Sage Journals: Discover world-class research

Abstract

Low intensity focused ultrasound (LIFU) is a novel approach that could activate drug release and considerably improve the delivery of anticancer drug. LIFU treatment has some features like is able to penetrate deep into the tissue and being non-invasive, as a consequence LIFU displays great capability for controlling the drug release and improving the chemotherapy treatment efficiency. The goal of this study is to research the feasibility of the entropy parameter of RF time series of ultrasound backscattered signals for measuring the changes in temperature induced by a LIFU device. Entropy Imaging is a technique for reconstructing ultrasound images based on the average uncertainty of time-series in a signal. Furthermore, the Shannon Entropy can quantify the uncertainty of a random process and is usually used as a measure for the information content of probability distributions. In this study, we use the Entropy Imaging method for measuring the LIFU-induced temperature changes in the deep region of ex vivo porcine tissue samples. The results obtained show that the changes of entropy parameter of RF time series signal are proportional to temperature changes recorded by a calibrated thermocouple in the temperature range of 37–47°C. In conclusion, in this study we show that Shannon entropy of RF time series signal possesses promising features like succinctly capturing the available information in a system by considering the uncertainty in a given data that can be used, as a new method, to measure temperature changes non-invasively and quantitatively in the deep region of tissue.

Keywords

Noninvasive ultrasound thermometry temperature estimation entropy imaging focused ultrasound (FUS)low-intensity focused ultrasound (LIFU)Shannon entropy

Get full access to this article

View all access options for this article.

References

Ferrara

. Driving delivery vehicles with ultrasound. Adv Drug Deliv Rev 2008; 60: 1097–1102.

Zhu

Torchilin

. Stimulus-responsive nanopreparations for tumor targeting. Integr Biol 2013; 5: 96–107.

Maass-Moreno

Damianou

Sanghvi

. Noninvasive temperature estimation in tissue via ultrasound echo-shifts. Part II. In vitro study. J Acoust Soc Am 1996; 100: 2522–2530.

Simon

Vanbaren

Ebbini

. Two-dimensional temperature estimation using diagnostic ultrasound. IEEE Trans Ultrason Ferroelectr Freq Control 1998; 45: 1088–1099.

Fallone

Moran

Podgorsak

. Noninvasive thermometry with a clinical x-ray CT scanner. Med Phys 1982; 9: 715–721.

Parker

Smith

Sheldon

, et al. Temperature distribution measurements in two-dimensional NMR imaging. Med Phys 1983; 10: 321–325.

Dickinson

Hall

Hind

, et al. Measurement of changes in tissue temperature using MR imaging. J Comput Assist Tomogr 1986; 10: 468–472.

Le Bihan

Delannoy

Levin

. Temperature mapping with MR imaging of molecular diffusion: application to hyperthermia. Radiology 1989; 171: 853–857.

Kuroda

Miki

Nakagawa

, et al. Non-invasive temperature measurement by means of NMR parameters—use of proton chemical shift with spectral estimation technique. Med Biol Eng Comput 1991; 29: 902.

10.

Qian

Fei

, et al. Noninvasive temperature monitoring in HIFU clinical uses. In: AIP conference proceedings on therapeutic ultrasound, 2007, pp.251–257. London, UK: AIP Publishing LLC.

11.

Georg

Wilkens

. Non-invasive estimation of temperature using diagnostic ultrasound during hifu therapy. In: AIP conference proceedings on therapeutic ultrasound, 2017, pp. 040002. London, UK: AIP Publishing LLC.

12.

Bohris

Schreiber

Jenne

, et al. Quantitative MR temperature monitoring of high-intensity focused ultrasound therapy. Magn Reson Imaging 1999; 17: 603–610.

13.

Rinaldi

Jones

Reines

, et al. Modification by focused ultrasound pulses of electrically evoked responses from an in vitro hippocampal preparation. Brain Res 1991; 558: 36–42.

14.

