The present invention relates to an implantable medical device. The implantable medical device of the invention has the particular feature of being very shock-resistant.
In the field of active implantable medical devices (known as AIMDs), in particular intracranial implants such as brain-machine interfaces, cochlear implants and neurostimulators, it is necessary to satisfy certain constraints:
The patent application WO2006/081361A2 relates to cochlear implants. It describes a device that has a hermetic container in which the electronics of the device are placed, a cover being affixed to the hermetic container and defining a non-hermetic internal space with said container. The patent application specifies that a material including silicone can be injected into this internal space in order notably to reinforce the shock resistance of the device.
However, the architecture proposed in that document is not satisfactory since it is unable to satisfy all of the constraints set out above. Specifically, it does not allow good heat dissipation since the electronics are isolated in the hermetic container, no solution being provided for dissipating the heat generated during operation. Moreover, it is unable to respond to the different types of shock that may arise and that may cause elastic deformations or plastic deformations of the device.
Therefore, the aim of the invention is to propose an implantable medical device that is capable of remedying the drawbacks of the prior art and can satisfy the various operating constraints listed above.
This aim is achieved by an implantable medical device comprising:
said module for heat dissipation and shock absorption having:
According to one particular embodiment, the structure of the third layer is realized in the form of a plurality of concentric cavities.
According to another particular embodiment, the structure of the third layer has a plurality of parallel rectilinear cavities that form trenches and a comb structure having a plurality of teeth of given height and width.
According to another particular embodiment, the structure of the third layer has a spiral.
According to one particular feature of the device, each cavity of the structure is a through-cavity.
According to another particular feature, the second layer is formed of a metal of high thermal conductivity such as copper, gold or aluminium.
According to another particular feature, the thermal paste of the first layer and of the third layer has a thermal conductivity of between 1 and 12 W/m/K.
According to another particular feature, the first layer and the third layer include filled silicone.
According to another particular feature, the module for heat dissipation and shock absorption includes one or more additional layers made of pyrolytic graphite that are deposited under the second layer and between the third layer and the internal wall of the housing.
The invention also relates to a method for manufacturing an implantable medical device as defined above, wherein the structure of the third layer is produced by applying punches to a layer of thermal paste deposited on a substrate, by compression moulding or by injection moulding in a chemically soluble or thermally liquefiable mould.
Further features and advantages will become apparent from the following detailed description given with reference to the appended drawings, in which:
In the rest of the description and in the drawings, the terms “top”, “bottom”, “upper”, “lower”, “above”, “below” or equivalent terms should be understood considering a main axis (X) drawn vertically.
The solution of the invention applies mainly to active implantable medical devices (AIMDs), in particular those of high energy consumption. Implantable stimulators of the “pacemaker” type have been the subject of numerous improvements and consume very little electrical energy (a few μW) and therefore dissipate very little heat. By contrast, recording systems of the BCI (“Brain Computer Interface”) type consume up to 350 mW (see the publication “Mestais, C. S., Charvet, G., Sauter-Starace, F., Foerster, M., Ratel, D., & Benabid, A. L. (2015), WIMAGINE: wireless 64-channel ECoG recording implant for long term clinical applications. IEEE transactions on neural systems and rehabilitation engineering, 23(1), 10-21”). For these devices, the problem of efficient and uniform extraction of energy therefore becomes critical.
With reference to
For operation, the device has an electronic board 2. The electronic board 2 has two faces, each of its faces being able to support one or more electronic components 20.
The device may have a frame 3 housed in the bottom of one of the two parts of the housing 1, to which the electronic board 2 is fastened. In
In the internal space of the housing, the implantable medical device also has a module 4 for heat dissipation and shock absorption.
This module 4 has an assembly of a plurality of superposed layers 40, 41, 42. The assembly of superposed layers has a lower face deposited on the upper face of the electronic board 2, on the opposite side of the latter from its lower face for fastening to the frame 3, and an upper face against which the internal wall 10 of the upper part of the housing 1 comes into contact, making it possible to wedge the device for heat dissipation and shock absorption in the housing and to serve as a shock absorber when the housing is subjected to shocks on its upper face.
The module for heat dissipation and shock absorption has:
The first layer 40 and the third layer 42 can be made from one and the same thermal paste. For the third layer 42, this material is chosen to ensure excellent thermal conductivity and to have a sufficiently deformable composition for absorbing shocks.
In a non-limiting manner, the material chosen to produce the thermal paste may be filled silicone. It may thus contain zinc oxide, in addition to the silicone that is used as binding agent allowing the thermal conductivity to pass from 0.2 W/m/K to values of between 3 and 5 W/m/K. If the electrical insulation of the components is provided by a varnish of the acrylic type or an epoxy layer, other thermal pastes can also be cited with thermal conductivities ranging up to 12 W/m/K. The material “Prolimatech PK1” (registered trade mark) is composed of 60 to 85% aluminium, 15-25% zinc oxide, 12-20% silicone oil and finally an antioxidant. Some thermally conductive pastes, such as “Arctic Silver 5” (registered trade mark) additionally contain particles of silver. Others make use of graphite, such as the paste referenced “WLPG 10” (registered trade mark) from Fischer Elektronik, the latter not using silicone and exhibiting excellent thermal conductivity (10.5 W/m/K). Finally, it is also known to add carbon nanoparticles.
According to one particular feature, the thermal paste employed has a thermal conductivity of between 1 and 12 W/m/k.
