Jump to content

Focused ultrasound

From Wikipedia, the free encyclopedia

Focused ultrasound
Diagram showing how HIFU can be used to destroy tissue in the body. An acoustic lens is used to focus sound to a small point in the body. The sound propagates through many layers of tissue. Because of the focal gain, only tissue at the focus is destroyed.
Other namesMagnetic-resonance-guided focused ultrasound surgery (MRgFUS), focused ultrasound surgery (FUS), MR-guided focused ultrasound ablation

High-intensity focused ultrasound (HIFU), or MR-guided focused ultrasound surgery (MR-guided focused ultrasound ablation), is an incisionless therapeutic technique[1] that uses non-ionizing ultrasonic waves to heat or ablate tissue. HIFU can be used to increase the flow of blood or lymph or to destroy tissue, such as tumors, via thermal and mechanical mechanisms. Given the prevalence and relatively low cost of ultrasound generation mechanisms, the premise of HIFU is that it is expected to be a non-invasive and low-cost therapy that can at least outperform care in the operating room.

The technology is different from that used in ultrasonic imaging, though lower frequencies and continuous, rather than pulsed, waves are used to achieve the necessary thermal doses. However, pulsed waves may also be used if mechanical rather than thermal damage is desired. Acoustic lenses are often used to achieve the necessary intensity at the target tissue without damaging the surrounding tissue. The ideal pattern diagram is the beam-focusing of a magnifying glass of sunlight; only the focal point of the magnifying glass has high temperature.

HIFU is combined with other imaging techniques such as medical ultrasound or MRI to enable guidance of the treatment and monitoring.

History

[edit]

Studies on localized prostate cancer showed that, after treatment, progression-free survival rates were high for low- and intermediate- risk patients with recurrent prostate cancer.[2] The InsighTec ExAblate 2000 was the first MRgFUS system to obtain FDA market approval,[3] US patent 5,247,935.

Medical uses

[edit]

There is no clear consensus on the boundaries between HIFU and other forms of therapeutic ultrasound. In particular literature, HIFU refers to the high levels of energy required to destroy tissue through ablation or cavitation, although it is also sometimes used to describe lower intensity applications such as occupational therapy and physical therapy.

Either way, HIFU is used to non-invasively heat tissue deep in the body without the need for an incision.[1] The main applications are the destruction of tissue caused by hyperthermia, increasing perfusion and physical therapy. The use of ultrasound in the treatment of musculoskeletal conditions is another use in the physiotherapy setting.[4]

Neurological disorders

[edit]
Frontal MRI four days after MRgFUS (MRI-guided high-intensity focused ultrasound): Left ventral intermediate nucleus (Vim) thalamotomy. 79-year-old man with essential tremor.

One of the first applications of HIFU was the treatment of Parkinson's disease in the 1940s. Although ineffective at the time, HIFU has the capacity to lesion pathology. A focused ultrasound system is approved in Israel, Canada, Italy, Korea and Russia to treat essential tremor,[5] neuropathic pain,[6] and Parkinsonian tremor.[7] This approach enables treatment of the brain without an incision or radiation. In 2016, the US Food and Drug Administration (FDA) approved Insightec's Exablate system to treat essential tremor.[8] Treatment for other thalamocortical dysrhythmias and psychiatric conditions are under investigation.[9]

Cancers

[edit]

Prostate

[edit]

HIFU may be effective for treating prostate cancer.[10][11][12]

Liver

[edit]

HIFU is studied in liver cancer and in many studies report a high response rate and positive outcome.[13] During the treatment of metastasized liver cancer with HIFU, immune responses have been observed in locations that are distant from the focal region.[14]

Prostate enlargement

[edit]

Treatment of prostate enlargement (benign prostatic hyperplasia) by HIFU from inside the intestine (transrectal) has turned out to be unsuccessful.[15][16]

In some countries, not in USA, HIFU has also been offered from the inside of the prostate, that is, via a catheter in the prostatic urethra. Evidence as of 2019 is lacking.[17]

In England the National Institute for Health and Care Excellence (NICE) in 2018 classified the method as "not recommended".[18]

Mechanism

[edit]

HIFU beams are precisely focused on a small region of diseased tissue to locally deposit high levels of energy.

  • Focused ultrasound may be used to generate highly localized heating to treat cysts and tumors (benign or malignant). This is known as Magnetic Resonance guided Focused Ultrasound (MRgFUS) or High Intensity Focused Ultrasound (HIFU). These procedures generally use lower frequencies than medical diagnostic ultrasound (from 0.7 to 2 MHz), but higher the frequency means lower the focusing energy. HIFU treatment is often guided by MRI.
  • Focused ultrasound may be used to dissolve kidney stones by lithotripsy.
  • Ultrasound may be used for cataract treatment by phacoemulsification.

