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Sudil PaudyalM.Sc. MIT (12)IOM, MMC
DOPPLER ULTRASOUND AND ADVANCES IN USG TECHNOLOGY
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INTRODUCTION Doppler effect: Change in the perceived frequency of
sound emitted by a moving source. First described by Christian Doppler in 1843. Same effect that causes a siren on a fire truck to sound
high pitched as the truck approaches the listener (the wavelength is compressed) and a shift to a lower pitch sound as it passes by and continues on (the wavelength is expanded).
In ultrasound, the Doppler effect used to measure blood flow velocity.
Ultrasound reflected from red blood cells will change in frequency according to the blood flow velocity.
When direction of blood flow is towards the transducer, the echoes from blood reflected back to the transducer will have a higher frequency than the one emitted from the transducer.
When the direction is away from the transducer, the echoes will have a lower frequency than those emitted.
The difference in frequency between transmitted and received echoes is called the Doppler frequency shift, and this shift in frequency is proportional to the blood flow velocity.
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DOPPLER FREQUENCY SHIFT The Doppler shift is the difference between the
incident frequency and reflected frequency. When the reflector is moving directly away from or
toward the source of sound, the Doppler frequency shift (fd) is calculated as
where fI is the frequency of the sound incident on the reflector and fr is the frequency of the reflected sound.
Thus, the Doppler shift is proportional to the velocity of the blood cells.
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When the sound waves and blood cells are not moving in parallel directions, the equation must be modified to account for less Doppler shift.
The angle between the direction of blood flow and the direction of the sound is called the Doppler angle.
This reduces the frequency shift in proportion to the cosine of this angle. If this angle is known then the flow velocity can be calculated.
FACTORS AFFECTING DOPPLER SHIFT1. Doppler angle
2. Transducer frequency
3. Scattering of US by blood
4. Blood flow characteristic
1. DOPPLER ANGLE Also known as the angle of insonation. Estimated by a process known as angle correction,
which involves aligning an indicator on the duplex image along the longitudinal axis of the vessel.
Few considerations that affect the performance of a Doppler examination: The cosine of 90° is zero, so if the ultrasound beam is
perpendicular to the direction of blood flow, there will be no Doppler shift and it will appear as if there is no flow in the vessel
The angle of insonation should also be less than 60° at all times, since the cosine function has a steeper curve above this angle, and errors in angle correction will be magnified
ANGLE EFFECTS Maximum Doppler shift at 0 degrees minimum at
90 degrees – proportional to the Cosine of the angle between the beam and direction of travel.
Direction of movement
Alignment of beam
Effect of the Doppler angle in the sonogram. Higher-frequency Doppler signal is obtained if the beam is aligned more to the direction of flow. In the diagram, beam (A) is more aligned than (B) and produces higher-frequency Doppler signals. The beam/flow angle at (C) is almost 90° and there is a very poor Doppler signal. The flow at (D) is away from the beam and there is a negative signal.
11If the beam direction is perpendicular to the direction of flow, the Doppler frequency is ZERO!
2. TRANSDUCER FREQUENCY Increase in transducer frequency causes
increased doppler frequency shift. At frequencies between 2-10 MHz, doppler shift
comparatively small & in audible range (shift from 0-10 KHz) for most physiological motion (for velocity range from 0-100 cm/s).
Change of frequency → measurable → movement of reflector towards/away from transducer.
Depending on ↑ or ↓ in frequency → direction of movement.
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3. SCATTERING OF US BY BLOOD Smooth wall of blood vessel → specular
reflection → strong echoes. Us wavelength > size of RBCs → scattering of
wave in all directions (Rayleigh-Tyndall scattering). Size of echo from blood → ↓.
Intensity of scattered us ↑ with 4th power of frequency as images of vessel lumen differ significantly with instruments of different frequency.
4. CHARACTERISTICS OF BLOOD FLOW Blood (viscous medium) → wall exerts drag effect on
moving blood → slow movement near the wall than center.
Non pulsatile flow with low velocity → parabolic velocity profile → laminar flow.
Fast /accelerated flow → same velocity all over → plug flow.
