The present invention relates to the fields of elastodynamics and elastography. More specifically, the present invention provides a method and device for estimating the elastic properties of incompressible elastic solids. The present invention has applications in, but is not limited to, food industry, polymers industry, biomechanics, bioengineering and medicine.
Incompressible elastic solids sometimes are also referred to as soft-solids because they are easy to deform. Elastic properties of soft-solids are of great interest in food industry (meat, beef, cheese, fruits), polymer industry (rubber, soft polymers) and medicine (muscles and soft tissues in general). Some of the existing methods to determine elasticity of soft-solids are destructive (Tensile tests, Warner-Bratzler shear force, WBSF, test). Non-destructive methods include ultrasound elastography and surface wave elastography.
Ultrasound elastography is capable of mapping locally the elasticity in soft-tissues. Another advantage is that the method estimates the elasticity of tissue in a direct way, without needing inversion algorithms. Ultrasound elastography needs a dedicated ultrasound scanner which is onerous. Moreover, ultrasound elastography has some limitations. For example, it does not work in materials without sound scatterers inside (termed as speckle-less materials). In addition, it is not useful in materials where ultrasound frequencies are highly attenuated (food industry in general like cheese, yoghurt and fruits). Thus, ultrasound elastography is limited to some applications in medicine.
Surface wave methods have been proposed as an alternative to ultrasound elastography. These methods have the advantage that they are low-cost compared with ultrasound. However, surface waves have not a direct relation with elasticity and thus, inversion algorithms are needed to properly estimate the elasticity. Most authors assume Rayleigh surface wave propagation. In such case, the inversion algorithm is simple. However, in most practical cases the conditions for Rayleigh wave propagation are not achieved. Thus, the elasticity estimation is biased due to the inversion algorithm. Other authors assume guided wave propagation in thin plates like skin or arteries. However, guided waves are affected by near-field effects that are not negligible in soft-solids. Most surface wave methods are based on laser vibrometry to scan de displacement field over the surface. A major drawback is that the elasticity estimation is not performed in real-time. These methods use a single measurement device, which scans over the surface of the sample. Thus, they can not follow rapid changes in elasticity like muscle activation.
The present invention provides a non-destructive device and a reliable method to estimate the elasticity of soft-solids samples using surface waves. The proposed method overcomes some drawbacks found in the previous works as described above. Thus, the present invention provides an alternative elastographic device and method, which is non-destructive, low-cost, real-time, quantitative and repeatable.
These and other objectives of the invention are met through a device and method for determining the elasticity of soft-solids. According to a first aspect, the invention comprises a device for determining the elasticity of soft-solids which comprises a wave source, a shaft coupled by one of its ends to the wave source and which bears a head piece in its opposite end, a plurality of vibration sensors linearly arrayed to each other, and an analogical-to-digital converter connected to the vibration sensors and to a processor. In the device of the invention, the face of head piece opposed to the shaft and the plurality of vibration sensors are substantially on a same plane on the same side of the device, and the axis of the shaft is normal to the plane containing the sensors and head of the shaft.
In a particular embodiment of the invention, the vibration sensors are piezoelectric sensors. In another particular embodiment of the invention, alone or in combination with any of the above or below embodiments, the sensors are four.
In another particular embodiment of the invention, alone or in combination with any of the above or below embodiments, the face of head piece opposed to the shaft (wave source) has the shape of a rectangle with its long side perpendicular to the line connecting the shaft and the sensors and its short side parallel to the said line.
In another particular embodiment of the invention, alone or in combination with any of the above or below embodiments, the device further comprises a temperature sensor.
In another particular embodiment of the invention, alone or in combination with any of the above or below embodiments, the device further comprises a pressure sensor. In a more particular embodiment of the invention, the pressure sensor consists of a load cell connected to a voltage divider circuit with comparator. The pressure sensor can be connected to led light indicators for indicating to the user if the correct amount of pressure is being applied to the sample to be measured.
In another particular embodiment of the invention, alone or in combination with any of the above or below embodiments, the device further comprises a distance sensor. In a more particular embodiment of the invention, the distance sensor is an infrared sensor.
