manifests as pain, soreness, or 
numbness of muscles, tendons and joints, and is the 
result of the body being "invaded" by the external 
climatological factors of Wind, Cold, Heat, and/or 
Dampness (Hua and O’Brien, 2010). Semen sojae 
germinatum (SSG) is one of Chinese folk recipes 
treating “Bi syndrome of bone” recorded by "Shen 

A Journal of the Bangladesh Pharmacological Society (BDPS) Bangladesh J Pharmacol 2013; 8: 365-370
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Abstract
As a complementary therapeutic approach, soy ingredients, such as 
soy protein and soybean unsaponifiables, recently attract more attention for 
relieving symptoms of osteoarthritis (OA). Semen sojae germinatum (SSG) 
processed from bean-sprout coming from germinating Glycine max L. Merr. is 
a traditional Chinese herbal medicine treating knee OA. We evaluated the 
effect of SSG as feed on the development of anterior cruciate ligament 
transaction (ACLT) -induced knee OA in rabbits. The results showed that SSG 
reduced the severity of cartilage degeneration in macroscopic grading scale, 
and delayed the degradation of the cartilage matrix. The contents of 
prostaglandin E2 (PGE2), nitric oxide (NO), tumor necrosis factor (TNF)- , 
interleukin-6 (IL-6) and IL-1  in synovial fluid, mRNA and protein
expressions of matrix metalloproteinases (MMP)-3, MMP-13 in cartilage were 
effectively decreased in SSG group. These results demonstrate that SSG had a 
protective effect against the development of knee OA. 

Article Info
Received:  23 September 2013 
Accepted:  11 October 2013 
Available Online:  29 October 2013  

DOI: 10.3329/bjp.v8i4.16446 

Cite this article: 
He B, Wang J. Effect of semen sojae 
germinatum on experimental osteoar-
thritis in the rabbit knee. Bangladesh J 
Pharmacol. 2013; 8: 365-70. 

This work is licensed under a Creative Commons Attribution 3.0 License. You are free to copy, distribute and perform the work. You must attribute the work in the 
manner specified by the author or licensor.

Effect of semen sojae germinatum on experimental osteoarthritis in 
the rabbit knee  
Bingshu He1 and Jun Wang2
1Department of Orthopedic Surgery, Hubei Woman and Child Hospital, Wuhan 430070, China; 2Department of 
Pharmacy, Medical College, Wuhan University of Science and Technology, Wuhan 430065, China.



Nong's Herbal Classic" and “Compendium of Materia 
Medica”. Indeed, SSG is processed bean sprout coming 
from germinating Chinese black soybean (Glycine 
max L. Merr.) variety, and has been included in Edition 
2010 Pharmacopoeia of People's Republic of China as a 
new kind. Although SSG has been widely used in 
traditional Chinese medicine clinical practices based on 
the ancient Chinese perception and experience, 
nowadays, study on the modern pharmacological 
effects of SSG is still rare. 

In this study, we attempted to determine whether SSG 
has the protective effect on articular cartilage in a rabbit 
knee OA model induced by anterior cruciate ligament 
transaction (ACLT), and study its mechanism. 

Materials and Methods 

SSG preparation 

SSG was prepared referring to Edition 2010 Pharma-
copoeia of People's Republic of China. Chinese black 
soybeans (Glycine max L. Merr.)  were sprouted. When 
the sprouts are 1 cm high, spread them out, let wind 
blow them to a half dry, then dry them in the sun to 
prepare SSG. Subsequently, Lophatherum gracile and 
Juncus effusus (Lophatherum gracile 2 kg, Juncus 
effusus 1 kg /SSG 100 kg ) were put in the pot, and 
decocted twice (first time 60 min, second time 30 min). 
Then the decoction solution was mixed and filtrated. 
The filtrate and SSG were both put in a pot, then 
cooked until the filtrate was all absorbed by SSG. The 
total amount of daidzin (C21H20O9) and genistein
(C21H20O10) accounted for no less than 0.08% (w/w) of 
the dry material using HPLC method as described in 
Edition 2010 Pharmacopoeia of People's Republic of 
China. Finally, the prepared SSG was dried and 
smashed to make the standard granulated feed. 

