Patent Description:
Valvular stenosis, also called heart valve disease or narrowed valve, occurs when tissues forming a cardiac valve leaflets become stiffer thereby narrowing the valve opening and reducing the amount of blood that can flow through it.

Valvular stenosis may occur in any of the four valves of the heart: the aortic valve, the mitral valve, the tricuspid valve or the pulmonic valve.

One of the known causes of valvular stenosis is a fibro-calcific degeneration of the valve leaflets wherein one or more of the valve leaflets become calcified and thus thickened and hardened, resulting in a narrowed valve opening.

Current treatments for valvular stenosis primarily involve an open or percutaneous surgery to replace the heart valve with a mechanical or tissue-based replacement heart valve.

Open surgery is done through a median sternotomy and involves a cardiopulmonary bypass of the patient. It is thus a major operation that conveys significant risk of death or serious complications. Moreover, a large class of older patients, as well as those who are frail and/or have multiple comorbidities, face significantly higher surgical risks and are thus excluded from the scope of application of this method.

Novel catheter-based approaches have been developed, such as percutaneous aortic valve replacement, which eliminate the need for open heart surgery. However, these catheter-based approaches are only applicable to selected groups of patients and still involve significant risk of death or serious complications.

Indeed it is estimated that more than <NUM>% of the patients with severe valvular stenosis are excluded from the field of application of both open and percutaneous surgical methods.

Even when a patient fulfils the conditions to receive a replacement valve by open or percutaneous surgery, both mechanical and tissue-based replacement heart valves present significant drawbacks.

Mechanical valves are made from pyrolytic carbon and require a life-time treatment of warfarin anticoagulant, with an accompanying risk of bleeding. While such bleeding events are rare, they are often fatal.

Tissue valves (or "bioprostheses") come with no requirement for anticoagulation therapy, which reduces the incidence of bleeding. However, the lifetime of a tissue valve is typically <NUM> to <NUM> years, often less in younger patients. Over this time the valve will likely be degenerating to the point of requiring replacement, which again carries a significant risk of death. Moreover, tissue valves are also subject to valvular diseases; in particular, they may also develop fibro-calcific degeneration requiring an early replacement.

Documents <CIT>, <CIT>, <CIT>, <CIT> and article titled "<NPL>ET AL. disclose relevant background art.

There is thus a need for a treatment or prevention of valvular stenosis that would involve a less invasive medical intervention with reduced risks, and for a treatment of valvular stenosis that would present benefits in term of long-term recovery of the patient.

The instant invention has notably for object to improve this situation.

The invention is defined in the appended independent claim <NUM>. Preferred embodiments are described in the dependent claims.

Methods disclosed hereinafter do not form part of the claimed invention. Disclosed is an exemplary method for treating or preventing a valvular disease comprises:.

The disclosure applies to the treatment of both native and tissue-based replacement valves (bioprostheses). Therefore, unlike specified otherwise, the term "cardiac valve" should be construed as designating both native valves and bioprostheses.

In some embodiments, one might also use one or more of the following features:.

Further disclosed is an apparatus for treating or preventing a valvular disease, said apparatus comprising:.

Other characteristics and advantages of the disclosure will readily appear from the following description of several of its embodiments, provided as non-limitative examples, and of the accompanying drawings.

On the different Figures, the same reference signs designate like or similar elements.

<FIG> illustrates a heart H of a patient which is a mammalian, for instance a human. The heart comprises four cardiac valves C1, C2, C3, C4 that determine the pathway of blood flow through the heart: the mitral valve C1, the tricuspid valve C2, the aortic valve C3 and the pulmonary valve C4.

Each cardiac valve C allows blood to flow in only one direction through the heart H by opening or closing incumbent on differential blood pressure on each side of the valve.

More precisely, each cardiac valve C comprises leaflets L, also called cusps, which are thin tissue layers that are able to be closed together, to seal the valve and prevent backflow, and pushed (i.e. bended) open to allow blood flow. The mitral valve C1 usually has two leaflets L, whereas the three others cardiac valves C2, C3, C4 usually have three leaflets L (only two leaflets are show on <FIG> for each cardiac valve). The leaflets are fixed to an annulus of the cardiac valve C. The annulus is a ring composed of fibrous tissue and forming a partial or complete valvular ring around the cardiac valve C.

Valvular stenosis occurs when a cardiac valve C is narrowed. Any of the heart valves C can be affected, resulting in so-called mitral valve stenosis, tricuspid valve stenosis, pulmonary valve stenosis or aortic valve stenosis.

Valvular stenosis can arise from various causes and may be congenital (inborn) or acquired. Valvular stenosis causes serious threat to the life of the patient. In the case of aortic stenosis for instance, it is estimated that, without repair, the chance of death at five years is about <NUM>% and at <NUM> years is about <NUM>%.

In developed society, a major cause of valve stenosis is an age-related progressive calcification of the valve. It is estimated that approximately <NUM>% of people over the age of <NUM>, <NUM>% of people over age <NUM>, and <NUM>% percent of people over age <NUM> are affected by this condition.

The process is currently understood as involving one or several leaflets L of a cardiac valve C becoming hardened and thickened and, as a result, the opening surface of the cardiac valve being reduced.

Cardiac valve leaflets L are thin tissue layers with a thickness normally of the order of <NUM>-<NUM>. With aging of the patient, the thickness of the leaflets L may increases to around <NUM>-<NUM> with an associated hardening of the leaflets.

A cardiac valve leaflet L is a double interface: a fluid-tissue-fluid interface. Consequently, its properties and behaviours strongly differ from bulk tissues and single tissue-fluid interfaces, such as vein walls.

Unlike a tissue-fluid interfaces that can usually be ablated or eroded without risks, the erosion of a leaflet causes high risks of perforating the leaflet thereby destroying its sealing function.

Unlike bulk tissues, a cardiac valve leaflet is a thin moving element, opening and closing at a high frequency during the cardiac cycle.

The present invention takes into account such properties and specific behaviour.

We now refer also to <FIG>, <FIG>, <FIG>, <FIG> and <FIG>. <FIG>, <FIG> illustrate an apparatus <NUM> for treatment of valvular stenosis. <FIG> details the apparatus according to the disclosure. <FIG> details a method of treating valvular stenosis.