The second layer 41 employed is advantageously a metal layer in order to incorporate a material of high thermal conductivity into the module 4 for heat dissipation and shock absorption. It may be a plate of copper, gold or aluminium. The second layer may have a thickness of between 0.1 and 0.6 mm. Since this second layer proves to be relatively rigid, the third layer, which is made of a more flexible and deformable material, is necessary to ensure a shock-absorbing function and to provide an implantable device that has a level of deformability greater than a device having only one metal layer disposed between the board and the cover.
Optionally, in order to improve heat transfer, the module 4 for heat dissipation and shock absorption may have one or more additional layers made of pyrolytic graphite, deposited under the layer of copper and optionally between the third layer 42 and the internal wall 10 of the cover of the housing. Pyrolytic graphite layers 43 and 44 are shown in
According to one particular aspect of the invention, the third layer 42, which is made of thermal paste, is said to be structured. The term “structured” means that it has a plurality of cavities in order to improve its deformability and thus to better protect the electronic assembly from shocks. The structure is thus produced so as to alternate full parts and recessed parts.
The cavities may or may not be through-cavities (that is to say made all the way through the thickness of the layer). The structure of the third layer 42 may have a mixture of several cavities, some of them being through-cavities and others not being through-cavities.
In
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Several methods may be envisaged to produce the structure in the third layer.
E1: A layer 50 of thermally conductive paste to be structured is deposited uniformly on a substrate 51. The thickness of the layer 50 may be rendered uniform by means of a doctor blade or a plate abutting a shim.
E2: The structure is produced by employing a tool 52 provided advantageously with a plurality of punches. The punches advantageously have a shape adapted to the final structure to be produced, for example in the form of a comb, ring, rectangle, etc. The tool is applied through the layer of material such that the punches pass through said layer.
E3: The withdrawal of the tool 52 makes it possible to remove the material and to obtain the desired structure.
E4: The structured layer 50 obtained can then be attached to the second layer 41 of the module for heat dissipation and shock absorption, in order to become the third layer 42 thereof.
E10: A negative structure that is chemically soluble or preferably liquefiable at temperature is used. This negative structure may be a heat-sensitive mould 60 made of wax or paraffin (solid/liquid transition temperature close to 45° C.), which comprises a base and structures in relief.
E20: Once the mould 60 has been applied to the second layer 41, a given quantity of thermal paste 61 is injected.
E30 and E40: The assembly is heated until the mould 60 employed has partially or completely dissolved. All that then remains is the desired structured layer 42, once the mould has disappeared.
E100: A layer 70 of thermal paste is deposited directly, with a uniform thickness, on the second layer 41 of the module 4.
E200: A mould 70 is applied to the layer 70 by compression until it passes through the latter. The mould 70 has a shape adapted to the structure to be obtained.
E300: The excess material released by the compression is removed.
E400: The mould 70 is withdrawn so as to obtain the third layer 42 with the chosen structure.
When the housing 1 is subjected to a mechanical load, it firstly deforms in the elastic domain (reversible deformation) and then in the plastic domain (irreversible deformation). The challenge of the invention is thus to absorb some of the deformation energy in order to avoid damaging the electronics in the housing and compromising the hermeticity of the device.
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Each tooth of the comb of the structure of the third layer, having a height h and a width e, is subjected to a dynamic compressive load. In a steady state, the deformation of the tooth is uniform and symmetric with respect to the neutral axis. If the elongation (h/e) is very high (>10), buckling may occur at the tooth, and the latter thus deforms mainly on one side. During the post-collapse phase, a great deal of energy is dissipated by plastic deformation.
This critical load for buckling F depends on the Young's modulus of the material, on the conditions of fastening of the ends that define the buckling length (Ik=h for a beam ball-jointed at its two ends) and on the axial moment of inertia I of the beam (and thus on the coefficient e and the depth p of the comb), according to the relationship:
If this relationship is applied to a single tooth, for a Young's modulus of 1 MPa, a height of 3 mm, a comb width of 0.3 mm and a depth of 10 mm, it is found that Fcritical=0.025 N.
This force is greater than a factor n, where n is the number of teeth, which is also dependent on the resolution of the production method.
In order to quantify the energy absorption of the structured thermal paste and the influence of the shape factors h, p and e, simulations were carried out.
A first type of simulation was established to compare the behaviour of the non-structured thermal paste with that of the structured thermal paste.
The non-structured thermal paste was considered to be a hexahedron with the dimensions: depth 10×width 4.8×height 3 mm3.
For a comb-like structured thermal paste, the teeth have a thickness e=h/10=0.3 mm (h=3 mm and p=10 mm). This comb is made up of 8 identical teeth.
These two structures were subjected to an impact energy of 75 mJ (block of mass 6 g impacting the thermal paste at a speed of 5 m/s).
The results show that the structured thermal paste absorbs 50% of the impact energy, whereas the non-structured thermal paste only absorbs 27% thereof.
The results thus indicate that structuring of the thermal paste in the third layer 42 can indeed give it improved energy absorption properties.
It will be understood from the above that the device according to the invention has numerous advantages, including the following:
Number | Date | Country | Kind |
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18 72524 | Dec 2018 | FR | national |
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Entry |
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French Preliminary Search Report dated Nov. 4, 2019 in French Application 18 72524 filed on Dec. 7, 2018 (with English Translation of Categories of Cited Documents & Written Opinion), 9 pages. |
Number | Date | Country | |
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20200187375 A1 | Jun 2020 | US |