Major artery → plug flow during systole & laminar flow during diastole. Venous flow → laminar.
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FLOW PATTERNS Laminar flow
Highest in center Zero at wall
Turbulent flow Larger distribution of
velocities
BASIC EQUIPMENT Same probe can be used for Doppler
Scanning. High Q transducer material (transducer will
produce narrow range of frequency) Air backing can be used for maximal sound
reflection from backing layer. Lower frequency probe. Usually 3.5MHZ
probe.
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TYPES OF DOPPLER OPERATION1. Continuous wave doppler
2. Pulsed wave doppler
3. Duplex scanning
4. Color flow doppler imaging
5. Power doppler
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1. CONTINUOUS WAVE DOPPLER Simplest and least expensive device for measuring
blood velocity Two transducers required, one transmitting the
incident ultrasound and other detecting the resultant continuous echoes.
Two elements in one transducer at inclination. High Q transducer with no backing block
Suffers from depth selectivity with accuracy affected by object motion within the beam path.
Multiple overlying vessels will result in superimposition, making it difficult to distinguish a specific Doppler signal.
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Advantages: Simple, Good quality low noise signal, No aliasing.
Disadvantages: Lacks depth resolution, Confusing superimposition,
Application: Superficial structures,e.g carotid artery, limb arteries.
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2. PULSED WAVE DOPPLER Combines the velocity determination of continuous
wave Doppler systems and the range discrimination of pulse-echo imaging.
Transducer is used in a pulse-echo format, similar to imaging.
The SPL is longer (a minimum of 5 cycles per pulse up to 25 cycles per pulse) to provide a higher Q factor and improve the measurement accuracy of the frequency shift (although at the expense of axial resolution).
Depth selection is achieved with an electronic time gate circuit to reject all echo signals except those falling within the gate window, as determined by the operator.
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Each Doppler pulse does not contain enough information to completely determine the Doppler shift, but only a sample of the shifted frequencies measured as a phase change.
Stationary objects within the sample volume do not generate a phase change in the returning echo when compared to the oscillator phase, but a moving object does.
Repeated echoes from the active gate are analyzed in the sample/hold circuit, and a Doppler signal is gradually built up.
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Depth (range) controlled by time between pulse transmission & gating on. Axial length ( thickness) determined by time the gate is open.
Width of sampling volume (gated Doppler acquisition area) → width of Doppler beam (pear shaped).
7 μs for ultrasound to travel 1 cm (average soft tissue)
PRF determines the maxm. depth for Doppler shift. So ↑PRF → ↓depth.
Doppler shift detection in pulsed Doppler = 1/2 of PRF.
If Doppler shift frequency > detectable frequency in deep vessels→ aliasing (incorrect shift).
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The discrete measurements acquired at the PRF produce the synthesized Doppler signal.
According to Nyquist sampling theory, a signal can be reconstructed unambiguously as long as the true frequency (e.g., the Doppler shift) is less than half the sampling rate.
Thus, the PRF must be at least twice the maximal Doppler frequency shift encountered in the measurement.
For Doppler shift frequencies exceeding one-half the PRF, aliasing will occur, causing a potentially significant error in the velocity estimation of the blood.
Thus, a 1.6-kHz Doppler shift requires a minimum PRF of 2 *1.6 kHz =3.2 kHz.
One cannot simply increase the PRF to arbitrarily high values, because of echo transit time and possible echo ambiguity.
Aliasing of the spectral Doppler display is characterized by "wraparound“ of the highest velocities to the opposite direction when the sampling (PRF) is inadequate. Right: Without changing the overall velocity range, the spectral baseline is shifted to incorporate higher forward velocity and less reverse velocity to avoid aliasing. The maximum, average, and minimum spectral Doppler display values allow quantitative determination of clinically relevant information such as pulsatility index and resistive index.
Advantages: Identification of source. Small signal crystal transducer (cardiology). Blood flow signal from ranges gate
Disadvantages: Quality may suffer d/t background noise
(switching). Aliasing.
