Reflection
Ultrasound imaging is based on echoes of transmitted sound waves.

The more a structure reflects the sound waves, the whiter the structure appears on the screen.

An-, hypo- and hyperechoic
Some structures are great reflectors of ultrasound waves and appear bright white (hyperechoic) on the ultrasound screen.

Other structures reflect only little and appear hypoechoic (gray).

Air, fluid, blood all appear anechoic (black) which means there is no reflection at all.

The transducer has an orientation marker (OM).

The OM facilitates the correct orientation of the transducer when scanning the patient.

The OM has to be oriented correctly with the corresponding orientation indicator (OI) on the monitor.

When in doubt use the “finger-on-transducer” test explained in the video below – press the PLAY triangle to watch the video

The image is generated by the transducer and the ultrasound system and displayed on the screen.

The sector is demarcated by the two radii and the arc. In the illustration below, the two radii of the sector are red and green.

The red and the green radii diverge from the probe at the top of the monitor (the skin surface).

By convention, the orientation indicator (OI – blue dot on the screen) is on the left side of the screen in conventional clinical ultrasound applications (it is the opposite in cardiac ultrasound, where the OI is placed on the right side of the screen).

When orienting the orientation marker (OM – blue dot on the transducer) to the same side as the OI on the screen, the red radius of the ultrasound beam sector corresponds to the red radius of the ultrasound image sector, and the green radius corresponds to the green radius of the ultrasound image sector.

A shared terminology to describe the movement of the transducer during scanning is important in order to optimize the image.

During the workshop it makes it easier for the supervisor to give instructions without touching the transducer which is crucial for the novice in order to achieve practical skill.

There are many available descriptions of the method of manipulation of the transducer.

We recommend using:
1. rotate (right – clockwise, left – counterclockwise)
2. rock (in-plane motion away or toward the indicator)
3. tilt (angling the transducer – perpendicular to rocking)
– sweep (is tilting with a continuous fanning motion back and forth)
4. slide (moving the transducer on the skin)

As a novice you should only manipulate the transducer in one direction at a time.

A systematic approach will facilitate successful scanning:

Frequency
The frequency of a sound wave is equal to the number of wave tops per time unit.

The SI unit for frequency is Hertz (Hz) = wave tops pr second.

Ok, so that does not sound simple…

This is what you need to know:
The longer the distance the sound wave travels, the more energy is lost to absorption.

The ability of a sound wave to penetrate through tissue depends on the frequency of the sound wave – a lower frequency (lower number of wave tops) gives a better penetration.

On the other hand, a higher frequency (more wave tops) causes a higher resolution, but a lower penetration.

Three types of transducers are used in basic emergency ultrasound:

The presets relevant for basic emergency ultrasound are:

Imaging
Ultrasonography is an imaging method based on ultrasound.

Ultrasonography uses the impulse-echo principle of generating and emitting short pulses of ultrasound that are reflected at tissue interfaces and subsequently recorded by the receiver.

The reflected sound wave is essential for the production of the ultrasound images.