In the signal transmission process, the transducer arrays, formed by ceramic polymer composite elements of variable shape and thickness, and the multilayered technology led to a more accurate shaping of the US pulses in terms of frequency, amplitude, phase, and length. The development of piezoelectric crystals with a lower acoustic impedance and greater electromechanical coupling coefficients, the improvement of the physical characteristics of the absorbing backing layers, and the quarter-wave impedance matching layers represent the most significant results of the US transducer research.²

Increased bandwidth of transducers allows a better spatial and contrast resolution with a consequent improvement of the axial resolution due to shorter pulse length. Shorter transmission pulses used in a broadband emission generates shorter echo pulses that can be faithfully converted into electric signals. Since short pulses are attenuated to a greater extent and are characterized by less penetration than long pulses, specific techniques have been introduced by the different manufacturers to allow a more accurate shaping of the US pulse in terms of the control of the transmission frequency, amplitude, phase, and pulse length. Phase can only be determined by the comparison with a reference waveform or with another pulse. This can be achieved by using multiple beamformers allowing the
direct integration of the phase information from the signal received from the adjacent lines.² Another way to improve penetration is by increasing the output power, even though it is limited by safety limits, or by utilizing excitation signals much more sophisticated than the single-carrier short pulses currently used in the US scanners. These signals are usually defined coded excitation and increase the signal-to-noise ratio and the frame rate. In coded-emission mode, the scanner transmits not a single pulse but a sequence of 8 to 22 short, high-frequency transmission pulses that may have different phases and are modulated in a code sequence. Comparison between transmitted pulses and received signal shapes using matched filtering (decoding) is subsequently performed with a very high sampling rate.² In chirp encoding, a long specially shaped pulse is transmitted with frequency and amplitude progressively varied. The matched filtering process involves comparing the echoes with a stored reference version of the transmitted chirp. When the two waveforms present identical shape but different amplitude, they are out of alignment and the output of the process is low. The filter output is a large-amplitude compressed pulse for every match between a genuine chirp echo and the reference chirp.

Electronic focusing, obtained by activating a series of elements in the array with appropriate delay, can easily be used to regulate the focal depth. The higher the number of channels involved to activate the array elements in a combined mode and with the appropriate delays, the more accurately the US beam can be focused. In the dynamic transmit focusing modality, edge crystal elements have a longer pulse excitation than center elements, making the US beam focus at two different points in the insonated field, improving lateral resolution. As the resulting wave front has the characteristics of a short excitation pulse, the axial resolution is preserved.² The spatial and contrast resolution of the US image had a further improvement due to matrix transducers, which allows a further reduction in the thickness of the US beam with better spatial resolution.

Tissue harmonic imaging has allowed a further improvement in the signal-to-noise ratio and image quality due to the improved contrast resolution and speckle and artifact reduction even in patients with a limited explorability including obese patients. Harmonic imaging requires large transducer bandwidth and that the system is configured to receive preferentially harmonic components produced by tissues, hence at double the transmitted frequency, by a high-pass filter, and to cancel out the fundamental echo signals generated directly from the transmitted acoustic energy. Such filtering is successful in eliminating echoes from solid stationary tissues that present prevalently linear properties, even though the effect is to reduce the range of frequencies (or bandwidth) contained in the received echoes, causing a low spatial axial resolution of the resulting image. Harmonic imaging and speckle reduction techniques have improved signal-to-noise ratio and image quality also in patients who are difficult to explore by US, such as obese or largebody-habitus subjects.

Compound imaging may be obtained by spatial (transmit compounding) or frequency compound. In spatial compound imaging, the same insonated slice is interrogated according to different insonation angles, while in frequency compound imaging, the same slice is insonated more times with different frequencies. The resulting images are managed by subtracting step by step all echoes, which appears incoherently in the different acquired images, corresponding essentially to noise. Compound imaging allows a reduction of speckles, clutter, and noise, without compromising other beneficial image characteristics such as spatial resolution, and improves contrast-to-noise ratio and better depiction of the curved surface such as the renal poles. Compounding also reduces shadowing from strongly reflecting interfaces such as organ boundaries, fascial planes, and vessel walls.

