THREE-DIMENSIONAL CARDIAC STRAIN IMAGING IN HEALTHY CHILDREN USING RF-DATA

Richard G. P. Lopata; Maartje M. Nillesen; Johan M. Thijssen; Livia Kapusta; Chris L. de Korte

doi:10.1016/j.ultrasmedbio.2011.05.845

THREE-DIMENSIONAL CARDIAC STRAIN IMAGING IN HEALTHY CHILDREN USING RF-DATA

Richard G. P. Lopata^*, Maartje M. Nillesen, Johan M. Thijssen, Livia Kapusta, Chris L. de Korte

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

In this study, a new radio-frequency (RF)-based, three-dimensional (3-D) strain imaging technique is introduced and applied to 3-D full volume ultrasound data of the heart of healthy children. Continuing advances in performance of transducers for 3-D ultrasound imaging have boosted research on 3-D strain imaging. In general, speckle tracking techniques are used for strain imaging. RF-based strain imaging has the potential to yield better performance than speckle- based methods because of the availability of phase information but such a system output is commercially not available. Furthermore, the relatively low frame rate of 3-D ultrasound data has limited broad application of RF-based cardiac strain imaging. In this study, the previously reported two-dimensional (2-D) strain methodology was extended to the third dimension. Three-dimensional RF-data were acquired in 13 healthy children, in the age range of 6-15 years, at a relatively low frame rate of 38-51 Hz. A 3-D, free-shape, coarse-to-fine displacement and strain estimation algorithm was applied to the RF-data. The heart was segmented using 3-D ellipsoid fitting. Strain was estimated in the radial (R), circumferential (C) and longitudinal directions (L). Our preliminary results reveal the applicability of the 3-D strain estimation technique on full volume 3-D RF-data. The technique enabled 3-D strain imaging of all three strain components. The average strains for all children were in the lateral wall R = 37 ? 10% (infero-lateral) and R = 32% ? 10% (antero-lateral), C = -9% ? 4% (antero-lateral) and C = -9% ? 4% (infero-lateral), L = -18% ? 6 % (antero-lateral) and L = -15% ? 4% (infero-lateral). In the septum, strains were found to be R = 24% ? 10% (antero-septal) and R = 13% ? 5% (infero-septal), C = -13% ? 5% (antero-septal) and -13% ? 5% (infero-septal) and L = -13% ? 3% (antero-septal) and L = -16% ? 5% (infero-septal). Strain in the anterior and inferior walls seemed underestimated, probably caused by the low (in-plane) resolution and poor image quality. The field-of-view as well as image quality were not always sufficient to image the entire left ventricle. It is concluded that 3-D strain imaging using RF-data is feasible, but validation with other modalities and with conventional 3-D speckle tracking techniques will be necessary. World Federation for Ultrasound in Medicine & Biology.

Original language	English
Pages (from-to)	1399-1408
Journal	Ultrasound in Medicine and Biology
Volume	37
Issue number	9
DOIs	https://doi.org/10.1016/j.ultrasmedbio.2011.05.845
Publication status	Published - Sept 2011

Keywords

Ultrasound
3-D strain estimation
Elastography
In vivo
Children
Cardiac strain
Echocardiography

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10.1016/j.ultrasmedbio.2011.05.845

