Patent Description:
The surgical kit object of the invention and the relative design method may be advantageously used in juxtaosseous surgery, in order to mount a subperiosteal (or juxtaosseous) implant on the mandibular or maxillary bone of a patient, and it may be advantageously used both during bone preparation, and during implant installation operations.

Therefore, the kit in question fits into the industrial sector of the production of surgical devices, in particular for juxtaosseous surgery.

Subperiosteal implants, also known as juxtaosseous implants, are dental implants used to restore teeth in patients with severe bone atrophy.

In fact, these implants allow the stumps necessary to support a dental prosthesis to be placed at the alveolar crest without the need to drill the crest itself, but fixing the implant on portions of the bone spaced from the crest and enveloping the latter.

Such implants comprise a grid, usually made of titanium, which rests on the patient's maxillary or mandibular bone, enveloping the alveolar crest, and is fixed to the bone by means of osteosynthesis screws. For this purpose, these grids are provided with several through fixing holes, usually placed close to a perimeter edge of the grid, which are engageable by the aforementioned osteosynthesis screws to fix the grid to the bone.

Furthermore, such grids of the known type comprise several stumps, which may be made in a single body or be assembled subsequently, and which are intended to support a dental prosthesis for restoring a patient's teeth.

As is known, the installation of the aforesaid implants requires drilling the bone using a surgical drill for fixing the implants themselves. This drilling operation requires a high degree of dexterity and precision by the surgeon, as it requires perfectly aligning all the fixing holes necessary to fix the juxtaosseous implant.

For this purpose, patent <CIT> discloses a kit for assembling a subperiosteal (juxtaosseous) implant which comprises a subperiosteal implant, intended to be placed in abutment on the patient's bone and provided with several fixing holes, to fix the bone implant using known osteosynthesis screws.

Such kit also comprises a plurality of guide bushings, which are fixed by screwing directly to the subperiosteal implant, each at a separate fixing hole, and are intended to be engaged by a surgical drill to guide the drill towards the patient's bone in order to drill the latter by making the holes at the fixing holes of the implant in order to be able to proceed subsequently with the fixing of the implant.

The kit for assembling a subperiosteal implant of the type described above has proved to be not free from drawbacks in practice.

A first drawback is given by the fact that this kit has proved to be extremely complicated to make from the production point of view. In fact, this kit envisages fixing the bushings by screwing directly onto the subperiosteal implant, and therefore needs a plurality of threaded fixing holes to be made on the implant, to allow the screwing of the guide bushings. From a practical point of view, the creation of threaded fixing holes implies a complicated milling process to be carried out on a subperiosteal implant.

A further drawback is given by the fact that this kit is more uncomfortable and invasive for the final patient. In fact, the arrangement of the threaded fixing holes determines the need to considerably increase the thickness of the subperiosteal implant, at least at the fixing holes themselves, in order to allow a secure and resistant fixing of the bushings on the implant. This determines a greater encumbrance of the subperiosteal implant, which is therefore more invasive once installed on the patient's bone.

If, on the other hand, the subperiosteal implant does not have an increased thickness at the aforementioned fixing holes, there will instead be a concrete risk of poor mechanical strength of the fixing between the bushings and the implant, resulting in a danger during the bone milling step in the event that the bushes become detached.

A further drawback is due to the fact that the kit of the known type described above requires high precision and tolerance in the production step, in order to obtain a precise engagement threading in the fixing holes of the implant.

A further drawback is due to the fact that this kit of the known type described above determines a high number of operations necessary for the assembly of the final system, and is onerous in terms of time to carry out the assembly of the system. In fact, this kit provides that the bushings are first fixed to the implant, to then proceed with the assembly of the implant with the bushings mounted, with which the surgeon carries out the milling operations. However, it is also necessary for the implant to be separated from the bone to allow easy disassembly of the bushings, and subsequently placed back on the bone to allow the actual fixing of the implant by means of the normal osteosynthesis screws.

A further drawback is due to the fact that this kit does not allow further preparation operations of the bone site to be carried out prior to the installation of the subperiosteal implant.

In this situation, the problem underlying the present invention is that of eliminating the drawbacks of the prior art cited above, providing a subperiosteal surgical kit which allows a subperiosteal implant to be mounted in a precise and reproducible manner.

A further object of the present invention is to provide a subperiosteal surgical kit which is comfortable and minimally invasive for the patient.

A further object of the present invention is to provide a subperiosteal surgical kit that is stably fixed to the bone throughout the surgical operation.