The apparatus <NUM> comprises an ultrasound probe <NUM>. The ultrasound probe <NUM> is located externally to a heart of a patient P and arranged to be able to produce ultrasound waves focused inside said patient P. The ultrasound probe <NUM> can be provided during a step <NUM> of the method illustrated on <FIG>.

As illustrated on <FIG>, the ultrasound probe <NUM> comprises at least one ultrasound transducer <NUM> able to produced focused ultrasounds.

The ultrasound probe <NUM> may further comprise a reflective cavity <NUM>. The ultrasound transducer <NUM> can then be arranged to emit an emission signal inside the reflecting cavity <NUM> to generate a focused ultrasound wave inside the patient P.

As illustrated on <FIG>, the ultrasound probe <NUM> can be arranged externally to the patient and, for instance, in contact with the skin S of the patient P, in particular close to the heart H of the patient P. This way, the method may be non-invasive.

In another embodiment, illustrated on <FIG>, the ultrasound probe <NUM> may be introduced inside the oesophagus O of the patient P and brought in proximity with the heart H of the patient P.

In yet another embodiment, not illustrated on the drawings, the skin and/or bones of the patient may be pushed aside during a preliminary surgical operation so that the ultrasound probe <NUM> can be arranged in closer proximity to the heart H. In a variant, the ultrasound probe <NUM> may also be introduced under the skin and/or bones of the patient to be arranged in close proximity to the heart H. For instance a sternotomy may be performed and the ultrasound probe <NUM> may be brought in contact with the external wall of the heart of the patient.

The apparatus <NUM> also comprises means <NUM> - e.g. an imaging device, and more particularly an ultrasonography (echography) probe - for mapping a treatment region R of a cardiac valve V of the patient P, the treatment region R comprising at least one leaflet L of the cardiac valve V.

Said at least one leaflet L of the cardiac valve V may be calcified leaflet(s), in particular in the case of a method for treatment of valvular disease.

The at least one leaflet L may also be stiff leaflet(s), for instance in the case of a method for preventing valvular disease.

The treatment region R may also comprises at least one portion of an annulus of the cardiac valve, in particular a stiff or calcified portion of the annulus.

In one embodiment of the invention, the means for mapping <NUM> can be an ultrasound imaging array, and can, in particular, be the array of transducer <NUM> of the ultrasound probe <NUM> used for generating focused ultrasound waves, as illustrated on <FIG>.

In a variant, the means for mapping <NUM> may comprise an ultrasound imaging array <NUM> integrated in the ultrasound probe <NUM> and separated from the array of transducer <NUM> used for generating focused ultrasound waves.

One example of such an embodiment is illustrated in detail on <FIG> where a central element <NUM> of the catheter ultrasound probe <NUM> comprises the ultrasound imaging array <NUM> of the means for mapping <NUM> and a surrounding element <NUM> comprises the array of transducer <NUM> used for generating focused ultrasound waves.

On the example of <FIG>, the central element <NUM> has the shape of a disc but it may also present the shape of a rectangle or another suitable shape. Moreover, the surrounding element <NUM> is shown with the shape of a circular annulus but may adopt other suitable shapes such as a rectangle ring or dots for instance.

The surrounding element <NUM> may be divided in several elements, for instance several concentric rings <NUM> that can be independently controlled.

The ultrasound imaging array <NUM> may acquire images in various imaging modes such as A-mode, B-mode, CW-Doppler, PW-Doppler, Color Doppler, Power Doppler, M-mode, Harmonic Imaging, Shear wave imaging, Elasticity Imaging, Tissue Strain Imaging, this list being not limitative.

In other embodiments of the invention, the means for mapping <NUM> may comprises a CT scanning apparatus, an X-ray imaging apparatus or an MRI apparatus for instance.

By "mapping", it is meant that a digital image of the treatment region R is obtained during a mapping step <NUM>. The digital image may for instance be stored in a memory. The digital image of the treatment region R may thus be obtained by ultrasound imaging, CT scanning, X-ray imaging or MRI, for instance.

The treatment region R can cover a surface of at least <NUM> square millimetres, measured in a plane P perpendicular to an opening direction D of the cardiac valve V.

By "opening direction", it is meant a general direction D of the blood flowing through the cardiac valve V when said valve is open as illustrated on <FIG>.

As illustrated on <FIG>, the apparatus <NUM> also comprises a controller <NUM> of the ultrasound probe <NUM>.

We now refers also to <FIG> which illustrates a detail of the ultrasound probe <NUM> of <FIG>.

The ultrasound transducers array <NUM> can comprise a few tens to a few hundred transducers <NUM>. The array <NUM> may be a linear array, with the transducers arranged side by side along a longitudinal axis of the array. The array <NUM> can also be a two-dimensional array so as to emit three-dimensional focused waves.

The controller <NUM> of the ultrasound probe <NUM> may then comprises for instance:.

As shown on <FIG>, the electronic system <NUM> may include for instance:.

The transducers T1-Tn are controlled independently of one another by the central processing unit.

In a step <NUM> of the method, the controller <NUM> controls the ultrasound probe <NUM> to emit a sequence of N focused ultrasound waves.

The ultrasound probe <NUM> emits focused ultrasound waves that generate negative pressure inside the tissues of the heart H of the patient P.

More precisely, the ultrasound probe <NUM> is controlled so that each focused ultrasound wave of the sequence of N focused ultrasound waves generates, at the focal spot, a pressure pulse sufficient to result in cavitation. A focal spot may be defined precisely as the volume wherein the ultrasound pressure exceeds the cavitation threshold.

The resulting cavitation may form a bubble cloud at a focal spot of the focused ultrasound wave. Such acoustic cavitation occurs when the acoustic intensity or pressure exceeds a threshold of the tissue (cavitation threshold).

To this aim, the ultrasound probe <NUM> may for instance emit focused ultrasound waves that generate, at their focal spot, a peak negative pressure half-cycle that exceeds a peak negative pressure of <NUM> MPa, for instance present an absolute value higher than <NUM> MPa.

At their focal spot, the peak positive pressure half-cycle of the focused ultrasound waves may also exceeds a peak positive pressure of <NUM> MPa, for instance present an absolute value higher than <NUM> MPa.

