APPARATUS AND METHOD FOR PRODUCING A BIOCOMPATIBLE
THREE-DIMENSIONAL OBJECT
DESCRIPTION Field of the invention
The present invention relates to an apparatus for making a biocompatible three-dimensional object with complex shape, i.e. made of two or more surfaces presenting different radius of curvature.
In particular, the present invention relates to the production of tissues as well as biocompatible and blood- compatible membranes for making vascular prostheses, concave or convex heart patches, ellipsoidal cardiac chambers, patches for calcaneal ulcers, or other components of anatomical parts.
The present invention relates also to a method for making such three-dimensional objects.
Description of the prior art.
As well known, many techniques and apparatus exist for making tissues and biocompatible artificial membranes.
In particular, the main known techniques provide the production of the above described artificial tissues by extrusion, or by spraying fluid substances.
More in detail, the spraying techniques provide the deposit of a polymeric solution of synthetic origin by overlapping the polymeric solution in diluted form and a non-solvent, for example water, to each other. To this
purpose a sprayer is used which sprays both substances in an alternated way, or, alternatively, two sprayers are used that deliver the two substances at the same time. The substances are deposited on a support body which has the same geometry of the desired tissue products or artificial membranes .
An example of an apparatus for making such membranes by spraying is disclosed in WO200405477.
The apparatus uses a plurality of sprayers, each of them drawing from a respective reserve a component of the biological mixture. A cylindrical support element is then arranged on which the fluid substances supplied by the sprayers are deposited, in order to make a coating that forms the desired membranes.
The cylindrical support element can kinematically rotate about a fixed rotation axis, whereas the sprayers are moved by a carriage that makes a translational movement along an axis that is substantially parallel to the rotation axis of the cylindrical support element. This way, the fluid substances supplied can deposit on the whole surface of the support element.
However, this solution, as it can be understood, is applicable only in case the membranes to make have a relatively simple and regular shape with surfaces presenting a wide radius of curvature and not too suddenly variable. Such membranes should also have substantially axisymmetric shape, in order to keep a constant spraying
flow during the rotation of the support element.
A similar apparatus is disclosed in WO2010136983. Even in this case, the apparatus is used for making a biocompatible structure that allows regenerating biological tissues with simple shape.
Notwithstanding the above, the apparatus as above described for making tissues or biocompatible artificial membranes cannot provide anatomical .prostheses with complex shape, such as concave or convex heart patches, ellipsoidal cardiac chambers, patches for calcaneal ulcers, or portions of organs.
In US5376117 is described a breast prosthesis for subcutaneous implants. The prosthesis consists of an outer shell comprising a non-porous layer of biocompatible polymeric material and a porous outer layer that coat wraps the non-porous layer. The outer layer is made by electrostatic deposit of biocompatible polymeric fibres on the inner layer. Once obtained the three-dimensional structure, the prosthesis is overturned and arranged on a spindle that is rotated about its own axis, in order to make the convex side of the prosthesis.
A breast prosthesis obtained by a process similar to that described in US5376117 is disclosed also in WO2010/059834.
However, both processes, as described in US5376117 and
WO2010/059834, are not suitable for the production of tissues and biocompatible artificial membranes with
complex shape and with small tolerances, since they cannot ensure an accurate definition of the modelled forms.
Summary of the invention
It is then a feature of the present invention to provide an apparatus that allows the production of a biocompatible three-dimensional object with complex shape, i.e. not necessarily equipped with significant symmetries and, in particular with surfaces having different radius of curvature.
It is also a feature of the present invention to provide an apparatus that allows the production of such three-dimensional object with high dimensional precision, in order to copy accurately a pre-designed model.
It is a further feature of the present invention to provide an apparatus that allows programming the whole production work so that it can be carried out in an automatic way.