According to a second aspect, the invention relates to a method for determining the elasticity of a soft-solid, the method comprising the steps of:
In one embodiment of the method of the invention, alone or in combination with any of the above or below embodiments, an analogic-to-digital converter receives analogical information from the sensors, transforms it into digital information, and transmits that digital information to a processor.
In another particular embodiment of the method of the invention, alone or in combination with any of the above or below embodiments, the calculated elasticity value is shown into a display.
1) EP0329817B1—date of filing: Mar. 3, 1988
This patent claims a non invasive acoustic testing of elasticity of soft biological tissues. In its preferred embodiment, it measures the velocity of the waves by means of a probe with one transmitting and two receiving piezotransducers, the receiving transducers being placed symmetrically with respect to the transmitter, being that this allows for the differential amplification of the received acoustic signals. These piezotransducers are mounted onto the probe by means of acoustic delay lines in the form of hollow thin-wall metallic shafts, long enough to delay the acoustic signal passing from transmitter to receiver through the body of the probe. There is also a needle contact (not a line source as in ours), a spring and a tubular contact. Converting the value of the elapsed time of the surface wave between the points of irradiation and reception is indicative of the elasticity of the tissue in the direction of wave propagation. All this is completely different—in principle and in physical construction—from our invention, which is based on surface waves and their phase shift, besides having an analog/digital conversion system and pressure sensor which are fundamentally different from this invention. Taking into consideration that shear waves travel through soft tissues approximately 1000 times slower and attenuate approximately 10000 times faster than longitudinal conventional ultrasound waves, both inventions are almost in different fields (radiographics.rsna.org, May-June 2017).
2) U.S. Pat. No. 9,044,192—date of filing: Apr. 3, 2009
This patent shows numerous and significant differences with the current invention, such as: it is useful only for soft tissue in living animals, not for soft solids in general as the current invention; it is based in a viscoelastic model, and must thus determine two factors, one elastic and one viscous, while the current invention is a purely elastic model and thus only an elastic parameter is determined; it includes multilayered tissues, while the current invention does not; phase velocity is measured by means of linear regression or phase vs. distance, while in the current invention this hypothesis is not present; it is based on distant field equations (although it is not said explicitly) since normal propagation modes are used, while in the current invention only the near field counts; it is only applied to isotropic tissues—although in claim 13 anisotropic tissues are considered, nothing in the Memory justifies such claim and there is no mention of how to quantify parameters in such a case—while in the current invention the device is used on isotropic and anisotropic (transversally isotropic) soft solids, furthermore in the current invention, a method of how to quantitatively obtain the parameters is described for both cases (isotropic and anisotropic); it does not include temperature corrections (since measurements are always taken at the same temperature) while the current invention does; it uses remote sensors (ultrasound or laser vibrometry), while the current invention uses contact sensors. The use of far-field equations causes a bias in the measurement results, bias which depends on frequency. This is not true for the current invention since, upon using near field equations, all the tissue and not only the superficial layers are accurately measured. Given all these substantial differences, patent U.S. Pat. No. 9,044,192 is only useful for medical purposes of inner organs, a field completely different from the one aimed at in the current invention.
3) UY36047—date of filing: Mar. 27, 2015
This patent and the one herewith filed are based on surface waves, but are significant differences, as follows:
It is our contention that, due to these significant differences, none of these patents is a useful antecedent to question either the novelty of the inventive step of the current invention.
The elements making up the equipment of the present invention are described below, with the numbers with which they appear in the figures.
The method is based in the following steps: 1) Using a wave source (1), excite low-amplitude audible frequency waves in a selected location of a free surface of the sample. The exciting frequency as well as the number of cycles excited are user-controlled. They can be selected in order to optimize the results for the particular application. 2) Record the time-traces of the surface displacement using contact vibration sensors arranged in a linear array along the free surface of the sample (2). 3) Compute the phase velocity of the surface wave by estimating the phase-shift between sensors and source. 4) Use an inversion algorithm to convert the phase velocity computed in the previous step to a meaningful elasticity value (Block diagram
The device also comprises an A/D converter (3) to digitize the analog signals from the linear array of surface vibration sensors and a processor to compute the time-shifts between sensors and perform the data processing (15). Detailed features of the present invention will be described in the following paragraphs.
