Mitral Valve Prolapse
Mitral Valve Prolapse (MVP) is one of the most common cause for heart murmurs. This condition occurs when the mitral valve, responsible for preventing back flow of blood during heart contraction malfunctions. Consequently the mitral valve allows a tiny amount of blood to leak through and might shut off with a faint clicking sound. A faulty flap of the heart valve moves back into the atrium when the heart beats, allowing blood flow from the ventricle back into the atrium. Mitral valve prolapse is also referred to as click-murmur syndrome, Barlow's syndrome or Floppy valve syndrome. It is genetic in nature and is seen to run in families. Women are more likely to suffer from mitral valve prolapse when compared to men. Slender women with long and tapering fingers are at increased risk of suffering from MVP. Factors that might trigger a mitral valve prolapse are hypoglycemia, magnesium deficiency, chemical sensitivity, rheumatic fever, heart disease and hypothyroidism. A person suffering from MVP notices symptoms such as migraine headache, dizziness, cold hands and feet and hyperventilation. There might be insomnia, vertigo and balance problems. Such a person usually has a hypersensitive startle reflex. There might be intermittent chest pain and a feeling of the heart skipping beats.
There are various diagnostic tools used to detect mitral valve prolapse:
Moderate regular exercise has extensive benefits on alleviating some of the symptoms of mitral valve prolapse. Avoid too much sugar and Monosodium glutamate (MSG) in the diet. Sufficient amounts of magnesium, l-carnitine, acetyl-l-carnitine and B vitamins can help in relieving the symptoms of mitral valve prolapse. Prophylactic use of antibiotics is useful in preventing infection of the heart valve.
Ultrasound
Ultrasonography is a medical imaging technique that is also called ultrasound scanning or sonography. High frequency sound waves and their echoes and used in this technique for obtaining images from inside the human body. The echoes of sound waves reflected from the human body are recorded and displayed as a real-time visual image. This technique is similar to the echo location used by bats, whales and dolphins. The sonar used by submarines also operates with the same technique. Ultrasound is useful method to examine many of the body's internal organs like heart, liver, gallbladder, spleen, pancreas, kidneys and bladder.
Ultrasound Scanning
Types of Ultra sound:
Preparation:
Procedure:
Benefits:
Applications:
Common Uses:
Ultrasound examinations are versatile and essential tools in modern medical diagnostics, providing crucial information for the diagnosis and management of many health conditions.
Carotid Doppler ultrasound scanning is a diagnostic method used to assess blood flow through the carotid arteries, which are the primary vessels supplying the neck and head. This non-invasive modality is employed in the evaluation of various conditions, including:
1. Carotid artery stenosis (narrowing) - a common finding associated with increased risk of stroke. Doppler echocardiography image reveals any narrowing of the arteries or turbulence in blood flow.
Echocardiography is a diagnostic technique used to evaluate structural and functional abnormalities of the heart including:
1. Heart wall: Detecting changes in thickness, texture or motion.
2. Heart chambers: Assessing size, shape, and function.
3. Heart valves: Evaluating valve leaflet movement, regurgitation and stenosis.
4. Large coronary arteries: Identifying narrowing or obstruction.
In addition to detecting cardiovascular lesions, echocardiography is also employed in the diagnosis of:
1. Congenital heart disease: Abnormalities present at birth.
2. Cardiomyopathy: Heart muscle disorders characterized by impaired function.
3. Aneurysms: Ballooning or dilation of the heart or blood vessel walls.
4. Pericarditis: Inflammation of the pericardial sac surrounding the heart.
5. Blood clots in the heart: Emboli that may have originated from other sources and traveled to the heart.
2. Transient ischemic attacks (TIAs), also known as "mini-strokes" or "warning strokes" - a temporary loss of blood flow to the brain.
3. Stroke - a neurovascular event characterized by permanent disruption of blood flow to the brain.
Doppler echocardiography is a valuable diagnostic tool that enables the measurement of blood flow velocity
(speed) within the heart. This modality allows cardiologists to:
1. Assess structural abnormalities: Such as mitral valve prolapse, where the mitral valve leaflets protrude into
the left ventricle.
2. Evaluate septal defects: Abnormal openings in the septum that separate the right and left sides of the heart.
By analyzing blood flow velocity, Doppler echocardiography can help diagnose and monitor various cardiovascular conditions, including those affecting the heart valves and septum.
