Point-of-care ultrasound

Last updated: June 13, 2023

CME information and disclosurestoggle arrow icon

To see contributor disclosures related to this article, hover over this reference: [1]

Physicians may earn CME/MOC credit by reading information in this article to address a clinical question, and then completing a brief evaluation, in which they will identify their question and report the impact of any information learned on their clinical practice.

AMBOSS designates this Internet point-of-care activity for a maximum of 0.5 AMA PRA Category 1 Credit(s)™. Physicians should claim only credit commensurate with the extent of their participation in the activity.

For answers to questions about AMBOSS CME, including how to redeem CME/MOC credit, see “Tips and Links” at the bottom of this article.

Summarytoggle arrow icon

Point-of-care ultrasound (POCUS) is an imaging protocol performed at the patient's bedside by the treating clinician as an extension of the physical examination. It is a valuable diagnostic tool in the emergency department (ED) because it is noninvasive, rapidly deployed, does not necessitate moving the patient from the resuscitation area, and does not interrupt urgent management. Sonographic assessment at the bedside helps narrow differential diagnoses and guide urgent management decisions, as it permits immediate (real-time) correlation of clinical features to imaging findings. To perform an adequate POCUS, it is imperative to have a basic understanding of ultrasound transducers, knobology, and acoustic windows for the areas of interest. POCUS has several applications, including diagnostic, screening, and procedural applications. Examination is limited to the area(s) of interest and specific objectives, which are based on the pretest probability of the diagnoses being considered. This article introduces the most common emergency clinical applications of POCUS. Focused assessment with sonography for trauma (FAST) is used to assess for free fluid within three main areas of interest: the peritoneal, pericardial, and pleural cavities. Additionally, extended FAST (eFAST) includes evaluation of the thorax for a possible pneumothorax. POCUS for the abdominal aorta focuses on the maximal aortic diameter to rule out an abdominal aortic aneurysm. POCUS of the subcostal IVC focuses on the diameter and collapsibility of the IVC to help estimate the intravascular volume status. POCUS of the gallbladder and biliary tree is used to evaluate for signs of gallbladder inflammation and cholelithiasis. POCUS of the female pelvis is used to rule in an intrauterine pregnancy in women within the reproductive age group. Finally, it is important to remember that negative or inconclusive POCUS findings should not be used to definitively rule out a diagnosis because POCUS is not a comprehensive examination and the results are operator-dependent.

More advanced POCUS techniques (e.g., lung ultrasound, cardiac ultrasound) are beyond the scope of this article. See the “Ultrasound” article for more information on fundamental concepts applied to broader sonographic modalities, e.g., formal ultrasound, endoscopic ultrasound, contrast-enhanced ultrasound.

Image generationtoggle arrow icon

  • Generating high-quality and reliably interpretable ultrasound images is essential for POCUS to aid clinical decision-making.
  • Good image generation is reliant on the following:
    • An understanding of basic ultrasound principles
    • Proper transducer selection, placement, and manipulation techniques
    • Use of appropriate image optimization strategies
    • A patient-oriented approach that minimizes discomfort and enhances cooperation
  • Once optimal images are generated, interpret POCUS findings alongside other clinical and diagnostic parameters according to each patient's individual context.

Transducerstoggle arrow icon

Proper transducer (or probe) selection, placement, and manipulation techniques are essential for image generation and should be guided by the clinical picture and area of interest.


Physical properties [2][3]

The ultrasound transducer emits ultrasound waves (via piezoelectric transducers) that are reflected back by organs or tissues, generating a two-dimensional image. The following features should be considered when selecting an appropriate transducer for POCUS:

  • Frequency: The frequency of ultrasound waves emitted by the transducer determines the image quality and affects clinical applicability.
    • High [4]
      • Higher-resolution image
      • Low depth of penetration
      • Better to visualize superficial tissues
    • Low
      • Lower-resolution image
      • High depth of penetration
      • Better to visualize deeper tissue/organs
  • Footprint: The surface of the probe from which the ultrasound waves are emitted

Transducer types

There are four types of transducers that are essential for POCUS. They differ in size, frequency, and footprint, and generate different image formats, all of which affect their clinical applications.

Ultrasound transducers typically used for POCUS [2][3][4]
Transducer Properties Examples of clinical applicability
Linear array transducer
  • Description
    • Piezoelectric crystals have a linear arrangement.
    • Produces parallel beams of ultrasound waves
    • Generates a rectangular image that is as wide as its footprint
  • Footprint: wide
  • Frequency: high (5–15 MHz)
    • Image resolution: high
    • Depth of penetration: low
Curvilinear array transducer
  • Description
    • Crystals have a convex arrangement.
    • Produces diverging beams of ultrasound waves
    • Generates a cone-shaped image
  • Footprint: wide
  • Frequency: low to medium (2–8 MHz)
    • Image resolution: low (in the far field)
    • Depth of penetration: high
Phased array transducer
  • Description
    • Crystals are arranged in a dense pattern in the center of the probe.
    • Ultrasound waves are generated in a phased manner.
    • Generates a cone-shaped or sector image with a very narrow near field
    • Allows for continuous wave Doppler application [3]
  • Footprint: small (can fit in intercostal spaces)
  • Frequency: low (1–5 MHz)
    • Image resolution: low
    • Depth of penetration: high
Endocavitary probe
  • Description
    • Crystals are arranged in the shape of a narrow cylindrical head.
    • Generates high-resolution images
  • Footprint: variable; typically small
  • Frequency: high (≥ 5 MHz)
    • Image resolution: very high
    • Depth of penetration: low

The frequency of ultrasound waves is inversely related to the depth of penetration and directly related to the quality of image resolution: High-frequency probes generate high-resolution images but only of superficial tissue; low-frequency probes enable visualization of deeper structures at a lower resolution.