The processing algorithm estimates the phase shift between the signals recorded by the linear array of vibration sensors and the reference signal sent to the source. Thus, the first step is to apply a band-pass filter centered on the source's frequency with a bandwidth between 30% and 50%. This allows eliminating unwanted frequencies that can affect the estimates. Then, the phase shift between the recorded signals and the reference signal is computed at a selected frequency within the bandwidth by Fourier transform. The phase shift is converted to time delay by dividing the phase shift between the corresponding angular frequency. This procedure allows the estimation of the surface wave velocity since the distance source-sensor is known (distances d and d′ in
The operation of the method does not present limitations concerning to the working frequency. However, depending on frequency, it may be necessary to correct the computed value taking into account guided wave propagation. Therefore, the main objective of this invention is to apply correction algorithms designed to automatically correct the incidence of guided waves. Thus, the invention provides a quantitative and reliable tool to estimate the shear wave velocity of tested samples. The shear wave velocity is related to an elastic modulus depending on the type of solid being tested.
The equipment comprising the present invention is constituted by an external wave source having a coupled shaft (1). The operation frequency range as well as the number of cycles are selected by the application for which the invention is intended to be used. That source should vibrate normally to a free surface of the sample in order to excite mainly the vertical component of the surface waves. The waves thus generated will be recorded by a linear arrangement of vibration sensors (2) (e.g. piezoelectric sensors, accelerometers, resistive sensors, microphones, etc.), which are placed along the free surface of the sample. These sensors record the vertical component of the vibrations (
In order to the device of the present invention to work properly, the source must be aligned with the array of sensors, which must avoid contact with each other (
Based on the above, the operation of the equipment described in the present invention has the advantage of being based on a few basic directions. In a preferred realization or modality, the equipment comprises four vibration sensors arranged in a linear array. Likewise, the vibrator should be placed on the surface of the soft solid whose elasticity is to be measured, being placed on the external side of the array (
In linear elasticity theory, the stress and strain within an elastic solid are related by the generalized Hooke's law:
τmj=Cmjklϵkl 1
where the Einstein's convention over repeated indices apply. In this equation τij is the stress tensor, ϵkl is the strain tensor defined as
uk is the k=1, 2, 3 component of the displacement field and Cmjkl is the stiffness tensor. It has 81 (34) elements representing elastic constants. However, since τmj=τjm and ϵkl=ϵlk, this number reduces to 36 independent coefficients. Moreover, since the symmetry of the derivative of the strain energy with respect to the strain tensor, this number reduces further to 21 independent coefficients. Thus, the 21 independent elastic coefficients define the general anisotropic elastic solid. In order to avoid working with a fourth rank tensor, it is usual to represent the independent constants of the stiffness tensor by two indices α and β with values 1 to 6 corresponding to a 6×6 array with the following convention:
(11)↔1 (22)↔2 (33)↔3
(23)=(32)↔4 (31)=(13)↔5 (12)=(21)↔6
Thus, Cmjkl=Cαβ with α related to (mj) and β related to (kl).
The fundamental relation of dynamics applied to this system gives:
where ρ is the material density. When using the Hooke's law (1) to express the stress tensor, this equation reads:
which is a system of three second order differential equation accounting for wave propagation in three dimensional anisotropic bodies. Plane wave solutions to this equation are expressed as:
where êm is a unit vector in the direction of particle displacement and is referred as the wave polarization and {circumflex over (n)}=(n1, n2, n3) is a unit vector in the direction of wave propagation. Inserting equation (4) into equation (3) gives:
ρV2êm=Cmjklnjnkêl; 5
Introducing the second rank tensor Γml=Cmjklnjnk this equation becomes the Christoffel equation:
ρV2êm=Γmlêl 6
Thus, the polarization and phase velocity of a plane wave propagating in direction {circumflex over (n)} are the eigenvector and eigenvalue of the Christoffel tensor Γml respectively. Since this tensor is symmetric, its eigenvalues are real and its eigenvectors are orthogonal with each other.