These and other objects are achieved by an apparatus for making a biocompatible three-dimensional object, said apparatus comprising at least one delivery unit arranged to deliver at least one biocompatible fluid substance towards a support body, also called core, that has a matrix surface, to obtain a coating layer of a predetermined thickness configured for coating the matrix surface, said biocompatible fluid substance comprising a plurality of particles,
whose main feature is that also a handling unit is
provided for determining a relative movement according to at least 3 degrees of freedom between the support body and the or each delivery unit, so that the support body is coated with said delivered biocompatible fluid substance, obtaining a three-dimensional object having an object surface copying the matrix surface of the support body, and in that a suction and/or blowing unit is also provided configured to provide a suction and/or blowing current arranged to remove from the support body any surplus particles of the biocompatible fluid substance supplied by the or each delivery unit. This way, it is possible to deposit a uniform predetermined thickness of coating layer on the matrix surface. The solution provided by the present invention, and in particular the possibility of actuating relatively the support body and the or each delivery unit according to at least 3 degrees of freedom during the coating steps of the matrix surface, makes it possible to control with high precision the deposit of the biocompatible fluid substance on the matrix surface and to adjust, in a correspondingly precise way and as it is needed, the thickness of the layers of deposited fluid substance.
This is possible since the handling unit is capable to expose the matrix surfaces of the support body to a jet of biocompatible fluid substance supplied by the delivery unit, positioning this matrix surface substantially orthogonally to said jet.
After the deposit of the fluid substances, the coating is removed from the support body giving rise to the sought three-dimensional object.
In particular, the handling unit is arranged to provide a relative movement according to 4 degrees of freedom, advantageously, according to 5 degrees of freedom, preferably according to 6 degrees of freedom.
Advantageously, the handling unit comprises an anthropomorphic robot having a chain of pivot joints that has an end connected to a fixed base and the other end connected to a support base to which the support body, and/or the or each delivery unit, can be mounted in a removable way. Such chain of. pivot joints is adapted to actuate the support body, and/or the or each delivery unit, according to at least 6 degrees of freedom, supplying higher design precision in generating the sought three-dimensional object.
Alternatively, the handling unit comprises a plurality of actuators, each of which has one end engaged with a fixed base and another end engaged with a support base to which the support body, and/or the or each delivery unit, can be mounted in a removable way.
In particular, the actuators are selected from the group consisting of:
- pneumatic actuators;
hydraulic actuators;
electric actuators;
or a combination thereof.
In particular, the suction device can be a fixed suction device.
Alternatively, the suction device can be a movable suction device associated with auxiliary moving means arranged to move the suction device, in order to follow spatially the position of the support body during its handling by the handling unit.
This way, any surplus particles of the biocompatible fluid substance can be removed regardless of the position of the support body.
In a further exemplary embodiment, the suction device comprises :
a suction hood integral to the support base and configured to surround laterally the support body, in order to maximise the suction of any surplus particles of the biocompatible fluid substance;
a suction tube which is arranged to connect pneumatically the suction hood with a suction system. This way, it is not necessary the implementation of the auxiliary moving means, since the hood is in a optimal position for suction of any surplus particles of the biocompatible fluid substance, whichever is the position of the support body.
In particular, the hood can have a shape selected from the group consisting of:
toroidal;
cylindrical;
tubular.
In particular, the suction system . can comprise a storage reservoir of any surplus particles or a filter on which such particles can deposit. Furthermore, the suction or blowing current can be generated by a fan or a compressor located upstream of the suction tube.
Advantageously, the apparatus provides:
a first delivery unit arranged to deliver a first jet of a first biocompatible fluid substance towards the support body, said first biocompatible fluid substance being a biomaterial of synthetic' origin;
a second delivery unit arranged to deliver a second jet of a second biocompatible fluid substance towards said support body, said second biocompatible fluid substance being a non-solvent, in particular water. Advantageously, the second delivery unit is arranged to direct the second .delivery jet towards the support body, in order to overlap the second delivery jet to the first delivery jet, in particular inducing a quick deposit of the synthetic biomaterial supplied onto the support body by the first delivery unit, obtaining a filamentous three-dimensional structure.
In particular, the apparatus also comprises a counter- mould that is adapted, once ended the delivery of the biocompatible fluid substances, to press, in particular to heat, the coating layer that is deposited on the support
body, in order to obtain a better finishing of the shape of the three-dimensional object, in addition to improved mechanical features.
Advantageously, the apparatus also comprises a third delivery unit arranged to deliver a third biocompatible fluid substance, in particular diluted in solution, both of synthetic and biological origin.