To best visualize the area of interest, place properly oriented probes on an appropriate acoustic window that takes into account the ultrasound conductivity and acoustic impedance of the underlying tissues.

Orientation [8]

  • Indicators (orientation markers): used to orient the transducer along the standard planes of view while scanning
    • On the probe: typically a groove or ridge on one side of the probe
    • On the monitor: typically appears as a white or green dot on one side of the screen
  • Orientation conventions
    • By POCUS convention, the monitor indicator should be on the left side of the screen.
    • Standard planes of view
      • Sagittal plane: Orient the probe so that its indicator points cranially.
      • Transverse plane: Orient the probe so that its indicator points toward the patient's right side.
  • Confirm probe-to-monitor orientation: Do this prior to scanning to ensure accurate interpretation of spatial relationships and relative location of findings.
    • Initially locate the probe indicator by inspection or palpation.
    • Next, verify that movement occurring on the indicator side of the probe corresponds to movement seen on the indicator side of the monitor.
      • Touch the indicator side of the probe surface with a gloved finger or apply gel to that side.
      • If movement is seen on the opposite side of the screen to the monitor indicator, this typically means the probe indicator was incorrectly identified and the probe needs to be rotated 180° before placement.

If the probe indicator is identified correctly and the monitor is set to POCUS conventions, the left side of the screen should displays structures seen on the indicator side of the probe.

Adhere to orientation conventions as much as possible to avoid misinterpretation of findings and medical errors.

Acoustic windows [2][7]

Ultrasound conductivity of different media
Acoustic impedance Medium Conductivity Clinical implications

Clear fluid (e.g., water, urine)

Solid organs

Soft tissue

Ultrasound gel

  • Good: allows easy transmission of sound waves
High Air
  • Bowel gas often obscures intraabdominal, pelvic, and retroperitoneal structures.
  • Air pockets between the probe and skin can cause visual artifacts and distort the image.
  • Intervening bone impedes visualization and can generate sound wave artifacts.
  • Obese body habitus reduces the resolution of deeper structures.

Choose acoustic windows with good ultrasound conductivity (e.g., fluid-filled or solid organs). Avoid areas with excessive intervening air, bone, or fat.

Manipulation [9]

There are five cardinal movements of the transducer that are required for most POCUS applications. These manipulations require movement of the transducer footprint in relation to the body and/or a change in the angle of insonation, which is the angle between the ultrasound beam and the area of interest.

Cardinal movements of the ultrasound transducer
Sliding (sweeping)
  • Move the transducer footprint along or to the desired plane.
  • Do not alter the angle of insonation.
Tilting (fanning)
  • Fix the transducer footprint over the area of interest.
  • Alter the angle of insonation along the short axis of the transducer by tilting backwards and forwards.
  • Fix the transducer footprint over the area of interest.
  • Alter the angle of insonation along the long axis of the transducer by tilting from side to side.
  • Fix the transducer footprint over the area of interest.
  • Rotate the transducer in a clockwise or anticlockwise manner along its central axis.
  • Do not alter the angle of insonation.


  • Fix the transducer footprint over the area of interest.
  • Apply pressure to the underlying tissue with the transducer.
  • Do not alter the angle of insonation.

Image optimization (knobology)toggle arrow icon

Ultrasound machines are typically equipped with factory presets for certain applications (e.g., preset for abdominal examination). The factory presets serve as a good starting point to visualize the desired target tissue. Knobology refers to the manual adjustment of the following knobs or features on the ultrasound machine to enable further image optimization. [3][5][8][10]

Familiarize yourself with the ultrasound machine you will be using before conducting examinations.


Depth penetration (sonography) [3]

  • Background
    • Depth penetration is the distance traveled by ultrasound waves to visualize the target tissue/organs.
    • The depth traversed by ultrasound waves is depicted on the monitor, typically in centimeters.
  • Action: Adjust the “Depth” or “Zoom” knob to optimize visibility and image quality.
    • An appropriate depth is one in which the image generated predominantly contains the area of interest.
    • As increasing the depth of penetration decreases the spatial resolution, select the least depth required to adequately visualize the target tissue/organs.
    • Increasing depth also decreases the frame rate.
  • Examples

The transducer frequency plays an important role in determining the depth penetration.

Gain (sonography) [3][8]

  • Background
    • Gain is the magnitude of amplification of the ultrasound wave being reflected back to the transducer, and it determines the brightness of the image on the monitor.
    • Increasing gain:
      • Increases the reflected ultrasound wave and generates a brighter image
      • Decreases the contrast and spatial resolution of the image
  • Action: Adjust the “Gain” knob to optimize the brightness and resolution of the image. [3]
    • Hypoechoic structures (e.g., fluid) should appear black.
    • Hyperechoic structures (e.g., bone) should appear white.
    • Adjoining structures should be distinguishable.

Avoid increasing gain too much, as overgained images result in poor contrast between adjacent structures.

Focal zone (sonography) [3][5][12]

  • Background
    • The focal zone (or focal plane) refers to the part of the ultrasound beam with the narrowest diameter.
    • The lateral resolution of the image is best at the focal zone.
    • The location of the focal zone is depicted (e.g., with an arrowhead) on the lateral border of the image on the monitor.
    • Some machines have more than one focal zone.
  • Action: Adjust the “Focus” knob so that the focal zone marker falls at the area of interest.

