3D ultrasound

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Short description: Rendering technique in medical imaging
A 3D ultrasound of a human fetus aged 20 weeks

3D ultrasound is a medical ultrasound technique, often used in fetal, cardiac, trans-rectal and intra-vascular applications. 3D ultrasound refers specifically to the volume rendering of ultrasound data. When involving a series of 3D volumes collected over time, it can also be referred to as 4D ultrasound (three spatial dimensions plus one time dimension) or real-time 3D ultrasound.[1]

Methods

When generating a 3D volume, the ultrasound data can be collected in four common ways by a sonographer:

  • Freehand, which involves tilting the probe and capturing a series of ultrasound images and recording the transducer orientation for each slice.
  • Mechanically, where the internal linear probe tilt is handled by a motor inside the probe.
  • Using an endoprobe, which generates the volume by inserting a probe and then removing the transducer in a controlled manner.
  • A matrix array transducer, which uses beam steering to sample points throughout a pyramid shaped volume.[2]

Risks

The general risks of ultrasound also apply to 3D ultrasound. Essentially, ultrasound is considered safe. While other imaging modalities use radioactive dye or ionizing radiation, for example, ultrasound transducers send pulses of high frequency sound into the body and then listen for the echo.

In summary, the primary risks associated with ultrasound would be the potential heating of tissue or cavitation. The mechanisms by which tissue heating and cavitation are measured are through the standards called thermal index (TI) and mechanical index (MI). Even though the FDA outlines very safe values for maximum TI and MI, it is still recommended to avoid unnecessary ultrasound imaging.[3]

Applications

Obstetrics

3D ultrasound is useful, among other things, for facilitating the characterization of some congenital defects, such as skeletal anomalies and heart issues. With real-time 3D ultrasound, the fetal heart rate can be examined in real-time.[4][5]

Cardiology

Applications of three-dimensional ultrasound in cardiac treatment have achieved outstanding progress in scanning and treating heart issues. When 3D ultrasound is used to visualize the cardiac state of an individual, it is called 3D echocardiography (3D ECG).[6] With the integration of other technologies, it is possible to obtain quantitative measurements such as chamber volume during the cardiac cycle. It also provides other useful information, for example, tracking the blood flow, or the speed of contractions and expansions.[7] With 3D echocardiography, physicians can detect artery diseases with relative ease, and can finely examine various cardiac defects. 3D echocardiography can achieve real-time imaging of the cardiac structure.[8]

Surgical guidance

Traditionally, with 2D ultrasound, the specific position of organs and tissues, which is useful in surgery, could not be located, especially in the oblique plane. With the advent of 3D ultrasound, the imaging technique has evolved such that it enables the surgeon to obtain a real-time picture of tissues and organs, visualizing the complete scan more efficiently.[9] In addition, 3D ultrasound provides surgical guidance in organ transplantation and cancer treatment, especially by employing rotational visualizing during scan.[10] Various methods are used in this area, including rotational scanning, slice projection, and the use of integrated array transducers.[11] With 3D ultrasound, it is possible to treat a broader range of tumors, as more tissues can be diagnosed and inspected.[12]

Vascular imaging

Blood vessels and arteries are relatively difficult to image, due to their distribution. 3D ultrasound has made it easier to track the dynamic movement of blood cells, veins and arteries.[13] Various types of diagnostic tasks can be achieved with 3D ultrasound, such as measuring blood vessel diameter and diagnosing arterial walls. Some of these tasks can be undertaken with a magnetic tracker, integrated with the ultrasound, which assists in accurate positioning.[14]

Regional anesthesia

Real-time 3D ultrasound is used during peripheral nerve blockade procedures to identify the relevant anatomy and monitor the spread of local anesthetic around the nerve. Peripheral nerve blockades prevent the transmission of pain signals from the site of injury to the brain without deep sedation, which makes them particularly useful for outpatient orthopedic procedures. Real-time 3D ultrasound allows muscles, nerves and vessels to be clearly identified while a needle or catheter is advanced under the skin. This type of ultrasound is capable of imaging the needle regardless of the plane of the image, which is a substantial improvement over 2D ultrasound. Additionally, the image can be rotated or cropped in real time to reveal anatomical structures within a volume of tissue. Physicians at the Mayo Clinic in Jacksonville have been developing techniques using real time 3D ultrasound to guide peripheral nerve blocks for shoulder, knee, and ankle surgery.[15][16]