In particular, in case of two or three delivery units, with respective delivery of jets of biocompatible fluid substances, there a program means configured for combining the alternation of such delivery is also provided. This way, the step of coating can be completely automated, and does not require, in normal conditions, a manual monitoring .
Advantageously, a control means is also provided for monitoring the thickness of the formed coating layer, in order to test that the coating layer has thickness corresponding to that of the designed coating layer.
In particular, the designed coating layer can be provided to apparatus by a control CAD.
According to another aspect of the invention, a method for making a biocompatible three-dimensional object comprises the step of delivery of at least one biocompatible fluid substance towards a support body, also called core, which has a matrix surface, obtaining a coating layer of predetermined thickness configured for coating the matrix surface, said delivery occurring using
at least one delivery unit,
wherein a step is provided of handling the support body and/or of the or each delivery unit, in order to provide a relative movement according to at least 3 degrees of freedom between the support body and the or each delivery unit, so that the support body is coated with said delivered biocompatible fluid substance, obtaining a three-dimensional object having an object surface copying the matrix surface, this handling occurring by a handling unit,
and wherein a step of removing from the support body any surplus particles of the or each biocompatible fluid substance dispensed is further provided, said removing being carried out through a suction or a blowing step, in order to make uniform said predetermined thickness of the coating layer, said step of removing occurring using a suction and/or blowing unit.
Advantageously, a step is also provided of pressing, in particular hot pressing, the coating layer that is deposited on the support body. Such step of pressing is carried out only at the end of the step of delivery of the fluid substance.
Brief description of the drawings
The invention will be now shown with the following description of some exemplary embodiments thereof, exemplifying but not limitative, with reference to the attached drawings in which:
Fig. 1 shows an exemplary embodiment of the apparatus, according to the invention, comprising an anthropomorphic robot arranged to handle the support body;
Fig. 2 shows an exemplary embodiment of the apparatus, according to the invention, which differs from that of Fig. 1 for the presence of a toroidal hood arranged to surround the support body;
Fig. 3 shows an exemplary embodiment of the apparatus, according to the invention, which differs from that of Fig. 2 since the handling unit the support body does not comprise an anthropomorphic robot, but a plurality of linear actuators;
Fig. 4 shows the counter-mould that allows a hot moulding of the coating layer;
Fig. 5 shows the three-dimensional object resulting from the production process;
Fig. 6A shows a cardiac chamber with a heart patch applied to it;
Fig. 6B shows a support from which the heart patch of Fig. 6A is generated.
Detailed description of some exemplary embodiments
With reference to Fig. 1, an exemplary embodiment of the apparatus 100 for making a biocompatible three- dimensional object 30, according to the invention, provides an anthropomorphic robot 132 having a kinematical chain of pivot joints 133.
Such chain of joints 133 is constrained at an end to a fixed base 134, and at another end to a support base 131 on which support body 20 engages in a removable way. The chain of pivot joints 133 of Fig. 1 allows handling the support body according to six degrees of freedom, allowing an optimum precision when generating the sought three- dimensional object 30.
In the figure, furthermore, three delivery units 110,111,112 are shown that are arranged to deliver three different biocompatible fluid substances. In particular, first delivery unit 110 is adapted to deliver a jet of a biomaterial of synthetic origin towards the support body 20. The second delivery unit 111 is, instead, arranged to deliver a jet of non-solvent, for example water, overlapping to the jet generated by first delivery unit 110, in order to induce a quick deposit of the biopolymeric material supplied onto support body 20 by first delivery unit 110, allowing to obtain a filamentous three-dimensional structure. The third delivery unit, finally, is adapted to deliver a third biocompatible fluid substance diluted in solution, in particular another biomaterial of synthetic or biological origin.
Each delivery unit 110,111,112 also has a hydraulic circuit (not shown in the figure, advantageously a cylinder-piston mechanism) consisting of ducts, with possible valves and pumps, which connect the or each delivery unit to reservoirs containing the biocompatible
fluid substances.