Ideal temperature

[edit]

The temperature of tissue at the focus will rise to between 65 and 85 °C, destroying the diseased tissue by coagulative necrosis. If tissue is elevated above the threshold of 60 °C for longer than 1 second this process is irreversible.[19] Each sonication (individual ultrasound energy deposition) treats a precisely defined portion of the targeted tissue. The entire therapeutic target is treated by using multiple sonications to create a volume of incompressible material, such as tap water.[20]

with the integral being over the treatment time, R=0.5 for temperatures over 43 °C and 0.25 for temperatures between 43 °C and 37 °C, a reference temperature of 43 °C, and time T is in minutes. The equations and methods described in this report are not intended to represent any clinical result, this is only an approach for thermal dose estimation in a incompressible material of just tap water; .[21]

As an ultrasound acoustic wave cannot propagates through the compressive tissue, such as rubber, human tissues part of it and the ultrasound energy will be turned to converted as heat, with focused beams, a very small region of heating can be achieved the part of shallow deep in tissues (usually on the order of 2~3 millimeters). Tissue occurs as a function of both the subtle shaking to which the water is heated and how long the part of water is exposed to this heat level in a metric referred to as "thermal dose". By focusing at more than one place or by scanning the focus, a volume can be thermally ablated.[22][23][24] Thermal doses of 120-240 min at 43 °C coagulate cellular protein and leads to irreversible tissue destruction.

There are some reports that HIFU could be applied to cancers to disrupt the tumor microenvironment and trigger an immune response, as well as possibly enhance the efficacy of immunotherapy.[25][26]

Mechanical

[edit]

Inertial cavitation

[edit]

At high enough acoustic intensities, cavitation (microbubbles forming and interacting with the ultrasound field) can occur. Microbubbles produced in the field oscillate and grow (due to factors including rectified diffusion), and can eventually implode (inertial or transient cavitation). During inertial cavitation, very high temperatures occur inside the bubbles, and the collapse during the rarefaction phase is associated with a shock wave and jets that can mechanically damage tissue.[27]

Stable cavitation

[edit]

Stable cavitation creates microstreaming which induces high shear forces on cells and leads to apoptosis. Elaborating, bubbles produced by the vaporization of water due to acoustic forces oscillate under a low-pressure acoustic field. Strong streaming may cause cell damage but also reduces tissue temperature via convective heat loss.[28]

Theory

[edit]

There are several ways to focus ultrasound—via a lens (for example, a polystyrene lens, parabola curve transducer, a phased array, etc. The special patents and very precise technology solve the problem. This can be determined using an exponential model of ultrasound attenuation. The ultrasound intensity profile is bounded by an exponentially decreasing function where the decrease in ultrasound is a function of distance traveled through tissue:

is the initial intensity of the beam, is the attenuation coefficient (in units of inverse length), and z is the distance traveled through the attenuating medium (e.g. tissue).

In this ideal model, [29] is a measure of the power density of the heat absorbed from the ultrasound field. This demonstrates that tissue heating is proportional to intensity, and that intensity is inversely proportional to the area over which an ultrasound beam is spread. Therefore, focusing the beam into a sharp point or increasing the beam intensity creates a rapid temperature rise at the focus.[citation needed]

The ultrasound beam can be focused in these ways:

  • Geometrically, for example with a lens or with a spherically curved transducer.
  • Electronically, by adjusting the relative phases of elements in an array of transducers (a "phased array"). By dynamically adjusting the electronic signals to the elements of a phased array, the beam can be steered to different locations, and aberrations in the ultrasound beam due to tissue structures can be corrected.[citation needed] This assumes no reflection, no absorption and no diffusion of intermediate tissue. The ultrasound itself can penetrate incompressible materials such as water, but compressible materials such as air, rubber, human tissue, fat, fiber, hollow bone, and fascia reflect, absorb and diffuse the ultrasound energy.

Beam delivery

[edit]

Beam delivery consists of beam steering and image guidance. The beam has the ability to pass through overlying tissues without harm and focus on a localized area with size limit of 2–3 mm, that is determined the clinical frequency of the ultrasound. Following ablation a distinct boundary forms between healthy and necrotic tissue (width less than 50 microns).[30]

Beam steering

[edit]

The most common transducer used is a concave focusing transducer with a fixed aperture and a fixed focal length.[30] Phased array transducers can also be used with different arrangements (flat/bowl).[30]

Image guidance

[edit]

HIFU therapy requires careful monitoring and so it is usually performed in conjunction with other imaging techniques.