Isotropic Solid
For an isotropic solid, the stiffness matrix takes the form:
where c11=c12+2c44. Thus, an isotropic solid has only two independent elastic constants c12=λ and c44=μ referred as Lame constants. In mechanical engineering literature two other constants are employed, the Young's modulus Y and the Poisson's ratio σ. They are related to Lamé constants by:
An incompressible elastic solid is defined as a solid with Poisson's ratio σ≈½. In terms of Lame constants this means λ>>μ and thus, c11>>c44. The objective of the present invention when applied to isotropic soft-solids is to estimate the value of μ=c44 from surface waves.
For an isotropic solid, the Christoffel tensor is independent of the propagation direction. It reads:
Therefore, the eigenvalues are VT=√{square root over (c44/ρ)} (degenerate) and VL=√{square root over (c11/ρ)} corresponding to polarizations perpendicular and parallel to the propagation direction respectively. Thus, VT is the velocity of transverse or shear waves and VL is the velocity of longitudinal or compressional waves. Due to the relation c11>>c44, VL>>VT in a soft-solid. If the material density of the sample is known, the value of c44 can be estimated by measuring the velocity VT of shear waves and inverting the first eigenvalue relation written above: c44=ρVT2. Thus, the task has changed to estimate VT from measuring the surface displacement field.
When inserting the stiffness matrix given in equation (7) into the wave equation (3), the wave equation for isotropic solids is obtained. It can be written in vectorial form as:
Taking the divergence in the equation above gives:
Thus, ∇·{right arrow over (u)} it is an irrotational wave that propagates with velocity VL, i.e., the compressional wave velocity. Let D be a characteristic dimension of the sample being tested (e.g. its length or width). If the excitation frequency f0 of the wave is chosen such that f0<<VL/D, then the wavelength of the irrotational wave ∇·{right arrow over (u)} is much larger than D. Therefore, ∇·{right arrow over (u)} it is approximately constant within the sample and it is possible to write ∇(∇·{right arrow over (u)})≅0. Under this condition, the wave equation (11) becomes:
That is, low-frequency waves in soft-solids propagate almost as shear waves. This last assertion is true for bulk wave propagation in an infinite solid. If the sample is limited by a free surface, surface waves also propagate.
Without loss of generality, consider a surface wave propagating along the x1 direction. The displacement field is given by:
um=ψm(kx3)ei(ωt−kx
where m=1,3 and u2 ≡0. Inserting (14) into the wave equation (3) and using the stiffness matrix for an isotropic solid (7), gives:
(ρV2−c11)ψ1(kx3)+c44ψ1″(kx3)−(c12+c44)ψ3′(kx3)=0 15
(ρV2−c44)ψ3(kx3)+c11ψ3″(kx3)−i(c12+c44)ψ1′(kx3)=0 16
where V=ω/k is the velocity of the surface wave and the primes over the functions indicates derivative with respect to their argument. The solution to this system is given by:
ψ1(kx3)=A1e−χ
ψ3(kx3)=−iχ1A1e−χ
in which the coefficients Al and A3 are determined by the mechanical boundary conditions and
For a free surface, the relevant boundary conditions at x3=0, are: τm3=0, where m=1,3. Using (1) and (7), the boundary conditions read:
2χ1A1+i(1+χ32)A3=0 20
i(−c12+c11χ12)A1+χ3(c12−c11)A3=0 21
In order to avoid the trivial solution, the determinant of the coefficient matrix must be zero. This gives rise to the secular equation for the surface waves:
2χ1χ3(c12−c11)+(1+χ32)(c11χ12−c12)=0 22
Replacing in this equation the values of χ1, χ3, c11 and c12 in terms of the velocities, the secular equation becomes the well-known Rayleigh equation:
It is known that if VL/VT>1.8, this equation has one real root and two complex conjugate roots. The real root corresponds to the velocity VR of a propagative surface wave (Rayleigh wave). The complex roots correspond also to a physical surface wave termed as the leaky surface wave with propagation velocity VLS. By using the relation VL>>VT in equation (23), it is found that:
VR=0.96VT;VLS=(1.97±i0.57)VT 24
