Mitral valve prolapse occurs when one of the valves of the heart does not work properly. The mitral valve is the valve between the upper and lower left chambers of the heart. When this valve does not close properly, it causes a condition known as mitral valve prolapse. Mitral Valve prolapse often causes no symptoms and is usually not a serious condition. However, it may sometimes cause blood to flow backward into the upper left chamber or left atrium of the heart. This back flow of blood is referred to as mitral valve regurgitation. Most people are born with mitral valve prolapse and this condition is often hereditary.
Symptoms of Mitral Valve Prolapse
Most people with mitral valve prolapse do not experience any symptoms or complications. Symptoms that do appear are often the result of mitral valve regurgitation. Symptoms may include:
- Arrhythmia, a racing or irregular heartbeat
- Dizziness
- Difficulty breathing
- Headache
- Fatigue
Some individuals with mitral valve prolapse experience chest pain or discomfort.
Causes of Mitral Valve Prolapse
The exact cause of mitral valve prolapse is not known. For some people with mitral valve prolapse, the flaps of the mitral valve have extra tissue which causes the valve to balloon back to the left atrium. Mitral valve prolapse tends to run in families and may be more prevalent in people with Marfan syndrome, certain types of muscular dystrophy, Grave’s disease, hyper mobility syndromes, especially Ehlers Danlos Syndrome and scoliosis.
Diagnosis of Mitral Valve Prolapse
Many people do not know they have a mitral valve prolapse and it is often diagnosed incidentally during a routine physical exam. The doctor initially listens to the heart using a stethoscope, and the following diagnostic tests may be used to confirm a diagnosis of mitral valve prolapse:
- Echocardiogram
- Cardiac catheterization
Although the Echocardiogram (ultrasound of the heart) is used to make the diagnosis of Mitral Valve Prolapse, several other tests are used to evaluate symptoms patients may have that would indicate the diagnosis of Mitral Valve Prolapse Syndrome or Dysautonomia. An EKG may be performed to detect any irregular heart beat or to monitor medication used to treat arrhythmias. A stress test may also be administered to determine if mitral valve regurgitation limits the patient’s ability to exercise or perform physical activities. It may also be performed to rule out any underlying cause of chest pain. A tilt table test is used when a patient has unexplained dizziness or passing out.
Treatment of Mitral Valve Prolapse
Often, no treatment is necessary for patients with mitral valve prolapse who do not experience any symptoms. If individuals also experience mitral valve regurgitation and a significant amount of blood is leaking through the mitral valve, our policy is to refer to a cardiologist for further appropriate diagnostic testing and treatment.
In severe cases, surgery may be necessary to repair or replace heart valves. Without treatment, severe mitral valve regurgitation can eventually cause heart failure, preventing the heart from effectively pumping blood.
Many Mitral Valve Prolapse patients have symptoms out of proportion to the degree of prolapse or regurgitation on their Echocardiogram. Many of these patients have Mitral Valve Prolapse Syndrome or Dysautonomia.
As everyone knows, the human heart has four chambers. The two upper chambers are the atria and the two lower ones are the ventricles. The left atrium receives oxygenated blood from the lung and passes it into the left ventricle through the mitral valve. The left ventricle then pumps oxygenated blood through the arterial system, delivering nutrients and oxygen to the entire body. The deoxygenated blood goes into the venous system and a central venous channel known as the inferior vena cava delivers this blood into the right atrium. The right atrium passes the venous blood through the tricuspid valve into the right ventricle which then pumps the blood to the lung where oxygen is extracted from the air to oxygenate the blood, thus completing the circulation.
Understanding the Heart Valves
The mitral and tricuspid valves have been described as “watch pocket” valves because their construction reminds us of the kind of pocket in the waistcoats of gentlemen that were used for carrying a watch. They are made of tissues that respond to the increasing pressure caused by the contraction of the ventricles, thus closing the respective apertures between the atria and the ventricles. It is not too difficult to imagine that the pressure generated particularly in the left ventricle is enormous, thus producing “wear and tear” on the tissues that make up the mitral valve. However, it is not that simple and we shall see in this post why mitral valve prolapse is surprisingly common and how it affects health. Prolapse means that the valve is not closing properly. This is because degeneration has occurred in one of the leaflets of the valve and it prolapses into the atrium as the pressure in the ventricle increases. This causes regurgitation of blood from the ventricle to the atrium.
Mitral Valve Prolapse: Incidence and Sex Distribution
Mitral valve prolapse (MPV) is the most common condition affecting the heart valves. Some studies show that it affects 2-3% of all women. It is interesting that it is diagnosed in young women, but the incidence decreases markedly in older women. This decrease in incidence is not seen in the male population which is consistent in both young and old men. As the result of a large study known as the Framingham study, the incidence of MPV is known to affect equal numbers of men and women. The cause for the difference in age distribution in women is unknown. Occasionally, MVP is associated with other heart conditions but it is generally considered that these diseases would have been present with or without MVP. The outcome differs for men and women. Recent studies have indicated that, for men, the requirement for surgical intervention to repair the valve is higher than for women and increases with age.