Image capture and analysis [3]

  • Freezing images
    • Use the “Freeze” or “FRZ” button to pause the real-time image in order to:
      • Closely inspect the frame
      • Obtain measurements
      • Save and print the frame
    • With most devices, it is possible to rewind frames after freezing using the trackball or touchpad.
  • Taking measurements
    • Areas of interest may need to be measured in various planes.
    • Use the “Caliper” button to obtain the straight-line measurement between two points and the “Trace” button to obtain curved line measurements.
    • Use the trackball or touchpad to maneuver the cursor to the desired point of measurement and set the points using the “Enter” or “Set” button.
    • Use the “Next” button to take another measurement.
    • Depending on the selected mode of examination, areas, volumes, angles, and more advanced measurements can also be calculated.
  • Saving and recording images
    • Use the “Store” button to save paused frames.
    • Use the “Clips” button to obtain short recordings.
    • The “Print” button may be used if a physical copy of the ultrasound is desired.

Transducer selection and knobology checklisttoggle arrow icon

  • Turn the ultrasound machine on.
  • Select an appropriate ultrasound transducer.
  • Select “B-mode” or “2D mode” (appropriate for most POCUS applications).
  • Select an application preset (e.g., abdominal, cardiac).
  • Confirm the orientation of the transducer.
  • Select an appropriate acoustic window to visualize the area of interest.
  • Place adequate amounts of a low-impedance gel on the area to be scanned or on the transducer.
  • Ensure firm and direct contact between the probe and skin to minimize air pockets.
  • Adjust depth to maximize the visibility of the area of interest on the screen
  • Adjust gain to optimize the contrast of structures
  • Choose the optimal focal zone
  • Manipulate the transducer (e.g., sliding, tilting) to visualize all areas of interest throughout the necessary planes.
  • Document any necessary measurements.
  • Record and save all relevant images.

General troubleshootingtoggle arrow icon

All views

  • Apply gel liberally to fill any spaces or crevices between the probe and skin, e.g., skin folds, umbilicus.
  • Ensure firm and direct contact between the probe and skin to minimize air pockets.

Abdominal and subxiphoid views

  • Consider applying sustained pressure, if tolerated, to allow bowel gas to slowly displace from the field of view.
  • To reduce discomfort and resistance from pressure applied, consider asking the patient to flex the hips and knees to relax the abdominal muscles.
  • Ask patients to take a deep breath and hold it, if tolerated, to inferiorly displace subdiaphragmatic abdominal organs that are obscured by rib and lung shadows.
  • Consider alternative imaging techniques for patients with:
    • Uncontrolled abdominal pain
    • Excessive gaseous bowel distension
    • Obese body habitus

Pelvic views

  • If using a transabdominal approach, consider asking patients to defer urination until after the scan, if tolerated.
  • If an empty bladder impairs visualization, consider the following:
    • Repeat the examination after a period of hydration.
    • For catheterized patients, consider temporarily clamping the catheter or instilling a small amount (e.g., 50 mL) of normal saline into the bladder.
  • Switch to an endocavitary probe if appropriate and tolerated, e.g., during POCUS for early pregnancy.

Thoracic views

  • Place the probe within the intercostal space to visualize thoracic structures whenever possible, and consider switching to a probe with a smaller footprint.
  • To better visualize the heart, consider asking the patient to turn towards the left-lateral decubitus position if tolerated.
  • Consider comparing lung findings with the contralateral lung at the same intercostal level to help determine if they are pathological.


FAST and eFASTtoggle arrow icon

FAST and eFAST are abbreviated scans that help with decision-making in select patients with acute traumatic injuries. They do not replace clinical judgment or other imaging modalities in trauma (e.g., CT scanning, radiography). Always interpret results along with other diagnostic and clinical findings within the individual patient context. [6]

Definitions [6][7][13][14]


FAST and eFAST can be performed by nonradiologist clinicians with appropriate training and experience.

Limitations [17]

A negative FAST does not rule out an intraabdominal or intrathoracic injury!

General technique [7][17][19]

If possible, obtain two planes of view for each area to avoid missing small fluid collections.

Subxiphoid view [6][7][19]

  • Areas of interest: pericardial space
  • Acoustic window: left lobe of liver
  • Technique
    • Start in the transverse plane (indicator pointing towards the patient's right side).
    • Place the transducer on the subxiphoid space in the midline.
    • Apply firm pressure posteriorly to direct the ultrasound beam behind the ribs.
    • To bring the heart into view, tilt the transducer anteriorly and toward the left shoulder, while maintaining posterior pressure to avoid losing contact with the skin.
    • Identify the pericardium in relation to the diaphragm and the beating cardiac chambers.
    • Scan the entire heart from base to apex and anterior to posterior by tilting and rocking the transducer through the planes of section.
  • Troubleshooting
    • Adjust gain so that the fluid within the cardiac chambers appears black.
    • Use more of the liver as an acoustic window: slide the probe towards the patient's right while rocking it towards the patient's left.
    • Ask the patient to bend their knees or take a deep breath and hold it (see “General troubleshooting”).
  • Findings: An anechoic (black) area between the hyperechoic pericardium and the myocardium represents a pericardial effusion.

Beware of false positives for free pericardial fluid: A hypoechoic area limited to the anterior apex that does not extend posteriorly to dependent regions of the pericardial space may represent periapical fat. Fluid in the pleural and peritoneal spaces may also be mistaken for pericardial fluid.

