|
heart - heart disease heart attack heart health blood vessels artery clogged lower cholesterol Why Our Arteries Become Clogged As We Age
The aging process damages blood vessels, even when conventional risk factors such as cholesterol and blood pressure are within normal ranges.
Despite aggressive intervention with diet, exercise, supplements, and drugs, pathological changes still occur in the arterial wall that predispose aging adults to vascular diseases. The encouraging news is that a non-prescription method has been developed to address the underlying reason why arteries become occluded as people reach the later stages of their lives.
For the past 35 years, the standard way to treat coronary atherosclerosis has been to bypass the blocked arteries. Recuperation from coronary bypass surgery can take months, and some patients are afflicted with lifetime impairments such as memory loss, chronic inflammation, and depression.
The scientific literature reveals that atherosclerosis is associated with high blood levels of homocysteine, C-reactive protein, insulin, iron, low-density lipoprotein (LDL), and triglycerides, along with low levels of high-density lipoprotein (HDL) and testosterone. Optimizing blood levels of these substances can dramatically reduce heart attack and stroke risk.
Prescribing a “statin” drug is what today’s doctors typically do to prevent and treat coronary atherosclerosis. Cholesterol and LDL, however, are only partial players in the atherosclerosis process.
Anatomy of the Artery
Arteries are the blood vessels that bear the full force of each heartbeat. Laypeople often think of arteries as flexible tubes whose only function is to carry blood that flows continuously throughout the body. In reality, arteries are dynamic, functioning muscular structures that in good health expand and contract to facilitate circulation and maintain optimal blood pressure.
The artery’s outer layer mostly consists of connective tissue and provides structural containment for the two layers beneath. The middle arterial area comprises elastic smooth muscle that provides the contractile strength to make possible the artery’s expansion and contraction with each heartbeat. The inner layer—known as the endothelium—consists of a thin area of endothelial cells whose integrity is crucial if atherosclerosis is to be prevented.
A vital function of the endothelium is to form a barrier to prevent toxic substances in the blood from entering the elastic smooth muscle in the middle vessel wall. Another specialized function of the endothelium is to react to mechanical forces such as blood pressure and blood flow generated by the heart's beating action. The endothelium releases substances into cells of the middle layer smooth muscle that changes the tone or firmness of the artery.
When endothelial cells sense an injury, they produce signals that prompt smooth muscle cells in the middle arterial wall to change. These changes result in the smooth muscle cells moving toward the site of vascular injury, where they reposition themselves just beneath the endothelial cell layer. In reaction to injury, endothelial cells also produce substances that signal circulating blood cells to stick to the endothelium (instead of effortlessly flowing through the vessel). Atherosclerosis gradually forms in response to this initial injury to the endothelium
Changes in the Aging Endothelium
As we grow older, some of the specialized functions of our endothelial cells become blunted. The self-renewal process weakens. The endothelial barrier becomes leaky. Signals to the middle wall smooth muscle cells that regulate their function become altered.
Smooth muscle cells behave as if in reaction to endothelial injury, migrating to the endothelium, where they multiply and produce matrix proteins that gradually occlude the blood vessel. The addition of these smooth muscle cells and matrix proteins within the sub-endothelial space results in thickening of the artery’s inner wall. In older arteries, the inner wall becomes a battleground where multiple reactions occur that are similar to the process of chronic injury. The inner wall dysfunction that occurs in the aging artery provides fertile soil for the seeds of atherosclerosis. All of these processes whereby normal endothelial function is compromised are collectively referred to as endothelial dysfunction
How Atherosclerosis Develops
Atherosclerosis is so common in older adults that some experts used to think it was part of normal aging. An alternative view is that atherosclerosis is a disease process that takes advantage of changes that occur within the aging artery.
The vascular aging process and atherosclerotic process influence each other and become intertwined as we age. The more severe vascular aging is, the easier it is for atherosclerosis to take hold. The more severe atherosclerosis is, the greater its impact on diseases associated with vascular aging, such as stroke and heart attack. Thus, it appears that with advancing age, atherosclerosis and the aging process combine forces.
An often-used analogy for atherosclerosis is a “clogged pipe.” This misguided perception either leads to bypass surgery or a procedure in which the blocked coronary artery is forced opened with a balloon catheter (angioplasty) and a stent is implanted to keep the artery open. While these surgical procedures have become necessary for many people, the “clogged pipe” analogy is an inaccurate way to view the process of atherosclerosis.
 The Arterial Wall Under Attack
High blood pressure, elevated LDL and triglycerides, low HDL, cigarette smoking, diabetes, obesity, and lack of exercise contribute to endothelial dysfunction and the subsequent development of atherosclerosis.
Additional endothelial-damaging factors include excess levels of glucose, insulin, iron, homocysteine, fibrinogen, and C-reactive protein, as well as low HDL and free testosterone (in men).
Homocysteine is particularly dangerous because it can induce the initial injury to the endothelium. Homocysteine then facilitates oxidation of the fat/LDL that accumulates beneath the damaged endothelium, and finally contributes to the abnormal accumulation of blood components around the atherosclerotic lesion.
Fibrinogen is a clotting factor that accumulates at the site of the endothelial lesion. Fibrinogen may contribute to plaque buildup or participate in blood clot-induced blockage of an artery after an unstable atherosclerotic plaque ruptures.
