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Principles of Medical Ultrasound

Principles of Medical Ultrasound. Zahra Kavehvash. Medical Ultrasound Course (25-636). Introduction Acoustic wave propagation Acoustic waves in fluids Acoustic waves in solids Attenuation and dispersion Reflection and Transmission Transducers Beam forming and Diffraction

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Principles of Medical Ultrasound

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  1. Principles of Medical Ultrasound Zahra Kavehvash

  2. Medical Ultrasound Course (25-636) • Introduction • Acoustic wave propagation • Acoustic waves in fluids • Acoustic waves in solids • Attenuation and dispersion • Reflection and Transmission • Transducers • Beam forming and Diffraction • Array beam forming • Ultrasonic imaging using pulse-echo technique • Doppler imaging • Special imaging techniques • Photo-Acoustic imaging (If time permits) • Ultrasonic CT

  3. Medical Ultrasound Course (25-636) • Reference: • Haim Azhari, Basics of Biomedical Ultrasound for Engineers, IEEE , Wiley, 2010.  • Thomas L. Szabo , Diagnostic Ultrasound Imaging: Inside Out , Elsevier , Academic Press Series in BME , 2004. • K. Kirk Shung and Gray A. Thieme, Ultrasonic Scattering in Biological Tissues, CRC Press, 1993. • B. D. Steinberg, Principles of Aperture and Array System Design, John Wiley and Sons, 1976. • D. H. Evans, W. N. McDicken, R. Skidmore, and J. P. Woodcock, Doppler Ultrasound, John Wiley and Sons, 1989. • J.W. Goodman, Introduction to Fourier Optics, McGraw-Hill, 1968. 

  4. Medical Ultrasound Course (25-636) • Journals: • IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency control. • IEEE Transactions on Medical Imaging • Journal of Acoustical Society of America

  5. Medical Ultrasound Course (25-636) • Grading: • Homework: 10 % (2) • Computer HW: 20 % (4) • Mid Term: 25 % (5) • Final: 45 % (9) • Midterm: 22 Aban

  6. History of UltrasoundWho are the smart guys?

  7. History of Ultrasound • A long time ago:

  8. History of Ultrasound • A long time ago:

  9. History of Ultrasound • 1822, Lake Geneva:

  10. History of Ultrasound • Piezoelectric effect, Pierre Curie, 1880:

  11. History of Ultrasound • 1954-1957:

  12. History of Ultrasound • 1954-1957:

  13. History of Ultrasound • Doppler (1842):

  14. History of Ultrasound

  15. What is Medical Ultrasound? • Prevention: actions taken to avoid diseases. • Diagnosis: the process of identifying a disease by its signs, symptoms and results of various diagnostic procedures. • Treatment: care by procedures or applications that are intended to relieve illness or injury.

  16. Diagnosis

  17. Medical Diagnosis: Heart Attack as an Example • Heart attack: Coronary artery disease, blockage of blood supply to the myocardium.

  18. Basics

  19. Basics

  20. Basics • Characteristic Impedance:

  21. Basics Amplitude of Acoustic Wave Pressure

  22. Scan Modes • A-mode (A-scan, 1D). • B-mode (Gray scale, 2D). • M-mode (motion) • Color Doppler (2D, blood flow). • Spectral Doppler (localized, blood flow). • Audio Doppler.

  23. A-Scan (Amplitude, 1D)

  24. B-Scan (Brightness, 2D)

  25. M-Mode (Brightness, 2D) • A-Mode data in time

  26. Scan Formats linear sector curved linear easy access wide view easy access limited view limited access wide view

  27. 3D Ultrasound

  28. Doppler-Mode • Doppler Effect

  29. Doppler Effect

  30. Doppler-Mode • Doppler Effect

  31. Doppler-Mode • Doppler Systems: • Continuous Doppler • Pulse Doppler

  32. Doppler-Mode • Continuous Doppler: • Just records the change in frequency • Display the changes in color or sound • Pulse Doppler: • Records the reflection depth along with the Doppler frequency

  33. Ultrasound vs. Other Imaging Systems

  34. Ultrasound Developements • Harmonic imaging

  35. Ultrasound Developements • Harmonic imaging

  36. Ultrasound Developements • 2D Transducers for 3D imaging • Increasing the Number of Transducer Elements • Intra Vascular Ultrasound

  37. Ultrasound Developements • Contrast improvement: • Contrast agents (containing bobbles for THI and Endothelial Dysfunction measurement)

  38. Ultrasound Developements • Miniaturization: • Decreasing the weight to a few hundred grams. • Leads to more invasive applications

  39. Ultrasound Developements • Immunity: • Appropriate power dose for different diagnostic and therapeutic applications

  40. Bio-Effects • Heating • Cavitation

  41. Cavitation • Formation and behavior of gas bubbles in acoustic fields. • Transient cavitation: sudden growth and collapse of bubbles, resulting shock waves and very high temperatures.

  42. Clinical Applications • Cardiology, surgical, intra-vascular, …etc. (From www.acuson.com)

  43. Characteristics of Diagnostic Ultrasound • Non-invasive. • Safe (under regulations). • Real-time. • Reflection mode (similar to RADAR). • Blood flow imaging. • Portable. • Body type dependent.

  44. Characteristics of Diagnostic Ultrasound • Spatial resolution: • Lateral : diffraction limited. • Axial: transducer and system bandwidth, pulse energy. • Contrast resolution: spatial resolution and speckle brightness variations. • Temporal resolution: speed of sound in tissue.

  45. Ultrasonic Transducers

  46. Ultrasonic Array Transducers (From www.acuson.com)

  47. Generic Ultrasonic Imaging System • Receiver: • Programmable apodization, delay control and frequency control. • Arbitrary receive direction. • Image processing: • Pre-detection filtering. • Post-detection filtering. • Scan converter: various scan format.

  48. Spatial Fourier Transform • Temporal frequency: • Spatial frequiency:

  49. Spatial Fourier Transform • Non-propagating signal: • Propagating signal:

  50. Spatial Fourier Transform • Spatial frequency as a vector: • Spatial Fourier transform:

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