<i>In vivo</i> Nakagami‐<i>m</i> parametric imaging of microbubble‐enhanced ultrasound regulated by RF and VF processing techniques

Wang, Diya; Liu, Dong; Sang, Yuchao; Wan, Mingxi; Diederich, Chris J.

doi:10.1002/mp.14474

Cited by 5 publications

(18 citation statements)

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“…Figure 1 shows the flow chart of logarithmic m ‐coding DCEUS scheme in the focused acoustic field, which is based on our previous m ‐coding contrast‐enhanced ultrasound studies 18,21 . Considering the different advantages of ME and WMCME methods, 18 we also investigated the performances of the assumed scheme using the ME and WMCME methods to overcome the limitations of DCEUS in the focused acoustic field.…”

Section: Methods and Experimentsmentioning

confidence: 99%

“…Under a focal depth of 2 cm, in vivo perfusion experiments ( n = 4 × 66 – 72 frames before pulse‐inversion summation) in the kidneys of four healthy rabbits were performed on DC‐6 platform (Mindray Inc., Shenzhen, China) equipped with a convex array scanner (emitted pulse frequency of 3.0 MHz). Part of in vivo data was from our previous study 18 . After the rabbit was anesthetized, 0.2 ml bolus of SonoVue dilution with a concentration of 2 × 10 8 MBs/ml was intravenously injected.…”

Section: Methods and Experimentsmentioning

confidence: 99%

“…The shape parameter m in the Nakagami model can characterize wide‐ranging scattering distributions of Rayleigh, pre‐, and post‐Rayleigh 16 . m parameter was formerly utilized to analyze radar signals and was first used to gather statistics of ultrasonic linear backscattered‐echoes from tissues by Shankar et al., 17 thereby predicting the in vitro vascular flow marked by nonlinear backscattered‐echoes from MBs by Tsui et al., 7 and characterize in vivo m ‐coding contrast‐enhanced ultrasound by Wang et al 18 …”

Section: Introductionmentioning

confidence: 99%

“…Moreover, the tissue speckles inevitably affect the m estimation of MB backscattered‐echoes in in vivo experiments because their Nakagami distributions overlap in large proportions 18 . Accordingly, we have previously used PIHI to suppress the tissue artifacts and investigate the regulation mechanism and impact of pulse‐inversion, harmonic filtering, and logarithmic transformation during PIHI implementation on the raw envelopes of MB backscattered‐echoes and their m estimation 18 . Compared with the moment‐estimator (ME) method, the window‐modulated compounding ME (WMCME) strategy could improve the estimation accuracy and ensure the estimation stability and robustness of m , respectively 18 .…”

Section: Introductionmentioning

confidence: 99%

“…Accordingly, we have previously used PIHI to suppress the tissue artifacts and investigate the regulation mechanism and impact of pulse‐inversion, harmonic filtering, and logarithmic transformation during PIHI implementation on the raw envelopes of MB backscattered‐echoes and their m estimation 18 . Compared with the moment‐estimator (ME) method, the window‐modulated compounding ME (WMCME) strategy could improve the estimation accuracy and ensure the estimation stability and robustness of m , respectively 18 . Nevertheless, the ME method has the best computational efficiency 18 …”

Section: Introductionmentioning

confidence: 99%

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Feasibility investigation of logarithmic Nakagami parametric imaging in recovering underestimated perfusion metrics of DCEUS in the uneven acoustic field

Wang

et al. 2022

Medical Physics

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Owing to acoustic-pressure dependence, amplitudes of backscattered-echoes of encapsulated microbubbles (MBs) are unavoidably regulated by an uneven acoustic field, resulting in the misestimation of hemodynamics in conventional amplitude-coding dynamic contrast-enhanced ultrasound (DCEUS) with focused pulse transmission. This study aimed to investigate the feasibility and performance of Nakagami statistical-feature parametric imaging to recover the above misestimation. Methods: Logarithmic Nakagami parameter (m)-coding DCEUS scheme was investigated via simulation and in vitro MB phantoms as well as in vivo kidneyperfusion experiments of four rabbits in the uneven acoustic fields with two different focal depths. In vivo tissue artifacts for m estimation were suppressed by pulse-inversion second-harmonic imaging and its robustness was enhanced by multiscale moment-estimation strategy. Time-Nakagami-m curves and the corresponding perfusion metrics of intensity and volume were calculated from the logarithmic m-coding DCEUS images within the prefocal and focal regions. These curves and metrics were further compared with the perfusion curves and metrics estimated from the conventional amplitude-coding images within the same regions. Results: Compared with amplitudes of nonlinear scattering MB echoes, their logarithmic m values were relatively independent of the changes in acoustics pressures. Compared with the fixed-scale moment-estimation, the perfusion intensity estimated from logarithmic m-coding DCEUS scheme using multiscale statistical moment-estimation had smaller differences between the prefocal and focal regions. The differences of perfusion intensity induced by an uneven acoustic field decreased to 3.47% ± 1.58 %. The differences decreased by the logarithmic m-coding DCEUS scheme were further regulated by threshold values of m estimation. Conclusions:The logarithmic m-coding DCEUS scheme could recover the underestimated MB backscattered-echoes and the misestimated perfusion intensity induced by the uneven acoustic field. The scheme had the potential to weaken the limitation of microvasculature identification and hemodynamic characterization marked by MBs within tissues or tumors in the uneven acoustic field. K E Y W O R D Scontrast-enhanced ultrasound, focused acoustic field, hemodynamic, Nakagami parameter 2452

