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Professor Wang Jingfeng of Ocean University of China, et al.: Antarctic krill oil, fish oil and arachidonic acid oil on osteoporosis

 Last Update: 2023-01-05
 Source: Internet
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Osteoporosis is a common bone imbalance that manifests as bone loss, damage to bone microstructures, and increased bone marrow fat
.
Clinical data show that osteoporosis is closely related to lipid metabolism disorders in the body
.
In postmenopausal women, bone mineral density was significantly negatively correlated with total cholesterol and LDL levels.
And a large number of studies have shown that patients with osteopenia have higher bone marrow fat content than healthy people
.
Bone marrow is the only tissue where fat cells and bone cells directly interact, and bone marrow adipose tissue is located in the bone marrow cavity, accounting for more than 10% of total fat in healthy adults, and plays an important role
in aging, osteoporosis, diabetes and many other diseases.

Xiaolin Bai, Yuying Bo, Jingfeng Wang*, etc.
from the School of Food Science and Engineering of Ocean University of China used the most common n-3 polyunsaturated fatty acid (PUFA) supplements on the market, fish oil (FO) rich in ethyl ester DHA and EPA, and Antarctic krill oil (AKO) rich in phospholipid DHA and EPA.
The effects of two different molecular forms of DHA, EPA and arachidonic acid on osteoporotic lipid metabolism were explored by using the most representative n-6 PUFA arachidonic acid oil (AAO) as a control, aiming to provide theoretical guidance
for the diet of osteoporosis patients.

1.
Effects of AKO, FO and AAO on body mass and white fat mass of OVX model mice

As shown in Figure 1, compared with the Sham group, the body weight increase of mice in the OVX group was significantly increased (P<0.
01), and the mass mass of white fat in the abdominal cavity to body fat ratio was also very significantly increased (P<0.
01).
<b10> Compared with the OVX group, after the intervention of AKO and FO, the body weight increase of mice was significantly reduced, and the mass and body fat ratio of white adipose tissue were significantly reduced.
In the gavage AAO group, the body weight increase increased by 18.
74%, and the white fat mass and body fat ratio did not change
significantly.
The results showed that both n-3 PUFAs could significantly inhibit the accumulation of fat in osteoporosis mice with ovarian osteoporosis, improve postmenopausal obesity, and the effect of AKO was better than that of FO.
The n-6 PUFA AAO does not have this effect
.

2.
Effects of AKO, FO and AAO on bone strength in OVX model mice

As shown in Figure 2A, compared to the Sham group, the bone density of mice in the OVX group was significantly reduced (P<0.
05).
<b10> Compared with the OVX group, after the intervention of AKO and FO, the bone density of mice increased to varying degrees, with an increase of 7.
14% (P<0.
01) in the AKO group and 2.
78% (P<0.
05) in the FO group, and a significant decrease in bone density (P<0.
01)<b11> after AAO gavage.
At the same time, Figure 2B showed that compared with the OVX group, after AKO and FO intervention, the biomechanical properties of mouse bones were improved to varying degrees, and the fracture breaking force increased, indicating that the ability to resist fracture fracture was enhanced, while AAO intervention showed the opposite effect
.
The results showed that both n-3 PUFA could improve bone strength and biomechanical properties of ovary-removed mice, and the AKO effect was better than that of FO.
N-6 PUFA AAO reduced bone density and bone biomechanical properties
in OVX mice.

3.
Effects of AKO, FO and AAO on bone tissue morphology of OVX model mice

As shown in Figures 3 and 4, severe bone microstructure destruction occurred in the OVX group, suggesting the occurrence of osteoporosis.
After AKO intervention, the bone trabeculae of OVX mice became significantly thicker and the continuity improved.
AAO intervention will further disrupt the bone microstructure
of OVX mice.
After ovarian removal, the number of fat cells in the OVX group increased significantly compared with the Sham group (P<0.
01).
<b11> Compared with the OVX group, the number of adipocytes was significantly reduced after AKO and FO intervention, while the number of adipocytes was higher after AAO intervention, which seriously damaged the bone microstructure
.
The results showed that both n-3 PUFA could improve bone microstructural damage caused by osteoporosis and reduce fat accumulation in the bone marrow cavity, and the effect of AKO intervention was better than FO.
N-6 PUFA AAO increases the number of fat cells in the bone marrow cavity and aggravates lipid metabolism disorders
.

