Wednesday, June 1, 2011

Echocardiogram



What is Ultrasound?
What is an Echocardiogram?
What is Doppler?
What information does it provide?
How safe is it?How long does it take?
How quickly do I get the results and what do they mean?
What is Ultrasound: Sound is made up of several different frequency waves. The very high frequency range is inaudible to the human ear and is known as ultrasound. Ultrasound was used by the Navy during World War II to detect submarines, and is widely used by fisherman to help find schools of fish.
In each case, an ultrasound machine is used. With the help of a microphone-shaped device (known as a transducer) ultrasound waves are created and beamed through water. When the beam encounters a boundary or interface between liquid (water) and a solid (submarine or fish) with a different density or compactness, part of the beam is reflected back to the transducer. The remaining waves move through the object and reach the back boundary between solid and water. Here, some more of the ultrasound waves are reflected back to the transducer. In other words, the transducer transmits ultrasound and constantly receives waves that are reflected back every time the beam travels from one density to another.
The reflected ultrasound waves are collected and analyzed by the machine. Determining the amount of time it took for the beam to travel from and to the transducer (plus the the consistency and changes in position of the different structures that it passed through), the ultrasound machine can determine the shape, size, density and movement of all objects that lay in the path of the ultrasound beam. The information is presented "real time" on a monitor screen and can also be printed on paper or recorded on tape, a CD or a computer disk. That is how warships detect submarines, fishermen identify choice fishing spots, an obstetrician evaluates the fetus of a pregnant woman, and a cardiologist examines the heart of a patient.
What is an Echocardiogram: An echocardiogram is a test in which ultrasound is used to examine the heart. The equipment is far superior to that used by fishermen. In addition to providing single-dimension images, known as M-mode echo that allows accurate measurement of the heart chambers, the echocardiogram also offers far more sophisticated and advanced imaging. This is known as two- dimensional (2-D) Echo and is capable of displaying a cross-sectional "slice" of the beating heart, including the chambers, valves and the major blood vessels that exit from the left and right ventricle
   An echocardiogram can be obtained in a physician's office or in the hospital. For a resting echocardiogram (in contrast to a stress echo or TEE, discussed elsewhere) no special preparation is necessary. Clothing from the upper body is removed and covered by a gown or sheet to keep you comfortable and maintain the privacy of females. The patient then lies on an examination table or a hospital bed