Pre-operative imaging, for instance CT and MRI, are usually used to identify general parameters of the target anatomy. Real-time imaging, on the other hand, is necessary for safe and accurate noninvasive targeting and therapy monitoring. Both MRI and Medical ultrasound imaging have been used for guidance in FUS treatment. These techniques are known as Magnetic Resonance guided Focused Ultrasound Surgery (MRgFUS)[31][32] and Ultrasound guided Focused Ultrasound Surgery (USgFUS) respectively.[1][33] MRgFUS is a 3D imaging technique which features high soft tissue contrast and provides information about temperature, thus allowing to monitor ablation. However, low frame rate makes this technique perform poorly in real-time imaging and high costs represent a significant limitation to its use.[34] USgFUS, differently, is a 2D imaging technique in which, although no system to provide quantitative information on temperature has been commercially developed so far, several benefits are exploited, such as high frame rate (up to 1000 images per second), low cost and minimal adverse health effects. Another reason why ultrasound is ideal for image guidance is it verifies the acoustic window in real time since it is the same modality as the therapy.[35] The implication of this is that if the target region is not visualized by ultrasound imaging before and during HIFU therapy, then it is unlikely that HIFU therapy will be effective in that specific region.[35] In addition, treatment outcomes can be estimated in real time through visual inspection of hyperechoic changes in standard B-mode images.[36]