Cataract Surgery: An ultrasound probe is inserted into the lens capsule through a small incision in the cornea. The incision is made using a diamond tipped instrument. The ultrasound probe softens the lens by emitting sound waves. It then sucks out the softened lens tissue. Only the front part of the lens capsule is removed.
Doppler ultrasound is a type of echocardiography that utilizes the principles of Doppler shift to measure the velocity of moving structures. This technique involves transmitting high-frequency ultrasonic waves from an emitter and detecting the frequency changes resulting from the interaction with moving targets,
such as blood flowing through a blood vessel.
Doppler ultrasonography has become a widely accepted diagnostic modality for detecting various vascular conditions. Specifically, it is commonly employed to:
1. Identify arterial narrowing or stenosis in the neck, often resulting from atherosclerosis (the accumulation of fatty deposits on artery walls).
2. Detect blood clots (thrombi) within veins, as seen in deep vein thrombosis.
In addition to its vascular applications, Doppler ultrasound is also used for:
1. Fetal monitoring: To non-invasively assess fetal heart rate and detect any potential abnormalities.
2. Dialysis and cardiopulmonary bypass procedures: To monitor for air emboli (air bubbles) that may form during these interventions.
3. Blood pressure measurement: As a non-invasive means to estimate blood pressure, particularly in situations where direct measurement is not possible or practical.
The process begins with the emission of pulses of ultrasound at a specific frequency. As these pulses interact with moving objects, such as red blood cells in a vessel, the frequency of the reflected signals (echoes) shifts due to the Doppler effect. A sensor detects these frequency changes and converts them into meaningful data, providing valuable information about the velocity or flow characteristics of the target structure, for example, blood flow through an artery or vein.
Ancillary term used in ultrasound imaging to describe an anechoic region or structure that does not produce any reflective echoes (sonographic signals) when exposed to ultrasound waves. This is typically seen in structures containing clear fluid, such as:
1. Cysts: Fluid-filled cavities that do not reflect ultrasound signals.
In these cases, the lack of echogenicity allows for better visualization and differentiation from surrounding tissues.
"Echogenic" - A descriptive term used in ultrasound imaging to identify structures that produce reflective echoes or signals when exposed to ultrasound waves.
In other words, an echogenic structure is one that generates a strong sonographic signal, allowing it to be visualized and characterized on the ultrasound image.
The frequency of ultrasound waves used in medical imaging varies depending on the type of examination and the depth of the tissue being imaged. Here are some general guidelines:
Common Frequencies:
Specific Frequency Ranges:
Normally the term ultrasound refers to frequencies above 20 kHz (the maximum frequency a human can hear), medical ultrasound utilizes frequencies in the range of several MHz to achieve the necessary balance between resolution and penetration for effective imaging of different tissues and organs.
Frequency Range |
Impact |
Application |
1 MHz to 3 MHz |
Deep Tissue Imaging. |
Deep structures like the liver, kidneys, and heart |
3 MHz to 5 MHz |
Provides a balance between penetration and resolution |
General Abdominal and Obstetric Imaging |
2.5 MHz to 5 MHz |
Specifically chosen for adequate penetration and resolution |
Cardiac Imaging (Echocardiography) |
5 MHz to 10 MHz |
Optimal for vascular imaging |
Breast, thyroid, and vascular imaging |
7.5 MHz to 15 MHz |
Provides higher resolution images but less penetration depth |
Musculoskeletal and Superficial Structures |
As you can see from the table above, specific band of frequencies are chosen for optimal imaging.
Movement of the internal tissues and organs are captured in ultrasound. Ultrasonography enables the physicians to diagnose a variety of disease conditions and also assess the damage caused to the systems. The ultrasound machine transmits high frequency sound pulses into the human body by using probes. These sound waves that travel into the body hit a boundary between the tissues inside the body and reflect the sound waves to the probe. Some waves travel even further and they reach another boundary and then get reflected back. The waves that are reflected are picked up by the probe and relayed back into the ultrasound machine.
The ultrasound machine in turn calculates the distance from the probe to the tissue or organ by using the speed of sound tissue and the time of each echo's return. The machine displays these distances and intensities of the echoes on the screen. Through the echoes that are produced the sonologist can identify how far away an object is, how large it is, its shape and consistency (fluid, solid or mixed). Two dimensional images are formed and reflected on the screen. Different types of ultrasound are used for different disease conditions. Ultrasound is used in a variety of clinical settings including obstetrics and gynecology, cardiology and cancer detection.
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Bibliography / Reference
Collection of Pages - Last revised Date: December 30, 2024