   Sticky patches or electrodes are attached to the chest and shoulders and connected to electrodes or wires. These help to record the electrocardiogram (EKG or ECG) during the echocardiography test. The EKG helps in the timing of various cardiac events (filling and emptying of chambers). A colorless gel is then applied to the chest and the echo transducer is placed on top of it. The echo technologist then makes recordings from different parts of the chest to obtain several views of the heart. You may be asked to move form your back and to the side. Instructions may also be given for you to breathe slowly or to hold your breath. This helps in obtaining higher quality pictures. The images are constantly viewed on the monitor. It is also recorded on photographic paper and on videotape. The tape offers a permanent record of the examination and is reviewed by the physician prior to completion of the final report.
What is a Doppler Examination? Doppler is a special part of the ultrasound examination that assess blood flow (direction and velocity). In contrast, the M-mode and 2-D Echo evaluates the size, thickness and movement of heart structures (chambers, valves, etc.). During the Doppler examination, the ultrasound beams will evaluate the flow of blood as it makes it way though and out of the heart. This information is presented visually on the monitor (as color images or grayscale tracings and also as a series of audible signals with a swishing or pulsating sound)..
What information does Echocardiography and Doppler provide?
Echocardiography is an invaluable tool in providing the doctor with important information about the following:
   Size of the chambers of the heart, including the dimension or volume of the cavity and the thickness of the walls. The appearance of the walls may also help identify certain types of heart disease that predominantly involve the heart muscle. In patients with long standing hypertension or high blood pressure, the test can determine the thickness and "stiffness" of the LV walls. When the LV pump function is reduced in patients with heart failure, the LV and RV tends to dilate or enlarge. Echocardiography can measure the severity of this enlargement. Serial studies performed on an annual basis can gauge the response of treatment.
   Pumping function of the heart can be assessed by echocardiography. One can tell if the pumping power of the heart is normal or reduced to a mild or severe degree. This measure is known as an ejection fraction or EF. A normal EF is around 55 to 65%. Numbers below 45% usually represent some decrease in the pumping strength of the heart, while numbers below 30 to 35% are representative of an important decrease.
   Echocardiography can also identify if the heart is pumping poorly due to a condition known as cardiomyopathy (pronounced cardio-myo-puth-e), or if one or more isolated areas have depressed movement (due to prior heart attacks). Thus, echocardiography can assess the pumping ability of each chamber of the heart and also the movement of each visualized wall. The decreased movement, in turn, can be graded from mild to severe. In extreme cases, an area affected by a heart attack may have no movement (akinesia, pronounced a-kine-neez-ya), or may even bulge in the opposite direction (dyskinesia, pronounced dis-kine-neez-ya). The latter is seen in patients with aneurysm (pronounced an-new-riz-um ) of the left ventricle or LV. It must be remembered that LV aneurysm due to an old heart attack does not usually rupture or "burst."
   The top diagram on the monitor shows an ultrasound beam (gray triangular area) traveling through the right (RV) and left (LV) ventricle. You can also see the aorta (Ao), left atrium (LA), aortic valve (AV) and mitral valve (MV). Please note that you can review cardiac anatomy and physiology by clicking here. The two pictures on the bottom of the monitor were taken from actual patients. The arrows point to the septum or partition between the RV and LV. The lower left picture demonstrates normal movement of the septum as it moves towards the opposite wall of the LV when the heart contracts. In contrast, the patient on the bottom right has had a heart attack involving the septum. Note that the septum moves sluggishly. Also, it is thinner and "shriveled" as a result of the heart attack.

   Valve Function: Echocardiography identifies the structure, thickness and movement of each heart valve. It can help determine if the valve is normal, scarred from an infection or rheumatic fever, thickened, calcified (loaded with calcium), torn, etc. It can also assess the function of prosthetic or artificial heart valves.
The additional use of Doppler helps to identify abnormal leakage across heart valves and determine their severity. Doppler is also very useful in diagnosing the presence and severity of valve stenosis (pronounced stee-no-sis) or narrowing. Remember, unlike echocardiography, Doppler follows the direction and velocity of blood flow rather than the movement of the valve leaflets or components. Thus, reversed blood direction is seen with leakages while increased forward velocity of flow with a characteristic pattern is noted with valve stenosis.
Echocardiography is used to diagnose mitral valve prolapse (MVP), while Doppler identifies whether it is associated with leakage or regurgitation of the mitral valve (MR). The presence of MR frequently prompts the use of antibiotics prior to any dental or non-sterile surgical procedure. Such action helps reduce the rare complication of valve infection.
   Volume status: Low blood pressure can occur in the setting of poor heart function but may also be seen when patient's have a reduced volume of circulating blood (as seen with dehydration, blood loss, use of diuretics or "water pill.", etc.). In many cases, the diagnosis can be made on the basis of history, physical examination and blood tests. However, confusion may be caused when patients have a combination of problems. Echocardiography may help clarify the confusion. The inferior vena cava (the major vein that returns blood from the lower half of the body to the right atrium) is distended or increased in size in patients with heart failure and reduced in caliber when the blood volume is reduced.
   Other Uses: Echocardiography is useful in the diagnosis of fluid in the pericardium (the sac that surrounds the heart). It also determines when the problem is severe and potentially life-threatening. Other diagnoses (plural for diagnosis) made by Doppler or echocardiography include congenital heart diseases, blood clots or tumors within the heart, active infection of the heart valves, abnormal elevation of pressure within the lungs, etc.
How safe is echocardiography? Echocardiography is extremely safe. There are no known risks from the clinical use of ultrasound during this type of testing.
How long does it take? A brief examination in an uncomplicated case may be done within 15 to 20 minutes. The additional use of Doppler may add an additional 10 to 20 minutes. However, it may take up to an hour when there are multiple problems or when there are technical problems (for example, patients with lung disease, obesity, restlessness, and significant shortness of breath may be more difficult to image).
When can I expect to receive the results? If a doctor is present during the test or reviews it while you are still in the office, you may be able to get the results before you leave. However, the doctor is not routinely present during the test and you may have to wait from one to several days before the images have been reviewed by a physician and the results are sent to you by phone or mail. Some physicians will discuss your case before the study is performed and will contact you if there are significant unexpected findings. For example, if you are expected to have a finding or known to have a given disease, your physician may indicate that he or she will call you only if there are significant unexpected findings. You may also be contacted if echocardiography reveals a finding that influences a change in treatment. For example, the presence of a distended inferior vena cava (discussed above) may result in increasing the dose of your diuretic or water pill, if it is indicated by other aspects of your condition.  