References

[edit]
  1. ^ a b c Dubinsky TJ, Cuevas C, Dighe MK, Kolokythas O, Hwang JH (2008). "High-Intensity Focused Ultrasound: Current Potential and Oncologic Applications". American Journal of Roentgenology. 190 (1): 191–199. doi:10.2214/AJR.07.2671. ISSN 0361-803X. PMID 18094311.
  2. ^ Gelet A, Murat FJ, Poissonier L (2007). "Recurrent Prostate Cancer After Radiotherapy – Salvage Treatment by High-intensity Focused Ultrasound". European Oncological Disease. 1 (1): 60–2. Archived from the original on 4 October 2013. Retrieved 4 October 2013.
  3. ^ "Food and Drug Administration Approval, ExAblate® 2000 System – P040003". Food and Drug Administration. Retrieved 2 December 2023.
  4. ^ Robertson VJ, Baker KG (2001). "A review of therapeutic ultrasound: Effectiveness studies" (PDF). Physical Therapy. 81 (7): 1339–50. doi:10.1093/ptj/81.7.1339. PMID 11444997.
  5. ^ Elias WJ, Huss D, Voss T, Loomba J, Khaled M, Zadicario E, Frysinger RC, Sperling SA, Wylie S, Monteith SJ, Druzgal J, Shah BB, Harrison M, Wintermark M (2013). "A Pilot Study of Focused Ultrasound Thalamotomy for Essential Tremor". New England Journal of Medicine. 369 (7): 640–8. doi:10.1056/NEJMoa1300962. PMID 23944301.
  6. ^ Jeanmonod D, Werner B, Morel A, Michels L, Zadicario E, Schiff G, Martin E (2012). "Transcranial magnetic resonance imaging–guided focused ultrasound: noninvasive central lateral thalamotomy for chronic neuropathic pain" (PDF). Neurosurgical Focus. 32 (1): E1. doi:10.3171/2011.10.FOCUS11248. PMID 22208894. S2CID 2231685.
  7. ^ Magara A, Bühler R, Moser D, Kowalski M, Pourtehrani P, Jeanmonod D (2014). "First experience with MR-guided focused ultrasound in the treatment of Parkinson's disease". Journal of Therapeutic Ultrasound. 2: 11. doi:10.1186/2050-5736-2-11. PMC 4266014. PMID 25512869.
  8. ^ FDA News Release. "FDA approves first MRI-guided focused ultrasound device to treat essential tremor", FDA, July 11, 2016
  9. ^ Martin-Fiori, E (2014). "Functional Neurosurgery with MR-Guided HIFU". Intraoperative Imaging and Image-Guided Therapy. New York: Springer. pp. 591–599. doi:10.1007/978-1-4614-7657-3_45. ISBN 978-1-4614-7657-3.
  10. ^ Chaussy CG, Thüroff S (April 2017). "High-Intensity Focused Ultrasound for the treatment of prostate cancer: A Review". Journal of Endourology. 31 (S1): S30 – S37. doi:10.1089/end.2016.0548. PMID 28355119.
  11. ^ Hu JC, Laviana A, Sedrakyan A (28 June 2016). "High-Intensity Focused Ultrasound for Prostate Cancer". JAMA. 315 (24): 2659–60. doi:10.1001/jama.2016.5002. PMID 27367874.
  12. ^ Lepor H, Gold S, Wysock J (2018). "Focal Ablation of Prostate Cancer". Reviews in Urology. 20 (4): 145–157. doi:10.3909/riu0809 (inactive 1 November 2024). PMC 6375006. PMID 30787673.{{cite journal}}: CS1 maint: DOI inactive as of November 2024 (link)
  13. ^ Ng KK, Poon RT, Chan SC, Chok KS, Cheung TT, Tung H, Chu F, Tso WK, Yu WC, Lo CM, Fan ST (May 2011). "High-intensity focused ultrasound for hepatocellular carcinoma: a single-center experience". Annals of Surgery. 253 (5): 981–987. doi:10.1097/SLA.0b013e3182128a8b. hdl:10722/135541. ISSN 1528-1140. PMID 21394012. S2CID 25603451.
  14. ^ Mauri G, Nicosia L, Xu Z, Di Pietro S, Monfardini L, Bonomo G, Varano GM, Prada F, Della Vigna P, Orsi F (March 2018). "Focused ultrasound: tumour ablation and its potential to enhance immunological therapy to cancer". The British Journal of Radiology. 91 (1083). doi:10.1259/bjr.20170641. ISSN 0007-1285. PMC 5965486. PMID 29168922.
  15. ^ Madersbacher S, Schatzl G, Djavan B, Stulnig T, Marberger M (2000). "Long-term outcome of transrectal high- intensity focused ultrasound therapy for benign prostatic hyperplasia". Eur Urol. 37 (6): 687–94. doi:10.1159/000020219. PMID 10828669. S2CID 46793601.
  16. ^ Sommer G, Pauly KB, Holbrook A, Plata J, Daniel B, Bouley D (2013). "Applicators for magnetic resonance-guided ultrasonic ablation of benign prostatic hyperplasia". Invest Radiol. 48 (6): 387–94. doi:10.1097/RLI.0b013e31827fe91e. PMC 4045500. PMID 23462673.
  17. ^ Salgaonkar VA, Diederich CJ (2015). "Catheter-based ultrasound technology for image-guided thermal therapy: current technology and applications". Int J Hyperth. 31 (2): 203–15. doi:10.3109/02656736.2015.1006269. PMC 4659534. PMID 25799287.
  18. ^ National Institute for Health and Care Excellence (NICE): Current care pathway (for BPH), August 2018.
  19. ^ Zhou YF (10 January 2011). "High intensity focused ultrasound in clinical tumor ablation". World Journal of Clinical Oncology. 2 (1): 8–27. doi:10.5306/wjco.v2.i1.8. ISSN 2218-4333. PMC 3095464. PMID 21603311.
  20. ^ Sapareto SA, Dewey WC (1984). "Thermal dose determination in cancer therapy". International Journal of Radiation Oncology, Biology, Physics. 10 (6): 787–800. doi:10.1016/0360-3016(84)90379-1. PMID 6547421.
