Atherosclerosis:
A Silent Cardiovascular Condition that Kills 1 Person Every 3 Seconds
High blood pressure, high levels of triglycerides, oxidation of Low Density Lipoprotein (LDL) cholesterol and lowering levels of High Density Lipoprotein (HDL) cholesterol are the primary cause that leads to oxidative stress and chronic inflammation in the vessels. This condition emerges at early age and gradually compromises vascular integrity leading to atherosclerosis at a later stage of a person lifespan. Atherosclerosis is a cardiovascular condition in which fat deposits and become oxidized along the inner lining of the artery walls. This silent yet deadly build up progressively thickens, hardens and eventually blocks the arteries leading to sudden and severe circulatory complications including vascular ischemia, stroke or heart attack. Cardiovascular and circulatory deaths related to atherosclerosis accounts for 29% of all deaths globally; the primary cause of death in EU (42%), Eastern Europe (48%), UK (39%), North America (49%), China (34%), South America (31%); Middle East (31%) and India (29%) – World Health Report, 2010.Salmon Consumption and Lower Incidence of Cardiovascular Diseases Among Japanese. Just a Coincidence?
The cardiovascular and circulatory benefits of natural astaxanthin are evident among Japanese who are the uppermost consumers of food containing astaxanthin (AX) in the world and have the lowest incidences of heart diseases amongst developed countries. As the French paradox of cardiovascular health is connected to “sipping red-wine” and Italians longevity to “olive oil dressed” salads, Japanese cardiovascular resilience can be associated with consumption of “astaxanthin-soaked” salmon. In fact, a growing number of scientific evidence points to a robust link between natural astaxanthin and cardiovascular health – 30 cardiovascular specific research publications including 10 clinical studies. Research suggests that oral supplementation of astaxanthin may reduce the risks of cardiovascular diseases by reducing hypertension while enhancing blood rheology, capillary circulation and vascular resilience.The Effects of Astaxanthin on Atherosclerosis Prevention and Development
Astaxanthin Increase HDL Cholesterol and Decrease Serum Triglycerides
For every 1 mg/dl increase in good cholesterol HDL, the risk of cardiovascular diseases drops by 3%. In fact, baby boomers with low-HDL (> 40mg/dL) increase their chances of experiencing coronary events by 50%. Recent studies suggest that individuals with low HDL cholesterol who also have high triglycerides levels are 11 times more likely to develop cardiovascular diseases. Achieving a significant increase of HDL is notoriously hard because it requires drastic lifestyle changes, so often ending with modest results or sudden relapses.Recent research suggests that astaxanthin supplementation can support lifestyle changers by synergizing HDL increasing effect with decreased level of serum triglycerides. Two recent studies demonstrated that astaxanthin consumption can steadily increase HDL cholesterol in both healthy and less healthy individuals -both as preventive and therapeutic use. Yoshida et al., (2009) conducted the first ever randomized, placebo-controlled human study to evaluate astaxanthin effect on dyslipidemia and metabolic syndrome. Sixty-one hyper-triglyceride subjects between 42-47 years old (BMI 24 mg/kg), received 0 (placebo), 6 mg, 12mg, 18mg of astaxanthin daily for 12 weeks. While the placebo group did not change their existing condition, the astaxanthin groups increased their HDL cholesterol by 11%, 15% and 7% respectively and decreased their serum triglycerides level by 17%, 25% and 24% respectively (figure 1).
Figure 1. Astaxanthin
increase HDL cholesterol and decrease Serum Triglycerides (STR).
Subjects with lower levels of HDL and higher levels of STR are 11 times
more likely to develop cardiovascular diseases (Yoshida et al., 2009)
In a recent clinical study, 73 subjects between 20-60 years of age
who received 4mg of natural astaxanthin per day for 4 weeks had their
serum triglycerides level decreased by 25 %(Satoh et al.,
2009). In another study conducted in Japan, 15 healthy adults increased
their HDL by 6% after ingesting 9mg/daily of astaxanthin for 8 weeks
(Matsumaya et al., 2010). In 2007, Hussein et al., has
shown that astaxanthin reduced the size of fat cells in rats, which
lead to a lower risk of cardiovascular complications and chronic
inflammation (figure 2).