Cite this

@article{f4fdfcf2f593434f8eb3746e0912a17e,

title = "THREE-DIMENSIONAL CARDIAC STRAIN IMAGING IN HEALTHY CHILDREN USING RF-DATA",

abstract = "In this study, a new radio-frequency (RF)-based, three-dimensional (3-D) strain imaging technique is introduced and applied to 3-D full volume ultrasound data of the heart of healthy children. Continuing advances in performance of transducers for 3-D ultrasound imaging have boosted research on 3-D strain imaging. In general, speckle tracking techniques are used for strain imaging. RF-based strain imaging has the potential to yield better performance than speckle- based methods because of the availability of phase information but such a system output is commercially not available. Furthermore, the relatively low frame rate of 3-D ultrasound data has limited broad application of RF-based cardiac strain imaging. In this study, the previously reported two-dimensional (2-D) strain methodology was extended to the third dimension. Three-dimensional RF-data were acquired in 13 healthy children, in the age range of 6-15 years, at a relatively low frame rate of 38-51 Hz. A 3-D, free-shape, coarse-to-fine displacement and strain estimation algorithm was applied to the RF-data. The heart was segmented using 3-D ellipsoid fitting. Strain was estimated in the radial (R), circumferential (C) and longitudinal directions (L). Our preliminary results reveal the applicability of the 3-D strain estimation technique on full volume 3-D RF-data. The technique enabled 3-D strain imaging of all three strain components. The average strains for all children were in the lateral wall R = 37 ? 10% (infero-lateral) and R = 32% ? 10% (antero-lateral), C = -9% ? 4% (antero-lateral) and C = -9% ? 4% (infero-lateral), L = -18% ? 6 % (antero-lateral) and L = -15% ? 4% (infero-lateral). In the septum, strains were found to be R = 24% ? 10% (antero-septal) and R = 13% ? 5% (infero-septal), C = -13% ? 5% (antero-septal) and -13% ? 5% (infero-septal) and L = -13% ? 3% (antero-septal) and L = -16% ? 5% (infero-septal). Strain in the anterior and inferior walls seemed underestimated, probably caused by the low (in-plane) resolution and poor image quality. The field-of-view as well as image quality were not always sufficient to image the entire left ventricle. It is concluded that 3-D strain imaging using RF-data is feasible, but validation with other modalities and with conventional 3-D speckle tracking techniques will be necessary. World Federation for Ultrasound in Medicine & Biology.",

keywords = "Ultrasound, 3-D strain estimation, Elastography, In vivo, Children, Cardiac strain, Echocardiography",

author = "Lopata, {Richard G. P.} and Nillesen, {Maartje M.} and Thijssen, {Johan M.} and Livia Kapusta and {de Korte}, {Chris L.}",

year = "2011",

month = sep,

doi = "10.1016/j.ultrasmedbio.2011.05.845",

language = "English",

volume = "37",

pages = "1399--1408",

journal = "Ultrasound in Medicine and Biology",

issn = "0301-5629",

publisher = "Elsevier Science",

number = "9",

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TY - JOUR

T1 - THREE-DIMENSIONAL CARDIAC STRAIN IMAGING IN HEALTHY CHILDREN USING RF-DATA

AU - Lopata, Richard G. P.

AU - Nillesen, Maartje M.

AU - Thijssen, Johan M.

AU - Kapusta, Livia

AU - de Korte, Chris L.