Mitral Valve Prolapse and Dysautonomia
Patients with MVP frequently have chest pain of undetermined cause. In 1975, 23 patients with deformity of this valve underwent metabolic studies. Chest pain occurred in five of these patients while being tested and in 2 patients a change in the electrocardiogram indicated myocardial ischemia. Lactate (lactic acid production in tissues is related to energy metabolism) abnormalities were reported in 30% of these patients, indicating abnormal metabolic changes. As early as 1979 it was recognized that MVP was associated with defective function of the autonomic nervous system (ANS). It will be remembered that the ANS is automatic and is the nervous system by which the lower part of the brain exercises control over body organs. This introduces a complex association that begs explanation.
In 1994, it was reported that recent research had shown that subsets of patients with MVP had a number of related symptoms that included fatigue, heart palpitations, chest pain, exercise intolerance, breathlessness, dizziness, headache, sleep disorders, gastrointestinal disturbances, cold extremities and panic attacks, classified as MVP syndrome. The lack of a proven cause-and-effect relationship between MVP and panic disorder does not diminish the clinical significance of the high rate of co-occurrence between the two conditions. In 1991, it was suggested that the nonspecific symptoms “with no discernible objective cause who fail to respond to medication” should be ascribed to panic disorder as a possible explanation for symptoms. This illustrates that this polysymptomatic disorder with an unknown explanation and little or no laboratory evidence is often ascribed erroneously to psychosomatic symptomology.
Increased activity of the sympathetic branch of the ANS has been reported in association with MVP, promoting “myxomatous degeneration” in the mitral valve. This branch of the ANS is the system that promotes brain/body action and has a high energy consumption. Sleep apnea, a common disease, is associated with repeated episodes of hypoxemia (reduced blood oxygen) and is considered to be the primary stimulus for sympathetic over activity in these patients.
Hypoxia and Pseudohypoxia
The prevalence of MVP was found to be significantly higher in people living at moderate altitude compared with those living at sea level. The difference is because of the decrease in oxygen concentration in the air. A common disorder occurring at altitude in people that are often regarded as being “unfit” is mountain sickness. Postural phenomena, cardiac arrhythmias and autonomic dysfunction are responsible for pre-syncope (dizziness) and syncope (short passing out spells) in patients with MVP. Of some interest, evidence has been reported that hyperglycemia (high blood sugar) as might be found in a poorly controlled diabetic, produces cellular chemical changes, mimicking the effects of hypoxia on vascular and neural function. This effect has been referred to as pseudohypoxia. The resulting dysfunction in cellular metabolism and accumulation of pyruvate and lactate during thiamine deficiency has been referred to as pseudohypoxia. Low levels of magnesium were found in the blood of some children with MVP and a five week treatment with magnesium chloride decreased the incidence of chest pain. In 1980, 7 patients with neurologic and cardiologic abnormalities in association with MVP were studied. Abnormal muscle biopsies revealed a peculiarity known as “ragged red fibers” (a characteristic of staining for histological examination). The manuscript was later withdrawn, but serum alanine and pyruvate levels were abnormal and clearly showed evidence for thiamine deficiency. “Ragged red fibers” in muscle have been shown to be the result of thiamine deficiency in an animal study.
Oxygen Deprivation and Mitral Valve Prolapse
It appears that some form of deprivation involving inefficient oxygen metabolism is well established as a constant relationship with the incidence of MVP. In order to affect 2-3% of women, the underlying cause must be common. Its polysymptomatic association is clearly produced by inefficient mitochondria that should certainly be recognized for what it is rather than proposing psychologic dynamics. In the large number of patients whose cases I experienced in my practice, with proven thiamine deficiency, I was often puzzled by a complaint of chest pain. It was almost invariably over the left side of the upper chest, reportedly in most cases to be intermittent and disappeared after treatment with thiamine. Because thiamine deficiency was invariably associated with evidence of dysautonomia, I had concluded that this chest pain, sometimes referred to as pseudo-angina, was in some way related to dysfunctional activity of the autonomic nervous system.
We may be making a common mistake by making the wrong associations. The underlying cause of panic attacks, chest pain and all the other symptoms recorded in MVP syndrome are really the result of poor oxidation (pseudohypoxia) similar to oxygen lack (true hypoxia). Oxidation is the consumption of oxygen in the synthesis of cellular energy. Therefore I am proposing here that the reason for the common appearance of MVP syndrome is because of the massive ingestion of sugar throughout the population. This induces an imbalance between the carbohydrate calories and the availability of vitamins involved in their oxidation, particularly thiamine. The symptoms recorded in MVP syndrome are exactly the same as those recorded in beriberi, known for years as the thiamine deficiency disease. Perhaps the reason for an age discrepancy in the diagnosis of MVP in women is a lesser degree of sympathetic nervous system over activity with increasing age.
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