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Section: Methods and Experimentsmentioning

confidence: 99%

Section: Methods and Experimentsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Feasibility investigation of logarithmic Nakagami parametric imaging in recovering underestimated perfusion metrics of DCEUS in the uneven acoustic field

Wang

et al. 2022

Medical Physics

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Classification of multi‐feature fusion ultrasound images of breast tumor within category 4 using convolutional neural networks

Xu,

Zhao,

Wan

et al. 2024

Medical Physics

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BackgroundBreast tumor is a fatal threat to the health of women. Ultrasound (US) is a common and economical method for the diagnosis of breast cancer. Breast imaging reporting and data system (BI‐RADS) category 4 has the highest false‐positive value of about 30% among five categories. The classification task in BI‐RADS category 4 is challenging and has not been fully studied.PurposeThis work aimed to use convolutional neural networks (CNNs) for breast tumor classification using B‐mode images in category 4 to overcome the dependence on operator and artifacts. Additionally, this work intends to take full advantage of morphological and textural features in breast tumor US images to improve classification accuracy.MethodsFirst, original US images coming directly from the hospital were cropped and resized. In 1385 B‐mode US BI‐RADS category 4 images, the biopsy eliminated 503 samples of benign tumor and left 882 of malignant. Then, K‐means clustering algorithm and entropy of sliding windows of US images were conducted. Considering the diversity of different characteristic information of malignant and benign represented by original B‐mode images, K‐means clustering images and entropy images, they are fused in a three‐channel form multi‐feature fusion images dataset. The training, validation, and test sets are 969, 277, and 139. With transfer learning, 11 CNN models including DenseNet and ResNet were investigated. Finally, by comparing accuracy, precision, recall, F1‐score, and area under curve (AUC) of the results, models which had better performance were selected. The normality of data was assessed by Shapiro‐Wilk test. DeLong test and independent t‐test were used to evaluate the significant difference of AUC and other values. False discovery rate was utilized to ultimately evaluate the advantages of CNN with highest evaluation metrics. In addition, the study of anti‐log compression was conducted but no improvement has shown in CNNs classification results.ResultsWith multi‐feature fusion images, DenseNet121 has highest accuracy of 80.22 ± 1.45% compared to other CNNs, precision of 77.97 ± 2.89% and AUC of 0.82 ± 0.01. Multi‐feature fusion improved accuracy of DenseNet121 by 1.87% from classification of original B‐mode images (p < 0.05).ConclusionThe CNNs with multi‐feature fusion show a good potential of reducing the false‐positive rate within category 4. The work illustrated that CNNs and fusion images have the potential to reduce false‐positive rate in breast tumor within US BI‐RADS category 4, and make the diagnosis of category 4 breast tumors to be more accurate and precise.

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Nakagami-m parametric characterization of contrast-enhanced ultrasound: In vivo validations

Wang

Wan

Diederich

2020

2020 IEEE International Ultrasonics Symposium (IUS)

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In vivo Nakagami‐m parametric imaging of microbubble‐enhanced ultrasound regulated by RF and VF processing techniques

Cited by 5 publications

References 40 publications

Feasibility investigation of logarithmic Nakagami parametric imaging in recovering underestimated perfusion metrics of DCEUS in the uneven acoustic field

Feasibility investigation of logarithmic Nakagami parametric imaging in recovering underestimated perfusion metrics of DCEUS in the uneven acoustic field

Classification of multi‐feature fusion ultrasound images of breast tumor within category 4 using convolutional neural networks

Nakagami-m parametric characterization of contrast-enhanced ultrasound: In vivo validations

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