Therefore, the Rayleigh velocity has a simple relation with the shear velocity: VR≅0.96VT. Thus, many authors use, as inversion algorithm to estimate c44 from surface wave measurements, the following expression:
c44=ρ(VR/0.96)2 25
However, this relationship only holds in a semi-infinite medium and in the far-filed where the leaky wave is negligible due to its complex velocity. Real samples are, of course, finite. Thus, in order to meet the conditions for equation (25) to be valid, many authors employ high frequency wave propagation. In this way, the wavelength of the Rayleigh wave is much lesser than the sample's height and the medium is considered semi-infinite Nevertheless, the use of high frequencies is not desirable for many reasons. Firstly, because the surface wave only senses a small portion of the whole sample (its penetration depth is limited to one wavelength). In addition, real samples are attenuating. The attenuation coefficient grows as a power of frequency. Thus, the higher the frequency, the smaller the propagation distance of the wave. Finally, for high frequencies, the compressional wave is not negligible and guided wave propagation is not avoidable.
If the wavelength of the shear wave is comparable to the height of the sample being tested, the inversion algorithm used in equation (25) is no longer valid. In such case, many authors appeal to the Rayleigh-Lamb model of guided wave propagation in plates. Since low frequencies are employed, inversion algorithms based on the zeroth order modes are used because these are the only modes without a cutoff frequency. However, data is usually collected in the near-field of the source and for short times. Within these conditions, the Rayleigh-Lamb modes are not yet developed. This fact leads to biases in the estimation of VT. Therefore, in the present invention, a different inversion algorithm is used to retrieve the shear wave velocity VT from surface displacements.
Consider a homogeneous soft-solid isotropic elastic plate of height 2h which is excited by a source located at the free surface in x3=0 as displayed in
and displayed in
where λT is the shear wavelength. Thus, the attenuation distance of the leaky surface wave along the x direction is comparable to the shear wavelength in soft-solids. Therefore, the inversion algorithm expressed in equation (25) is valid only if ζ<x1<xs. However, the value of is not negligible at low frequencies. For example, typical values of the involved velocities in soft-tissues are VL˜1500 m/s and VT˜10 m/s. Therefore, the shear wavelength may vary from 10 to 1 cm for excitation frequencies in the range 100-1000 Hz. Then, the leaky wave is not negligible in the near-field. Therefore, interference between the Rayleigh and the leaky surface wave is possible. This fact has consequences over the phase velocity of the surface field as shown below.
Note that, depending on frequency, the value of can be greater than xs. A critical frequency fc can be defined such as ζ=xs. The value of fc is given by:
From the considerations above, the x3-component of the surface displacement u3 (x1<xs, x3=0) for frequencies below fc can be written as:
u3(x1<xs)=exp(−ikRx1)−exp(−x1/ζ)exp(−ikLSx1) 29
corresponding to the sum of the Rayleigh and leaky surface wave, where kLs is the real part of the wavenumber of the leaky surface wave. For low frequencies, kRx1<<1 and therefore:
where δ is defined as δ=kLS/kR≅½. Defining
the phase ϕ(x1, ω, VT) of this wave can be expressed as:
Thus, the phase velocity V of the surface wave for a given frequency ω0 is expressed as:
where the primes over the function indicates derivative with respect to x1. Note that this expression gives a different dispersion curve for each value of x1. Thus, it is not the dispersion curve for Rayleigh-Lamb modes. At this stage, two inversion methods are envisaged to retrieve VT from the experimental values of V.
So far, the inversion methods proposed above only consider the surface displacement field for x1<xs. If x1>xs, the reflected shear waves are not negligible and must be taken into account in the inversion method. To this end, the effects of an impinging shear wave on the free surface must be considered first.