RUQ view [6][7][19]

LUQ view [6][7][19]

  • Main areas of interest (craniocaudally)
  • Additional areas of interest for free fluid
  • Acoustic window: spleen
  • Ideal patient position: Trendelenburg position
  • Technique
    • Begin in the sagittal plane (indicator pointing towards the patient's head)
    • Place the transducer in one of the inferior intercostal spaces over the left midaxillary line.
    • Rotate the transducer so that it is parallel to the ribs, with the orientation marker pointing toward the vertebral end of the rib.
    • Slide the transducer in an anteroposterior and/or cephalocaudal direction to locate and center the splenorenal interface.
    • Once it is identified, tilt and rock the transducer to assess for free fluid (anechoic areas) within all areas of interest
  • Troubleshooting: To improve image generation and visualization
    • Adjust gain so that the diaphragm and renal sinus fat appear white and fluid-filled structures such as the aorta appear black.
    • If possible, ask the patient to take a deep breath and hold it.
  • Findings: Anechoic or hypoechoic fluid collections within the areas of interest should be considered pathological in the setting of trauma.

To assess the LUQ, place the transducer more cranially and more posteriorly than for the RUQ.

Beware of false positives for free fluid in the LUQ: contained fluid collections (e.g., abscesses, cysts, loculations, or accessory organs) or pleural fluid collections can be mistaken for intraperitoneal free fluid. [6]

Pelvic view [6][7][17][19]

Following ovulation and menstruation in women of reproductive age, a small amount (e.g., < 50 mL or ≤ 1 cm diameter) of anechoic free fluid in the pouch of Douglas may be physiological. Clinical correlation is essential.

Limited lung ultrasound [6][7][19]

Views to screen for pneumothorax in both lungs are added to the FAST components to make up the eFAST protocol.

In hemodynamically unstable patients, an abbreviated scan as described here is acceptable to detect a large pneumothorax. In stable patients, multiple areas of the chest should ideally be scanned to detect a pneumothorax. [6]

Further management

In trauma patients, it should be assumed that free fluid within any of the potential spaces is pathological.

Abdominal aortatoggle arrow icon

POCUS is a key diagnostic tool in the acute evaluation of patients with suspected AAA. Although it has high accuracy, it does not replace clinical judgment, formal ultrasound, or CT scanning, especially if performed by an inexperienced practitioner. Always interpret results along with other diagnostic and clinical findings within the individual patient context. [6][20]

Indications [4][21]

Technique [4][6][21]

Initial steps

  • Patient position: supine
  • Preferred transducer: curvilinear or phased array
  • Ultrasound preset: abdomen

Identifying the area of interest

The area of interest is the abdominal aorta lying just anterior to the hyperechoic vertebral body and its acoustic shadow.

Scanning the aorta

Inability to visualize the entire aorta from celiac artery to iliac bifurcation, e.g., due to overlying bowel gas, results in an indeterminate study.


  • Measure from outer wall to outer wall at the greatest width of the aorta.
  • Ensure that the transducer is accurately aligned along or perpendicular to the aorta to avoid over- or underestimating the aortic diameter.
  • Ideally, both anteroposterior and transverse diameters should be measured.

As an intraluminal clot may mimic the aortic wall, measuring only the inner lumen of the aorta may underestimate the size of the aorta.


  • Consider asking the patient to bend their knees to help relax the abdominal muscles.
  • If bowel gas obstructs the view
    • Attempt to displace it: Rock the transducer back and forth while applying firm but gentle pressure over the area of interest.
    • If attempted displacement is unsuccessful, consider obtaining lateral views.
  • Consider additional color Doppler imaging for the following:
    • Evaluating for luminal patency
    • Distinguishing the aorta from adjacent structures (i.e., lymph nodes) [6][22]
Distinguishing between the aorta and the IVC using POCUS
Aorta IVC
Wall appearance Thick Thin
Response to pressure Noncompressible Easily compressible
Response to respiration Unchanged Can be collapsible
Pulsatility ++ +
Typical location Patient left Patient right


  • Normal: A normal abdominal aorta should have a uniform appearance without thrombi or wall irregularities and a diameter < 3 cm from the celiac artery to the iliac bifurcation. [20]
  • POCUS findings of AAA [20]

POCUS may miss small or saccular AAAs (e.g., due to intervening bowel gas).

Paraaortic lymph nodes and retroperitoneal masses can have a similar appearance to AAA.

Further management

AAA may not be the cause of the presenting features. Corroborate imaging findings with clinical features and consider alternate diagnoses. [6]

In patients with negative or indeterminate POCUS findings, consider CT angiography if the pretest probability for AAA is high. [4][6]

Inferior vena cavatoggle arrow icon

POCUS of the subcostal IVC is widely used as part of the assessment of volume status and prediction of fluid responsiveness, however, its accuracy and utility remain unclear. [23][24][25][26]

Clinical applications [17][25][27]

Interpret IVC ultrasound alongside other diagnostic and clinical parameters of volume status. Avoid using it in isolation to predict fluid responsiveness.

Technique [4][17][32]

Initial steps

Identifying the area of interest

The area of interest is the intrahepatic IVC as it flows into the right atrium (RA).

