Difference between revisions of "Team:UST Beijing/Background"

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             <h1><span>Cholesterol</span></h1>
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             <h2><span>Cholesterol</span></h2>
             <p>an essential component of membrane structure, but gradually  
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             <h3>an essential component of membrane structure, but gradually  
               accumulates in arteries of human body, which becomes the top one killer mechanism of human life:</p>
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               accumulates in arteries of human body, which becomes the top one killer mechanism of human life: <span>atherosclerosis</span></h3>
            <p><span>atherosclerosis</span></p>
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             <h2><span> An alarming health threat: Atherosclerosis</span></h2>
             <h1><span> An alarming health threat: Atherosclerosis</span></h1>
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             <h3>Shown on the right are the cholesterol structure and pie charts of epidemic statistics of atherosclerosis-related mortality in China (black area: atherosclerosis-related death).</h3>
             <p>Shown on the right are the cholesterol structure and pie charts of epidemic statistics of atherosclerosis-related mortality in China (black area: atherosclerosis-related death).</p>
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         <h2><span>Pathology of Atheroscleosis</span></h2>
 
         <h2><span>Pathology of Atheroscleosis</span></h2>
         <p>Cholesterol is the main culprit of cardio-and cerebro-vascular disease. Artery atherosclerosis refers to arteries accumulated with cholesterol resulting in blockage of blood flow. In heart it causes heart attack. In brain it causes blockage stroke.</p>
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         <h3>Cholesterol is the main culprit of cardio-and cerebro-vascular disease. Artery atherosclerosis refers to arteries accumulated with cholesterol resulting in blockage of blood flow. In heart it causes heart attack. In brain it causes blockage stroke.</h3>
 
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         <h2><span>Molecular Mechanism of Atherosclerosis Formation</span></h2>
 
         <h2><span>Molecular Mechanism of Atherosclerosis Formation</span></h2>
         <p>Because of foam cell apoptosis, which is formed by macrophages overloading cholesterol, cholesterol is deposited on the inner wall of artery.</p>
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         <h3>Because of foam cell apoptosis, which is formed by macrophages overloading cholesterol, cholesterol is deposited on the inner wall of artery.</h3>
 
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         <h2><span>Nuclear receptor LXR as therapeutic target against atherosclerosis</span></h2>
 
         <h2><span>Nuclear receptor LXR as therapeutic target against atherosclerosis</span></h2>
         <p>Live X receptor(LXR) functions as a master regulation switch, which can accelerate the transport of cholesterol and prevent the formation of foam cells.</p>
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         <h3>Live X receptor(LXR) functions as a master regulation switch, which can accelerate the transport of cholesterol and prevent the formation of foam cells.</h3>
 
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        <h2><span>Nuclear receptor LXR as therapeutic target against atherosclerosis</span></h2>
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        <h3>Live X receptor(LXR) functions as a master regulation switch, which can accelerate the transport of cholesterol and prevent the formation of foam cells.</h3>
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  <blockquote><p>Ginseng triterpenes' structure is similar to that of cholesterol, therefore it has the potential of regulating LXRs.
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  <h3>Ginseng triterpenes' structure is similar to that of cholesterol, therefore it has the potential of regulating LXRs.
       LXRs is a typical nuclear receptor. In the presence of co-regulators, bound by agonists (such as ginsenosides), LXRs could be demobilized to specific site on a target gene promoter region to activate transcription of the target gene. Ginsenosides or like could therefore regulate the metabolism of cholesterol. </p></blockquote>
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       LXRs is a typical nuclear receptor. In the presence of co-regulators, bound by agonists (such as ginsenosides), LXRs could be demobilized to specific site on a target gene promoter region to activate transcription of the target gene. Ginsenosides or like could therefore regulate the metabolism of cholesterol. </h3>
 
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         <div class="item_description"><h1><span>Atherosclerosis formation is delayed<br>by ginsenosides in vivo</span></h1></div>
 
         <div class="item_description"><h1><span>Atherosclerosis formation is delayed<br>by ginsenosides in vivo</span></h1></div>
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Revision as of 12:29, 16 October 2018

Team:UST_Beijing/Collaborations

Cholesterol

an essential component of membrane structure, but gradually accumulates in arteries of human body, which becomes the top one killer mechanism of human life: atherosclerosis

An alarming health threat: Atherosclerosis

Shown on the right are the cholesterol structure and pie charts of epidemic statistics of atherosclerosis-related mortality in China (black area: atherosclerosis-related death).

Pathology of Atheroscleosis

Cholesterol is the main culprit of cardio-and cerebro-vascular disease. Artery atherosclerosis refers to arteries accumulated with cholesterol resulting in blockage of blood flow. In heart it causes heart attack. In brain it causes blockage stroke.

Molecular Mechanism of Atherosclerosis Formation

Because of foam cell apoptosis, which is formed by macrophages overloading cholesterol, cholesterol is deposited on the inner wall of artery.

Nuclear receptor LXR as therapeutic target against atherosclerosis

Live X receptor(LXR) functions as a master regulation switch, which can accelerate the transport of cholesterol and prevent the formation of foam cells.

Nuclear receptor LXR as therapeutic target against atherosclerosis

Live X receptor(LXR) functions as a master regulation switch, which can accelerate the transport of cholesterol and prevent the formation of foam cells.

Ginseng triterpenes' structure is similar to that of cholesterol, therefore it has the potential of regulating LXRs. LXRs is a typical nuclear receptor. In the presence of co-regulators, bound by agonists (such as ginsenosides), LXRs could be demobilized to specific site on a target gene promoter region to activate transcription of the target gene. Ginsenosides or like could therefore regulate the metabolism of cholesterol.

Ginsenoside TR1 modulates
LXR biological activity

Atherosclerosis formation is delayed
by ginsenosides in vivo