A further object of the present invention is to provide a subperiosteal surgical kit which allows the time required for the patient's clinical procedure to be reduced.

A further object of the present invention is to provide a subperiosteal surgical kit which allows distinct preparation operations of the implant site to be carried out.

A further object of the present invention is to provide a subperiosteal surgical kit which allows depending less on the ability of the clinician who has to perform operations for preparing the implant site.

A further object of the present invention is to provide a subperiosteal surgical kit which allows operating safely even in areas where there are sensitive structures such as for example alveolar nerves, palatal arteries, maxillary sinuses, etc..

A further object of the present invention is to provide a subperiosteal surgical kit and a design method which are quick, cost-effective and simple to implement.

A further object of the present invention is to provide a subperiosteal surgical kit and a design method which are easily conformable to the maxillary or mandibular bone of the different patients to be operated on.

The technical features of the invention, according to the aforesaid aims, can clearly be seen in the content of the claims below, and its advantages will become more readily apparent in the detailed description that follows, made with reference to the accompanying drawings, which illustrate a preferred embodiment, which is purely exemplary and not limiting, in which:.

With reference to the accompanying drawings, the subperiosteal surgical kit object of the invention has been indicated as a whole with reference numeral <NUM>.

The subperiosteal surgical kit <NUM> object of the invention is advantageously intended to be used in maxillofacial surgery, in particular in juxtaosseous or subperiosteal surgery, in order to install a subperiosteal implant on a patient's maxillary or mandibular bone.

Advantageously, the kit <NUM> object of the invention may also be used to prepare an implant site by means of several milling operations and in order to install the subsequent subperiosteal implant, as better illustrated below.

According to the invention, the subperiosteal surgical kit <NUM> comprises a subperiosteal implant <NUM> fixable to the maxillary or mandibular bone O of a patient (hereinafter referred to generically as bone O for simplicity of explanation).

The subperiosteal implant <NUM> comprises a first frame <NUM>, arranged to rest on an external surface of the patient's maxillary or mandibular bone O and is provided with several through fixing holes <NUM>, each of which is provided with a corresponding first axis and is arranged to receive a corresponding bone screw V, for example an osteosynthesis screw, to fix the subperiosteal implant <NUM> to the patient's maxillary or mandibular bone O.

Advantageously, the subperiosteal implant <NUM> is made of a biocompatible material, for example titanium, and may preferably be made by means of a rapid prototyping process such as for example laser melting, powder technology, milling, etc..

Of course, it is also possible to make this subperiosteal implant <NUM> of a different material, such as for example of a plastic material, preferably also biocompatible, or alternatively of a ceramic material.

The first frame <NUM> is counter-shaped to the bone O of the patient on which it must rest, so as to define an intimate and non-punctual support capable of increasing the stability of the entire subperiosteal implant <NUM> during the surgical operation, as better described hereinafter.

Advantageously, the first frame <NUM> of the subperiosteal implant <NUM> is a frame of the type with arms, preferably made in a single body, and is preferably formed by several support arms, intended to rest on the patient's bone O and connected to each other, as visible in <FIG>.

In particular, the aforesaid support arms define corresponding support portions <NUM> on the maxillary or mandibular bone O.

In more detail, the first frame <NUM> of the subperiosteal implant <NUM> is provided with several first support arms <NUM>', which are intended to be placed on opposite lateral sides of the alveolar crest C of the bone O, and several second support arms <NUM>", which are placed as a connection between the first support arms <NUM>' and are placed at least to partially envelop the alveolar crest C of the patient, straddling the latter.

In this way, it is possible to lighten the structure of the subperiosteal implant <NUM>, which is therefore more comfortable and less invasive for the user.

Advantageously, in a manner known per se, the subperiosteal implant <NUM> is provided with one or more stumps <NUM>, which project overhanging from the first frame <NUM>, and on each of which a dental restoration implant of the patient is intended to be mounted.

Advantageously, the stumps <NUM> are made in one piece with the first frame <NUM>, but alternatively they may be fixed to the latter by screwing, preferably providing a threaded seat on the first frame <NUM> and a counter-threading on the abutment <NUM>.

Preferably, the stumps <NUM> are fixed on the second support arms <NUM>" of the first frame <NUM> of the subperiosteal implant <NUM>, in particular in an apical, substantially median position of the latter.

Preferably, the fixing holes <NUM> of the subperiosteal implant <NUM> are obtained on the first support arms <NUM>', so as to distance the aforementioned fixing holes <NUM> from the stumps <NUM>, improving the ease of installation of the subperiosteal implant <NUM>.