  • Suggested starting point
  • Alternative starting point
    • Start in the sagittal plane (indicator pointing towards the patient's head).
    • Place the transducer in the subxiphoid region at the patient's midline.
    • Slide and/or angle the transducer toward the patient's right side until the IVC is at the center of the image, taking care to distinguish the IVC from the aorta using POCUS.
  • Common endpoint
    • Once the IVC is visible in the sagittal plane, rock the transducer cranially until the IVC-RA junction can be seen on the indicator side of the screen.
    • Slide and/or angle the transducer to capture the IVC in the longitudinal section where it appears widest (i.e., the midline of the vessel).


  • If possible, follow the IVC in a cephalad direction to visualize the site at which it drains into the right atrium (RA) and the liver veins.
  • Measure the IVC diameter at peak inspiration and expiration, ideally at either of the following sites:


  • Consider rewinding the image after hitting “Freeze” to select images with both the widest and narrowest diameter of the IVC during the respiratory cycle.
  • If visualization of the IVC is difficult, e.g., because of interposed bowel gas, consider obtaining lateral views:
  • Consider switching to M-mode, as this may help to obtain precise measurements.

Findings [27][29][33]

  • Normal maximal IVC diameter: ∼ 1.5–2.5 cm [17][34]
  • IVC diameter variation (caval index): percentage of change in the IVC diameter over the respiratory cycle
Interpretation of IVC ultrasound to estimate volume status [17][34]
Parameter Findings suggestive of:
Volume overload Volume depletion
Maximal IVC diameter
  • > 2–2.5 cm
  • < 1.5–2 cm
IVC diameter variation [26][27][35][36]
  • Low
  • High

The absence of IVC diameter variability on respiration is suggestive of elevated central venous pressure (e.g., due to volume overload or right heart failure), while total IVC collapse suggests volume depletion. [6][32]

Ensure IVC measurements are taken in the midline of the vessel to avoid underestimating the diameter.

Further management

Management of patients with volume overload or depletion is based on the underlying etiology.

Gallbladder and biliary tracttoggle arrow icon

Biliary POCUS does not replace clinical judgment or formal ultrasound. Always interpret results along with other diagnostic and clinical findings within the individual patient context. [6]

Indications [4][6]

Technique [4][6]

Initial steps

Although biliary ultrasound is best performed in the fasting state, do not delay examination if the patient presents with acute symptoms.

Identifying the area of interest [6]

The main area of interest is the gallbladder body and contents.

  • Start in the sagittal plane (indicator pointing toward the patient's head).
  • Place the transducer in the subxiphoid region at or slightly to the right of the patient's midline.
  • Optimize depth and gain as needed.
  • Locate the gallbladder by sliding the transducer along the right costal margin (subcostal sweep).

Avoid confusing the gallbladder with other fluid-filled structures in the area, e.g., portal vein, IVC, liver or kidney cysts, abscesses. Scan in multiple planes or use color doppler if there is doubt. [6]


  • Ask the patient to breathe deeply and hold their breath in inspiration, if feasible.
  • If the lower liver margin cannot be visualized, use an intercostal approach.
    • Place the transducer in one of the inferior intercostal spaces, parallel to the ribs.
    • Ensure that the orientation marker points toward the vertebral end of the rib.
    • Slide the transducer from the sternal border toward the patient's right side to locate the gallbladder.

The gallbladder may be difficult to identify because it contracts in the postprandial state and its position is variable. If the gallbladder cannot be identified or adequately assessed on POCUS, rescan the patient after 6–8 hours of fasting in nonurgent cases or obtain a formal abdominal ultrasound.

Scanning the gallbladder [6]

  • Longitudinal plane (long axis)
    • Rotate the transducer to align with the long axis of the gallbladder so that the fundus appears on the right side of the screen.
    • Tilt and/or slide the transducer to visualize the entire gallbladder.
  • Transverse plane (short axis)
    • Rotate the transducer so that the orientation marker points toward the patient's right side.
    • Tilt and/or slide the transducer to visualize the entire gallbladder, from fundus to neck.
  • Examination
    • Assess for gallstones, gallbladder wall thickening, pericholecystic fluid, and sonographic Murphy sign (see “Pathological findings and further management” for details).
    • If cholelithiasis is suspected, change the patient's position and evaluate for movement of the intraluminal echogenic foci.

Measurements [4][6]

Pathological findings and further management [6]

Cholelithiasis [39]

Biliary sludge, which can cause biliary colic, is seen on ultrasound as low-level echogenic material in the dependent portion of the gallbladder. Biliary sludge moves slowly on repositioning the patient and does not cause posterior acoustic shadowing. [40][41][42]

A gallbladder polyp can be differentiated from a gallstone as it does not cast a posterior acoustic shadow and does not move on repositioning the patient. [6]

Acute cholecystitis [6][43]

Do not forget to rule out other life-threatening causes of epigastric pain (e.g., AAA, MI) even in patients with POCUS findings consistent with acute cholecystitis. [6]

Early pregnancytoggle arrow icon

Basic POCUS for early pregnancy is a limited study focused on the presence of an intrauterine pregnancy (IUP). It does not replace clinical judgment or formal ultrasound. Always interpret results along with other diagnostic and clinical findings within the individual patient context. [6]

Indications [6][46]

Obtain β-HCG in symptomatic patients at risk of early pregnancy, regardless of contraception use, followed by sonographic evaluation for IUP if positive.


Technique: transabdominal approach [6]

Initial steps

Identifying the areas of interest

The endometrial stripe is the initial area of interest for POCUS to rule in an IUP.