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3. DUPLEX SCANNING Combination of 2D B-mode imaging and pulsed
Doppler data acquisition. Operates in the imaging mode and creates a real-
time image. The Doppler gate is positioned over the vessel of
interest with size (length and width) appropriate for evaluation of blood velocity, and at an orientation (angle with respect to the interrogating US beam) that represents the Doppler angle.
When switched to Doppler mode, the scanner electronics determines the proper timing to extract data only from within the user-defined gate.
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Most often, electronic array transducers switch between a group of transducers used to create a B-mode image and one or more transducers used for the Doppler information.
The duplex system allows estimation of the blood velocity directly from the Doppler shift frequency, since the velocity of sound and the transducer frequency are known, while the Doppler angle can be estimated from the B-mode image and input into the scanner computer for calculation.
Once the velocity is known, flow (in units of cm3/s) is estimated as the product of the vessel’s cross-sectional area (cm2) times the velocity (cm/s).
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Errors in the flow volume may occur. The vessel axis might not lie totally within the scanned plane, the vessel might be curved, or flow might be altered from the perceived direction.
The beam-vessel angle (Doppler angle) could be in error, which is much more problematic for very large angles, particularly those greater than 60 degrees
The Doppler gate (sample area) could be mispositioned or of inappropriate size, such that the velocities are an overestimate (gate area too small) or underestimate (gate area too large) of the average velocity.
Noncircular cross sections will cause errors in the area estimate, and therefore errors in the flow volume.
Advantages: Selection of site & sample volume for Doppler. No overlap of information from other
vessels/structures. Measurement of vessel angle in 2-3 sec.
Disadvantages: Angle restriction if same transducer for imaging &
Doppler. Flow information from one site in image
4. COLOUR DOPPLER FLOW IMAGING. Provides a 2D visual display of moving blood in
the vasculature which is superimposed on the conventional gray scale image.
Imaging of flow through entire real-time image. Allowing visualization of blood vessels and their
flow characteristics + image of tissue surrounding.
Multiple gate in receiving transducer circuit each gate is controlled by time delay circuit.
These gate arrange close to each other so they can simultaneously sample Doppler shift information across entire lumen of large vessels.
Multiple gate+ real time35
Velocities and directions are determined for multiple positions within a subarea of the image, and then color encoded (e.g., shades of red for blood moving toward the transducer, and shades of blue for blood moving away from the transducer).
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Advantages: Vessels small on gray scale image can be seen (presence of flow
detected with relative ease) Differentiation between and other structure simplified. Improved definition of lumen. Improved measurement of stenosis.
Limitations: Compute mean velocity and image not corrected for doppler
angle so it is qualitative . PRF limited Detailed study of vessels not possible. May obscure vascular pathology due improper adjustment. Other motion like peristalsis, cardiac motion may represented
as color which may obscure signal. High cost. spatial resolution poorer than gray scale image, noise of slowly
moving structure can affect the small echoes returning from the moving blood cell.
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5. POWER DOPPLER A signal processing method that relies on the total
strength of the Doppler signal (amplitude) and ignores directional (phase) information.
The power (also known as energy) mode of signal acquisition is dependent on the amplitude of all Doppler signals, regardless of the frequency shift.
This dramatically improves the sensitivity to motion (e.g., slow blood flow) at the expense of directional and quantitative flow information.
Does not give the flow direction or the velocity, but is more sensitive to detecting small amounts of flow, as noise in the image is reduced.
Aliasing artifacts do not occur in Power Doppler 3-dimensional Power Doppler is also possible
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Power Doppler produces images that have more sensitivity to motion and are not affected by the Doppler angle (largely nondirectional),
Aliasing is not a problem as only the strength of the frequency shifted signals are analyzed (and not the phase).
Greater sensitivity allows detection and interpretation of very subtle and slow blood flow.
On the other hand, frame rates tend to be slower for the power Doppler imaging mode, and a significant amount of "flash artifacts" occur, which are related to color signals arising from moving tissues, patient motion, or transducer motion.
