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organ approach, TFAST through echo views and volume status, and Vet BLUE through a regional, pattern‐based approach. Courtesy of Dr Gregory Lisciandro, Hill Country Veterinary Specialists and FASTVet.com, Spicewood, TX.

       Other Terms

      We have done our best to make this second edition uniform in terminology and up to date with the current consensus in both human and veterinary medicine. Some examples in which multiple terms relating to similar things are used are listed here.

      The preferred term is listed first but each may be considered synonymously.

       POCUS exam and Focused exam

       sonographer and ultrasonographer

       ultrasonographically and sonographically

       color Doppler and color flow Doppler

       beam and scanning plane

       acoustic window and view

       fanning and tilting

       longitudinal and sagittal (and long axis)

       transverse (and short axis)

       orientation and plane

       probe and transducer

       curvilinear probe and microconvex probe

       B‐lines and ultrasound lung rockets

       lung sliding and glide sign

       gallbladder halo sign, gallbladder halo effect, and gallbladder double rim effect

       FAST diaphragmatico‐hepatic view and subxiphoid view

       acoustic coupling and probe–skin contact

      We have provided a comprehensive list of abbreviations, terms, and definitions in the Appendices.

Recording Your Findings on Goal‐directed Templates

      Recording data on goal‐directed templates with clear objectives for answering defined clinical questions is imperative to gain the respect of our colleagues, to stay disciplined during the respective POCUS or FAST examination, to allow post hoc evaluation of studies, and to detect training strengths and deficiencies. Without recording your data, you cannot measure. If you cannot measure, you cannot critically study with the potential to improve. We have made great strides in Global FAST training by reevaluating our results recorded on goal‐directed templates and saved video clips. A prime example is the establishment of clear tenets for the accurate TFAST diagnosis of pericardial effusion (Lisciandro 2016).

      We have presented POCUS and FAST goal‐directed templates and methods to efficiently save video clips for you to adapt and modify for your practice according to the types of cases you see, your practice type, and your skill level in the Appendices and Chapter 45.

Echogenicity – Whites, Grays, and Blacks

The jargon of ultrasound can be intimidating to the novice sonographer. Clarity may be accomplished through acknowledging that ultrasound is generally the opposite of how free fluid, air, and soft tissue appear on radiographic studies (our brain needs to reformat itself). For example and very simplistically, air is white on ultrasound and black on radiographs. Fluid is black on ultrasound and white on radiographs. However, bone is black (shadows) on ultrasound? And white on radiographs? Or white along its proximal surface with acoustic shadowing through the far field. Now if we are losing you, hang in there. The figures help (Figures 1.2, 1.3, 1.4, 1.5). Study them now.

The ultrasound terms describing whites, grays, and blacks are anechoic (black), degrees of echogenicity (hypoechoic, shades of gray), and hyperechoic (white). The terms may be used relatively between structures like “X relative to Y” and “Y relative to Z.” For example, the spleen is hyperechoic (brighter than) to the left kidney. The liver is hypoechoic (darker than) to the falciform fat. The feline cortex of the kidney is isoechoic (same as) to the spleen (see Figure 1.3).

Figure 1.2. The figure shows the ultrasound differences in B‐mode gray scale of various tissues, with bone, stone and air being most reflective of the ultrasound beam and thus portrayed as white along its surface, to soft tissues being shades of gray, to fluid which is black. Ultrasound terminology corresponds to these gray‐scale colors as hyperechoic, degrees of echogenicity (hypoechoic), and anechoic. Study this chart to get the visual of what these gray‐scale terms mean. Courtesy of Dr Gregory Lisciandro, Hill Country Veterinary Specialists and FASTVet.com, Spicewood, TX.

Figure 1.3. This figure is similar to Figure 1.2 but with some of the gray scale removed to illustrate how descriptive ultrasound terminology is used for different tissues. The soft tissue is isoechoic (same as), hyperechoic (brighter than), and hypoechoic (darker than) relative to one another. Correlate with Table 1.1 Courtesy of Dr Gregory Lisciandro, Hill Country Veterinary Specialists and FASTVet.com, Spicewood, TX.

Figure 1.4. This figure is unlabeled and labeled for contrast of what tissue looks like in a gravid female, illustrating the different tissues and structures that correlate with concepts in Figures 1.1 and 1.2. Image used with permission from E.I. Medical, Loveland, CO, USA. www.eimedical.com

Figure 1.5. Ultrasound and different tissues and elements. Schematic that ties into the previous images showing various elements and the general behavior of ultrasound and its associated artifacts. The arrows represent the ultrasound beam being transmitted and returned to the transducer (probe). In (A) and (B), bone, stone, and air reflect because ultrasound (its echoes) does not transmit through them. As a result, they create shadowing of the beam, resulting in (A) “clean shadowing” (anechoic or black past the surface of the structure or element) or (B) “dirty shadowing,” including air reverberation called A‐lines (hyperechoic horizontal bars past the air). Soft tissues will absorb the ultrasound in different degrees depending on the soft tissue, thus (C) shows different degrees of echogenicity. Lastly, fluid will not absorb much of the ultrasound (echoes pass through the fluid), resulting in (D) acoustic enhancement through the far‐field beyond the distal boundary of fluid, making tissues more hyperechoic (brighter) than their adjacent counterparts outside the fluid‐related beam. Courtesy

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