Scanning the uterus

Following ovulation and menstruation, a small amount (≤ 1 cm in diameter) of anechoic free fluid in the pouch of Douglas is considered physiological. [22]

Technique: transvaginal approach [6]

The field of view on a transvaginal ultrasound is limited, and specialized training is required to adequately perform and interpret a transvaginal ultrasound.

  • Patient position
  • Transducer: endocavitary
  • Initial steps
    • Ideally, the bladder should be empty.
    • Apply the low-impedance ultrasound gel inside the disposable sleeve for the transvaginal transducer.
    • Apply lubricant liberally outside the sleeve.
  • Scanning technique: Scan the uterus in longitudinal and coronal planes.
    • Slowly insert the transducer (with the indicator pointing ventrally) using gentle pressure
    • Advance until the probe tip makes contact with the cervix and uterine tissue can be seen on the monitor.
    • Sweep the transducer to each side to obtain longitudinal views.
    • Gently rotate the transducer 90° counterclockwise (indicator pointing towards patient right) and tilt anteroposteriorly to obtain additional coronal views.
    • Once the endometrial stripe is identified, look for sonographic signs of IUP throughout the planes of interest.
    • Evaluate for free fluid within the pouch of Douglas.

Patients undergoing transvaginal ultrasound should have a chaperone present. [6]

Avoid color doppler ultrasound in the first trimester because of possible risks to the fetus. [47]


See also “Pelvic views” in “General troubleshooting.”

  • Transabdominal approach
  • Transvaginal approach
    • Use lubricant liberally.
    • Ensure no air pockets are present between the probe and the sleeve.
    • Patients may be more comfortable inserting the probe themselves.
    • For patients in the supine position with flexed legs in whom anterior visualization is difficult, consider placing a pillow under the patient's sacrum.

Sonographic signs of IUP [47]

In chronological order of appearance:

  1. Gestational sac: the earliest sign of a possible IUP
  2. Yolk sac: the earliest definitive sign of an IUP
    • A 3–5 mm spherical structure with an echogenic rim eccentrically located within the gestational sac
    • Identifiable by ∼ 5.5 weeks of gestational age
  3. Fetal pole (embryo): a definitive sign of an IUP
    • An echogenic thickening attached to the inner wall of the yolk sac
    • First visible at ∼ 6 weeks of gestational age when it has reached a size of ∼ 1–2 mm [47]
  4. Fetal heart activity: a definitive sign of a viable IUP

Only confirm IUP if definitive signs are present, i.e., gestational sac PLUS either yolk sac, fetal pole, or fetal heart activity, and that these can be seen implanted within normal endometrium and myometrium. If the diagnosis is uncertain, obtain a formal ultrasound.

The inability to visualize an IUP on both transabdominal and transvaginal ultrasound at the β-hCG discriminatory level strongly suggests ectopic pregnancy.

The absence of IUP in a pregnant patient with hemodynamic instability and/or POCUS evidence of intraperitoneal free fluid strongly suggests ruptured ectopic pregnancy. This is a medical emergency requiring acute stabilization and definitive surgical treatment without delay.