Consider an impinging shear wave at the free surface x3=0. This wave produces a reflected shear wave and, due to mode conversion, a reflected compressional wave. If Asi and θsi are the amplitude and angle of the incident shear wave, the amplitude Apr and angle θpr of the reflected compressional wave are given by:
Since VL>>VT, the angle of is complex even if θsi<<1. Let θrp=π/2−iγ where γ is real and positive. Consider now the components of the wavevector {right arrow over (k)}p of the reflected compressional wave along x1 and x3:
k1p=kp sin(θpr)=kp sin(π/2−iγ)=kp cos h(γ)
k3p=kp cos(θpr)=kp cos(π/2−iγ)=ikp sin h(γ)
Thus, whatever the incident angle, the impinging shear wave produces an evanescent compressional wave confined to the free surface of the soft-solid. Thus, it is a surface wave which we call the SP wave (
Therefore, the phase velocity of the SP wave varies from nearly infinite for θsi≅0 to VT for θsi≅π/2. After some computation, the amplitude of the SP wave is given by:
where the approximation is valid if γ>>1. This is always the case since θsi≥34°. Thus, due to the complex denominator, the SP wave is out of phase with the reflected shear wave. The phase difference depends upon the incident angle θsi of the shear wave. We expect to observe the SP wave whenever the amplitude Asi of the shear wave is maximum. According to the directivity pattern of the shear wave, it has a maximum for θsi≅34°. At this angle, the phase velocity of the SP wave is VSp≅1.8VT. Thus, the surface displacement field in the vicinity of xs is a complicated superposition of different wave types, each with its own phase velocity. If ω>ωc the x3 component of the surface field can be expressed as the superposition of the Rayleigh wave, the reflected shear wave and the SP wave as:
u3(x1≈xs)=e−ik
where ks1 is the component of the shear wave vector along x1, η is the phase angle of the SP wave with respect to the shear wave and As(x1) is the amplitude of the reflected shear wave at θ≅θs=34°. Taking into account the directivity and the geometrical attenuation, it is given by:
Now, for low frequencies, equation (35) can be expressed as:
u3(x1≈xs)≅1+As(x1)|Arp(θs)|(cos(η)−ksp sin(η))−½((kR2+As(x)(ks1)2+As(x1)|Arp(θs)|ksp2 cos(η))x12+⅙As(x1)|Arp)(θs)|ksp2 sin(η)x13−i[As(x1)|Arp(θs)|sin(η)+(kR+As(x)|Arp(θs)|ksp cos(η)+As(x)ks1)x1−½As(x1)|Arp(θs)|ksp2 sin(η)x12−−⅙(kR3+As(x1)(ks1)3+As(x1)|Arp(θs)|ksp3 cos(η))x13] 36
Defining Ns(x)=Im[uz] and Ds(x)=Re[u2], the phase velocity is expressed as:
Thus, a third inversion method is possible:
Third inversion method. If, for a given position x1≈xs, an experimental dispersion curve V(ω) for frequencies ω>ωc is available, then equation (37) can be fitted in a least-squares sense to the experimental data. The value of VT that minimizes the sum of quadratic differences is the best estimation for the shear wave velocity. This was the inversion method employed in
A third possibility regarding the position x1 at which the surface displacement is measured must be considered. If x1>>xs a few reflections back and forth in the interfaces of the sample have taken place. Thus, in this zone, the Rayleigh-Lamb modes have developed. Due to the source type and polarization used in this invention, it favors the antisymmetric modes. In addition, since low-frequencies are employed, only the zeroth order mode propagate. Thus, other two inversion methods are possible, in the same spirit of methods #1 and #2:
As a final observation for isotropic solids, we note here that, due to the interference of the different surface wave types, the amplitude of the surface displacement is a complicated function of position x and frequency ω. Thus, an estimation of the attenuation coefficient by fitting the amplitude of the displacement field to the usual exponential decay does not make sense, at least in the near field. If far-field (x1>>xs) measurements are available, then, the amplitude should be corrected by diffraction before trying to estimate the attenuation coefficient.
