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Figure 4.9. Sliding. The probe is moved across the body in the longitudinal axis of the patient, and the angle of insonation in relation to the patient's body is not changed.
Source: Illustration courtesy of Randi Taggart, Richmond, VA.
Pearl: Rocking, fanning, and rotating are on the same fixed external point on the patient; however, the angle of insonation is changed with rocking and fanning (but not rotating).
Sliding (Figure 4.9)
During sliding, the angle of insonation in relation to the patient's body is not changed as the probe is moved across the body in the longitudinal axis of the patient (Bahner et al. 2016).
Pearl: Gradual increase in probe pressure is much better tolerated by the patient than a quick stabbing motion.
Pearl: Excessive pressure can push or move the area of interest out of view.
Pearl: There are three major reasons to use probe pressure knowing that your patient may not like the maneuver: reduce contact and air‐trapping artifact, push structures out of the way, such as gas‐filled small intestine, and gain more depth by moving the transducer closer to the area of interest.
Sweeping (Figure 4.10)
Like sliding, during sweeping the angle of insonation in relation to the patient’s body is not changed as the probe is moved in the transverse axis of the patient (Bahner et al. 2016).
Pressure/Compression (Figure 4.11)
During pressure/compression, the probe is pressed or pushed into the body, causing compression of body tissues. The pressure/compression maneuver may help to reduce contact and air‐trapping artifact, push structures out of the way, such as gas‐filled small intestine, and gain more depth by moving the transducer closer to the area of interest. Uncontrolled pressure may result in moving the intended target (area of interest) out of the field of view. This effect commonly occurs with the feline spleen and kidney and at the AFAST spleno‐renal (SR) view.
Figure 4.10. Sweeping. The probe is moved across the body in the transverse axis of the patient, and the angle of insonation in relation to the patient’s body is not changed.
Source: Illustration courtesy of Randi Taggart, Richmond, VA.
Figure 4.11. Pressure/Compression. Neither the probe position on the body nor its angle of insonation is changed. Rather, the probe is pushed into the body, compressing the underlying tissues.
Source: Illustration courtesy of Randi Taggart, Richmond, VA.
Cardiac Orientation
See Chapters 17–21 for detailed information on cardiac orientation.
Pearl: For the POCUS and FAST ultrasound scans, begin with an intermediate setting of 8 MHz as a general rule of thumb. That being said, most chapters in this textbook provide probe frequency recommendations.
Image Optimization: Using the “Big 4” Knobs of Depth, Gain, Frequency, and Focus
For an ultrasound image to have meaning, it must have adequate detail. The best rule of thumb is that the image should simply look “nice.” This idea may be a little different from one person to another but they should all be relatively similar. Always keep in mind the angle of insonation. The ideal angle of ultrasound reflection for generating the best image is 90° on the surface of the organ of interest (see Figure 4.5). In fact, this is why linear probes, while not used by most small animal practitioners, provide superior detail when compared to curvilinear probes, which are more commonly used among small animal practitioners.
Although there are numerous buttons and knobs on the ultrasound machine that can be used to improve, or worsen, the image, the “Big 4” are depth, gain, frequency, and focus position and number. See also Chapter 5 for additional examples.
Pearl: Know the “Big 4” knobs: depth, gain, frequency, and focus position and number.
Depth
When reviewing a radiograph, the clinician can become narrow‐sighted by focusing on one area and not looking at the rest of the film. With ultrasound, however, the goal is to focus on one area. Adjust the depth to the area of interest. Filling up the screen with the area of interest will result in a better diagnostic ultrasound image and this strategy is used for detailed parenchymal assessment. However, during AFAST and TFAST target organs are usually reduced to 25–33% of the screen, depending on the target organ and the respective view.
Every sonographer performing ultrasound has a responsibility to know where the ultrasound scale is located; usually values are in centimeters and are displayed along the side of the machine's screen. The awareness of depth within the image is often overlooked by beginning sonographers. However, recognizing depth is of the utmost importance because what looks large on ultrasound may in fact be small. Attention to the centimeter scale on the screen also allows for eyeballing not only the depth but also the dimensions of structures in view.
Gain
Gain is the overall brightness of the image. The ideal is not too bright and not too dark. The gain knob is the one that will adjust the overall gain setting. After first setting the overall gain, minimize dark or light bands across the screen by using the time gain compensation (TGC) knobs. These are usually sliders that adjust brightness along discrete bands across the image, although some machines have reduced the numbers of sliders to near‐ and far‐field. The goal is to have a consistent brightness from top to bottom of the screen, in other words, gain extending through the far‐field.
Frequency
Find a happy medium between penetration and resolution. Use the highest frequency (MHz) possible yet still see as deeply as needed. The smaller the patient, the higher the frequency and the larger the patient, the lower the frequency. High MHz
