Transmission
When the sound wave propagates in a medium without striking any interfaces, it passes through the interface without any reflection, scattering or refraction (change of sound wave
Transmission and penetration
The ultrasound transducer
Transducer characteristics, such as frequency and shape of the probe, determine ultrasound image quality
4 tranducers are used in clinical ultrasound
– Linear probes
– Curved array probes (abdominal)
– Microconvex array transducers
– Phased array transducers (cardiac)
Linear probes have frequencies in the range 8-20 MHz provide excellent 2D images, but have limited penetration due to their high frequency
Curved array probes (abdominal) with frequencies between 2-5 MHz produce adequate 2D images and permit deep penetration
Phased array transducers (cardiac) are optimised for scanning between ribs and penetrate deeply

XX Biological effect and possible damage
To date there have been no indications that the clinical use of ultrasound can compromise health
Ultrasound waves with an energy value below 100 W/cm2 do not cause significant tissue warming
100 W/cm2 is a limit that is not usually transcended in routine B-mode diagnostic ultrasound
Some of the effects of ultrasound that have been shown under laboratory conditions, such as the disruption of cell membranes, cavitation and formation of free radicals have not been demonstrated in the human body
To our knowledge, diagnostic ultrasound does not represent a risk factor for tissue damage

Equipment and skills
A basic understanding of the user controls in the ultrasound system is required to learn ultrasound
Before you start clinical ultrasound scanning it is important to become familiar with the probe (or transducer) and the user interface of the ultrasound system
In this lesson you will learn about the probe and the most important user control buttons allowing you to optimize the ultrasound image quality

Preparation of the ultrasound (US) system
Correct preparation of the ultrasound system will facilitate US examination and US guided procedures
– Ensure power supply for the procedure – either by connecting to network voltage or sufficient battery capacity
– Turn on the ultrasound system
– Choose the right “program” for the procedure (e.g. cardiac, nerve etc)
– Adjust the depth setting in order to align the target to the center of the monitor
– Adjust the gain setting
– Set the focus point

Reflection
Ultrasound imaging is based on the reflection of sound, which are detectable echoes of the transmitted pulse
Reflection is a result of acoustic impedance mismatch
Reflection attenuates the sound wave reducing transmission beyond the reflecting interface. Reflected sound waves are synonymous to echoes – Reflection can be specular or diffuse
Specular reflection happens when the sound wave strikes a smooth surface (a specular reflector). In that case, the angle of incidence equals the angle of reflection
Diffuse (non-specular) reflection scatters the sound in multiple random directions. Diffusion occurs when the sound wave strikes small and irregular objects like red blood cells or interfaces in the tissue
In a completely homogeneous medium or tissue no reflection is made, and therefore no echoes are produced

What is ultrasound ?
Ultrasound is defined as sound with frequencies above the upper limit of the human hearing range of 20 kHz and up to 10 GHz
Its primary clinical application today is as a diagnostic tool and as a means to display anatomical structures, for which frequencies between 1 and 20 MHz are most commonly used

Waves
A sound wave is a mechanical wave
Mechanical waves require a medium in order to transport their energy from one location to another
They cannot propagate in vacuum
Mechanical waves can be longitudinal or transverse
A sound wave is a longitudinal wave
In a longitudinal wave the oscillating disturbance is parallel to the direction of travel
Sound waves are always longitudinal waves: The air molecules vibrate in the same direction as the sound wave travels and form a series of compressions (high pressure) and rarefactions (low pressure), where the molecules are squeezed together and pulled apart respectively

Sound wave characteristics
Waves can be described mathematically with a location-amplitude-coordinate system and a time-amplitude-coordinate system with a sinus curve
The basic parameters of a harmonic wave are:
Course objectives
The course provides an introduction to ultrasound
- lung ultrasound
- aortic ultrasound
- abdominal ultrasound (FAST protocol)
- focused cardiac ultrasound (FATE protocol)
- ultrasound-guided vascular access
The theory provided is a prerequisite for effective practical training in the hands-on workshops