Transversely Isotropic Solid
Potential applications of the present invention include estimating the elastic properties of skeletal semi-tendinous muscles, e.g., meat samples or application in vivo to external human muscles such as biceps, triceps, quadriceps, etc. Due to the parallel fiber orientation in these kind of muscles, they can be modelled as transversely isotropic materials. In addition, some long-chain polymers with chains aligned within a preferred direction are also modelled as transversely isotropic materials.
The stiffness matrix has five independent elastic modulus for this kind of materials. Let x1 be the axis of symmetry, i.e., the orientation axis of muscular fibers or long molecule-chains. Thus, the axes x2 and x3 are perpendicular to the fibers as shown in
The constants c11 and c22 are related to the compressional wave propagating along and perpendicular to the symmetry axis respectively: VL∥=√{square root over (c11/ρ)} and VL⊥=√{square root over (c22/ρ)}. In many incompressible transversely isotropic solids (such as skeletal muscle for example), these two values of compressional wave velocities are almost equal each other. Thus, c22≅c11, i.e. the solid is isotropic regarding the compressional waves. The constant c44 is related to a shear wave propagating perpendicular to the symmetry axis with perpendicular polarization VT⊥=√{square root over (c44/ρ)}. The constant c55 is related to a shear wave propagating parallel to the symmetry axis with perpendicular polarization VT⊥=√{square root over (c55/ρ)}. As in the isotropic solid case, VL>>VT, whatever the polarization. Thus, c22−2c44≅c22≅c11. Finally, the constant c12 is related to wave propagation (either compressional or shear waves) in directions out of the principal axes.
Consider now an anisotropic soft-solid where VL>>VT whatever the propagation direction of the waves. The wave equation for this case cannot be written in a simple manner as for the isotropic case. However, it is still valid that the contribution of the compressional waves are negligible at low-frequencies. Thus, low-frequency waves propagate almost as shear waves. The objective of the present invention, when applied to transversely isotropic solids, is to estimate either c44, c55 or both of them.
A. Estimation of c44
If wave propagation takes place in a plane perpendicular to the symmetry axis (plane (x2, x3) in
B. Estimation of c55
For estimating c55, consider the line source oriented parallel to the x2 axis. For this case, the wave propagation takes place in a plane that includes the symmetry axis (plane (x1, x3) in
where ∂=c11+c22−2c12. Since the medium is considered isotropic for compressional waves, the constant c12 is no longer an independent constant. It is related to other constants by:
c12=c11−c55
Since c22=c11, the secular equation (39) is expressed as:
As for the isotropic case, this equation has one real root (corresponding to the Rayleigh wave) and two complex conjugate roots corresponding to the leaky surface wave:
VR=0.84VT∥;VLS=(1.42±0.6i)VT∥ 41
Note that the attenuation distance for the leaky wave ζ is larger than for the isotropic case, ζ=1.6λT. Another difference with respect the isotropic solid concerns the directivity pattern of the shear wave. There is no simple expression for the directivity pattern in the (x1, x3) plane. However, some authors have computed it numerically. It is shown that the main lobe is oriented towards 60° from the source. Therefore the value of xs is now given by xs≅7h. Thus, the value of the critical frequency at which ζ=xs is given by fc=0.23VT/h, which is lower than the isotropic case. Therefore, if x1<xs and ω>ωc=2πfc, the inversion method to obtain c55 proceeds as given by equation (32) for the isotropic solid but changing the values of VR and VLS by the ones given in equation (41).
Inversion procedures for x1≥xs are complicated since no analytic expressions are available for the directivity of shear waves. In addition, Rayleigh-Lamb modes in the (x1, x3) plane are difficult to compute even numerically. Therefore, the present invention does not include inversion methods for these cases.
The lack of inversion algorithm for x1>xs, does not forbids the estimation of c55 in common applications of the invention. Consider for example skeletal muscles such as biceps branchii. The mean value of its height in adults is 2h=28±7 mm. Thus, xs≅7h≅100 mm. The mean height for other skeletal muscles like vastus lateralis or vastus medialis is even larger than 28 mm. Therefore, if the data is collected at positions x<100 mm, the value of c55 can be estimated by the inversion methods proposed in the present invention.