The kit <NUM> also comprises at least one surgical template <NUM>, which comprises a second frame <NUM>, arranged to rest on the external surface of the patient's maxillary or mandibular bone O.

Of course, the subperiosteal implant <NUM> and the surgical template <NUM> may also rest on different portions of bone O of the patient, such as for example the bony walls of the maxillary sinus, the zygomatic bone, etc. without thereby departing from the scope of protection of the present invention.

Advantageously, at least the second frame <NUM> of the surgical template <NUM> is made of a biocompatible material, preferably of a biocompatible polymeric material, or alternatively of titanium.

The second frame <NUM> is counter-shaped to the bone O of the patient on which it must rest, so as to define an intimate and non-punctual support capable of increasing the stability of the entire implant during the surgical operation, as better described hereinafter.

The surgical template <NUM> comprises several guide bushings <NUM>, fixed to the second frame <NUM> and each internally defining a corresponding guide channel <NUM>. In more detail, the expression "guide channel" will hereafter mean a generic through guide channel formed inside the corresponding guide bushing <NUM>, without this channel necessarily being understood as defining a closed internal surface.

The guide channel <NUM> is provided with a corresponding second axis and is arranged to receive, preferably to size, and to guide a surgical drill to make a corresponding mounting hole in the maxillary or mandibular bone O of the patient.

In particular, each guide channel <NUM> is a through channel, which extends along the corresponding guide bushing <NUM>, along an extension direction Z, coinciding with the second axis, between an upper insertion opening and a lower outlet opening, opposite the insertion opening.

In particular, the surgical drill is intended to be inserted into the insertion opening and, passing through the aforesaid guide channel <NUM>, exit from the outlet opening.

The second axes of the guide channels <NUM> of the surgical template <NUM> have the same spatial distribution as the first axes of the corresponding fixing holes <NUM> of the first frame <NUM> of the subperiosteal implant <NUM> to fix the bone screws V of the subperiosteal implant <NUM> on corresponding mounting holes <NUM>.

In other words, each fixing hole <NUM> of the subperiosteal implant <NUM>, when the latter is fixed to the patient's bone O, is intended to be placed in the same position in which a corresponding guide channel <NUM> is placed when the surgical template <NUM> is mounted on the patient's bone O, so as to be able to fix the subperiosteal implant <NUM> exploiting the mounting holes made with the surgical drill guided by the guide bushings <NUM>.

Advantageously, the second frame <NUM> of the surgical template <NUM> is provided with at least two main arms <NUM>, which extend side by side and spaced apart from each other, and are arranged to be positioned on opposite sides of an alveolar crest C of the maxillary bone O.

Preferably, the guide bushings <NUM> are mounted on the main arms <NUM>.

Advantageously, the second frame <NUM> of the surgical template <NUM> is provided with at least one connecting arm <NUM>, and preferably several connecting arms <NUM>, which extend as a connection between the main arms <NUM> and are arranged to be placed on the alveolar crest C, straddling the aforesaid sides.

In particular, the connecting arms <NUM> extend to envelope at least partially the alveolar crest <NUM>.

The particular configuration of the second frame <NUM>, provided with connecting arms <NUM>, allows an extremely solid but at the same time light and easy to install surgical template <NUM> to be created, and furthermore allows a template <NUM> to be obtained which allows a wide visibility of the whole area of implantation and sliding of the tools for the surgeon.

Advantageously, the second frame <NUM> is shaped in such a way that the surgical template <NUM> may be orientated unequivocally on the patient's bone, to allow rapid installation of the surgical template <NUM> itself and to reduce the risk of errors by the surgeon.

Advantageously, the second frame <NUM> rests exclusively on bone tissue and not on soft tissue, so as to avoid yielding or misalignments of the surgical template <NUM> due to possible inflammation of the mucous membrane or anomalous absorption of the anesthetic by the mucous membrane itself.

In particular, the second frame <NUM> comprises a first main arm <NUM>', which is placed at a palatal portion of the patient's bone, on a first side of the alveolar crest C, and a second main arm <NUM>" which is placed at a buccal portion of the patient's bone, on an opposite second side of the alveolar crest C.

Advantageously, the main arms <NUM> extend following a development substantially parallel to the alveolar crest C.

In more detail, the main arms <NUM> extend along a first direction of development X, substantially curvilinear, and the connecting arms <NUM> extend along a second direction of development Y, transversal to the first direction of development X.