The duration of the pressure pulse generated by each focused ultrasound wave at the focal spot may be less than <NUM> microseconds, or even <NUM> microseconds.

In one example, the duration of each focused ultrasound wave is less than <NUM> microseconds.

This way, the sequence of N focused ultrasound waves does not heat the tissues of the heart which prevent damaging the heart valve and the surrounding structures of the heart.

The method of the disclosure and the apparatus of the invention thus prevent erosion and heating of the tissues of the heart and preserve structures surrounding the cardiac valves.

The sequence of focused ultrasound waves is also such that the focal spots k of the sequence of N focused ultrasound waves scan the entire treatment region R.

By "scan the entire treatment region", it is meant that the centres of the focal spots k of the sequence of N focused ultrasound waves are arranged to fill the entire treatment region R with a given minimal distance separating the centre of each focal spots k and a given maximal distance separating the centre of each focal spots k from its nearest neighbour.

The centre of each focal spots may be separated from its nearest neighbour by a given maximal distance of less than <NUM> millimetre.

In one embodiment, the centre of each focal spots of the sequence of focused ultrasound waves may be separated from one another by a minimal distance larger than <NUM> microns, for instance larger than <NUM> millimeter.

In a variant, some focused ultrasound waves of the sequence of focused ultrasound waves may present focal spots that have the same location inside the treatment region R.

The focused ultrasound waves of the sequence of focused ultrasound waves may be periodically spaced or may be grouped on some predefined locations of the treatment region R.

<FIG> illustrates on example of the centres of the focal spots k of a sequence of N focused ultrasound waves. The order of emission of the sequence of N focused ultrasound waves is illustrated by dashed arrows connecting the centres of focal spots k as matter of non-limitative example.

According to some embodiments of the invention, neighbouring focal spots may overlap; otherwise stated, the maximal distance between their centres may be smaller than their width. This ensures that all the points of the treatment region R (or of at least a connected subset thereof) are exposed at least once to ultrasound waves whose intensity is sufficient to induce cavitation.

According to alternative embodiments of the invention, neighbouring focal spots may not overlap, their centres being separated by distances larger than their widths. In this case, only discrete locations of the treatment region R are exposed at least once to ultrasound waves whose intensity is sufficient to induce cavitation.

An hybrid approach may also be followed, wherein some neighbouring focal spots overlap, while other do not.

By using such a sequence of N focused ultrasound waves, it is possible to soften the tissues of the calcified cardiac valve leaflet L while preventing erosion of said tissues, and thus a puncture of the cardiac valve leaflet L.

It is thus possible to restore leaflet mobility and valve function in patient.

An ultrasound probe <NUM> suited for emitting such high intensity controlled focused ultrasound waves is illustrated on <FIG>.

In the illustrated embodiment, the ultrasound probe <NUM> comprises a reflective cavity <NUM> and at least one transducer <NUM>.

The reflective cavity <NUM> may be filled with a liquid <NUM>, for example water and in which the ultrasound transducers array <NUM> are located. The reflective cavity <NUM> comprises walls made of a material forming a highly reflective interface for acoustic waves, for example thin films separating the liquid contained in the cavity from the air outside the cavity.

The reflective cavity <NUM> may be in contact at one of its ends with the patient P through a window 9a in the cavity wall, directly or through an acoustic lens <NUM> mounted on the window 9a.

The reflective cavity <NUM> may further comprises a multi-scattering medium <NUM> adapted to be traversed by acoustic waves emitted by the ultrasound transducers before said waves reaches the patient's body. The multi-scattering medium <NUM> is able to cause multiple scattering of said acoustic waves.

The multi-scattering medium <NUM> is located, for example, near the window 9a of the reflective cavity <NUM> and comprises a number of scatterers <NUM>, for instance between several tens to several thousands of scatterers <NUM>.

The scatterers <NUM> are adapted to scatter acoustic waves and are advantageously distributed randomly or non-periodically in the multi-scattering medium <NUM>, meaning that their distribution does not exhibit a periodic structure. The scatterers 8a may thus exhibit a surface having a significant difference in impedance compared to the medium of the reflective cavity.

The scatterers <NUM> can have the general shape of vertical rods held in place by frames or attached to the walls of the reflective cavity. Alternatively, the scatterers <NUM> may take the form of beads, granules or cylinders and be held in place by foam, an elastomer, or three-dimensional frames so that they are distributed over all three dimensions of the space to form the multi-scattering medium <NUM>.

The scatterers <NUM> may, for example, have transverse cross-sections that are substantially between <NUM> and <NUM> times the wavelength of the wave in the reflective cavity, for example between <NUM> and <NUM> times said wavelength. Said transverse cross-section is understood to be a cross-section taken perpendicularly to the extension direction of the scatterers <NUM> and/or to the longest extension direction of the multi-scattering medium <NUM>.

The scatterers <NUM> can be distributed within the multi-scattering medium <NUM> so that their surface density in a cross-section of the multi-scattering medium <NUM> transverse to the extension direction Z of the scatterers <NUM>, is, for an acoustic wave having a centre frequency of about <NUM>, ten or so scatterers <NUM> per square centimetre, for example eighteen acoustic scatterers <NUM> per square centimetre.

In the case of a three-dimensional multi-scattering medium, the scatterers <NUM> can be distributed in the multi-scattering medium <NUM> so that their volume packing density within the multi-scattering medium <NUM> is between <NUM>% and <NUM>%.

The length of the multi-scattering medium <NUM>, along the direction of propagation of the wave, may be a few centimetres, for example two centimetres.

The array <NUM> of ultrasound transducers can be arranged on a face of the reflective cavity <NUM> facing the window open on the patient's body or may be oriented so as to emit waves toward the multi-scattering medium <NUM>, at a certain angle relative to a cavity extension direction Y, for example <NUM>°.

Such a reflective cavity <NUM> forms a reverberator that permits, at the same time,.

To this aim, prior to performing the method of treatment, a calibration <NUM>, or learning step <NUM>, of the ultrasound probe <NUM> may be conducted.

Such a calibration may involve the determination of matrix of individual emission signals eik(t) such that, to generate a focused ultrasound wave s(t) focused at a target point k of the treatment region R, each transducer i of the array <NUM> emits an emission signal:<MAT>.