References

  1. "What Is 4D Ultrasound Technology?". 19 Apr 2011. https://www.ge.com/news/reports/what-is-4d-ultrasound-technology. 
  2. Hoskins, Peter; Martin, Kevin; Thrush, Abigail (2010). Diagnostic ultrasound : physics and equipment (2nd ed.). Cambridge, UK: Cambridge University Press. ISBN 978-0-521-75710-2. 
  3. Health, Center for Devices and Radiological (28 September 2020). "Medical Imaging - Ultrasound Imaging" (in en). https://www.fda.gov/Radiation-EmittingProducts/RadiationEmittingProductsandProcedures/MedicalImaging/ucm115357.htm#benefitsrisks. 
  4. Baba, Kazunori; Okai, Takashi; Kozuma, Shiro; Taketani, Yuji (1999). "Fetal Abnormalities: Evaluation with Real-time-Processible Three-dimensional US—Preliminary Report". Radiology 211 (2): 441–446. doi:10.1148/radiology.211.2.r99mr02441. PMID 10228526. 
  5. Acar, Philippe; Battle, Laia; Dulac, Yves; Peyre, Marianne; Dubourdieu, Hélène; Hascoet, Sébastien; Groussolles, Marion; Vayssière, Christophe (2014). "Real-time three-dimensional foetal echocardiography using a new transabdominal xMATRIX array transducer". Archives of Cardiovascular Diseases 107 (1): 4–9. doi:10.1016/j.acvd.2013.10.003. PMID 24364911. 
  6. Huang, Qinghua; Zeng, Zhaozheng (2017). "A Review on Real-Time 3D Ultrasound Imaging Technology". BioMed Research International 2017: 1–20. doi:10.1155/2017/6027029. PMID 28459067. 
  7. Pedrosa, J.; Barbosa, D.; Almeida, N.; Bernard, O.; Bosch, J.; d'Hooge, J. (2016). "Cardiac Chamber Volumetric Assessment Using 3D Ultrasound - A Review". Current Pharmaceutical Design 22 (1): 105–21. doi:10.2174/1381612822666151109112652. PMID 26548305. https://lirias.kuleuven.be/handle/123456789/515274. 
  8. Picano, E.; Pellikka, P. A. (2013). "Stress echo applications beyond coronary artery disease". European Heart Journal 35 (16): 1033–1040. doi:10.1093/eurheartj/eht350. PMID 24126880. 
  9. Yan, P. (2016). "SU-F-T-41: 3D MTP-TRUS for Prostate Implant". Medical Physics 43 (6Part13): 3470–3471. doi:10.1118/1.4956176. Bibcode2016MedPh..43.3470Y. 
  10. Ding, Mingyue; Cardinal, H. Neale; Fenster, Aaron (2003). "Automatic needle segmentation in three-dimensional ultrasound images using two orthogonal two-dimensional image projections". Medical Physics 30 (2): 222–234. doi:10.1118/1.1538231. PMID 12607840. Bibcode2003MedPh..30..222D. 
  11. Mahboob, Syed; McPhillips, Rachael; Qiu, Zhen; Jiang, Yun; Meggs, Carl; Schiavone, Giuseppe; Button, Tim; Desmulliez, Marc et al. (2016). "Intraoperative Ultrasound-Guided Resection of Gliomas: A Meta-Analysis and Review of the Literature". World Neurosurgery 92: 255–263. doi:10.1016/j.wneu.2016.05.007. PMID 27178235. http://pure-oai.bham.ac.uk/ws/files/29203860/Mahboob_et_al_Intraoperative_ultrasound_World_Neurosurgery_2016.pdf. 
  12. Moiyadi, Aliasgar V.; Shetty, Prakash (2016). "Direct navigated 3D ultrasound for resection of brain tumors: A useful tool for intraoperative image guidance". Neurosurgical Focus 40 (3): E5. doi:10.3171/2015.12.FOCUS15529. PMID 26926063. 
  13. Jin, Chang-zhu; Nam, Kweon-Ho; Paeng, Dong-Guk (2014). "The spatio-temporal variation of rat carotid artery bifurcation by ultrasound imaging". 2014 IEEE International Ultrasonics Symposium. pp. 1900–1903. doi:10.1109/ULTSYM.2014.0472. ISBN 978-1-4799-7049-0. 
  14. Pfister, Karin; Schierling, Wilma; Jung, Ernst Michael; Apfelbeck, Hanna; Hennersperger, Christoph; Kasprzak, Piotr M. (2016). "Standardized 2D ultrasound versus 3D/4D ultrasound and image fusion for measurement of aortic aneurysm diameter in follow-up after EVAR". Clinical Hemorheology and Microcirculation 62 (3): 249–260. doi:10.3233/CH-152012. PMID 26484714. 
  15. "Real-Time 3-D Ultrasound Speeds Patient Recovery" (Press release). Mayo Clinic. July 13, 2007. Retrieved May 21, 2014.
  16. Feinglass, Neil G.; Clendenen, Steven R.; Torp, Klaus D.; Wang, R. Doris; Castello, Ramon; Greengrass, Roy A. (2007). "Real-Time Three-Dimensional Ultrasound for Continuous Popliteal Blockade: A Case Report and Image Description". Anesthesia & Analgesia 105 (1): 272–274. doi:10.1213/01.ane.0000265439.02497.a7. PMID 17578987. 

External links

clinic in Sacramento, CA that specializes in performing 3D ultrasound and training sonographers.