Animal and experimental arthritis 

New Zealand white rabbits (2.0-2.5 kg) were obtained 
from the Laboratory Animal Center of Wuhan 
University (Wuhan, Hubei, China). Animal care and 
treatment were in accordance with the guidelines of the 
Laboratory Animal Management and Review 
Committee of Wuhan University of science and 

technology. Rabbits were randomly divided into 3 
groups of 5 rabbits each: sham operated group, the OA 
model control group and SSG group. Rabbits in SSG 
group were fed with the diet made of prepared SSG, 
while rabbits in sham operated group and the OA 
model control group were fed with normal diet. The 
basis of the food which was used to prepare the SSG 
containing food was the same as the food given to the 
control animals 

After the animals were fed with the corresponding diet 
for 4 weeks, OA was induced by ACLT and excisions of 
medial menisci in the right knees (Yoshioka et al., 1996) 
on the rabbits of OA model control group and SSG 
group. The sham operated group only had the right 
joint cavity opened and then the incision was sutured. 
The corresponding diet was given unceasingly. 

Gross pathology observation and histological evalua-
tion 

After 8 weeks, the rabbits were sacrificed and femoral 
condyles were collected for observation. The depth of 
erosion was graded on a scale of 0-4 (Pelletier et al., 
1998). All samples were graded by three independent 
observers unaware of the treatment groups. The carti-
lage samples were embedded in paraffin, and standard 
frontal sections of 5 μm sections were prepared and
stained with toluidine blue in the lateral part of the 
femoral condyle cartilage according to gross observa-
tion (Cake et al., 2000). 

Prostaglandin (PG)E2, nitric oxide (no), tumor necrosis 
factor (tnf)- , interleukin (il)-6 and il-1 in synovial
fluid 

After the rabbits were sacrificed, knees were washed 
with 1 mL of 0.9% (w/v) physiological saline solution 
through the patellar tendon. The contents of PGE2 and 
NO in synovial fluid were measured by the correspond-
ding kits (Chinese Academy of Medical Sciences, 
Beijing, and Jiancheng Co., Nanjing, China, respec-
tively). Concentrations of TNF- , IL-6 and IL-1 in
synovial fluid were measured using ELISA kits 
(Jiancheng Co., Nanjing, China). 

mRNA and protein expression of matrix 
metalloproteinases (mmp)-3 and mmp-13 in cartilage 

The expression levels of MMP-3 and MMP-13 mRNA in 

366 Bangladesh J Pharmacol 2013; 8: 365-370 

Table I 

Primer sequences used in the study 

Gene Length Sequence of primers 

MMP-3 Sense 5′-AGCCAATGGAAATGAAAACTCTTC-3′ 72 bp 

Antisense 5′-CCAGTGGATAGGCTGAGCAAA-3′ 
MMP-13 60 bp Sense 5’- TTT TGA AGA CAC GGG CAA G -3’ 

Antisense 5’- TCA TCA TAG CTC CAG ACT TGG TT -3’ 
GAPDH  66 bp Sense 5’- AGC CAC ATC GCT CAG ACA -3’ 

Antisense 5’- GCC CAA TAC GAC CAA ATC C -3’ 



cartilage were detected by quantitative real-time PCR 
using TaqMan probes 59-fluorescent labeled with either 
FAM or VIC in a thermal cycler (ABI PRISM 7500 
Sequence Detector System, Applied Biosystems, Foster 
City, CA, USA), employing glyceraldehyde-3-
phosphate dehydrogenase (GAPDH) gene as a 
reference gene. The sequences of each primer set 
(Invitrogen, Carlsbad, CA) used are given in Table I. 

The protein expression levels of MMP-3 and MMP-13 
were detected by Western blot. Proteins in cartilage 
were separated by SDS-PAGE and proteins were trans-
ferred onto a polyvinylidene difluoride membrane by 
electroblotting. Membrane was blocked overnight and 
then incubated for 2 hours with a 1:1000 dilution of goat 
polyclonal MMP-3 or rabbit polyclonal MMP-13 
antibody (Santa Cruz, CA). After incubation with the 
secondary antibody, proteins were detected with an 
ECL chemiluminescence detection kit (Advansta, USA.) 
and scanned. The amount of protein expression was 
corrected by the amount of GAPDH in the same 
sample. 