Figure 2. Astaxanthin
reduced the size of fat cells. Large cells usually indicate higher risk
of fat-oxidation chronic inflammation and oxidative stress, which are
the leading causes of cardiovascular diseases (x10) (Hussein et al., 2006)
Astaxanthin Decrease Red Blood Cells Oxidation and Lipid-Peroxidation
High levels of triglycerides and low levels of HDL also increase the likelihood of fat-oxidation in vessels and formation of "wounds" in the inner lining of artery walls (endothelium) leading to chronic inflammation and oxidative stress; this situation causes degradation, narrowing and thickening of arteries. Three recent clinical studies have robustly pointed to astaxanthin ability to reduce fat peroxidation in blood plasma. In a randomized-double-blind placebo study, 33 overweight subjects received 5mg or 20mg astaxanthin daily for 3 weeks. Their lipid peroxidation markers plasma MDA Level (mmol) and plasma ISP (ng/mL) decreased by 30% and 60% in average (Choi et al., 2011).In another randomized double blind placebo controlled study, 30 subjects between 50 and 69 years of age received 0 (placebo), 6 or 12mg astaxanthin daily for 12 weeks (Nakagawa et al., 2011). The amount of oxidized red blood cells (PLOOH um0l/ml) decreased by 17% and 24% respectively(figure 3).
Figure 3. Astaxanthin
reduces red blood cells oxidation (RBCO) in senior subjects. RBCO cells
has high correlation with neuro-degenerative (eg. dementia) and
cardiovascular diseases (eg. heart attack) (Nakagawa et al., 2011)
In 2007, Karppi et al., conducted a randomized double blind
conducted placebo controlled study with 40 non-smoking subjects between
19-33 years of age who received 0 (placebo) or 8mg of astaxanthin daily
for 12 weeks. Their lipid peroxidation markers -plasma-15-hydroxy fatty
acidsdecreased by 60% and plasma-12-hydroxy fatty acids by 36%. In 2000,
Iwamoto et al., has also shown that astaxanthin inhibited LDL
oxidation in human subjects. Professor Aoi from Kyoto Prefectural
University, has shown that astaxanthin limits exercise-induced cardiac
oxidation damage in mice.Astaxanthin Enhance Biomarkers of Anti-oxidant Healthiness in the Blood Plasma
Low antioxidant activity in the blood correlates with high incidences of stroke, neurological impairment in stroke patients and cardiovascular diseases. Therefore, it is crucial to monitor the biomarkers of antioxidant capacity in the blood when assessing the efficacy of an active ingredient. In a randomized double blind study, 33 overweight subjects received 5mg or 20mg astaxanthin daily for 3 weeks. Their plasma Superoxide Dismutase Level (SOD) (U/mL) and Plasma Total Antioxidant Capacity (TAC) Level (mmol) increased 45% and 19% respectively. (Choi et al., 2011) (figure 4).Other studies have produced similar results using different assessment methods. In an open label clinical study, 35 postmenopausal women were treated with astaxanthin daily dose of 12 mg for 8 weeks (Yonei et al., 2009). Astaxanthin supplementation increased biological antioxidant potential in the blood plasma by 5% in 8 weeks. In addition, Camera et al., suggested that astaxanthin protects and synergize with our endogenous antioxidant systems (superoxide dismutase, catalase and glutathione) from early degradation when subjected to oxidative stress (Camera et al., 2008).
Figure 4. Astaxanthin
increases Plasma SOD Level and Plasma TAC level. Low levels of SOD and
TAC correlates with higher incidences of stroke, neurological impairment
and cardiovascular diseases (Choi et al., 2011)
Astaxanthin Decrease Chronic Inflammation that comprise Blood Vessels Integrity
In the presence of oxidized cells in the endothelial lesions, macrophages white blood cells infiltrate in affected areas to clear away pathogens and dead cells. Yet, in the attempt to clean up the oxidized areas, macrophages may get overweighed with excessive lipoproteins and unable to leave the artery walls. This peculiar but common situation triggers a cascade of chronic inflammatory responses and pro-oxidant activities that degraded the structural integrity of the vessels. Therefore, up-regulated activity of oxidized LDL via macrophage induced inflammation is central to the initiation and progression of atherosclerosis. They are closely associated with plaque development, aggravation and ruptures.A recent study shows that astaxanthin decreased macrophage occupied lesion areas and therefore inflammation in the vessels of rabbits by 40% compared to control group (figure 5). Furthermore, rabbits that ingested 4mg astaxanthin everyday for 24 weeks decreased programmed cell death (apoptosis) by 42% and cell death (necrosis) by 17% in the aorta (Li et al., 2004).