Tissue equalization is based on regional and adaptive methods to analyze, using regional speckle statistics and thermal noise identification, and applies an algorithm to perform region-by-region adjustment to lateral gain, depth gain, and overall gain.²

The color and power Doppler techniques have reached a high sensitivity for the renal parenchymal flows. In particular, the introduction of wideband Doppler technology, making use of short pulses, has led to some advantages in imaging subtle blood flows due to the improved frame rate and axial resolution. Differently from color Doppler, the sensitivity of power Doppler for the renal flows is not dependent from the angle of insonation. Moreover, power Doppler has a higher sensitivity than color Doppler for the renal parenchyma flow in particular at renal poles. The introduction of wideband color Doppler (e.g., advanced dynamic flow) has improved the sensitivity and contrast resolution for the flow signal of the renal parenchymal vessels up to the interlobular vessels, which can be imaged with a 2- to 5-MHz convex US transducer. 3D US (volume sonography), elastography, and microbubble contrast agents represent further advancements in US.

3D US acquisition is obtained by using multidimensional matrix transducers with parallel processing of the signal. Digitally stored volume data can then be displayed in a multiplanar array that simultaneously shows three perpendicular planes throughout the volume: axial, sagittal, and reconstructed coronal views. The volume can be explored by scrolling through parallel planes in any of the three views and by rotating the volume to obtain an optimal view of the structure of interest.² Data can also be displayed as true 3D images using various rendering algorithms, including maximum-intensity projections and surface renderings.

The first factor that determines the persistence of microbubbles in the peripheral circle is the diffusibility of the filling gas throughout the peripheral shell.⁵ The diffusibility, expressed by the diffusion coefficient, and the solubility of the filling gas in the blood strongly affect microbubble persistence in the circle, according to the following equation:

where T is the microbubble persistence in the blood, ρ is the density of the gas, R is the initial radius of the microbubble, D is the diffusion coefficient of the gas in the substance of the shell, and C_s is the saturation coefficient of exchange of gas between aqueous and gaseous phases, which is higher in gas with increased solubility in the blood.

The previous equation is an effective approximation of the microbubbles persistence in the bloodstream. Anyway, the surface tension is another important mechanism responsible for the disappearance of the filling microbubble gas in a gas-saturated liquid.⁵ The microbubble shell contains surface-active molecules, namely, phospholipids, which act as surfactant reducing the surface tension. The surfactant layer exerts a counterpressure against the tendency of surface tension and other forces to cause gas diffusion from a microbubble. The relation of the surface tension with microbubble dissolution is

where is the variation of microbubble radius (R), with time (t), which is related to microbubble disappearance from the peripheral circle; D is the diffusion coefficient of the gas; L is the Ostwald coefficient, which corresponds to the ratio of the amount of gas dissolved in the surrounding liquid and in the gas phase per unit volume; C_i/C_s is the ratio of the dissolved gas concentration to the saturation concentration; S_T is the surface tension; and p₀ is the ambient pressure. In Eq. (2), the surface tension is showed to strongly affect the dissolution of microbubbles, and the higher is the surface tension, the lower is the microbubble persistence.

The stability of a microbubble in the peripheral circle is related to the osmotic pressure of the filling gas, which counters the sum of the surface tension and blood arterial pressure⁵:

where C_G and C_A are concentrations of the filling gas (_G) and air (_A), K is the gas constant, T is the absolute temperature, S_T is the surface tension, R is the bubbles radius, p_b is the systemic blood pressure, and p_atm is the atmospheric pressure (101 kPa). The limited solubility in blood determines an elevated vapor concentration in the microbubble relative to the surrounding blood and establishes an osmotic gradient that opposes the gas diffusion out of the microbubble. After the initial size adjustment due to the effect of body temperature, the microbubbles will either swell or shrink depending on the partial pressure of the air in the bubble, followed by a period of slow diffusion of gas into the bloodstream.

Also, diffusion and Ostwald coefficients strongly determine the rate of decrease of the bubble radius, which is a direct measure for the disappearance rate of the microbubble:

where C_G and C_A are concentrations of the filling gas (_G) and air (_A); R is the bubbles radius; D_G, D_a and L_G, L_a are diffusion and Ostwald coefficients, respectively, for the filling gas (_G) and the air (_A); p_atm is the atmospheric pressure (101 kPa); K is the gas constant; and T is the absolute temperature. From Eqs. (4) and (5), it can be derived that the diffusion and Ostwald coefficients determine the rate of decrease of the bubble radius, which is a direct measure for the disappearance rate of the microbubble. Thus, microbubble filled with gases having lower diffusion and/or Ostwald coefficient will persist longer in the bloodstream.