Tufail

Matyushov

Baldwin

, et al. Transcranial pulsed ultrasound stimulates intact brain circuits. Neuron 2010; 66: 681–694.

15.

Wahab

Choi

Liu

, et al. Mechanical bioeffects of pulsed high intensity focused ultrasound on a simple neural model. Med Phys 2012; 39: 4274–4283.

16.

Baek

Pahk

Kim

. A review of low-intensity focused ultrasound for neuromodulation. Biomed Eng Lett 2017; 7: 135–142.

17.

Zhou

. Principles and applications of therapeutic ultrasound in healthcare. Boca Raton, FL: CRC Press, 2015.

18.

Tsui

Chen

Kuo

, et al. Small-window parametric imaging based on information entropy for ultrasound tissue characterization. Sci Rep 2017; 7: 41004–41007.

19.

Fang

Chang

Tsui

. Performance evaluations on using entropy of ultrasound log-compressed envelope images for hepatic steatosis assessment: an in vivo animal study. Entropy 2018; 20: 120.

20.

Monfared

Behnam

Rangraz

, et al. High-intensity focused ultrasound thermal lesion detection using entropy imaging of ultrasound radio frequency signal time series. J Med Ultrasound 2018; 26: 24–30.

21.

Mobasheri

Behnam

Rangraz

, et al. Radio frequency ultrasound time series signal analysis to evaluate high-intensity focused ultrasound lesion formation status in tissue. J Med Signals Sens 2016; 6: 91–98.

22.

Marsh

Korenblat

Liu

, et al. Resolution of murine toxic hepatic injury quantified with ultrasound entropy metrics. Ultrasound Med Biol 2019; 45: 2777–2786.

23.

Hughes

McCarthy

Marsh

, et al. Properties of an entropy-based signal receiver with an application to ultrasonic molecular imaging. J Acoust Soc Am 2007; 121: 3542–3557.

24.

Imani

Lasso

, et al. Monitoring of tissue ablation using time series of ultrasound RF data. In: International conference on medical image computing and computer-assisted intervention, 2011, pp.379–386. Berlin: Springer.

25.

Rivens

Shaw

Civale

, et al. Treatment monitoring and thermometry for therapeutic focused ultrasound. Int J Hyperthermia 2007; 23: 121–139.

26.

Shaswary

Assi

Yang

, et al. Noninvasive calibrated tissue temperature estimation using backscattered energy of acoustic harmonics. Ultrasonics 2021; 114: 106406.

27.

Hughes

. Analysis of digitized waveforms using Shannon entropy. J Acoust Soc Am 1993; 93: 892–906.

28.

Tsui

. Ultrasound detection of scatterer concentration by weighted entropy. Entropy 2015; 17: 6598–6616.

29.

Bao

Lai

, et al. Depth-aware video frame interpolation. In: Proceedings of the IEEE/CVF conference on computer vision and pattern recognition, 2019, pp.3703–3712. Long Beach, USA: IEEE.

30.

Van Drie

. The Boltzmann/Shannon entropy as a measure of correlation. arXiv: Mathematical Physics 2000.

31.

Ben-Naim

. Entropy, Shannon’s measure of information and boltzmann’s H-theorem. Entropy 2017; 19(2): 48.

32.

Huang

Sun

Chen

, et al. Simulation of thermal ablation by high-intensity focused ultrasound with temperature-dependent properties. Ultrason Sonochem 2015; 27: 456–465.

33.

Guntur

Choi

. Temperature dependence of tissue thermal parameters should Be considered in the thermal lesion prediction in high-intensity focused ultrasound surgery. Ultrasound Med Biol 2020; 46(4): 1001–1014.

34.

Sapareto

Dewey

. Thermal dose determination in cancer therapy. International Journal of Radiation Oncology, Biology, Physics 1984; 10(6): 787–800.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

4.62 MB

Thermometry using entropy imaging of ultrasound radio frequency signal time series

Abstract

Keywords

Get full access to this article

References

Supplementary Material