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Ultrasound

Sonogram

Ultrasound uses high-frequency sound waves to make images of organs and structures inside the body.

How the Test is Performed

An ultrasound machine makes images so that organs inside the body can be examined. The machine sends out high-frequency sound waves, which reflect off body structures. A computer receives the waves and uses them to create a picture. Unlike with an x-ray or CT scan, this test does not use ionizing radiation.

The test is done in the ultrasound or radiology department.

  • You will lie down for the test.
  • A clear, water-based gel is applied to the skin on the area to be examined. The gel helps with the transmission of the sound waves.
  • A handheld probe called a transducer is moved over the area being examined. You may need to change position so that other areas can be examined.

How to Prepare for the Test

Your preparation will depend on the part of the body being examined.

How the Test will Feel

Most of the time, ultrasound procedures do not cause discomfort. The conducting gel may feel a little cold and wet. You will feel the sonographer press the ultrasound probe against your body in the area they are reviewing.

Why the Test is Performed

The reason for the test will depend on your symptoms. An ultrasound test may be used to identify problems involving:

Normal Results

Results are considered normal if the organs and structures being examined look OK.

What Abnormal Results Mean

The meaning of abnormal results will depend on the part of the body being examined and the problem found. Talk to your health care provider about your questions and concerns.

Risks

There are no known risks. The test does not use ionizing radiation.

Considerations

Some types of ultrasound tests need to be done with a probe that is inserted into your body. Talk to your provider about how your test will be done.

Open References

References

Butts C. Ultrasound. In: Roberts JR, Custalow CB, Thomsen TW, eds. Roberts and Hedges' Clinical Procedures in Emergency Medicine and Acute Care. 7th ed. Philadelphia, PA: Elsevier; 2019:chap 66.

Fowler GC, Lefevre N. Emergency department, hospitalist, and office ultrasound (POCUS). In: Fowler GC, ed. Pfenninger and Fowler's Procedures for Primary Care. 4th ed. Philadelphia, PA: Elsevier; 2020:chap 214.

Merritt CRB. Physics of ultrasound. In: Rumack CM, Levine D, eds. Diagnostic Ultrasound. 5th ed. Philadelphia, PA: Elsevier; 2018:chap 1.

Morris AE, Adamson R, Frank J. Ultrasonography: principles and basic thoracic and vascular imaging. In: Broaddus VC, Ernst JD, King TE, et al, eds. Murray and Nadel's Textbook of Respiratory Medicine. 7th ed. Philadelphia, PA: Elsevier; 2022:chap 23.

  • Abdominal ultrasound

    Abdominal ultrasound - illustration

    Abdominal ultrasound is a scanning technique used to image the interior of the abdomen. Like the X-ray, MRI, and CT scan, it has its place as a diagnostic tool. Ultrasound scans use high frequency sound waves to produce an image and do not expose the individual to radiation. The procedure is painless and safe.

    Abdominal ultrasound

    illustration

  • Ultrasound in pregnancy

    Ultrasound in pregnancy - illustration

    The ultrasound has become a standard procedure used during pregnancy. It can demonstrate fetal growth and can detect increasing numbers of conditions including meningomyelocele, congenital heart disease, kidney abnormalities, hydrocephalus, anencephaly, club feet, and other deformities. Ultrasound does not produce ionizing radiation and is considered a very safe procedure for both the mother and the fetus.

    Ultrasound in pregnancy

    illustration

  • 17 week ultrasound

    17 week ultrasound - illustration

    During seventeen to twenty weeks of development, fetal movements known as quickening are commonly felt by the mother.

    17 week ultrasound

    illustration

  • 30 week ultrasound

    30 week ultrasound - illustration

    Around 30 weeks, the growth of the brain markedly increases. Most systems are well developed, and the fetus can see and hear. A baby may survive if born this early, although the lungs may still be immature.

    30 week ultrasound

    illustration

  • Carotid duplex

    Carotid duplex - illustration

    Carotid duplex is an ultrasound procedure performed to assess blood flow through the carotid artery to the brain. High-frequency sound waves are directed from a hand-held transducer probe to the area. These waves bounce off the arterial structures and produce a 2-dimensional image on a monitor, which will make obstructions or narrowing of the arteries visible.

    Carotid duplex

    illustration

  • Thyroid ultrasound

    Thyroid ultrasound - illustration

    Thyroid ultrasound is a sound wave picture of the thyroid gland taken by a hand-held instrument and translated to a 2-dimensional picture on a monitor. It is used in diagnosis of tumors, cysts or goiters of the thyroid, and is a painless, no-risk procedure.

    Thyroid ultrasound

    illustration

  • Ultrasound

    Ultrasound - illustration

    Ultrasound is a scanning technique used to image the growing fetus. The transducer portion emits inaudible sound waves, which fan out as they travel through your abdomen. When they hit dense structures like the fetus and the wall of your uterus, the sound waves bounce back to the transducer and are translated into a visual image by the computer.

    Ultrasound

    illustration

  • Ultrasound, normal fetus - ventricles of brain

    Ultrasound, normal fetus - ventricles of brain - illustration

    This is a normal fetal ultrasound performed at 17 weeks gestation. The development of the brain and nervous system begins early in fetal development. During an ultrasound, the technician usually looks for the presence of brain ventricles. Ventricles are spaces in the brain that are filled with fluid. In this early ultrasound, the ventricles can be seen as light lines extending through the skull, seen in the upper right side of the image.