4.
Effects of AKO, FO and AAO on the liver of OVX model mice

There was no significant difference in hepato-body ratio (liver mass/body weight) between the different groups (Figure 5A), however, liver histology showed significant white lipid droplet vacuoles in the cytoplasm of liver cells in mice in the OVX group compared to the Sham group (Figure 5B); After the intervention of AKO and FO, liver cells were arranged neatly and well-defined, lipid droplets disappeared in the cytoplasm, there was no obvious steatosis, and the morphology of liver cells in the AKO group was closer to that of the Sham group.
After AAO intervention, the liver cells of mice were arranged disorganized, the lipid droplet vacuoles in the cells increased, and liver lipids accumulated
.

5.
Effects of AKO, FO and AAO on serum and liver lipid levels in OVX model mice

As shown in Figure 6A, compared with the Sham group, the serum concentrations of TC and TG in the OVX group were significantly increased
.
Compared with the OVX group, after gastric gavage of AKO or FO, the serum TC and TG concentrations in the AKO group decreased significantly by 9.
77% (P<0.
01) and 11.
54% (P<0.
05), respectively, and the serum TC and TG concentrations in the FO group did not change significantly.
After AAO intervention, the serum concentrations of TC and TG increased by 18.
55% (P<0.
01) and 15.
14% (P<0.
05),<b11> respectively.

It can be seen from Figure 6B that compared with the OVX group, the content of TC and TG in the liver decreased compared with the OVX group after AKO and FO intervention, while the trend
was higher after AAO intervention.
It was suggested that both n-3 PUFA could inhibit the increase of blood lipid and liver lipid levels in OVX mice, and the AKO effect was more significant.
n-6 PUFA AAO promotes the rise
of lipid levels.

6.
Effects of AKO, FO and AAO on key genes for liver lipid synthesis in OVX model

It can be seen from Figure 7 that compared with the Sham group, the expression levels of mRNA of SREBP1c, FAS, ACC and SCD1 in the liver of mice in the OVX group were significantly increased, indicating that lipid synthesis in the liver of ovary mice was increased.
Compared with the OVX group, after AKO and FO intervention, the expression level of key genes for lipid synthesis in the liver of mice decreased significantly or very significantly, and the effect of AKO was better overall.
Compared with the OVX group, the mRNA expression levels of SREBP1c, FAS, ACC and SCD1 increased by 31.
85%, 21.
12%, 40.
71% and 18.
35%, respectively
.

conclusion

In summary, the intake of n-3 PUFA can improve the accumulation of lipids caused by postmenopausal osteoporosis, and the effects of phospholipid DHA and EPA are better than those of ethyl ester DHA and EPA.
The intake of n-6 PUFA exacerbates lipid metabolism disorders and increases the risk of
disease exacerbation in patients with osteoporosis.

Corresponding author

Jingfeng Wang, female, is a doctoral supervisor at the School of Food Science and Engineering, Ocean University of China, focusing on high-value utilization of marine biological resources, molecular nutrition and marine functional foods
.
He has long been engaged in the research
of high-value development and utilization of marine biological resources, molecular nutrition, and research and development of marine functional foods.
He has presided over and completed more than 10 national "863" plans, national science and technology support plans, national natural science foundations, national marine public welfare industry scientific research projects, national key research and development plans and provincial and ministerial research projects, with funds exceeding 20 million yuan
.
He has published more than 200 core papers, published more than 60 SCI/EI articles as corresponding authors, obtained more than 10 authorized national invention patents, and won the first prize of Shandong Province Science and Technology Progress Award
.

First author bio

Xiaolin Bai, female, holds a master's degree in food science and human health and molecular nutrition, Ocean University of China
.
E-mail: 1601983641@qq.
com

This article "Effects of Antarctic krill oil, fish oil and arachidonic acid oil on lipid metabolism in osteoporosis mice" is from Food Science, Vol.
43, No.
17, 2022, pages 131-137, authors: Xiaolin Bai, Yuying Bo, Ning Ding, Qinghui Wang, Lihua Han, Jingfeng
Wang.
DOI:10.
7506/spkx1002-6630-20210606-073
。 Click below to read the original article to view information about
the article.

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