The nature of the encapsulating shell is the last fundamental factor, which affects microbubble persistence in the bloodstream.⁵ Of course, the more stable is the peripheral shell or the less is its solubility in the water, the longer is the microbubble persistence and the echo-enhancing effect. Galactose-covered microbubbles present a low persistence for the high solubility of the sugar in the water. New-generation microbubble-based agents present an albumin or lipid shell, which presents a low solubility in the water, further improving microbubble persistence in the bloodstream and the effect of scattering.

Encapsulation of microbubbles affects their ability to oscillate, due to the presence of viscoelastic damping effects determined by the shell, which influence the microbubble acoustic properties. To produce effective backscattering, microbubbles have to be insonated by their characteristic resonance frequency, and the exposure to US at their resonance frequency forces microbubbles to contract and expand their diameter severalfold.⁵ At low acoustic power, microbubbles produce a US signal with the same frequency as the sound that excited them. By increasing the acoustic power of insonation, microbubbles exhibit nonlinear vibrations at their resonance frequency (f₀) generating signals at f₀, harmonics (2f₀, 3f₀, 4f₀, etc.), and subharmonics (f₀/2, f₀/3, etc.). At further higher acoustic power, the expansion eventually disrupts the microbubbles’ shell generating a wideband harmonic signal similar to a burst.

The resonance—fundamental—frequency (f₀) is inversely related to the microbubble diameter, and it may be expressed as

where R is the microbubble diameter, γ is the ideal adiabatic constant of gas, p₀ is the ambient fluid pressure, and ρ₀ is the density of the surrounding medium. To derive Eq. (6), the damping caused by the surrounding medium is assumed negligible, as no effects due to bubble surface tension or thermal conductivity.

Considering the same model employed for the backscattering of an air-filled microbubble surrounded by a thin elastic shell and taking into account the increased restoring force due to shell elasticity,

where S_e is the shell elasticity parameter, which is defined as

where R_i and R_o are the inner (i) and the outer (o) diameters of the microbubble (the difference R_o — R_i is the thickness of the shell); v is the Poisson ratio, which describes the ratio of transverse contraction strain to longitudinal extension strain in the direction of stretching acoustic pressure (tensile deformation is considered positive, and compressive deformation is considered negative); and E is the modulus of Young—modulus of elasticity in tension— which describes the stiffness of a microbubble.

According to Eq. (7), the higher is the shell elasticity due to encapsulation, the higher is the resonant frequency, at equivalent microbubble radius. Moreover, the lower is the shell elasticity due to encapsulation, the lower is the generation of harmonics, due to the damping provided by the shell viscosity, which produces a notable decrease in the pulsation amplitude. So, for a stiff and thick shell, the stability in the peripheral blood is higher if compared with a flexible and thin shell, but production of harmonics is lower. In practical terms, for any given US power and frequency, less acoustic signal can be expected from microbubbles with thick, stiff shells. Since microbubble with a thick and stiff shells present an increased resistance to the US acoustic power of insonation, the produced acoustical backscattering signal may be improved simply by increasing the acoustic power of insonation.

Moreover, according to Eq. (7), the ideal resonant frequency for a microbubble is inversely related to the square of its radius. The larger the microbubble radius, the lower the resonance frequency, and the resonance frequency of microbubble with a diameter of few µm is in the low MHz frequency range, which is employed in abdominal US. Specifically, the resonance frequency for phospholipid-coated microbubbles with a diameter of 1 to 5 µm is approximately 3-4MHz.

According to the most accepted physical model describing microbubble backscattering properties, the microbubble is considered coated by a continuous layer of incompressible solid elastic material,
with a spherically symmetric motion, and surrounded by an incompressible liquid, which presents infinite extent and a constant viscosity according to the Newton law. A Newtonian fluid is a fluid in which the shear stress—the ratio of force up to the area subjected to the force—is proportional to viscosity and velocity gradient. The rheologic parameters (surface tension and viscosity) for microbubble-based agents may be calculated. The wavelength of the US field is assumed to be much larger than the microbubble diameter, and only the motion of the bubble surface is of interest. It is assumed that the vapor pressure remains constant during the compression and expansion phase and that there is no rectified diffusion during the short period of exposure to US. The gas in the bubble is assumed to be ideal and compressed and expanded according to the ideal gas law with the polytropic exponent (Γ) remaining constant during vibration.