PY - 2011/9

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N2 - In this study, a new radio-frequency (RF)-based, three-dimensional (3-D) strain imaging technique is introduced and applied to 3-D full volume ultrasound data of the heart of healthy children. Continuing advances in performance of transducers for 3-D ultrasound imaging have boosted research on 3-D strain imaging. In general, speckle tracking techniques are used for strain imaging. RF-based strain imaging has the potential to yield better performance than speckle- based methods because of the availability of phase information but such a system output is commercially not available. Furthermore, the relatively low frame rate of 3-D ultrasound data has limited broad application of RF-based cardiac strain imaging. In this study, the previously reported two-dimensional (2-D) strain methodology was extended to the third dimension. Three-dimensional RF-data were acquired in 13 healthy children, in the age range of 6-15 years, at a relatively low frame rate of 38-51 Hz. A 3-D, free-shape, coarse-to-fine displacement and strain estimation algorithm was applied to the RF-data. The heart was segmented using 3-D ellipsoid fitting. Strain was estimated in the radial (R), circumferential (C) and longitudinal directions (L). Our preliminary results reveal the applicability of the 3-D strain estimation technique on full volume 3-D RF-data. The technique enabled 3-D strain imaging of all three strain components. The average strains for all children were in the lateral wall R = 37 ? 10% (infero-lateral) and R = 32% ? 10% (antero-lateral), C = -9% ? 4% (antero-lateral) and C = -9% ? 4% (infero-lateral), L = -18% ? 6 % (antero-lateral) and L = -15% ? 4% (infero-lateral). In the septum, strains were found to be R = 24% ? 10% (antero-septal) and R = 13% ? 5% (infero-septal), C = -13% ? 5% (antero-septal) and -13% ? 5% (infero-septal) and L = -13% ? 3% (antero-septal) and L = -16% ? 5% (infero-septal). Strain in the anterior and inferior walls seemed underestimated, probably caused by the low (in-plane) resolution and poor image quality. The field-of-view as well as image quality were not always sufficient to image the entire left ventricle. It is concluded that 3-D strain imaging using RF-data is feasible, but validation with other modalities and with conventional 3-D speckle tracking techniques will be necessary. World Federation for Ultrasound in Medicine & Biology.

AB - In this study, a new radio-frequency (RF)-based, three-dimensional (3-D) strain imaging technique is introduced and applied to 3-D full volume ultrasound data of the heart of healthy children. Continuing advances in performance of transducers for 3-D ultrasound imaging have boosted research on 3-D strain imaging. In general, speckle tracking techniques are used for strain imaging. RF-based strain imaging has the potential to yield better performance than speckle- based methods because of the availability of phase information but such a system output is commercially not available. Furthermore, the relatively low frame rate of 3-D ultrasound data has limited broad application of RF-based cardiac strain imaging. In this study, the previously reported two-dimensional (2-D) strain methodology was extended to the third dimension. Three-dimensional RF-data were acquired in 13 healthy children, in the age range of 6-15 years, at a relatively low frame rate of 38-51 Hz. A 3-D, free-shape, coarse-to-fine displacement and strain estimation algorithm was applied to the RF-data. The heart was segmented using 3-D ellipsoid fitting. Strain was estimated in the radial (R), circumferential (C) and longitudinal directions (L). Our preliminary results reveal the applicability of the 3-D strain estimation technique on full volume 3-D RF-data. The technique enabled 3-D strain imaging of all three strain components. The average strains for all children were in the lateral wall R = 37 ? 10% (infero-lateral) and R = 32% ? 10% (antero-lateral), C = -9% ? 4% (antero-lateral) and C = -9% ? 4% (infero-lateral), L = -18% ? 6 % (antero-lateral) and L = -15% ? 4% (infero-lateral). In the septum, strains were found to be R = 24% ? 10% (antero-septal) and R = 13% ? 5% (infero-septal), C = -13% ? 5% (antero-septal) and -13% ? 5% (infero-septal) and L = -13% ? 3% (antero-septal) and L = -16% ? 5% (infero-septal). Strain in the anterior and inferior walls seemed underestimated, probably caused by the low (in-plane) resolution and poor image quality. The field-of-view as well as image quality were not always sufficient to image the entire left ventricle. It is concluded that 3-D strain imaging using RF-data is feasible, but validation with other modalities and with conventional 3-D speckle tracking techniques will be necessary. World Federation for Ultrasound in Medicine & Biology.

KW - Ultrasound

KW - 3-D strain estimation

KW - Elastography

KW - In vivo

KW - Children

KW - Cardiac strain

KW - Echocardiography

U2 - 10.1016/j.ultrasmedbio.2011.05.845

DO - 10.1016/j.ultrasmedbio.2011.05.845

M3 - Article

C2 - 21767901

SN - 0301-5629

VL - 37

SP - 1399

EP - 1408

JO - Ultrasound in Medicine and Biology

JF - Ultrasound in Medicine and Biology

IS - 9

ER -