Figure 5. Astaxanthin
decrease chronic inflammation and cell death in the inner lining of the
vessels. Chronic inflammation and apoptosis in the endothelium
dramatically accelerates vascular degradation and atherosclerotic plaque
formation. (Li et al., 2004)
In-vitro study provides further evidences that astaxanthin (5-10uM)
decreases macrophages related activation (SR-A and CD36) by 48% and 58%
respectively (Kishimoto et al., 2009). A recent animal studies
show that astaxanthin could ameliorate endothelial dysfunction by
significantly improving the level of substances important for the
regulation of vascular integrity. In more details, treatment with
astaxanthin for 42 days decreased serum oxidized LDL cholesterol, aortic
MDA levels, attenuated endothelium-dependent vasodilatory to
acetylcholine, up-regulate eNOS expression and decreased LDL cholesterol
receptor expression (figure 6).
Figure 6. Astaxanthin
treatment improved markers of endothelial dysfunction by reducing
oxidation of LDL cholesterol and MDA. Higher levels of LDL oxidation and
MDA expression highly correlates with structural damages in blood
vessels and impairment of blood flow. (Zhao et al., 2011)
Animal studies have also shown that astaxanthin ameliorated
structural changes in the blood vessels - reduction in wall thickness by
47% and improved vascular tone by 36% in spontaneously hypertensive
rats (Hussein et al., 2006). Such structural changes was
observed in the reduction of the number of branched elastin bands and
improved vessel wall to lumen thickness ratio.In another study, 24 weeks supplementation of natural astaxanthin reduced levels of MMP3 expression in the aorta of rabbits - a crucial factor that lead to a degradation of elastin and collagen structures which determines the mechanical properties of connective tissues in the vessels (figure 7). In the experiment, astaxanthin enhanced plaque stability leading to a significant reduction of plaque ruptures (Li et al., 2004).
Figure 7. Astaxanthin
inhibit MMP over-expression in the thoracic aorta. Over-expression of
MMP is a crucial factor that leads to the degradation of vascular
integrity and escalation of atherosclerotic plaque ruptures (Li et al., 2004)
Astaxanthin Improving Vascular Resilience and Capillary Blood Flow
Good circulation, quality of blood and resilient vessels are the key features required to fight development and progression of atherosclerosis. Blood rich in antioxidants bring nutrients and oxygen to organs while removing waste through a smooth vascular resilience and capillary flow.Recent human studies suggest that 6mg daily of astaxanthin can enhance blood flow by 10% in terms of capillary transit time -how fast the blood runs through the vessels (Miyawaki et al., 2008). Another complementary study showed that astaxanthin decreased lower limb vascular resistance by 17% - the degree to which the blood vessels impede the flow of blood (Iwabayashi et al., 2009).(figure 8) High resistance causes an increase in blood pressure, which increases the workload of the heart. In 2005, Nagaki et al., conducted another randomized double-blind study in which 36 subjects who received oral astaxanthin, 6mg/day for 4 weeks experienced a 4% improvement in capillary blood flow (Nagaki et al., 2005).
Figure 8. astaxanthin
decreased lower limb vascular resistance (LLVR) – the degree to which
the vessels impede the flow of blood. LLVR increase blood pressure and
circulatory complications that lead to peripheral vascular diseases,
venous thrombosis and painful claudication (Yonei et al., 2009)
Astaxanthin Reduces Hypertension
A series of human studies suggest that astaxanthin decreases blood pressure by improving blood flow and vascular tone. In a recent clinical study, 73 subjects, between 20-60 years of age, who received 4mg of astaxanthin for day for 4 weeks showed a significant decrease in systolic blood pressure (Satoh et al., 2009). In another study, 15 healthy subjects, between 27-50 of age, who received 9mg/day of astaxanthin for 12 weeks had their diastolic blood pressure decreased significantly (Matsuyama et al., 2010).A series of animal studies have largely replicated the effects of astaxanthin found in human studies (e.g. Ruiz et al., 2010; Preuss, 2011).
Outlook
Clinical studies suggests that oral supplementation of natural astaxanthin (4mg-12mg) may reduce the risk cardiovascular complications by enhancing blood rheology, lipid-metabolism, capillary circulation, vascular resilience and the endogenous antioxidant defense. Other clinical studies have also shown that astaxanthin reduce lipid-peroxidation, LDL cholesterol, blood pressure and DNA damage. Mechanism of action includes inhibition of macrophage-induced inflammation in the endothelium, oxidative stress-induced apoptosis and MPP-induced-structural degradation of the vessels. Furthermore, recent studies have also outlined that astaxanthin ameliorates nitric oxide dependent vessels dilation and reduce sensitivity to the angiotensin.References
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Mr. Mitsunori Nishida,
President of Corporate Fuji Chemical Industry Co., Ltd.
Croatian Center of Renewable Energy Sources (CCRES)
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