  21. ^ Mouratidis PX, Rivens I, Civale J, Symonds-Tayler R, Haar Gt (1 January 2019). "'Relationship between thermal dose and cell death for "rapid" ablative and "slow" hyperthermic heating'". International Journal of Hyperthermia. 36 (1): 228–242. doi:10.1080/02656736.2018.1558289. ISSN 0265-6736. PMID 30700171.
  22. ^ Huisman M, Lam MK, Bartels LW, Nijenhuis RJ, Moonen CT, Knuttel FM, Verkooijen HM, van Vulpen M, van den Bosch MA (2014). "Feasibility of volumetric MRI-guided high intensity focused ultrasound (MR-HIFU) for painful bone metastases". Journal of Therapeutic Ultrasound. 2: 16. doi:10.1186/2050-5736-2-16. PMC 4193684. PMID 25309743.
  23. ^ Köhler MO, Mougenot C, Quesson B, Enholm J, Le Bail B, Laurent C, Moonen CT, Ehnholm GJ (2009). "Volumetric HIFU ablation under 3D guidance of rapid MRI thermometry". Medical Physics. 36 (8): 3521–35. Bibcode:2009MedPh..36.3521K. doi:10.1118/1.3152112. PMID 19746786.
  24. ^ Monteith SJ, Kassell NF, Goren O, Harnof S (2013). "Transcranial MR-guided focused ultrasound sonothrombolysis in the treatment of intracerebral hemorrhage". Neurosurgical Focus. 34 (5): E14. doi:10.3171/2013.2.FOCUS1313. PMID 23634918.
  25. ^ Haen SP, Pereira PL, Salih HR, Rammensee HG, Gouttefangeas C (2011). "More Than Just Tumor Destruction: Immunomodulation by Thermal Ablation of Cancer". Clinical and Developmental Immunology. 2011: 1–19. doi:10.1155/2011/160250. PMC 3254009. PMID 22242035.
  26. ^ Wu F (2013). "High intensity focused ultrasound ablation and antitumor immune response". The Journal of the Acoustical Society of America. 134 (2): 1695–701. Bibcode:2013ASAJ..134.1695W. doi:10.1121/1.4812893. PMID 23927210.
  27. ^ Leighton T (1997). Ultrasound in food processing. Chapter 9: The principles of cavitation: Thomson Science, London, Blackie Academic and Professional. pp. 151–182.{{cite book}}: CS1 maint: location (link)
  28. ^ Levario-Diaz V, Bhaskar P, Galan MC, Barnes AC (22 May 2020). "Effect of acoustic standing waves on cellular viability and metabolic activity". Scientific Reports. 10 (1): 8493. Bibcode:2020NatSR..10.8493L. doi:10.1038/s41598-020-65241-4. ISSN 2045-2322. PMC 7244593. PMID 32444830.
  29. ^ Hariharan P, Myers MR, Banerjee RK (21 July 2007). "HIFU procedures at moderate intensities—effect of large blood vessels". Physics in Medicine and Biology. 52 (12): 3493–3513. Bibcode:2007PMB....52.3493H. doi:10.1088/0031-9155/52/12/011. PMID 17664556. S2CID 26124121.
  30. ^ a b c Izadifar Z, Izadifar Z, Chapman D, Babyn P (7 February 2020). "An Introduction to High Intensity Focused Ultrasound: Systematic Review on Principles, Devices, and Clinical Applications". Journal of Clinical Medicine. 9 (2): 460. doi:10.3390/jcm9020460. ISSN 2077-0383. PMC 7073974. PMID 32046072.
  31. ^ Kotopoulis S, Wang H, Cochran S, Postema M (2011). "Lithium niobate transducers for MRI-guided ultrasonic microsurgery" (PDF). IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control. 58 (8): 1570–1576. doi:10.1109/TUFFC.2011.1984. PMID 21859576. S2CID 11382728.
  32. ^ Medel R, Monteith SJ, Elias WJ, Eames M, Snell J, Sheehan JP, Wintermark M, Jolesz FA, Kassell NF (2012). "Magnetic Resonance–Guided Focused Ultrasound Surgery". Neurosurgery. 71 (4): 755–763. doi:10.1227/NEU.0b013e3182672ac9. ISSN 0148-396X. PMC 4104674. PMID 22791029.
  33. ^ Belzberg M, Mahapatra S, Perdomo-Pantoja A, Chavez F, Morrison K, Xiong KT, Gamo NJ, Restaino SA, Thakor N, Yazdi Y, Iyer R, Tyler B, Theodore N, Luciano MG, Brem H, Groves M, Cohen AR, Manbachi A (2020). "Minimally invasive therapeutic ultrasound: Ultrasound-guided ultrasound ablation in neuro-oncology". Ultrasonics. 108 (12): 106210. doi:10.1016/j.ultras.2020.106210. PMC 8895244. PMID 32619834.
  34. ^ Cafarelli A, Mura M, Diodato A, Schiappacasse A, Santoro M, Ciuti G, Menciassi A (25–29 August 2015). "A computer-assisted robotic platform for Focused Ultrasound Surgery: Assessment of high intensity focused ultrasound delivery". 37th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC). pp. 1311–1314. doi:10.1109/EMBC.2015.7318609. ISBN 978-1-4244-9271-8. PMID 26736509. S2CID 4194253.
  35. ^ a b Chen PH, Hsieh KS, Huang CC (2017). "An Acoustic Tracking Approach for Medical Ultrasound Image Simulator". Journal of Medical and Biological Engineering. 37 (6): 944–952. doi:10.1007/s40846-017-0258-9. ISSN 1609-0985. PMC 6208925. PMID 30416414.
  36. ^ Ebbini ES, Ter Haar G (2015). "Ultrasound-guided therapeutic focused ultrasound: Current status and future directions". International Journal of Hyperthermia. 31 (2): 77–89. doi:10.3109/02656736.2014.995238. ISSN 0265-6736. PMID 25614047. S2CID 23590340.