    Ultrasound, normal fetus - ventricles of brain

    illustration

  • 3D ultrasound

    3D ultrasound - illustration

    3D ultrasound provides a three dimensional image of the fetus. Sound waves are sent at different angles by the transducer for the computer to reconstruct the height, width, and depth of the image.

    3D ultrasound

    illustration

  • Ultrasound comparison

    Ultrasound comparison - illustration

    To demonstrate how an ultrasound works, imagine this tennis ball as an internal organ in the body. Like many organs, the tennis ball is solid on the outside and hollow on the inside. Solid structures, such as bones and muscles, reflect sound waves from the ultrasound transducer and show up as white in an ultrasound image. Soft or hollow areas, like chambers of the heart, do not reflect sound waves and appear as black. The white ring is the outer edge of the tennis ball being reflected back as an image while the center hollow area remains as black.

    Ultrasound comparison

    illustration

  • Abdominal ultrasound

    Abdominal ultrasound - illustration

    Abdominal ultrasound is a scanning technique used to image the interior of the abdomen. Like the X-ray, MRI, and CT scan, it has its place as a diagnostic tool. Ultrasound scans use high frequency sound waves to produce an image and do not expose the individual to radiation. The procedure is painless and safe.

    Abdominal ultrasound

    illustration

  • Ultrasound in pregnancy

    Ultrasound in pregnancy - illustration

    The ultrasound has become a standard procedure used during pregnancy. It can demonstrate fetal growth and can detect increasing numbers of conditions including meningomyelocele, congenital heart disease, kidney abnormalities, hydrocephalus, anencephaly, club feet, and other deformities. Ultrasound does not produce ionizing radiation and is considered a very safe procedure for both the mother and the fetus.

    Ultrasound in pregnancy

    illustration

  • 17 week ultrasound

    17 week ultrasound - illustration

    During seventeen to twenty weeks of development, fetal movements known as quickening are commonly felt by the mother.

    17 week ultrasound

    illustration

  • 30 week ultrasound

    30 week ultrasound - illustration

    Around 30 weeks, the growth of the brain markedly increases. Most systems are well developed, and the fetus can see and hear. A baby may survive if born this early, although the lungs may still be immature.

    30 week ultrasound

    illustration

  • Carotid duplex

    Carotid duplex - illustration

    Carotid duplex is an ultrasound procedure performed to assess blood flow through the carotid artery to the brain. High-frequency sound waves are directed from a hand-held transducer probe to the area. These waves bounce off the arterial structures and produce a 2-dimensional image on a monitor, which will make obstructions or narrowing of the arteries visible.

    Carotid duplex

    illustration

  • Thyroid ultrasound

    Thyroid ultrasound - illustration

    Thyroid ultrasound is a sound wave picture of the thyroid gland taken by a hand-held instrument and translated to a 2-dimensional picture on a monitor. It is used in diagnosis of tumors, cysts or goiters of the thyroid, and is a painless, no-risk procedure.

    Thyroid ultrasound

    illustration

  • Ultrasound

    Ultrasound - illustration

    Ultrasound is a scanning technique used to image the growing fetus. The transducer portion emits inaudible sound waves, which fan out as they travel through your abdomen. When they hit dense structures like the fetus and the wall of your uterus, the sound waves bounce back to the transducer and are translated into a visual image by the computer.

    Ultrasound

    illustration

  • Ultrasound, normal fetus - ventricles of brain

    Ultrasound, normal fetus - ventricles of brain - illustration

    This is a normal fetal ultrasound performed at 17 weeks gestation. The development of the brain and nervous system begins early in fetal development. During an ultrasound, the technician usually looks for the presence of brain ventricles. Ventricles are spaces in the brain that are filled with fluid. In this early ultrasound, the ventricles can be seen as light lines extending through the skull, seen in the upper right side of the image.

    Ultrasound, normal fetus - ventricles of brain

    illustration

  • 3D ultrasound

    3D ultrasound - illustration

    3D ultrasound provides a three dimensional image of the fetus. Sound waves are sent at different angles by the transducer for the computer to reconstruct the height, width, and depth of the image.

    3D ultrasound

    illustration

  • Ultrasound comparison

    Ultrasound comparison - illustration

    To demonstrate how an ultrasound works, imagine this tennis ball as an internal organ in the body. Like many organs, the tennis ball is solid on the outside and hollow on the inside. Solid structures, such as bones and muscles, reflect sound waves from the ultrasound transducer and show up as white in an ultrasound image. Soft or hollow areas, like chambers of the heart, do not reflect sound waves and appear as black. The white ring is the outer edge of the tennis ball being reflected back as an image while the center hollow area remains as black.

    Ultrasound comparison

    illustration

Tests for Ultrasound

 
 

Review Date: 7/5/2022

Reviewed By: Jason Levy, MD, FSIR, Northside Radiology Associates, Atlanta, GA. Also reviewed by David C. Dugdale, MD, Medical Director, Brenda Conaway, Editorial Director, and the A.D.A.M. Editorial team.

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