These individual emission signals are ultrasound signals that may be determined by calculation (for example using a spatio-temporal inverse filter method), or may be determined experimentally during a preliminary learning step <NUM>.

During an example of such a learning step <NUM>, an ultrasonic pulse signal may be emitted by a hydrophone, successively placed at a succession of target points k in a volume of liquid placed in contact with the ultrasound probe <NUM>. The signals rik(t) received by each transducer i of the array <NUM> from the emission of said ultrasonic pulse signal are captured. The signals rik(t) are then converted by the analog-to-digital converters and stored in the memory connected to the processor CPU, which then calculates the individual emission signals eik(t) by time reversal of said received signals: <MAT>.

When one or more focused ultrasound waves are then to be focused on a predetermined target point k within the treatment region R, the ultrasound probe <NUM> is placed in contact with the patient P, and an emission signal Si(t)is emitted by each transducer i of the array <NUM> to generate a focused ultrasound wave: <MAT>.

The duration of the emission signal emitted by each transducer of the array <NUM> to generate a focused ultrasound wave of the sequence of focused ultrasound waves may be less than <NUM> milliseconds, in particular less than <NUM> millisecond.

The duration of the pressure pulse generated by said focused ultrasound wave at the focal spot may be at least <NUM> times shorter, and preferably at least one hundred times shorter, than the duration of the emission signal emitted by each transducer of the array <NUM>. Otherwise stated, the duration of the emission signal emitted by each transducer of the array <NUM> to generate a focused ultrasound wave of the sequence of focused ultrasound waves may be at least ten times longer than the duration of the pressure pulse generated by said focused ultrasound wave at the focal spot, preferably at least hundred times longer than the duration of said pressure pulse.

Therefore, the duration of the pressure pulse may be of less than <NUM> millisecond, preferably of less than <NUM> microseconds, even more preferably of less than <NUM> microsecond; for example, the emission signal may has a duration of the order of <NUM> microseconds and the pressure pulse at the focal point a duration of less than <NUM> microseconds.

Different ultrasound probes may also be used to carry out the exemplary method. <FIG> illustrate different exemplary embodiments of such probes.

The ultrasound probe <NUM> of <FIG> comprises an assembly of four reflective cavities <NUM>, <NUM>, <NUM>, <NUM>, each one similar to that of <FIG>, forming a square. An imaging array <NUM> is situated at the centre of the assembly. The reflective cavities are coupled to the patient's body through respective plastic bags filled with gel (not represented) while the imaging array <NUM> is almost directly in contact with it (in practice, with the interposition of a plastic sheet interconnecting the bags and of a thin layer of gel).

The ultrasound probe of <FIG> comprises a multi-element transducer <NUM> consisting of a bi-dimensional array TA of several tens or hundreds of independently-driven elementary transducers (one of which is designated by reference IT). An imaging array <NUM> may be situated at the centre of the multi-element transducer, in order to be in direct - or almost direct - contact with the patient's body. This embodiment allows electronically steering the focused ultrasound waves, like the embodiments based on reflective cavities; its main drawback is the complexity of the controller <NUM>, which has to comprise several tens or hundreds of independent power drivers for the individual elementary transducers.

<FIG> shows a much simpler ultrasound probe, based on a concave mono-element transducer <NUM>, focusing ultrasound waves at a fixed depth. An imaging probe <NUM> is situated at the centre of the mono-element transducer. In this case, the focused ultrasound waves have to be mechanically steered, e.g. by displacing the transducer along three axes. A significant drawback is that, in order to allow a displacement of the transducer in the axial direction, the imaging array cannot be kept in direct contact with the body of the patient; imaging has then to be performed through a significant depth of matching gel, which reduces the quality of the acquired images.

<FIG> illustrates an annular array transducer <NUM>, consisting of a limited number (typically <NUM> to <NUM>, <NUM> in the example of the figures) of concentric ultrasound annular transducers 64a - 64j. Driving the annular transducers with an appropriate phase difference allows focusing an ultrasound wave at an adjustable depth. In-plane scanning is performed mechanically, by moving the transducer. Imaging probe <NUM> is situated at the centre of the innermost annular element. The complexity of the driver <NUM> is much lesser than in the case of <FIG>, due to the reduced number of power drivers; moreover, unlike the case of <FIG>, the imaging probe may be kept in contact with the patient's body, as the scanning in the axial direction is performed electronically. Document <CIT> discloses an annular array transducer of this kind.

An ultrasound probe suitable for the invention may be optimized to focus ultrasound energy in a predefined region, called a scannable region E illustrated on <FIG>.

A scannable region E is a region of the patient body where the focusing of ultrasound energy by the ultrasound probe is more efficient and/or is calibrated.

The scannable region E may be predefined during the preliminary learning step mentioned. The scannable region can for instance be defined by the succession of target points k where the hydrophone has been successively located during the preliminary learning step.

The method according to the disclosure may also comprise a real-time imaging <NUM> of the cardiac valve, to map the treatment region. In this embodiment, the step of real-time imaging of the cardiac valve may further allow to map the scannable region of the ultrasound probe.

A mechanical control <NUM> of the location of the ultrasound probe externally to the heart of the patient may then be used to keep the treatment region inside the scannable region of the ultrasound probe.

To this aim, the ultrasound probe <NUM> can be mounted on a robotic arm <NUM>, or holder, able to control the location of the ultrasound probe <NUM> with regard to the patient's heart H location. The robotic arm <NUM>, driven by controller <NUM>, may control the location of the ultrasound probe to keep the treatment region inside the scannable region of the ultrasound probe.

We will now describe in greater details how a controlled softening of the tissues of a cardiac valve leaflet L can be obtained by selecting the timing, duration and focal spot location of each focused ultrasound waves.

In one embodiment of the method of treatment according to the disclosure illustrated on <FIG>, the sequence of focused ultrasound waves is thus emitted at a predefined rate of emission while the focal spot of the focused ultrasound waves is moved to scan the entire treatment region R.

The predefined rate of emission may be for instance comprised between <NUM> and <NUM> shots per second, preferably between <NUM> and <NUM> shots per second. In one example, the rate of emission may be about <NUM> shots per second. In another example it may be about <NUM> shots per second.