Further management

Referencestoggle arrow icon

  1. Qaseem A, Etxeandia-Ikobaltzeta I, Mustafa RA, et al. Appropriate Use of Point-of-Care Ultrasonography in Patients With Acute Dyspnea in Emergency Department or Inpatient Settings: A Clinical Guideline From the American College of Physicians. Ann Intern Med. 2021; 174 (7): p.985-993.doi: 10.7326/m20-7844 . | Open in Read by QxMD
  2. Orso D, Paoli I, Piani T, Cilenti FL, Cristiani L, Guglielmo N. Accuracy of Ultrasonographic Measurements of Inferior Vena Cava to Determine Fluid Responsiveness: A Systematic Review and Meta-Analysis. J Intensive Care Med. 2018; 35 (4): p.354-363.doi: 10.1177/0885066617752308 . | Open in Read by QxMD
  3. Martin ND, Codner P, Greene W, Brasel K, Michetti C. Contemporary hemodynamic monitoring, fluid responsiveness, volume optimization, and endpoints of resuscitation: an AAST critical care committee clinical consensus. Trauma Surgery & Acute Care Open. 2020; 5 (1): p.e000411.doi: 10.1136/tsaco-2019-000411 . | Open in Read by QxMD
  4. Millington SJ. Ultrasound assessment of the inferior vena cava for fluid responsiveness: easy, fun, but unlikely to be helpful. Canadian Journal of Anesthesia/Journal canadien d'anesthésie. 2019; 66 (6): p.633-638.doi: 10.1007/s12630-019-01357-0 . | Open in Read by QxMD
  5. Richards JR, McGahan JP. Focused Assessment with Sonography in Trauma (FAST) in 2017: What Radiologists Can Learn. Radiology. 2017; 283 (1): p.30-48.doi: 10.1148/radiol.2017160107 . | Open in Read by QxMD
  6. Pourmand A, Pyle M, Yamane D, Sumon K, Frasure SE. The utility of point-of-care ultrasound in the assessment of volume status in acute and critically ill patients.. World J Emerg Med. 2019; 10 (4): p.232-238.doi: 10.5847/wjem.j.1920-8642.2019.04.007 . | Open in Read by QxMD
  7. Long E, Oakley E, Duke T, Babl FE. Does Respiratory Variation in Inferior Vena Cava Diameter Predict Fluid Responsiveness. Shock. 2017; 47 (5): p.550-559.doi: 10.1097/shk.0000000000000801 . | Open in Read by QxMD
  8. Corl KA, George NR, Romanoff J, et al. Inferior vena cava collapsibility detects fluid responsiveness among spontaneously breathing critically-ill patients. J Crit Care. 2017; 41: p.130-137.doi: 10.1016/j.jcrc.2017.05.008 . | Open in Read by QxMD
  9. Yealy DM, Mohr NM, Shapiro NI, Venkatesh A, Jones AE, Self WH. Early Care of Adults With Suspected Sepsis in the Emergency Department and Out-of-Hospital Environment: A Consensus-Based Task Force Report. Ann Emerg Med. 2021; 78 (1): p.1-19.doi: 10.1016/j.annemergmed.2021.02.006 . | Open in Read by QxMD
  10. Prekker ME, Scott NL, Hart D, Sprenkle MD, Leatherman JW. Point-of-Care Ultrasound to Estimate Central Venous Pressure. Crit Care Med. 2013; 41 (3): p.833-841.doi: 10.1097/ccm.0b013e31827466b7 . | Open in Read by QxMD
  11. De Backer D, Fagnoul D. Intensive Care Ultrasound: VI. Fluid Responsiveness and Shock Assessment. Annals of the American Thoracic Society. 2014; 11 (1): p.129-136.doi: 10.1513/annalsats.201309-320ot . | Open in Read by QxMD
  12. American Institute of Ultrasound in Medicine. AIUM Practice Parameter for the Performance of Point‐of‐Care Ultrasound Examinations. Journal of Ultrasound in Medicine. 2019; 38 (4): p.833-849.doi: 10.1002/jum.14972 . | Open in Read by QxMD
  13. Gaskamp M, Blubaugh M, McCarthy LH, Scheid DC. Can Bedside Ultrasound Inferior Vena Cava Measurements Accurately Diagnose Congestive Heart Failure in the Emergency Department? A Clin-IQ.. J Patient Cent Res Rev. 2016; 3 (4): p.230-234.
  14. Rudski LG, Lai WW, Afilalo J, et al. Guidelines for the echocardiographic assessment of the right heart in adults: a report from the American Society of Echocardiography endorsed by the European Association of Echocardiography, a registered branch of the European Society of Cardiology, and the Canadian Society of Echocardiography.. J Am Soc Echocardiogr. 2010; 23 (7): p.685-713; quiz 786-8.doi: 10.1016/j.echo.2010.05.010 . | Open in Read by QxMD
  15. Ilyas A, Ishtiaq W, Assad S, et al. Correlation of IVC Diameter and Collapsibility Index With Central Venous Pressure in the Assessment of Intravascular Volume in Critically Ill Patients. Cureus. 2017.doi: 10.7759/cureus.1025 . | Open in Read by QxMD
  16. Yildizdas D, Aslan N. Ultrasonographic inferior vena cava collapsibility and distensibility indices for detecting the volume status of critically ill pediatric patients.. Journal of ultrasonography. 2020; 20 (82): p.e205-e209.doi: 10.15557/JoU.2020.0034 . | Open in Read by QxMD
  17. Via G, Tavazzi G, Price S. Ten situations where inferior vena cava ultrasound may fail to accurately predict fluid responsiveness: a physiologically based point of view. Intensive Care Med. 2016; 42 (7): p.1164-1167.doi: 10.1007/s00134-016-4357-9 . | Open in Read by QxMD
  18. American College of Emergency Physicians. Emergency ultrasound imaging criteria compendium. Ann Emerg Med. 2006; 48 (4): p.487-510.doi: 10.1016/j.annemergmed.2006.07.946 . | Open in Read by QxMD
  19. $Contributor Disclosures - Point-of-care ultrasound. None of the individuals in control of the content for this article reported relevant financial relationships with ineligible companies. For details, please review our full conflict of interest (COI) policy:.
  20. Dudley NJ, Gibson NM. A case study in scanner optimisation.. Ultrasound (Leeds, England). 2014; 22 (1): p.21-5.doi: 10.1177/1742271X13517231 . | Open in Read by QxMD