Data analysis 

Comparisons between groups were per-formed with 
one-way ANOVA analysis using SPSS 11.5 software. 
The data were reported as means ± standard deviation 
(SD). Statistical significance was defined by the value of 
p<0.05. 

Results 

Knee articular cartilage of rabbits in sham operated 
group is smooth and lustrous. In the OA model control 
group, the articular cartilage surface was rough and 
had some superficial leakage and ulcers. In SSG group, 
cartilage lesions associated with OA were clearly seen, 
but the severity was milder than in OA group (Figure 1 
A). Macroscopic grades in SSG group were significantly 
lower than those in the OA model control group (p< 
0.05) as seen in Figure 1B, suggesting SSG can reduce 
the severity of the cartilage degeneration in macros-
copic grading scale.  

Articular cartilage consists of chondrocytes sparsely 
embedded within an abundant extracellular matrix 
which is composed essentially of water, proteoglycans, 
collagens and non-collagenous proteins (Cake et al., 
2000). And cartilage proteoglycan loss is believed as one 
of the hallmarks of OA, because proteoglycans have the 
properties of resisting compression and generating the 
swelling pressure due to their affinity for water 
(Echtermeyer et al., 2009). Toluidine blue staining for 
proteoglycans (Getzy et al., 1982) showed a distinct 
reduction of these compounds in the cartilage matrix of 
OA rabbits. In SSG group, the matrix degradation was 
less evident than OA group (Figure 2). 

Pro-inflammatory mediators alter matrix homeostasis 

and participate in the destruction of articular cartilage, 

thereby contributing to OA. It has been shown that OA 

Bangladesh J Pharmacol 2013; 8: 365-370   367 

Sham operated group    OA model control group     SSG groupA

p<0.01   p<0.01
G

ra
de

4 

3 

2 

1 

0 

B

Sham operated 
group 

OA model control 
group

SSG 
group

Figure 1. Gross pathological observation of the femoral condyle. A: Representative images of the femoral condyle from rabbits in 
sham operated, OA model control and SSG groups; B: Macroscopic grading scale of cartilage. 



cartilage spontaneously releases PGE2 at 50-fold higher 

levels than in normal cartilage (Wang et al., 

2010b). Also, NO has been identified as another agent in 

OA. NO is produced in large amounts by chondrocytes 

upon pro-inflammatory cytokine stimulation，and 

correlates with the pathophysiological changes in 

chondrocytes (Schwager et al., 2011). In addition, pro-

inflammatory cytokines IL-1 , IL-6 and TNF-  have
been suggested as key players in OA pathogenesis, and 

they are of an important role for development of 

synovitis and destruction of cartilage matrix (Bondeson 

et al., 2006; Goekoop et al., 2010). 

The levels of PGE2, NO, TNF- , IL-6 and IL-1  in
synovial fluids were markedly higher in OA group than 

in sham operated group (p<0.01). In SSG group, the 

PGE2 , NO, TNF- , IL-6 and IL-1 secretion reduced
13.9, 18.9, 22.7, 38.5 and 28.0% respectively com-pared 

to the OA group (p<0.05; p<0.01)(Table II), suggesting 

SSG inhibited the synovial inflammation. 

Increased MMP expression can be detected in the early 

stages of OA (Pelletier et al., 1990). MMP-3 can degrade 

the proteoglycan of cartilage (Yamanaka et al., 2000), 

while MMP-13 is known to degrade collagens and 

glycosaminoglycans (Roberts et al., 2000). As seen in 

Figure 3, SSG showed the beneficial effect on MMP-13 

and MMP-3 mRNA and protein expression in cartilage 

which are related to cartilage matrix degradation 

(p<0.05). 