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Color flow (top) and power Doppler (bottom)images of the same phantom under the same conditions.The directions of flow toward and away fromthe transducer are seen in the color flow image (top).The power Doppler image (bottom) displays only theintensity of the Doppler shift
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Advantages: No aliasing Angle independent Increased sensitivity to detect low- velocity flow Useful in imaging tortuous vessels Increases accuracy of grading stenosis
Disadvantages: Do not provide velocity of flow Donot provide direction of flow Very motion sensitive( poor temporal resoultion)
SPECTRAL ANALYSIS The Doppler signal is typically represented by a
spectrum of frequencies resulting from a range of velocities contained within the sampling gate at a specific point in time.
With the pulsatile nature of blood flow, the spectral characteristics vary with time.
Interpretation of the frequency shifts and direction of blood flow is accomplished with the fast Fourier transform, which mathematically analyzes the detected signals and generates amplitude versus frequency distribution profile known as the Doppler spectrum
The intensity of the Doppler signal at a particular frequency and moment in time is displayed as the brightness at that point on the display.
Velocities in one direction are displayed as positive values along the vertical axis, and velocities in the other direction are displayed as negative values. As new data arrive, the information is updated and scrolled from left to right.
Pulsed-wave US spectrum displays the maximum, minimum, and average calculated blood flow velocities. The pulsatility index, resistivity index, and systolic-to-diastolic ratio are calculated from these values
The PI will increase as flow is impeded by a stenosis. Care must be taken when the PI is used. Proximal and distal stenoses as well as natural flow resistance from the vascular bed may affect PI measurement. The RI is easier to calculate and is used to evaluate a number of physiologic conditions. Both of these indexes are used to assess the resistance to flow in the vascular system
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ADVANCEMENTS IN USG TECHNOLOGY
HARMONIC IMAGING Harmonic frequencies are integral multiples of the
frequencies contained in an ultrasound pulse (a f MHz, upon interaction with a medium, will contain high-frequency harmonics of 2f,3f, 4f and so on, etc.)
These higher frequencies arise through the vibration of encapsulated gas bubbles used as ultrasound contrast agents or with the nonlinear propagation of the ultrasound as it travels through tissues.
Harmonic imaging enhances contrast agent imaging by using a low-frequency incident pulse and tuning the receiver (using a multi frequency transducer) to higher-frequency harmonics.
For harmonic imaging, longer spatial pulse lengths are often used to achieve a higher transducer Q factor.
Improve the sensitivity to the ultrasound contrast agent. 47
Body wall region close to transducer →less harmonics.
At depth → less harmonics (increasing attenuation of higher order harmonics). Strongest harmonics at greatest pressure amplitudes (near pulse center).
Resultant effect → at near surface good rejection of artifacts & clutter from multiple pulse reflections.
Most useful in technically difficult patients i. e. thick & complicated body wall structures.
Conventional imaging → hazy image (distortion of the transmitted beam by shallow surface layers or to reverberations between the skin and ribs). The distortions and reverberations consist entirely of us energy at the fundamental frequency.
Peculiarities of harmonic image: Increase signal-to-noise ratio with better
interpretation of image. Superior lateral & elevational resolution as
compared to the fundamental images. Removal of clutter and haze with more
clear and defined image due to side-lobe level reduction in the second harmonic beam. Harmonic beams are narrower with lower side-lobe levels than fundamental ones.
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EXTENDED FOV IMAGING The transducer is slowly translated laterally
across the large anatomic region of interest. During this motion, multiple images are
acquired from many transducer positions. The proper relative positions of the multiple
images are determined in the regions of overlap between successive images.
The registered image data are accumulated in a large image buffer and then combined to form the complete large FOV image
Can be used to view whole course of vessels.
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CODED PULSE EXCITATION Short, highly focused ultrasound pulses that optimize
spatial resolution are generally obtained at higher frequencies.
Higher frequency-more attenuation. Coded ultrasound pulses are a potential means of
overcoming this limitation, providing good penetration at the higher frequencies necessary for high spatial resolution.
The coded pulses are produced with a very specific, characteristic shape, and the resulting echoes will have a similar shape.
These pulse shape locations may be determined with a tight spatial tolerance and are assumed to correspond to the locations of reflective structures in the body.