 Electrocardiogram, EKG or ECG: An EKG is an important part of the initial evaluation of a patient who is suspected to have a heart related problem. Small sticky electrodes are applied to the patient's chest, arms and legs. However, with some systems, the electrodes may be applied to the chest, shoulders and the sides of the lower chest, or hips . Wires are used to connect the patient to an EKG machine. You will be asked to remain very still while a nurse or technician records the EKG. The electrical activity created by the patient's heart is processed by the EKG machine and then printed on a special graph paper. This is then interpreted by your physician. It takes a few minutes to apply the EKG electrodes, and one minute to make the actual recording.
EKG test
   The EKG is extremely safe and there is no risk involved. In rare cases, some people may develop skin irritation from the electrode adhesive, but no serious allergic reactions have been reported.
   The only preparation for an EKG to wear clothes that allow easy access to your chest. Thus, a blouse or shirt with buttons down the front is a lot more practical than a pantsuit or dress. Once you arrive in your doctor's office or in the hospital, your chest may be cleansed with alcohol to ensure good electrical contact with the EKG electrode. In men with hairy chest, small areas may have to be shaved to allow adequate skin contact with the electrode. This avoids interfering artifacts from being recorded on the EKG and produces a technically satisfactory study.
   The EKG can provide important information about the patient's heart rhythm, a previous heart attack, increased thickness of heart muscle, signs of decreased oxygen delivery to the heart, and problems with conduction of the electrical current from one portion of the heart to another. For example, the EKG tracing shown above demonstrates an acute or ongoing heart attack involving the bottom (or inferior portion of the heart). An example of an EKG of a patient with a heart attack is shown below.
EKG
   It is important to remember that EKGs are not 100% accurate. Normal recordings can be obtained in patients with significant heart disease, or some "abnormalities" may exist in the presence of a normal heart.


Heart Electrical Activity

 The heart has a natural pacemaker that regulates the pace or rate of the heart. It sits in the upper portion of the right atrium (RA) and is a collection of specializes electrical cells known as the SINUS or SINO-ATRIAL (SA) node.

   Like the spark-plug of an automobile it generates a number of "sparks" per minute. Each "spark" travels across a specialized electrical pathway and stimulates the muscle wall of the four chambers of the heart to contract (and thus empty) in a certain sequence or pattern. The upper chambers or atria are first stimulated. This is followed by a slight delay to allow the two atria (atria is plural for atrium and pronounced ay-tree-ya) to empty. Finally, the two ventricles are electrically stimulated.
   In an automobile, the number of sparks per minute generated by a spark plug is increased when you press the gas pedal or accelerator. This revs up the motor. In case of the heart, adrenaline acts as a gas pedal and causes the sinus node to increase the number of sparks per minute, which in turn increases the heart rate. The release of adrenaline is controlled by the nervous system. The heart normally beats at around 72 times per minute and the sinus node speeds up during exertion, emotional stress, fever, etc., or whenever our body needs an extra boost of blood supply. In contrast, it and slows down during rest or under the influence of certain medications. Well trained athletes also tend to have a slower heart beat.
Electrical activation 1
Electrical activation 2

   The sequence of electrical activity within the heart is displayed in the diagrams above and occurs as follows:
As the SA node fires, each electrical impulse travels through the right and left atrium. This electrical activity causes the two upper chambers of the heart to contract. This electrical activity and can be recorded from the surface of the body as a "P" wave" on the patient's EKG or ECG (electrocardiogram).
   The electrical impulse then moves to an area known as the AV (atrio-ventricular) node. This node sits just above the ventricles. Here, the electrical impulse is held up for a brief period. This delay allows the right and left atrium to continue emptying it's blood contents into the two ventricles. This delay is recorded as a "PR interval." The AV node thus acts as a "relay station" delaying stimulation of the ventricles long enough to allow the two atria to finish emptying.