The focal spot of the focused ultrasound waves may be moved to scan the entire treatment region with a predefined travelling speed. The predefined travelling speed may be comprised between <NUM>/s and <NUM>/s, preferably of the order of <NUM>/s.

In one embodiment of the invention, the focused ultrasound waves emitted by the ultrasound probe <NUM> can be steered to scan the entire treatment region R.

For instance, the ultrasound probe <NUM> illustrated on <FIG>, and described here before, may be able to electronically steer the focused ultrasound waves to scan the entire treatment region R.

By "the focused ultrasound waves are electronically steered", it is meant that the successive locations of the focal spots of the focused ultrasound waves are selected without physically moving the ultrasound probe <NUM>, it this meant that the focal spot of focused ultrasound waves emitted by the ultrasound probe <NUM> can be moved without physically moving the ultrasound probe <NUM> but by controlling the emission signals of the transducers <NUM> of the ultrasound probe <NUM>.

Alternatively or in addition, the location of the ultrasound probe <NUM> may be mechanically controlled <NUM>, e.g. using the robotic arm <NUM> or different mechanical actuators, in function of said motion of the treatment region, in order to scan the entire treatment region.

Real-time imaging <NUM> may also be used to estimate a motion of the treatment region R with regard to the ultrasound probe <NUM>; in the case of a heart valve, motion of the treatment region results mainly from a combination of breathing and hearth beat. The focused ultrasound waves emitted by the ultrasound probe <NUM> may then be steered in function of said motion of the treatment region, in order to scan the entire treatment region. Otherwise stated, real-time imaging <NUM> may allow performing real-time tracking of the valve to be treated. A tracking algorithm suitable to be used in the invention is discussed in the paper by <NPL>. Another suitable tracking algorithm is described in <NPL>.

This way, motions of the treatment region R can be compensated for by electronical steering of the focused ultrasound waves and/or mechanical control of the location of the ultrasound probe <NUM>.

More precisely, the focused ultrasound wave emission may be driven by the following process, carried out by the controller <NUM>:.

Typically, the controller <NUM> will be configured to perform the electronical and/or mechanical steering of the focused ultrasound waves in order to scan the target reason to be treated while tracking its motion during the treatment. On the contrary, in the above-referenced paper by R. Miller et al. , tracking is used to keep ultrasound pulses focused on a same point of a heart.

It is possible to predefine a plurality of N successive insonification times t<NUM>-tN and/or a plurality of N cavitation locations P<NUM>-PN inside the treatment region.

In one variant, the successive insonification times and the cavitation locations may be computed to correspond to a travelling speed of the focal sport comprised between <NUM>/s and <NUM>/s, preferably of the order of <NUM>/s.

Alternatively, the successive insonification times and the cavitation locations may be computed to correspond to alternate trajectory of the focal spot that may then correspond to a travelling speed of the focal sport higher than <NUM>/s.

As already mentioned above, the centre of each focal spots of the sequence of N focused ultrasound waves may be separated from one another by a minimal distance shorter than a diameter (more generally, a width) of the focused ultrasound waves focal spots.

This way, a point of the treatment region may be included in the focal spots of several focused ultrasound waves, and each point of the treatment region is included in the focal spot of at least one focused ultrasound wave. As a matter of non-limitative example, the diameter of the focal spots of the focused ultrasound waves may be about <NUM>.

The sequence of N focused ultrasound waves may be such that a point of the treatment region is included in the focal spots of a number M of focused ultrasound waves of the sequence of focused ultrasound waves, said number M being comprised between <NUM> and <NUM>, preferably between <NUM> and <NUM>, preferably of the order of <NUM>.

Alternatively, the centres of at least some focal spots of the sequence of N focused ultrasound waves may be separated from one another by a minimal distance longer than a diameter (more generally, a width) of the focused ultrasound waves focal spots. This way, at least some points of the treatment region may not be included in the focal spots of any focused ultrasound wave. In some cases, the centre of each focal spots of the sequence of N focused ultrasound waves may be separated from one another by a minimal distance longer than a diameter (more generally, a width) of the focused ultrasound waves focal spots.

As illustrated on <FIG>, the method according to the disclosure may also comprise a step of using a measuring device (which, in some embodiment, may be or include the imaging array <NUM> itself) for measuring an index of valvular stenosis <NUM> after having emitted the sequence of focused ultrasound waves.

In one embodiment of the invention, the index of valvular stenosis is a function of a hemodynamic parameter. The hemodynamic parameter may for instance be a heart pressure gradient across the cardiac heart valve or a blood flow velocity across the cardiac heart valve. These parameters may be measured using e.g. a Swan-Ganz catheter of a Millar catheter. However, use of such catheters is not preferred because it is invasive.

In another embodiment, performed hemodynamic parameter may be determined by using Doppler imaging to measure the blood flow velocity across the cardiac heart valve. Doppler imaging may be performed by a Doppler imager, which may include the imaging array <NUM>, or a dedicated imaging device.

In another embodiment that may be combined with the previous embodiment, the index of valvular stenosis can be function of a shear wave propagation parameter. In this embodiment, the step of measuring the index of valvular stenosis may thus comprise a shear wave imaging step carried out using a shear wave imaging device, as described in document <CIT> for instance.

In yet another embodiment that may be combined with one or both of the previous embodiments, the index of valvular stenosis may be function of a valve motion parameter. The step of measuring said index of valvular stenosis may then comprise an estimation of a valve motion, e.g. obtained by Doppler imaging.

In both embodiments, the index of valvular stenosis may then be compared <NUM> with a predefined threshold. This way, it is possible to assess the progress of the method. The predefined threshold may be representative of tissues softness to be achieved.

According to the invention, at least the steps of controlling <NUM> the ultrasound probe to emit a sequence of N focused ultrasound waves and measuring <NUM> the index of valvular stenosis are reiterated until the index of valvular stenosis reaches, or crosses, the predefined threshold.

Several series of N focused ultrasound waves may thus be emitted, separated by steps of control to assess the state of the cardiac heart valve tissues and its evolution.

The exemplary method has been tested experimentally.