The first parameter to be considered in the backscattering is the motion of the microbubble wall:

where ρ is the density of the surrounding liquid medium (=998 kg/m³), R is the instantaneous microbubble radius, is the first-time derivative of the radius (the velocity of the microbubble wall), R is the second-time derivative of the radius (the acceleration of the microbubble wall), p_L is the liquid pressure at the microbubble wall, and p_∞ is the liquid pressure at infinity.

The assumption is that presence of the microbubble shell completely dominates the motion of the microbubble wall. Therefore, the microbubbles are considered to be elastic particles, which have an effective bulk modulus, K_eff, describing the elasticity of the shell and a friction parameter describing the viscosity of the shell.

The effective bulk modulus describes the elasticity of the shell. For a spherical volume V deformed by a quasi-static pressure change, ΔP determines the volume change of the microbubble and it is uniform over the microbubble surface. The volume strain (deformation) corresponds to , where V is the initial volume and ΔV is the change in volume, while the volume stress (ΔP) corresponds to the ratio of the magnitude of the normal force to the area.⁵,⁶ The effective bulk modulus—K_eff—is given by the ratio of the volume stress to the volume strain:

Since the volume is spherical, symmetric, and defined by the radius, the volume strain can be written as

where R₀ is the initial microbubble radius. Combining Eqs. (10) and (11) gives

The friction damping parameter describes the viscosity of the shell.⁵,⁶ Since the pressure change, ΔP, determining the volume change of the microbubble, can be split into three parts: (a) the liquid pressure at the bubble wall (p_L), (b) the damping pressure caused by friction damping of the system bubble—liquid (p_d), and (c) the hydrostatic pressure (p₀), it may be expressed as

Substitution of Eqs. (12) and (13) into Eq. (9) and using the expanded expression for p₈ (p₈ = p₀ + P_(t), where p₀ is the hydrostatic pressure and P_(t) is the time-varying applied acoustic pressure) yield

By equating the damping pressure, multiplied by the bubble surface, to the damping force, an expression for p_d can be derived from the equation of motion of a damped forced oscillator:

where β is the mechanical resistance, R is the instantaneous microbubble radius, and is the first time derivative of the radius (the velocity of the microbubble wall).

The total viscous and friction damping coefficient, , where ω is the insonating frequency of the applied acoustic field and m is the effective microbubble mass , the damping pressure can be written as

where δ_tot = δ_rad + δ_vis + δ_th + δ_fr and δ_rad is the damping coefficient due to reradiation; δ_vis is the damping coefficient due to the viscosity of the surrounding medium; δ_th is the damping coefficient due to heat conduction; and δ_fr is the damping coefficient due to internal friction or viscosity of the shell.

Including friction damping, the final expression for the Rayleigh-Plesset theory is

or

or

or

where R is the instantaneous microbubble radius; is the first time derivative of the radius (the velocity of the microbubble wall); R is the second time derivative of the radius (the acceleration of the microbubble wall); p_go is the initial internal gas pressure in the microbubble (=[C_A + C_G]RT, where C_A and C_G are concentrations of the filling air and gas, respectively, and T is the absolute temperature); R₀ is the initial microbubble radius; Γ is the polytropic exponent of the gas; p_v is the vapor pressure; p_o is the ambient hydrostatic pressure; S_T is the surface tension; δ_tot is the total damping constant;
ω is the angular frequency of the applied acoustic field; ρ is the density of the surrounding medium; P_(t) is the time-varying applied acoustic pressure; η is the shear viscosity of liquid; ω is the driving frequency; and t is the time. These differential equations predict that the surface shell supports a strain that counters the surface tension and thereby stabilizes the microbubble against dissolution.

The scattering cross section, σ, is used as the parameter defining the acoustic behavior of the microbubble and is defined as the quotient of the acoustic power scattered in all directions per unit incident acoustic intensity.⁵,⁶ The scattered US intensity (I_s) is a function of the incident intensity I₀, the distance between the receiving transducer and the scatterer z, and the scattering cross section of the scatterer σ according to

The scattering cross section is directly related to the scattered acoustic power and to microbubble radius and inversely related to the applied pressure.