The end result is an image with good echo signal and good spatial resolution at large depths. 54
Conventional B-mode and coded pulse US images of the liver. The spatial resolution of the coded pulse image is very comparable with that of the 13-MHz conventional image . However, the useful imaging depth is about 7.5 cm for the coded pulse image compared with only about 2.8 cm for the conventional image.
3D US 3D ultrasound imaging acquires 2D tomographic image
data in a series of individual B-scans of a volume of tissue.
Forming the 3D dataset requires location of each individual 2D image using known acquisition geometries.
3D ultrasound works by taking thousand of slices in a series (called volume of echoes) the volume are then digitally stored and shaded to produce 3D images that look more life like.
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Volume sampling can be achieved in several ways with a transducer array: (1)linear translation, (2)freeform motion with external localizers to a
reference position, (3)rocking motion, and (4)rotation of the scan
4D ULTRASOUND 4D Ultrasound represents the difference between
video and a still photograph. Through this technology, three-dimensional image
is continuously updated, providing a "live action" view.
The entirely digital platform and very fast processors cope with the large volume of data required to reconstruct 3D images again and again, giving the impression of a moving image.
4D Ultrasound takes multiple 2-dimensional ultrasound images, creates a 3-dimensional image and adds the element of time to the process. The result: live action images of any internal anatomy. 58
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Chewing
Sleepy
Firstwhinge
Smiling
ELASTOGRAPHY Stiffness and compliance of different tissue can be
assessed . A set of digital RF echo data from ROI is obtained and
the tissue is then compressed usually by transducer and further set of RF echo data obtained.
This is then cross correlated with initial data and any changes in arrival time of pulses from equivalent volume of tissue can be obtained.
An estimate of local tissue strain can be asssessed and from this the degree of tissue stiffness can be assessed.
Tissue stiffness is described by the Young modulus expressed in kilopascals (E = 3γC2).
The elastography methods are based on a common approach: measurement of deformation induced in a tissue by a force. 60
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Elastography is therefore an application, which produces the force coupled with a measurement system for the deformities caused by the force.
There are several types of forces or applications: static compression induced externally by manual
compression or internally by organ motion (heart, vessel, breathing);
dynamic compression induced with a continuous vibration at a given frequency;
impulse compression (transient vibration): induced externally by a transient mechanical impulse (FibroScan®) or internally by an ultrasound impulse (ARFI, SWE), both compression types producing shear waves.
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ELASTOGRAPHY TECHNIQUES Impulse elastography:
Uses an external mechanical device (FibroScan) or an internal acoustic radiation force (ARFI and SWE) to induce shear waves in the tissue to be explored.
Shear wave propagation velocity (Vs) is then measured in m/s using ultrasound imaging in the tissue being studied in order to assess its stiffness.
Uni-dimensional transient elastography: FibroScan Developed around 10 years ago Based on shear wave, which is generated by an
external mechanical impulse and whose speed is measured by an ultrasound one-dimensional probe.
The one-dimensional probe (3.5 MHz) is mounted along the axis of an electro-dynamic transducer (vibrator).
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• The FibroScan® estimates liver stiffness by measuring the velocity of elastic shear waves in the liver parenchyma generated by the mechanical push.
• The propagation velocity is directly related to the stiffness of the medium, defined by the Young modulus.
• Stiff tissues exhibit higher shear wave velocities than soft tissues.
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Acoustic Radiation Force Impulse (ARFI) Imaging mode elastography: A new method for quantifying mechanical properties of
tissue, without manual compression, by measuring the shear wave velocity induced by acoustic radiation and propagating in the tissue.
Developed by Siemens. Provides a single uni-dimensional measurement of
tissue elasticity like the FibroScan, although the measurement area can be positioned on a two-dimensional Bmode image.
The region is a 1 × 0.5 cm rectangular, which can be freely moved in the two-dimensional Bmode image to a maximum depth of 8 cm from the skin plane.
The measurement is expressed in m/s, expressing shear wave speed, travelling perpendicular to the shear wave source.
The technique has been implemented on the ultrasound probe designed for abdominal imaging.