Glucose at even high-normal levels may accelerate the glycation process that causes arterial stiffening, while high-normal fasting insulin inflicts direct damage to the endothelium.
High levels of iron promote LDL oxidation in the damaged endothelium, while low levels of testosterone appear to interfere with normal endothelial function.
Propionyl-L-Carnitine (PLC)
Research suggests that propionyl-L-carnitine (PLC) plays an important role in protecting the function and health of endothelial cells. Studies also indicate that PLC may act as a nutritional corrective agent, relieving clinical symptoms of cardiovascular conditions such as peripheral arterial disease, angina, coronary artery disease, cardiomyopathy, intermittent claudication, ischemic heart disease, atherosclerosis, and congestive heart failure. PLC appears to be more potent than L-carnitine in improving vascular function.
PLC passes across the mitochondrial membrane to supply L-carnitine directly to the mitochondria, the energy-producing organelles of all cells. Carnitines are essential for mitochondrial fatty acid transport and energy production. This is important because heart muscle cells and endothelial cells burn fatty acids rather than glucose for 70% of their energy. By contrast, most cells generate 70% of their energy from glucose and only 30% from fatty acids.
 Carnitine deficiency has been associated with congestive heart failure. PLC supplementation has been reported to increase exercise capacity, optimize energy production, and reduce ventricular size in patients with congestive heart failure.
The myocardium, the muscular substance of the heart, comprises cells called cardiomyocytes. A study of cardiomyocytes found that PLC helped to correct an imbalance between the production and utilization of adenosine triphosphate (ATP), the energy currency used throughout the body. This suggests that PLC may improve cardiac performance by improving energy metabolism and optimizing ATP levels.
PEAK ATP WITH GLYCOCARN 60 CAP
The endothelium is the thin barrier that separates circulating blood from the smooth muscle interior of the artery. Healthy endothelial cells help to maintain a normal cardiovascular system. Aging, poor lifestyle habits and nutrition can lead to endothelial problems.
Propionyl-L-Carnitine (PLC) plays an important role in protecting the function and health of endothelial cells. PLC passes across the mitochondrial membrane to supply carnitine directly to the energy-producing organelles of all cells. Carnitine is essential for mitochondrial fatty acid transport and energy production. This is important because endothelial cells burn fatty acids for 70 percent of their energy.
Adenosine triphosphate (ATP) is a critical component of the cellular energy cycle. When administered orally to rabbits, ATP increased blood flow, reduced vascular resistance, and increased arterial oxygen pressure. In baboons, ATP infusions increased cerebral blood flow by nearly 50 percent and boosted oxygen consumption in the brain.
Peak ATP™ is a patented brand of ATP that has been tested in human and animal studies. Peak ATP™ is readily absorbed and boosts circulating ATP levels. Red blood cells release ATP to produce endothelial vasodilation, or widening of the arteries. Ensuring adequate red blood cell pools of ATP to help regulate vascular tone is critical to maintaining circulatory health. For the first time, Americans have access to proprionyl-L-carnitine and Peak ATP™, two nutrients that are critical for optimal endothelial function and structural integrity.
Pomegranate promotes healthy blood flow
In a group of aging humans with risk factors for cardiovascular events, pomegranate or placebo was ingested on a daily basis. After twelve months, blood flow through the carotid arteries improved 44% in the pomegranate group, whereas carotid blood flow worsened by 9% in the placebo group.
In another similar group, pomegranate or placebo was ingested daily. After only three months, coronary artery blood flow improved by 18% in the pomegranate group, but worsened by 17% in the placebo group. A standardized pomegranate extract is one of the three active components of the Endothelial Defense formula.
Cocoa promotes healthy endothelial function
Endothelial function can be evaluated by using a sensitive ultrasound test to assess blood flow velocity. In a controlled human study, arterial blood flow improved by 37% following ingestion of standardized cocoa polyphenols and this persisted about eight hours. This same study showed a 36% decrease in undesirable platelet activation in the cocoa polyphenol groups. In a recent randomized controlled trial, healthy individuals with above-optimal blood pressure taking small amounts of dark chocolate containing 30 mg of polyphenols as part of a usual diet efficiently improved their blood pressure readings as well as plasma markers of vasodilative nitric oxide. The cocoa polyphenols appear to exert their beneficial effect by enhancing endothelial nitric oxide production and inhibiting pro-angiogenic factors. The age-related depletion of nitric oxide is considered a major impediment to healthy arterial blood flow. A standardized cocoa polyphenol extract is the second active component of the Endothelial Defense formula.
SOD protects against nitric oxide degradation
Aging results in a reduction of our body's production of the critical antioxidant called superoxide dismutase (SOD). One consequence of SOD depletion is excess degradation of endothelial nitric oxide. An orally active superoxide dismutase (SOD) called GliSODin® has been clinically proven to support healthy arterial function and structure, while boosting levels of the body's most powerful antioxidant enzymes (SOD and catalase) and protecting against oxidative stress-induced cell death.
Studies show that damaging carotid artery thickness increases by 0.04 mm every ten years. However, the recent study with GliSODin® suggests that 2.8 years of supplementation may turn back the clock on ten years of age-related damage due to carotid artery wall thickening. The third ingredient of the Endothelial Defense formula is the patented GliSODin® in the identical dose used in the successful human study.
|
|