Temperature Dependence of c55
The elasticity of soft tissues depends on the temperature. In order to compare the elasticity of different beef samples it is important that all are taken at the same temperature. However, this is not always the case. The temperature in slaughter houses can vary within a range between 3 and 10° C. In this example, the temperature dependence of c55 in beef samples is shown in
Age Maturation Process
Age maturation is a fundamental process in meat industry. It is mediated by the action of many enzymatic systems. After rigor mortis, these enzymatic systems produce a progressive softening of beef allowing to reach the desired tenderness requested by consumers. There is a lack of nondestructive monitoring method of enzymatic maturation. In this example, the maturation process of 5 different cuts, consisting in 5 samples of each, is monitored with the present invention. The samples were kept vacuum sealed inside a cold room between 0 and 4° C. during 21 days. All samples were measured once a day.
Comparison with Warner-Bratzler Shear Force Test (WBSF)
The WBSF test is a destructive method. It measures the force that a sharp inverted “V” shaped knife needs to cut the beef sample while moving at constant speed. It is the standard test in meat industry to quantify the tenderness. In this example, the results of WBSF tests in two different beef samples are shown (
Sorting Beef Cuts According to Tenderness
The tenderness of beef samples represents a variable that defines, in a high percentage, its commercial value. The standard procedure to evaluate tenderness is the WBSF test. In the previous example, it was shown that the shear force test and the elasticity are correlated. Thus, the present invention can be employed to discriminate beef samples according to their tenderness.
Elasticity Estimation in Skeletal Muscle in Vivo
Estimation of elastic properties of skeletal muscle in dynamic conditions is important in sport science to evaluate the health state of muscles. Thus, the present invention would be beneficial in this and related areas. In this example, the present invention is used to monitor changes in c55 in biceps brachial of three healthy volunteers during isometric contraction. The volunteers were asked to contract the muscle to 40% of their maximum voluntary contraction (MVC, measured previously with an isokinetic dynamometer) in 20 seconds. Then, keep this contraction for other 5 seconds and finally reduce the contraction to 0% in 20 seconds.
Determination of VT in Tissue Mimicking Phantoms
In this section we present experimental results for the application of the present invention in agar-gelatin based phantoms (isotropic solid). These types of phantoms are widely used to simulate the mechanical properties of soft tissues. They were made from a mixture of agar (1% w/w) and gelatin (3% w/w) in hot water (>80° C.). Alcohol and antibiotics were also added for conservation purposes. Thus, we elaborated a sample with parallelepiped shape of height 2h=20 mm, long and width 100 and 120, respectively.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/BR2018/050395 | 10/30/2018 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2019/084646 | 5/9/2019 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
20130305831 | Zimmermann | Nov 2013 | A1 |
20140193547 | Brown | Jul 2014 | A1 |
20170030877 | Miresmailli | Feb 2017 | A1 |
20170306608 | Goldberg | Oct 2017 | A1 |
Entry |
---|
Grinspan G A et al, Optimization of a surface wave elastography method through diffraction and guided waves effects characterization, Journal of Physics, Conference Series, May 10, 2016, Jan. 2014, vol. 705, IOP Publishing, Pulished Online. |
Benech N et al, In vivo assessment of muscle mechanical properties using a low-cost surface wave method, Proceedings of the 2012 IEEE International Ultrasonics Symposium, Oct. 2012, pp. 2571-2574, Published on CD-Rom. |
Zhang X et al, Noninvasive ultrasound image guided surface wave method for measuring the wave speed and estimating the elasticity of lungs: A feasibility study, Ultrasonics, Oct. 23, 2010, pp. 289-295, vol. 51—Issue 3, Elsevier B.V., Published online. |
Zhang X, A surface wave elastography technique for measuring tissue viscoelastic properties, Medical Engineering & Physics, Apr. 2017, pp. 111-115, vol. 42, Elsevier B.V., Published online. |
Number | Date | Country | |
---|---|---|---|
20200271624 A1 | Aug 2020 | US |
Number | Date | Country | |
---|---|---|---|
62579262 | Oct 2017 | US |