Correction for Spatial Averaging Artifacts in Hydrophone Measurements of High-Intensity Therapeutic Ultrasound: An Inverse Filter Approach

Wear, Keith A.; Howard, Samuel M.

doi:10.1109/tuffc.2019.2924351

Cited by 21 publications

(4 citation statements)

References 100 publications

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“…The value for a eff ( f ) chosen for each frequency and each hydrophone was the value that minimized the root mean square difference (RMSD) between the experimental directivity and model directivity (1) over angles from −30° to 30°. This angular range optimized the directivity model for beams with angular spectra mostly confined to | θ | < 30°, which can accommodate transducers with f-numbers ≥ 1 [7, 8, 37]. The relative difference between effective and nominal geometrical sensitive element radii Δaag=aeff−agag was fit to a power-law function of ka g , Δaag=C(kag)n The power law fit parameters were obtained from linear fits to log-transformed data.…”

Section: Methodsmentioning

confidence: 99%

Directivity and Frequency-Dependent Effective Sensitive Element Size of Membrane Hydrophones: Theory Versus Experiment

Wear

Baker

Miloro

2019

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

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It is important to know hydrophone frequency-dependent effective sensitive element size in order to account for spatial averaging artifacts in acoustic output measurements. Frequency-dependent effective sensitive element size may be obtained from hydrophone directivity measurements. Directivity was measured at 1, 2, 3, 4, 6, 8, and 10 MHz from ±60° in two orthogonal planes for 8 membrane hydrophones with nominal geometrical sensitive element radii (a g) ranging from 100 to 500 μm. The mean precision of directivity measurements (obtained from four repeat measurements at each frequency and angle) averaged over all frequencies, angles, and hydrophones was 5.8%. Frequency-dependent effective hydrophone sensitive element radii a eff (f) were estimated by fitting the theoretical directional response for a disk receiver to directivity measurements using the sensitive element radius (a) as an adjustable parameter. For the 8 hydrophones in aggregate, the relative difference between effective and geometrical sensitive element radii, (a eff-a g) / a g , was fit to C / (ka g) n where k = 2π/λ and λ = wavelength. The functional fit yielded C = 1.89 and n = 1.36. The root mean square difference between data and model was 34%. It was shown that, for a given value for a g , a eff (f) for membrane hydrophones far exceeds that for needle hydrophones at low frequencies (e.g., < 4 MHz when a g = 100 μm). This empirical model for a eff (f) provides information required for compensation of spatial averaging artifacts in acoustic output measurements and is useful for choosing an appropriate sensitive element size for a given experiment.

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Section: Methodsmentioning

confidence: 99%

Directivity and Frequency-Dependent Effective Sensitive Element Size of Membrane Hydrophones: Theory Versus Experiment

Wear

Baker

Miloro

2019

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

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“…Measurement accuracy depends on the hydrophone effective active element radius being comparable with or smaller than one‐quarter of the effective wavelength of the ultrasound in water to avoid spatial averaging errors, at least for the fundamental frequency 48 . However, even if this condition is not met or if the pressure wave has significant harmonic content (as is commonly true), an inverse filter method exists for correcting for spatial averaging loss across the hydrophone sensitive element for the fundamental and all harmonics 52 . (Note that the harmonic beamwidth decreases with frequency 52 ).…”

Section: Quantitative Metrics Data Types and Terminologymentioning

confidence: 99%

“…However, even if this condition is not met or if the pressure wave has significant harmonic content (as is commonly true), an inverse filter method exists for correcting for spatial averaging loss across the hydrophone sensitive element for the fundamental and all harmonics 52 . (Note that the harmonic beamwidth decreases with frequency 52 ). To account for the fact that the intensity is highly localized and the ultrasound may be pulsed, the IEC/TS 62556 report lists several different intensity parameters, including: I SAL : the spatial average intensity, linear conditions.…”

Section: Quantitative Metrics Data Types and Terminologymentioning

confidence: 99%

AAPM Task Group 241: A medical physicist’s guide to MRI‐guided focused ultrasound body systems

Payne

Chopra

Ellens³

et al. 2021

Medical Physics

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Magnetic resonance‐guided focused ultrasound (MRgFUS) is a completely non‐invasive technology that has been approved by FDA to treat several diseases. This report, prepared by the American Association of Physicist in Medicine (AAPM) Task Group 241, provides background on MRgFUS technology with a focus on clinical body MRgFUS systems. The report addresses the issues of interest to the medical physics community, specific to the body MRgFUS system configuration, and provides recommendations on how to successfully implement and maintain a clinical MRgFUS program. The following sections describe the key features of typical MRgFUS systems and clinical workflow and provide key points and best practices for the medical physicist. Commonly used terms, metrics and physics are defined and sources of uncertainty that affect MRgFUS procedures are described. Finally, safety and quality assurance procedures are explained, the recommended role of the medical physicist in MRgFUS procedures is described, and regulatory requirements for planning clinical trials are detailed. Although this report is limited in scope to clinical body MRgFUS systems that are approved or currently undergoing clinical trials in the United States, much of the material presented is also applicable to systems designed for other applications.

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“…The spatial averaging corrections can be estimated by integrating the pressure over the effective diameter of the hydrophone [69][70][71][72], or calculated from the empirical relationship of the ratio of the measured harmonic acoustic beam width and the effective diameter of the hydrophone [73]. Assuming a quadratic [74] or Gaussian [60,75] profile distribution for the pressure, the spatial averaging model can be simplified, and the spatial averaging can be corrected by the inverse technique [74,75]. Notably, the aforementioned directional response is commonly considered only a directional modulus response.…”

Section: Spatial Averaging Of Hydrophonesmentioning

confidence: 99%

Review of field characterization techniques for high intensity therapeutic ultrasound

Xing

Wilkens

2021

Metrologia

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High-intensity therapeutic ultrasound (HITU) is a minimally invasive and non-ionizing medical procedure used to combat cancers. Faithful characterization of HITU fields is fundamental to ensure patient safety and clinical efficiency. However, standardized quality assurance protocols have not yet been established for HITU, which is a prerequisite for the wide acceptance of HITU as a therapeutic modality. This review discusses the challenges in the acoustic output characterization of HITU and the solutions that have been proposed to overcome this issue. The purpose of this review is to discuss the state of art of the metrological techniques, and invoke new ideas to prompt further development of HITU usage and characterization techniques, to ensure the safe and effective usage of therapeutic ultrasound.

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Correction for Spatial Averaging Artifacts in Hydrophone Measurements of High-Intensity Therapeutic Ultrasound: An Inverse Filter Approach

Cited by 21 publications

References 100 publications

Directivity and Frequency-Dependent Effective Sensitive Element Size of Membrane Hydrophones: Theory Versus Experiment

Directivity and Frequency-Dependent Effective Sensitive Element Size of Membrane Hydrophones: Theory Versus Experiment

AAPM Task Group 241: A medical physicist’s guide to MRI‐guided focused ultrasound body systems

Review of field characterization techniques for high intensity therapeutic ultrasound

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