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Three-Dimensional Echocardiography: Image Acquisition


Introduction

In the modern echocardiography laboratory, three-dimensional transthoracic echocardiography (3D-TTE) complements the standard two-dimensional transthoracic echocardiographic (2D-TTE) examination. 3D-TTE adds value, improves workflow, and substantially improves accuracy in the quantification of cardiac chambers by avoiding errors inherent in the geometric assumptions made in 2D-TTE ( Figs. 10.1 and 10.2 , and ). 3D TTE provides a more accurate assessment of cardiac morphology and pathology, native and prosthetic valve structure and function, and guidance in interventional intracardiac procedures.

FIG. 10.1, Three-dimensional transthoracic echocardiography (3D-TTE) 3D-TTE employed in the assessment of LV volumes and ejection fraction (EF). 3D-TTE substantially improves the workflow and accuracy in the quantification of cardiac volumetric measures, and avoiding errors inherent in the geometric assumptions made in 2D-TTE, such as LV foreshortening. See also Video 10.1 . (See text and Box 10.1 .) EDV, End-diastolic volume; EF, ejection fraction (LV); ESV, end-systolic volume; SV, stroke volume.

FIG. 10.2, Three-dimensional transthoracic echocardiography (3D-TTE) delivers improved workflow in the modern echocardiography laboratory. Until recently, the 3D exam involved switching from the two-dimensional (2D) phased array transducer to a separate 3D matrix array transducer. However, newer 3D transducer designs facilitate simultaneous 2D and 3D image acquisition using a single probe. (See text and Boxes 10.2 and 10.3 .)

This chapter presents an overview of the basic 3D-TTE image acquisition and optimization techniques used in the echo lab. Optimal utilization of 3D-TTE requires an understanding of the clinical or research application ( Box 10.1 and Table 10.1 ). A comprehensive understanding of the clinical application helps determine the optimal 3D-TTE technique employed in image optimization, acquisition, rendering, display, and analysis ( Fig. 10.3 and , , , , ). The specific clinical applications of 3D-TTE employed in the assessment of cardiac structure and function are covered elsewhere in this book (see Chapter 5 ).

BOX 10.1
Clinical and Research Applications of Three-Dimensional Echocardiography

Clinical and Research Applications

  • Ventricular structure and function: LV, R:

    • Ventricular volumes

    • LV mass

    • LV Geometry/shape

    • LV dyssynchrony

    • Stress echocardiography

  • Atria volumes

  • Intracardiac shunts

  • Valvular structure and function:

  • Native valve anatomy

  • Native valve pathology

    • Mitral stenosis, regurgitation

    • Aortic stenosis, regurgitation

  • Prosthetic valves

  • Invasive procedures:

    • Transcatheter guidance procedures

    • Intracardiac biopsies

    • Ablation procedures in electrophysiology

TABLE 10.1
Examples of Choice of Three-Dimensional Transthoracic Echocardiography Acquisition Mode in the Echo Lab
Clinical Application Mode
Ventricular volumes (LV, RV)
Atrial volumes
Ejection fraction
Whole heart		 Full volume (wide-angle, multibeat)
Valve anatomy
Valvular pathology
Shunt lesions
Small structures visualized within narrow sector		 Live 3D zoom (color)
Guidance for transcatheter procedures Live 3D zoom (color)
Native heart biopsies
Electrophysiology ablations		 Live 3D
LV, Left ventricle; RV, right ventricle; 3D, Three-dimensional.

FIG. 10.3, Optimizing the three-dimensional (3D) transthoracic echocardiography imaging involves a series of techniques, including optimization of the two-dimensional image, acquisition of the 3D image based on the clinical question, rendering the image, finalizing the image display, and postprocessing analysis. See also Video 10.2 , Video 10.3 , Video 10.4 , Video 10.5 , Video 10.6 . (See text and Box 10.2 .)

The Three-Dimensional Transthoracic Echocardiography Data Acquisition Protocol

The optimization of both patient and machine preparation for 3D-TTE, consistent with the 2D-TTE examination, is important (see Chapter 11 ). Electrocardiography (ECG) gating is critical for 3D trigger-mode imaging. Therefore it is important to obtain a good ECG signal with clearly visible R-waves. Until recently, the 3D-TTE exam required switching from the standard 2D phased array transducer to a 3D matrix array transducer. Today, the most recent 3D “all-in-one” transducer designs facilitate simultaneous 2D and 3D image acquisition using a single probe. This improves workflow efficiency (see Fig. 10.2 ). The following steps are generally required during 3D-TTE image acquisition ( Box 10.2 ; see also Fig. 10.3 and , , , , ).

  • 1.

    2D image optimization

  • 2.

    Acquisition modes

    • Narrow volume vs. wide (full) volume

    • Single-beat vs. multibeat

    • 3D zoom

    • 3D color

  • 3.

    Rendering

  • 4.

    Final image display and analysis

BOX 10.2
Typical Workflow in Three-Dimensional Transthoracic Echocardiography

  • 1.

    Optimize the two-dimensional (2D) images, including imaging depth, sector size

  • 2.

    Use lower-frequency transducer to improve penetration

  • 3.

    Apply tissue harmonic imaging

  • 4.

    Apply automated gain optimization

  • 5.

    Increase overall gain compensation, usually by more than 50% (55–60 units)

  • 6.

    Ensure that the region of interest is fully within the scan sector by using multiplane scanning

  • 7.

    Apply three-dimensional (3D) zoom

  • 8.

    Optimize box size and position; make sure the region of interest is within the box size range

  • 9.

    Activate 3D zoom

  • 10.

    For 3D color zoom, add the color over the selected anatomic area of interest

  • 11.

    Ensure that the color box occupies the entire selected area

  • 12.

    Remember the trade-off between image acquisition and frame rate: the larger the area, the larger the volume, the lower the frame rate.

  • 13.

    If necessary, acquire six-beat electrocardiography data set for higher color frame rates.

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