   Following the delay, the electrical impulse travels through both ventricles (via special electrical pathways known as the right and left bundle branches). The electrically stimulated ventricles contract and blood is pumped into the pulmonary artery and aorta. This electrical activity is recorded from the surface of the body as a "QRS complex". The ventricles then recover from this electrical stimulation and generates an "ST segment" and T wave on the EKG.
    In summary, the heart constantly generates a sequence of electrical activity with every single heart beat. This can be recorded on paper or displayed on a monitor by attaching special electrodes to a machine that can amplify and record an EKG or ECG (electrocardiogram). The animation (above) shows the sequence of electrical activity throughout the heart. Note how the chambers of the heart contract when they are electrically stimulated. This in turn makes the heart valves open and shut.


 


Physical Exam
After obtaining a history, the physician proceeds to perform a physical examination. Depending upon the patient's condition and suspected medical problem, a physician may include one or more of the following four phases of the physical examination:Inspection
Palpation or "hands-on" examination
Percussion or "tapping" examination
Auscultation or use of stethoscope

Inspectgion   Inspection: During this portion of the examination, the physician inspects or looks at different parts of the patient's body. For example, while inspecting the eyes, the physician could obtain a clue about an overactive thyroid that could be responsible for the patient's rapid heart beat. A characteristic growth on the eyelids could point to a high cholesterol level that is a risk factor for coronary artery disease.
     Inspection of the neck veins and its prominence could be indicative of heart failure and an excessive load on the right side of the heart. A bluish discoloration of the tongue and nail beds could point to a low oxygen level in the blood, while pallor or a pale appearance could indicate a low level of hemoglobin.  Additionally, inspection of the chest may provide information about enlargement of the heart. Thus, a physician obtains an enormous amount of information even before touching the patient.



   Palpation
 or "hands-on examination": During palpation, the physician uses his or hands to examine the patient. During this phase, the physician can feel the heart beat and diagnose enlargement. Loud heart murmurs may also be felt without the use of a stethoscope. This is known as a "thrill."  Palpation of the belly could help diagnose liver enlargement, find the tenderness of an active ulcer, or help uncover an aneurysm.
       The patient's pulses are also felt to help determine if there is disease of the blood vessel accounting for calf pain when the patient walks. Pressing the legs and feet with the fingertip can diagnose the presence of edema or excess fluid.



Percussion
  Percussion or Tapping: During percussion, the examiner places one hand on the patient and then taps a finger on that hand, with the index finger of the other hand. Since hollow and solid areas generate different vibrations, the physician or other examiner uses this technique to determine if various organs (heart, liver, etc.) are enlarged or not.  Percussion is also used to diagnose fluid in the abdominal and chest cavities or make one suspect the presence of pneumonia.



  Auscultation or listening with a stethoscope: During auscultation, the physician listens to the patient's heart beat, lungs and blood vessels of the neck and groin. Abnormal heart sounds, known as gallops, are a clue to heart disease. Also, the location, character and timing of a heart murmur (this is a prolonged sound that is created by turbulent blood flow across  heart valves) are used to diagnose various valve diseases. However, it should be recognized that murmurs may also be heard in many normal individuals.
     Certain characteristics of the murmur and other portions of the examination help the physician diagnose specific forms of heart diseases. Similarly, blockages in the arteries of the neck and those that supply the legs may also produce a turbulent flow. This can be heard with a stethoscope and is known as a "bruit" (pronounced broo-ee). Listening to the lungs, when integrated with the history and other portions of the physical examination, can diagnose such conditions as heart failure, accumulation of fluid, asthma, bronchitis, pneumonia, collapsed lungs, etc.





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