To this aim, Carpentier-Edwards Perimount Magna™ aortic valve bioprostheses, explanted on humans, were used as model of heart calcified valve. The indication of explant was a significant stenosis with calcification. Each valve was fixed in glutaraldehyde <NUM>% immediately after explant. Before each experimentation, the valve was immersed in saline serum (<NUM>% NaCl) during <NUM> minutes, three consecutive times.

The protocol was in agreement with institutional guidelines (French national reference number of the study: <NUM>).

A <NUM>,<NUM> focused single-element transducer (Imasonic®, Besangon, France), called hereafter a "therapy transducer", was used to generate focused ultrasound waves. It had a <NUM> focal length (f-number = <NUM>). This transducer was driven by a high-voltage amplifier. The therapy transducer was used to generate <NUM>-cycle pulses, each <NUM> long, delivered at a pulse repetition frequency (PRF) of <NUM>. It is estimated the pressure peak amplitudes at the focal spot was <NUM> MPa and -<NUM> MPa respectively for the positive and negative peak.

3D Echocardiography was used to guide and monitor the treatment. An IE33 (Philips™) scanner and X5-<NUM> probe (xMATRIX™ array, <NUM>, <NUM> elements with microbeam-forming) were used. The imaging probe was fixed through a hole in the center of the therapy transducer. The focal spot of the therapy transducer was positioned on the central axis of the imaging probe at a depth of <NUM>. A bi-plane imaging mode with two imaging planes set at <NUM>° was used during the whole procedure. The histotripsy focal spot was visible within the two imaging planes. The combination of therapy transducer and imaging probe was called the "therapy device". The same material was used for in vitro and in vivo procedures.

For all the procedures, sequences of <NUM> minutes of ultrasound waves were applied, and repeated until reaching a stabilization of the transvalvular gradient for <NUM> consecutive sequences. The therapy device was controlled by a <NUM>-axis motor for scanning the ultrasounds continuously and uniformly over the entire valve.

In order to assess the modification of the biomechanical properties induced by the application of ultrasound focused waves, shear wave elastography, an ultrasound-based tool for noninvasive evaluation of soft tissue's stiffness, was used. The Aixplorer ultrasound imaging system (Aixplorer™, Supersonic Imagine, Aix-en-Provence, France) with a linear probe (SL10-<NUM>) was used to evaluate the stiffness of each valvular leaflet. Three acquisitions were made for each leaflet, using the shear wave elastography imaging mode (SWE™) of the Aixplorer scanner in the 'penetration' setting. A ''QBox™'' region of interest (mean diameter <NUM>) was positioned inside the elasticity image after each acquisition to obtain a mean stiffness value.

The setup of the in vitro procedure is illustrated on <FIG>. A bioprothesis A is placed right in front to the therapy device B, including transducer <NUM> and imaging probe <NUM>, both immersed in degassed water. A three-axes motor 3AM was used to adjust the position of the therapy device <NUM>. An artificial cardiac pump C (Harvard Apparatus Pulsatile Blood Pump®) induced a pulsatile flow through the valve. The flow rates were applied at <NUM>, <NUM> and <NUM> per minute, monitored by a flow sensor D (Small flow Meter Kit, Atlas scientific®; accuracy +/- <NUM>/min). The transvalvular pressure gradient was estimated by:.

The pump operated during <NUM> hours at <NUM> / min flow rate (<NUM> cycles per minute, ejection volume equal to <NUM>) to control the variation of the gradient before carrying out the exemplary method, after which sequences of ultrasound focused waves were applied.

After the procedure, Elastography was performed again on each valve.

Finally, the bioprostheses were sent to the department of pathology of Hôpital Européen Georges Pompidou (Paris) for histopathological analysis.

For carrying out the in vivo procedures, bioprostheses explanted on humans, of the same type as those used in the in-vitro procedure, were implanted on sheep.

The implantation was performed in mitral position, and not in aortic position, because of the relative diameters of the implanted valves and of the sheep's aortic valves (diameter between <NUM> and <NUM>). The inventors consider that the mitral implantation was acceptable to determinate if the application of focused ultrasound waves could decrease the calcified stenosis. The setup is illustrated on <FIG>.

Elastography of the bioprosthesis was done before and after each procedure. The animal procedure was approved by the Institutional Animal Care and Use Committee of Hôpital Européen Georges Pompidou (PARCC) according to the European Commission guiding principles (<NUM>/<NUM>/EU).

The sheep were anesthetized with thiopentothal (<NUM>/kg), intubated, ventilated at <NUM>/kg with <NUM>% isoflurane, and given glycopyrrolate (<NUM> intravenous) and vancomycin (<NUM> grams intravenous). A sterile sternotomy was performed. The calcified bioprosthesis was implanted in mitral position, after CPB. Vital signs (including heart rate (HR), oxygen saturation, arterial blood pressure (BP)), left atrial and ventricle pressure (by two Mikro-Tip® Millar Catheter Transducers MC , to have the transvalvular pressure gradient in real time) and cardiac flow (by a Swan-Ganz CCOmbo Pulmonary Artery Catheter, Edwards Lifesciences®, reference SG) were monitored. The CPB was stopped and removed to restore independent cardiac activity. Sternotomy was maintained and the thorax was filled with degassed saline water. A completed echocardiography was realized, especially to evaluate the calcified bioprosthesis.

The therapy device B was immersed in the water filling the thorax and positioned near the heart H (RA: right atrium, LA: left atrium; RV: right ventricle; LV: left ventricle) with the help of a three-axis motor 3AM in order to apply several sequences of focused ultrasound waves onto the implanted bioprothesis A. An echocardiographic evaluation was realized between each sequence, in parallel of the catheters evaluation (pressure and cardiac flow).

At the end of the procedure, the animal was sacrificed (Dolethal™ intravenous injection, <NUM>/kg) and an anatomical macroscopic evaluation of the cardiac structure was performed. The bioprosthesis was then explanted and sent after elastography to the department of pathology for histopathological analysis.

Immediately after the procedure (in vitro and in vivo), the bioprosthesis were dissected, fixed in formalin and embedded in individual paraffin blocks. Regions of interest, like macroscopic calcification on leaflet, were labeled with tattoo ink. Serial sections were stained with H&E (hematoxylin and eosin) for histopathological analysis.