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Shear Wave Elastography (SWE): Was introduced in 2005. Relies on the measurement of the shear wave
propagation speed in soft tissue; like ARFI, does not require an external vibrator to generate the shear wave. Based on the generation of a radiation force in the tissue to create the shear wave.
The ultrasound probe produces a very localized radiation force deep in the tissue of interest that induces a shear wave, which then propagates from this focal point.
Several focal points are then generated almost simultaneously, in a line perpendicular to the surface of the patient's skin.
This creates a conical shear wave front, which sweeps the image plane, on both sides of the focal point. The progression of the shear wave is captured by the very rapid acquisition of ultrasound images (up to 20,000 images per second), called UltraFast Imaging.
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A high-speed acquisition is necessary to capture the shear wave as it moves at a speed in the order of 1 to 10 m/s.
Comparison of two consecutive ultrasound images allows the measurement of displacements induced by the shear wave and creates a “movie” showing the propagation of the shear wave whose local speed is intrinsically linked to elasticity.
The propagation speed of the shear wave is then estimated from the movie that is created and a two-dimensional color map is displayed, for which each color codes either the shear wave speed in meters per second (m/s), or the elasticity of the medium in kilopascals (kPa).
This color map is accompanied by an anatomic reference gray scale (or B-mode) image. This quantitative imaging technique is a real-time imaging mode.
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Static elastography: Developed by Hitachi. The operator manually applies gentle pressure with the
ultrasound probe in order to induce in the underlying tissues a deformation.
Only the deformed tissue subject to the manual compression is measured, rather than a direct measurement of elasticity. The deformation is considered to be inversely proportional to elasticity.
A color map of tissue elasticity is obtained: this is a qualitative approach. In more recent systems, the deformation of the liver parenchyma as a result of vascular beating or respiration alone has also been used.
TRANSDUCER DEVELOPMENTS
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Multielement array transducers: Possible for US beam focus and stear
electronically, different group of elements can be used for different tasks e.g pulse doppler.
Beam can be manipulated in two direction thus improving resolution.
Now days 2D array are available possible for volume scan(3D and 4D possible)
Small sized transducers: Can be mounted on catheter to pass into
coronary arteries. Specialized transducer like trans rectal and
TVS(endo cavitary).
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ECHO-ENHANCING AGENT Most agents comprised of encapsulated microbubbles
of 3 to 5 micrometer diameter containing air, nitrogen, or insoluble gaseous compounds such as perfluorocarbons.
Encapsulation materials, such as human albumin, provide a container for the gas to maintain stability for a reasonable time in the vasculature after injection.
Response of US to microbubble depends on acoustic power. At low power (MI -0.1-0.3) they reflect and scatter Us. At moderate power (MI abt 0.5) they resonate frequency of
US. At high power (MI-0.7-0.8) microbubble oscillate nonlinear
fashion and production of harmonic signal which are specific to agent .
More than this power micro bubble disrupted and brust.71
SPATIAL COMPOUND IMAGING Aims to improve image quality by averaging
several coplanar ultrasound frames into a single image.
Mechanism: Repeated us beam steering in same tissue by
an array transducer using parallel beams oriented in different directions→ echoes from multiple aquisition of same tissue → averaged → single composite image.
Multiple beams for same tissue (vs one beam in conventional B-mode imaging) hence more time for data acquisition & reduced frame rate.
set of us beam lines for conventional imaging
Two additional set of us beam lines for spatial compound imaging. Upto nine sets are used.
Advantages of compound imaging: greater spatial details of lesions and tissue in the
FOV with decreased image graininess (due to speckle). Speckle varies with beam line direction, averaging echoes from different directions average out and smooth the speckle with less grainy image.
Improved contrast & margin definition. Reduction of enhancement & shadowing
artifacts.
Conventional image of breast mass
Spatial compound imaging of breast mass
ELECTRONIC SECTION FOCUSING Electronic focusing of US pulse in the lateral direction by
transducer arrays produces great benefits compared with mechanical focusing.
Most transducers in current clinical use still employ mechanical focusing (curved piezoelectric elements or acoustic lenses) in section thickness direction → resultant highly variable section thickness → great difficulty in accurately visualizing small structures.