  21. Zander D, Hüske S, Hoffmann B, et al. Ultrasound Image Optimization ("Knobology"): B-Mode.. Ultrasound international open. 2020; 6 (1): p.E14-E24.doi: 10.1055/a-1223-1134 . | Open in Read by QxMD
  22. Amo Wiafe Y, Badu-Peprah A. The Influence of Ultrasound Equipment Knobology in Abdominal Sonography. IntechOpen ; 2019
  23. Carmody K, Moore C, Feller-Kopman D. Handbook of Critical Care and Emergency Ultrasound. McGraw Hill Professional ; 2011
  24. Saul T, Siadecki SD, Berkowitz R, Rose G, Matilsky D, Sauler A. M-Mode Ultrasound Applications for the Emergency Medicine Physician.. J Emerg Med. 2015; 49 (5): p.686-92.doi: 10.1016/j.jemermed.2015.06.059 . | Open in Read by QxMD
  25. Ng A, Swanevelder J. Resolution in ultrasound imaging. Continuing Education in Anaesthesia Critical Care & Pain. 2011; 11 (5): p.186-192.doi: 10.1093/bjaceaccp/mkr030 . | Open in Read by QxMD
  26. Szabo TL, Lewin PA. Ultrasound Transducer Selection in Clinical Imaging Practice. Journal of Ultrasound in Medicine. 2013; 32 (4): p.573-582.doi: 10.7863/jum.2013.32.4.573 . | Open in Read by QxMD
  27. American Institute of Ultrasound in Medicine, American College of Emergency Physicians. AIUM Practice Parameter for the Performance of the Focused Assessment with Sonography for Trauma (FAST) Examination.. J Ultrasound Med. 2014; 33 (11): p.2047-56.doi: 10.7863/ultra.33.11.2047 . | Open in Read by QxMD
  28. Bahner DP, Blickendorf JM, Bockbrader M, et al. Language of Transducer Manipulation. Journal of Ultrasound in Medicine. 2016; 35 (1): p.183-188.doi: 10.7863/ultra.15.02036 . | Open in Read by QxMD
  29. American Institute of Ultrasound in Medicine. Ultrasound Guidelines: Emergency, Point-of-Care and Clinical Ultrasound Guidelines in Medicine. Ann Emerg Med. 2017; 69 (5): p.e27-e54.doi: 10.1016/j.annemergmed.2016.08.457 . | Open in Read by QxMD
  30. Christie-Large M, Michaelides D, James S. Focused assessment with sonography for trauma: the FAST scan. Trauma. 2008; 10 (2): p.93-101.doi: 10.1177/1460408608090919 . | Open in Read by QxMD
  31. Kool DR, Blickman JG. Advanced Trauma Life Support®. ABCDE from a radiological point of view. Emerg Radiol. 2007; 14 (3): p.135-141.doi: 10.1007/s10140-007-0633-x . | Open in Read by QxMD
  32. Natarajan B, Gupta PK, Cemaj S, Sorensen M, Hatzoudis GI, Forse RA. FAST scan: Is it worth doing in hemodynamically stable blunt trauma patients?. Surgery. 2010; 148 (4): p.695-701.doi: 10.1016/j.surg.2010.07.032 . | Open in Read by QxMD
  33. Quinn AC, Sinert R. What is the utility of the Focused Assessment with Sonography in Trauma (FAST) exam in penetrating torso trauma?. Injury. 2011; 42 (5): p.482-7.doi: 10.1016/j.injury.2010.07.249 . | Open in Read by QxMD
  34. American College of Surgeons and the Committee on Trauma. ATLS Advanced Trauma Life Support. American College of Surgeons ; 2018
  35. Rubano E, Mehta N, Caputo W, Paladino L, Sinert R. Systematic Review: Emergency Department Bedside Ultrasonography for Diagnosing Suspected Abdominal Aortic Aneurysm. Academic Emergency Medicine. 2013; 20 (2): p.128-138.doi: 10.1111/acem.12080 . | Open in Read by QxMD
  36. American Institute of Ultrasound in Medicine. Practice Parameter for the Performance of Diagnostic and Screening Ultrasound Examinations of the Abdominal Aorta in Adults. Journal of Ultrasound in Medicine. 2021; 40 (5).doi: 10.1002/jum.15668 . | Open in Read by QxMD
  37. Palmer P. Manual of Diagnostic Ultrasound. World Health Organization ; 1995
  38. Matcuk GR, Grant EG, Ralls PW. Ultrasound Measurements of the Bile Ducts and Gallbladder. Ultrasound Q. 2014; 30 (1): p.41-48.doi: 10.1097/ruq.0b013e3182a80c98 . | Open in Read by QxMD
  39. Rossi P. Biliary Tract Radiology. Springer Science & Business Media ; 2012
  40. Kim M, Kang TW, Jang KM, et al. Tumefactive Gallbladder Sludge at US:Prevalence and Clinical Importance. Radiology. 2017; 283 (2): p.570-579.doi: 10.1148/radiol.2016161042 . | Open in Read by QxMD
  41. Shaffer EA. Gallbladder sludge: what is its clinical significance?. Curr Gastroenterol Rep. 2001; 3 (2): p.166-73.doi: 10.1007/s11894-001-0015-6 . | Open in Read by QxMD
  42. Bope ET, Kellerman RD. Conn's Current Therapy 2016. Elsevier Health Sciences ; 2015
  43. Yokoe M, Hata J, Takada T, et al. Tokyo Guidelines 2018: diagnostic criteria and severity grading of acute cholecystitis (with videos). Journal of Hepato-Biliary-Pancreatic Sciences. 2018; 25 (1): p.41-54.doi: 10.1002/jhbp.515 . | Open in Read by QxMD
  44. Smith EA, Dillman JR, Elsayes KM, Menias CO, Bude RO. Cross-Sectional Imaging of Acute and Chronic Gallbladder Inflammatory Disease. American Journal of Roentgenology. 2009; 192 (1): p.188-196.doi: 10.2214/ajr.07.3803 . | Open in Read by QxMD
  45. Bates DDB, LeBedis CA, Soto JA, Gupta A. Use of Magnetic Resonance in Pancreaticobiliary Emergencies. Magn Reson Imaging Clin N Am. 2016; 24 (2): p.433-448.doi: 10.1016/j.mric.2015.11.010 . | Open in Read by QxMD
  46. Walls R, Hockberger R, Gausche-Hill M. Rosen's Emergency Medicine. Elsevier Health Sciences ; 2018
  47. Rodgers SK, Chang C, DeBardeleben JT, Horrow MM. Normal and Abnormal US Findings in Early First-Trimester Pregnancy: Review of the Society of Radiologists in Ultrasound 2012 Consensus Panel Recommendations. RadioGraphics. 2015; 35 (7): p.2135-2148.doi: 10.1148/rg.2015150092 . | Open in Read by QxMD

Icon of a lockAccess full content

Sign up and get unlimited access.
 Evidence-based content, created and peer-reviewed by physicians. Read the disclaimer