Discussion 

Alternative and complementary therapeutic appro-
aches, such as the use of a wide array of herbal and 
nutritional manipulations, are becoming popular for 
relieving symptoms of OA (Pirotta, 2010). Notably, 
some components of soy have great potential in OA 
control. It has been demonstrated (Arjmandi et al., 
2004) that 40 g of supplemental soy protein daily for 3 
months improved OA-associated symptoms, such as 
range of motion and several factors associated with 
pain and quality of life, in comparison to same dosage 
of milk-based protein. Furthermore, biochemical mar-
kers of cartilage metabolism further supported the 
efficacy of soy protein supplementation in relieving 
symptoms of OA as indicated by a significant increase 
in serum level of insulin-like growth factor-I, a growth 
factor associated with cartilage synthesis, and a signifi-
cant decrease in serum level of glycoprotein 39, a 
marker of cartilage degradation (Arjmandi et al., 2004). 
Besides, avocado/soybean unsaponifiables (ASU), a 
new antiarthritic agent derived from unsaponifiable 
residues of avocado and soybean oils mixed in the ratio 
of 1:2 respectively, has also been recommended for treat
-ing OA with published basic and clinical trials in
animals and humans (Maheu et al., 1998; Appelboom et
al., 2001; Kut-Lasserre et al., 2001; Henrotin et al., 2003),
thus considered a symptomatic disease-modifying osteo
-arthritic compound (Lippiello et al., 2008). Meta-
analysis data support better chances of success
in patients with knee OA than in those with hip OA
(Christensen et al., 2008). Therefore, components of soy

368 Bangladesh J Pharmacol 2013; 8: 365-370 

A B C

Figure 2. Histologic examination of cartilage change in rabbits of sham operated (A), OA model control (B) and SSG (C) groups. 
Cartilages were stained with toluidine blue. (original magnification × 100) 

Table II 

Concentration of PGE2, NO, TNF- , IL-6 and IL-1 in synovial fluids from knees of rabbit OA

Group PGE2/ng/mL NO/µmol/L TNF- / ng/mL IL-1 /pg/mL IL-6/pg/mL 

Sham operated 2.2 ± 0.4 29.8 ± 8.2 0.002 ± 0.0 8.5 ± 0.9 0.1± 0.03 

OA model control 3.1 ± 0.3a 151.1 ± 21.2a 15.1 ± 3.1a 322.2 ± 84.5a 219.7 ± 45.5a 

SSG 2.7 ± 0.4b 122.6 ± 26.2b 11.7 ± 2.6b 198.2 ± 74.5c 158.2 ± 51.2b 

Data are mean ± SD; n ＝ 5; ap<0.01, vs Sham operated group; bp<0.05, cp<0.05 vs OA model control group  



seem to be the feasible alternative to the control of OA. 

Similar to the soy protein and ASU, SSG, a traditional 
Chinese medicine for “bi syndrome of bone” and “knee 
pain”, also comes from the soy. SSG has been used for 
the treatment of joint pain and arthritis by Chinese 
medical doctor for over 2000 years. From the unique 
perspective of Chinese medicine, SSG has the effects of 
relieving exterior syndrome, activating blood circulation, 
detumescence and dehumidify. These effects, interpreted 
as analgesia, anti-inflammatory, promoting microcircu-
lation and reducing swelling respectively in modern 
pharmacology, are all helpful for OA control. This 
study has shown that SSG as the feed material reduced 
the severity of the cartilage degeneration and delayed 
the degradation of cartilage matrix on rabbit knee OA 
model, indicating that SSG has a protective activity for 
OA.  

Many researches have demonstrated that enzymatic 
cleavage by MMPs together with pro-inflammatory 
cytokines plays critical roles in the initiation and 
progression of cartilage destruction (Ju et al., 2010). The 
results of this study demonstrated that the contents of 
PGE2, NO, TNF- , IL-6 and IL-1  in synovia and
expressions of MMP-3, MMP-13 in cartilage were 
elevated in OA model group, whereas the elevation of 
PGE2, NO, TNF- , IL-6, IL-1 , MMP-3 and MMP-13
levels were significantly suppressed in SSG groups. 
Interestingly, these effects are similar to the anti-
osteoarthritic mechanism of ASU (Maheu et al., 1998; 
Appelboom et al., 2001; Kut-Lasserre et al., 2001; 

Henrotin et al., 2003). 

In addition, SSG is widely used in Chinese medicine, 
and also a kind of processed food - bean sprout, so its 
excellent safety record is reassuring. In the present 
study, no observable adverse effect of SSG as the feed 
material was seen during and after the 12-week feeding. 

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370 Bangladesh J Pharmacol 2013; 8: 365-370 

Author Info 
Jun Wang (Principal contact) 
e-mail: wangj79@hotmail.com

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	Materials and Methods: 
	Gene Length Sequence of primers: 
	DatePrinted: This article was downloaded by you on: Aug 27, 2018