Electronic focusing is employed with more than one-dimensional single row of piezoelectric elements {referred to as 1.25D, 1.5D, 1.75D, or full 2D (two-dimensional) arrays} as per the number of element rows and the level of independence with which the individual rows may be excited.
Full-size, filled 2D array transducers are not yet commercially available, only 1.25D arrays are available.
The greater the number of rows, the greater the ability for full electronic focusing which provide multiple, user-selectable elevational focusing and more uniform section profiles.
US images of a phantom with small anechoic spheres in conventional B mode & electronic focusing in section thickness direction.
MINIATURIZATION Modern full-size US scanners are relatively
portable and inexpensive. The general trend toward hardware
miniaturization and the use of dedicated integrated circuitry is making possible even smaller and less expensive US scanners, with few (if any) compromises in general image quality and available features.
This trend toward lower cost and smaller systems has great potential to radically alter the overall role of US in medicine.
Commercially available small US scanners from two vendors. The left scanners are 13.3 in (33.8 cm) tall and weigh 5.7 lb (2.6 kg), whereas the right scanners weigh about 3 lb (1.4 kg). The dedicated electronics module attached to the transducer cable weighs 10 oz (0.3 kg) and is 7.6 in (19.3 cm) long.
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FUSION TECHNOLOGY An emerging technique in the field of abdominal
imaging with translation possibilities to neuroradiology. Involves co-registered display of live ultrasound with a
reference series from another modality, such as CT, MRI or PET.
As the ultrasound exam is performed the fusion system continuously generates reformatted planes from the reference series matching the oblique imaging planes of the ultrasound transducer.
The reformatted planes are displayed either as an overlay or side-by-side with the live ultrasound.
This display enhances interpretation of ultrasound by enabling a direct comparison with the reference images from the same view angle.
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Fusion imaging makes use of a tracking system to localize ultrasound transducers and other devices relative to the patient.
Optical and electromagnetic systems are available, the latter being most commonly used.
Various software tools are also used to bring the reference series into alignment with the tracking system for fusion display.
Tracking sensors are also incorporated into some interventional devices such as introducers and ablation needles, enabling the display of needle location as an overlay on live ultrasound image.
For the fusion imaging technique, a variety of tracking methods are available, including optical, image-based, and EM tracking.
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Fusion imaging and contrast-enhanced ultrasonography (US)-guided radiofrequency ablation (RFA) of a 1-cm hepatocellular carcinoma (HCC) in a patient with a hepatitis B virus carrier
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WIRELESS TRANSDUCER
They feature proprietary ultra-wideband (UWB) wireless radio to help ensure images are transferred at high speeds, with full data integrity and free from interfering with other medical equipment—and all without cables.
These breakthrough cable-free innovations help provide uninterrupted, hassle-free, real-time imaging that allows you to scan in the position that is comfortable for you and safe for your patient.
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SMARTPHONE ULTRASOUND Inexpensive, which will lead to even
wider use, especially in rural and third-world areas
Widespread use in Emergency Rooms, and in the surgical and medical wards, as well as in office practice
A great start for diagnosing all types of medical problems, as a screening device, such as vascular problems, gallstones, kidney stones, abdominal masses, and other problems.
The model shown is a Mobisante which is the world’s first smartphone-based ultrasound imaging system, the MobiUS SP1 ultrasound system.
CONCLUSIONS Modern US equipments are based on many of
the same fundamental principles employed in the initial devices used for human imaging over 50 years ago.
USG is relatively inexpensive, portable, safe, and real-time in nature, all of which make it one of the most widely used imaging modalities in medicine.
B-mode US continues to experience very significant evolution in capability with the US science, technology, and applications are expanding at a brisk pace and are far from mature with exciting developments in future.
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FIND MORE AT: The essential physics of medical imaging;
Bushberg JT, Seibert JA et.al. AAPM/RSNA Physics Tutorial for Residents:
Topics in US Ultrasound elastography in liver; Frulio N,
Trilaud H. Fusion imaging of real-time ultrasonography
with CT or MRI; Lee MW http://e-ultrasonography.com
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