In addition, <NUM> calcified bioprostheses were also sent for histopathological analysis directly after their explantation from human, without any application of ultrasound. The objective was to allow a histopathological comparison between bioprostheses with or without treatement.

Results are presented and discussed belows. Continuous variables are presented as mean ± standard deviation (SD) or median with minimum and maximum range, and categorical variables are presented as percentage ± <NUM>% CI. Comparisons of categorical variables were made using chi-square test, or Fisher exact test when appropriate. Univariate analyses of continuous variables were performed with the paired two-tailed Student's t-test (normal distribution). Univariate comparisons for categorical variables were performed with the two-tailed χ2 test or, when necessary (one or more of the cells have an expected frequency of five or less), the Fisher's exact test. The level of significance was set at an alpha level of <NUM> or less. Analysis was conducted using Medcalc™ (MedCalc Software, Mariakerke, Belgium).

All the results show a softening of the valve leaflets allowing a decrease of the anterograde gradient. This decrease is persistent one month after the treatment. The decrease of transvalvular gradient measured by Doppler echocardiography was confirmed by invasive pressure sensors in both in vitro and in vivo setup.

<FIG> illustrates results obtained for the in vitro procedure. Eight bioprostheses were explanted and used for this procedure. At a flow rate of <NUM>/min, the mean transvalvular gradient over the set of valves was <NUM> ± <NUM> mmHg (max=<NUM>, min=<NUM>, <FIG>, H0) and the maximum gradient was <NUM> ± <NUM> mmHg (max=<NUM>, min=<NUM>). After two hours (H2) of controlled pulsatile flow, no statistically significant change of the transvalvular gradients was observed. The mean duration of the treatment was <NUM> ± <NUM> minutes with a maximum duration of <NUM> minutes and a minimum of <NUM> minutes. The pump flow was adjusted to maintain a constant flow of <NUM>/min during and after the treatment. After the procedure, the mean transvalvular gradient was <NUM>±<NUM> mmHg (max=<NUM>; min=<NUM>), which corresponds to a decrease of <NUM>±<NUM> % (p<<NUM>) and the maximum gradient was <NUM>±<NUM> mmHg (max=<NUM>; min=<NUM>), which corresponds to a decrease of <NUM> % (p<<NUM>).

Hemodynamic parameters were also measured at <NUM>/min and at <NUM>/min, before and after procedure, and the gradients also showed a significant decrease (p<<NUM>). At <NUM>/min, the mean gradient varies from <NUM>±<NUM> to <NUM>±<NUM> mmHg (p<<NUM>) and the maximum gradient from <NUM>±<NUM> to <NUM>±<NUM> mmHg (p<<NUM>). At <NUM>/min, the mean gradient varies from <NUM>±<NUM> to <NUM>±<NUM> mmHg (p<<NUM>) and the maximum gradient from <NUM>±<NUM> to <NUM>±<NUM> mmHg (p<<NUM>).

All post-treatment transvalvular gradients were reassessed one month after the procedure and there was no statistically significant difference (<FIG>).

<FIG> shows mean transvalvular gradient results for each valve treated in vitro. <FIG> shows multi flow results (<NUM>, <NUM> and <NUM>/min) obtained in vitro for each valve.

Results for in vivo procedure are reported in table <NUM> and illustrated by <FIG> and <FIG>.

Fourteen explanted bioprostheses were used for this procedure. Seven of the animals suffered a massive acute pulmonary edema with severe heart failure, just after the implantation of the valve and the cessation of the CPB. These animals died before the procedure. The other animals tolerated the implantation, seven valves were thus treated and analyzed.

The mean weight of the animals was <NUM>. <NUM> (min=<NUM>; max=<NUM>).

Just after the valve implantation, all the parameters were monitored for one hour, before any treatment, and there was no statistically significant change of the transvalvular gradients (p=<NUM>) and mitral valve areas (planimetry, p=<NUM>; continuity equation, p=<NUM>; PHT, p=<NUM>).

The mean duration of procedure was <NUM> ± <NUM> minutes with a maximum duration of <NUM> minutes and a minimum of <NUM> minutes. An important decrease of the transvalvular gradient was observed after treatment (see table <NUM>). The mean cardiac frequency was <NUM> (min=<NUM>; max=<NUM>) and all the hemodynamic parameters were stable during the procedures: HR (p=<NUM>), BP (p=<NUM>), O2 saturation (p=<NUM>). The results of elastography, of echocardiography and of pressure/flow cardiac catheters of the procedures are synthesized in the table <NUM> and illustrated on <FIG>.

<FIG> shows echocardiography images acquired before, during and after the treatment. During the treatment, the "cloud of cavitation" (microbubble) is visible, and highlighted by an arrow. After treatment, the modification of the bioprothesis opening is confirmed by echocardiography (see the arrow on the lowest-leftmost image of the figure).

No mitral valve regurgitation was observed at the end of procedures.

Isolated ventricular extrasystols (VES) was observed in two animals, without any repercution on hemodynamic parameters. As long as the focal spot of the therapy device remained at the bioprosthesis, no arrhythmia was visible.

Macroscopic analysis of hearths explanted after euthanasia of the animals showed all cardiac structures were intact, except in one animal in which a superficial hematoma (epicardium) of <NUM> diameter was visible at the lateral LV wall (on the path of the ultrasound beam). This animal was also one of two animals who presented isolated VES.

At the end, the bioprosthesis was sent to the department of pathology for histopathological analysis.

In vitro, before the tratment, the mean stiffness of the valves leaflets measured by elastography was <NUM> ± <NUM> kPa. After the procedure, the mean stiffness of valves leaflets measured by elastography was <NUM> ± <NUM> kPa. It corresponds to a decrease of <NUM> ± <NUM>% (p<<NUM>).

A similar stiffness decrease was observed for the bioprosthesis used in vivo (<NUM> ± 10kPa before the procedure and <NUM> ± <NUM> kPa after the treatment, <NUM> ± <NUM> % decrease, p< <NUM>). <FIG> shows exemplary Shear Wave Elastography images acquired in vitro to measure mean stiffness. <FIG> shows numerical results obtained in vitro (upper panel) and in vivo (lower panel). Stiffness results for each individual bioprosthesis are shown on <FIG>.