The general expression for the scattering cross section in the frequency domain including higher harmonics is

where R is the microbubble radius, R₀ is the initial microbubble radius, ω is the insonating frequency, with f₀ is the resonance frequency, and δ is the damping constant.

Equation (22) may be further developed as

where δ is the damping constant, ρ is the density respectively of the scatterer (subscript s, microbubble) and the surrounding medium (tissue or plasma), and k is the adiabatic compressibility. The k and ρ are also related to the speed of sound . Consequently, the scattering cross section is strongly dependent from frequency both for free air and encapsulated microbubbles and from the difference in density between the microbubble and the surrounding medium.

At the resonant frequency, the scattering cross section of a microbubble is no longer simply dependent on their size and can reach peak values a thousand times higher compared to values at off-resonance frequencies. Since the scattering cross section is strongly dependent between the ratio between the insonating frequency and the resonant frequency (Eq. (23)), at frequency below resonance most of the scattering occurs at 180 degrees relative to the incident wave, with an angular distribution pattern depending on the scatterer shape and the contrast in the acoustic properties between the particle and the surrounding medium.

The compressibility (k value, see Eq. (24)) of air is 7.65 × 10^-6 m²/N, and the compressibility of water is 4.5 × 10^-11 m²/N, similarly to tissue and plasma, while the compressibility of a coated microbubble-based agents falls within this range (5 × 10^-7 m²/N in the case of Albunex). This high difference in compressibility, and so in impedance, results in a very high echogenicity, which increases the sensitivity of the US equipments to microbubble.

Scattering cross-sectional equations may be simplified to

known as Born approximation, where R₀ is the initial microbubble radius, f₀ is the resonance frequency, and Z is the difference in acoustic impedance (ratio of acoustic pressure to sound flow) between the surrounding medium and the microbubble. Encapsulation drastically reduces the influence of resonance frequency on scattering cross section since the lower is the shell elasticity due to encapsulation, the higher is the resonant frequency. Moreover, since Eq. (22) shows that the scattering cross section is inversely related to the damping constant, the encapsulation of microbubbles with a thick and stiff shell produces a lower scattering cross section also for the viscoelastic properties of the surrounding shell.

The US weakening results from scattering and absorption.⁵,⁶ The combined effect of scattering and attenuation depends on microbubbles concentration. Scattering is the prevalent phenomenon with low microbubble concentrations while the attenuation, caused by multiple scattering, dominates when the microbubble concentration increases.

where a(f) is the US frequency-dependent attenuation coefficient expressed in nepers[Np]/length and neper is a dimensionless quantity, R_max and R_min are minimum and maximum microbubble radii, n(r) is the microbubble concentration, and σ is the scattering cross section.

Equation (26) may be employed to calculate the microbubble size distribution, which is in agreement with values measured with optical methods. Microbubble-size distribution is normal shaped, and the standard deviation is larger for first-generation agents and lower for new-generation agents, which present a more uniform microbubble diameter.

In a suspension of microbubbles, each microbubble has to be considered as an element, which absorbs and scatters US at the same time.⁵,⁶ The total energy loss or attenuation for an acoustical beam traveling through a screen of microbubbles is called the extinction coefficient, µ_e(ω), and is given by

where µ_a(ω) is the absorption coefficient and µ_s(ω) is the scattering coefficient.

The scattering to attenuation ratio (STAR) is a measure of the acoustical effectiveness of the contrast agent. The STAR is defined as

and substituting Eq. (28) into Eq. (27) gives

where µ_s(ω) represents the part of the energy that is scattered away omnidirectionally by the microbubbles, while µ_a(ω) represents the part of the energy that is absorbed by the microbubbles.

Therefore, the lower the absorption of the incoming plane US wave, the higher the STAR. A maximum value of STAR = 1 is obtained when there is no absorption. However, this index is only valid for low acoustic pressures, and at high acoustic pressures, nonlinear transient effect appears.

The attenuation of the acoustical beam traveling through a screen of microbubbles can cause shadowing of underlying biologic structures and is not considered to be a useful parameter. An effective contrast agent, therefore, is defined by good scattering properties and low attenuation. For these reasons, the higher is the STAR, the more effective is the contrast agent. There is a nonlinear relation between the increase in microbubble acoustic pressure of insonation and the produced backscattering and attenuation.