In this exemplary embodiment, a suction and/or blowing unit 120 is further provided, adapted to generate a suction and/or blowing current. This way, the suction and/or blowing unit 120 makes it possible to level the thickness of the coating layer 35 and to remove from support body 20 any surplus particles of the biocompatible fluid substances supplied by the or each delivery unit 110, 111, 112.
The device 120 is also spatially moved by auxiliary moving means 140, in such a way that this device 120 can follow spatially the position of support body 20 during its handling steps by handling unit 130.
In Fig. 2 a second exemplary embodiment is shown, which differs from an exemplary embodiment of Fig. 1 as from the type of the device 120.
In this exemplary embodiment, in fact, device 120 comprises a toroidal suction hood 121, which is integral to support base 131 and is configured to surround laterally support body 20. Toroidal hood 121 is then joined to a suction tube 122 arranged in turn to connect pneumatically the suction hood 121 with a suction system 123 that has a compressor to generate a suction flow and with a storage reservoir containing any surplus particles of the dispensed fluid substance.
Alternatively, in an exemplary embodiment not shown in the figures, device 120 is advantageously a blowing
device comprising a compressor adapted to generate a blowing current for removing any surplus particles of the delivered fluid substance.
This way, it is not necessary that the apparatus comprises also auxiliary handling unit 140, like the exemplary embodiment of Fig. 1, since the toroidal hood 121 surrounds laterally the support body 20, whichever is the position reached by handling unit 130.
In Fig. 3 an exemplary embodiment is shown where handling unit 130, instead of comprising the anthropomorphic robot 132 of the previous figures, comprises a plurality of linear actuators 133, each of which engages, at one end, to fixed base 134, and at another end, to support base 131. Support body 20 engages in a removable way with support base 131, like the previous exemplary embodiments.
The handling unit can reach the same degrees of freedom of an anthropomorphic robot, even if with narrower handling range.
The advantage offered by this solution is shown by a high reduction of the encumbrance.
In Fig. 4 the step is shown of pressing, in particular to hot pressing, of the coating layer 35 deposited by the or each delivery unit 110,111,112, using a counter-mould 150. The coating layer 35 is then removed from support body 20 and becomes substantially the final biocompatible three-dimensional object 30, visible in Fig. 5.
Owing to the hot pressing an optimum finishing of the shape of the three-dimensional object 30 can be achieved, in such a way that such shape is closest to the designed patch shape, for example provided by CAD or the like.
Such pressing operation also gives to the three- dimensional object 30 mechanical improved features, reaching any design standards.
The apparatus 100, as described above, and shown in Figs. 1 to 5, provides biocompatible three-dimensional objects 30 of whichever shape.
In particular, biocompatible three-dimensional objects 30 can be manufactured both of simple and regular shape, such as a tetrahedron or a cone, and of irregular shape and/or with surfaces which cannot worked out in a simple way, such as a concave or convex patch or an ellipsoidal patch .
Furthermore, biocompatible three-dimensional objects 30 can be provided having surfaces with different radius of curvature and/or with different angles .
In Fig. 6A a cardiac chamber of a human heart is shown to which a biocompatible three-dimensional object 30 is mounted, in particular a heart patch, consisting of an inner portion 30a and an external portion 30b.
In Fig. 6B part of the apparatus 100 comprising the support 20 is shown, from which the inner portion 30a of the heart patch of Fig. 6A is generated.
The foregoing description of specific exemplary
embodiments will so fully reveal the invention according to the conceptual point of view, so that others, by applying current knowledge, will be able to modify and/or adapt in various applications the specific exemplary embodiments without further research and without parting from the invention, and, accordingly, it is meant that such adaptations and modifications will have to be considered as equivalent to the specific embodiments. The means and the materials to realise the different functions described herein could have a different nature without, for this reason, departing from the field of the invention, it is to be understood that the phraseology or terminology that is employed herein is for the purpose of description and not of limitation.
The above described application relates to the MBP project "Fibrin-based nanostructured materials and platelet factors for stimulating angiogenesis" ("Materiali nanostrutturati a base di fibrina e fattori piastrinici in grado di promuovere 1' angiogenesi") admitted to R.T. financing, R&D Single Announcement, year 2008, 1.5 - 1.6 line B - Executive Decree 6744 of 31/12/2008.