<FIG> shows histological images of a treated bioprothesis. All the superficial structures of the leaflets (fibrosa and ventricularis) were intact - see reference S. In comparison with the five bioprostheses explanted without application of the procedure, it was possible to observe:.

There was no histological evidence for acute inflammation or acute thrombosis on the bioprosthesis.

Similar results are observed on native valves.

The experimental results show that, after the treatment, the mean and maximal transvalvular gradients were decreased by two-fold both in vitro and in vivo. Moreover, these hemodynamical modifications persisted after one month (in vitro procedure). The evolution of other echocardiographic parameters measured in vivo (valve area, PAP) confirmed the decrease of the valvular stenosis. Finally, it was shown that the treatment induced a decrease of the valves leaflet stiffness.

There was no statistical difference between the duration of the in vitro (<NUM>±<NUM> minutes) and the in vivo (<NUM> minutes) procedures (p=<NUM>).

Additional tests were performed to determine whether the stiffness reduction induced by the treatment results from softening of the valve tissues, fragmentation and cracking of the calcifications or both.

In order to assess the effect of focused ultrasound waves on the valvular tissue, tests were performed using detergent-decellularized porcine pericardium, which is a suitable model. Ultrasound focused waves at <NUM>, <NUM> cycles/pulse (<NUM> microseconds), where emitted at a repetition rate of <NUM> and steered to scan the pericardium sample at two different speeds, <NUM>/s and <NUM>/s. Scanning was performed along three parallel lines, run through in two opposite directions. The pericardium stiffness was measured by elastography at three different spots. <FIG> shows the evolution of the average stiffness with the number of runs at a scanning speed of <NUM>/s (curve S1) and <NUM>/s (curve S3). Taking into account the fact that a run at <NUM>/s takes three times longer than at <NUM>/s, it can be seen that stiffness decreases faster at <NUM>/s, but in both cases a five-fold stiffness reduction is achieved. Perforation is achieved at <NUM> runs, independently from the scanning speed.

In order to assess the effect of focused ultrasound waves on calcifications, tests were performed on formaldehyde-fixed calcified human aortic valves. The samples were treated in hydraulic bench with a <NUM> transducer at an emission frequency of <NUM>, a pulse repetition frequency of <NUM> and <NUM> cycles. The power level was set at a level necessary to observe cavitation and the saline was degassed to below <NUM>/L of O<NUM>. The cusps were placed on an absorber with needles with the fibrosa facing the transducer. The samples were moved in the X and Y direction with a "snake" pattern to treat the chosen area with a speed of <NUM>/s.

In order to perform Micro-CT image acquisition, the cusps of the valves were placed in saline in a plastic tube cap and imaged with a field of view of <NUM> (FOV10) and a voxel size of <NUM>. Software was used to attempt to realign slices of stacks taken before and after treatment. The results are only qualitative so far; however, there seems to be a fragmentation and cracking of the calcifications following ultrasonic treatment of the cusps.

It can then be inferred that the stiffness reduction induced by the treatment results from both softening of the valve tissues and fragmentation of the calcifications.

The results above suggest that pulsed cavitational focused ultrasound can have a real clinical impact on calcified valves and can be considered as a new therapeutic strategy. Its two main advantages are that it could theoretically be applied totally noninvasively and would allow the preservation of the native valve ad intergrum.

Another challenge for our in vivo study is the accuracy of the treatment that will allow to have a safe procedure. For a few animals indeed (two animals) a few non persistent ventricular extrasystoles were observed, and post mortem anatomic exploration showed bruising of the cardiac wall, due to off target cavitation. These two undesirable effects are mostly induced by the inaccuracy of the target positioning and motion and could be greatly reduced by tracking the valve motion, as explained above. This will be even more important in actual non-invasive implementations, wherein the therapy transducer will be much farther away from the valve than in the setup of <FIG>.

An alternative or complementary solution would be to trigger histotripsy exposures by electrocardiogram. Indeed, it is possible to select specific moments in the cardiac cycle for example during the refractory period of the myocardium (to avoid inducing extrasystoles) or when the aortic valve is closed and thus its whole surface is equally exposed, and far away from the cardiac wall.

<FIG> is a simplified representation of an electrocardiographic trace; references TW, PW, QW, RW, SW correspond to T-waves, P-waves, Q-waves, R-waves and S-waves respectively; G1 and G2 correspond to suitable gating time, i.e. start times for ultrasound pulses; PH1, PH2 and PH3 identify time periods during which ultrasound pulses may be applied with optimal safety and/or effectiveness.

The first period, PH1, starts at G1, after the T-wave, and ends after the R-wave; it has duration of about <NUM>. It corresponds to the period when the aortic valve is closed.

The second period, PH2, starts at G2 (i.e. on the R-wave) and ends at the T-wave; it has duration of about <NUM>. It corresponds to a refractory period of the heart, where the risk of inducing extrasystoles is minimal, and therefore safety is maximal.

Claim 1:
An apparatus for treating or preventing valvular stenosis, the apparatus comprises:
- a ultrasound probe (<NUM>,<NUM>) located externally to a heart (H) of patient (P), able to produce ultrasound waves focused inside said heart and suitable to generate, at a focal spot, a pressure sufficient to result in cavitation,
- an imaging device (<NUM>) for mapping in real time a treatment region (A, C) of a cardiac valve of the patient, said treatment region comprising at least one leaflet of the cardiac valve,
- a controller (<NUM>, <NUM>, <NUM>) configured for driving the ultrasound probe to emit a sequence of focused ultrasound waves,
the controller being further configured for estimating in real-time a motion of the treatment region from images acquired by said imaging device, and for steering the focused ultrasound waves emitted by the ultrasound probe in function of said motion of the treatment region to scan the entire treatment region;
characterized in that the apparatus further comprises a measuring device suitable for measuring an index of valvular stenosis after the ultrasound probe is controlled to emit the sequence of N focused ultrasound waves, the controller being further configured for reiterating the steps of controlling the ultrasound probe to emit a sequence of focused ultrasound waves and measuring said index of valvular stenosis until said index crosses a predefined threshold.