Advantageously, the second frame <NUM> is provided with several through openings <NUM> each of which is aligned with the second axis of the guide channel <NUM> of the corresponding guide bushing <NUM>, so as to allow the passage of the surgical drill.

Advantageously, the second frame <NUM> of the surgical template <NUM> is provided with several mounting seats <NUM>, in each of which a corresponding guide bushing <NUM> is mounted.

Advantageously, the guide bushings <NUM> are removably mounted in the mounting seats <NUM>, so that they may be removed and separated from the second frame <NUM> once the installation of the subperiosteal implant <NUM> has been completed.

Of course, it is also possible for production reasons to provide disposable kits in which the second frame <NUM> and the guide bushings <NUM> are thrown away after a single use.

Advantageously, the second frame <NUM> is provided with a rear surface intended to face the outer surface of the maxillary or mandibular bone O, and with an opposite front surface.

Preferably, each housing seat <NUM> extends passing between the rear surface and the front surface of the second frame <NUM>, and in particular extends between a lower opening, formed on the lower surface and intended to face the patient's bone O, and an opposite upper opening obtained on the upper surface of the second frame <NUM>.

Preferably, each through opening <NUM> is defined by a corresponding mounting seat <NUM> and even more preferably the lower opening coincides with a through opening <NUM> of the second frame <NUM>. Advantageously, the surgical template <NUM> is provided with several mounting elements <NUM>, which project from the front surface of the second frame <NUM>, and each of which is internally provided with a corresponding mounting seat <NUM>.

In particular, the centering elements <NUM> are advantageously fixed to the second frame <NUM>, preferably in a single body. Advantageously, the centering elements <NUM> project from the main arms <NUM> of the second frame <NUM>.

Advantageously, each guide bushing <NUM> is mounted in a mounting seat <NUM> of a corresponding centering element <NUM>.

In particular, each guide bushing <NUM> is mounted coaxially in the mounting seat <NUM>, with its own guide channel <NUM> which has a development direction Z preferably coinciding with a development direction of the respective mounting seat <NUM>.

In other words, the mounting seat <NUM> extends along the second axis of the guide channel <NUM>.

As explained above, the guide bushings <NUM> are removably mounted in the mounting seats <NUM>. For example, the guide bushings <NUM> may be inserted inside the mounting seats <NUM>, preferably by interference, so as to allow easy assembly and disassembly but at the same time ensuring that the guide bushings <NUM> are kept in position during the milling operations of the bone O.

For this purpose, the mounting seats <NUM> have an internal diameter of between <NUM> and <NUM>, and preferably the guide bushings <NUM> have an external diameter of between <NUM> and <NUM>.

Advantageously, the centering elements <NUM> and the guide bushings <NUM> may be fixed together, for example by screwing.

For this purpose, the centering elements <NUM> are advantageously provided with a first threading, and the guide bushings <NUM> are provided with a second threading, which may be screwed into the first threading of the centering elements, to screw the guide bushings to the centering elements <NUM>.

Advantageously, each guide bushing <NUM> is provided with an external surface.

Preferably, the first threading is formed inside the mounting seat <NUM>, in particular at one of its internal surfaces, and the second threading is formed on the external surface of the guide bushing <NUM>.

Advantageously, the first threading is obtained in the vicinity of the upper opening and is preferably located only at the aforementioned upper opening.

Advantageously, the kit <NUM> comprises fixing means adapted to allow the second frame <NUM> to be temporarily fixed to the patient's bone O, once the surgeon has made the hole with the drill F, for the subsequent drilling steps.

In particular, the fixing means, for example fixing pins or screws, are placed across the guide bushings <NUM> to engage the lower opening and the mounting hole previously made using the drill F.

Alternatively, in particular in the case in which the guide bushings <NUM> are removably mounted in the mounting seats <NUM>, it is possible to remove the guide bushings <NUM> once the surgeon has made the hole with the drill F, to engage the mounting seats <NUM> by means of the aforesaid fixing means.

Advantageously, the first frame <NUM> of the subperiosteal implant <NUM> comprises several support portions <NUM> which, when the subperiosteal implant <NUM> is fixed to the maxillary or mandibular bone O, are placed in abutment on corresponding support areas of the external surface of the maxillary or mandibular bone O.

Advantageously, the surgical template <NUM> comprises a positioning template <NUM> and an osteoctomy template <NUM>, each of which may be provided with the aforementioned features described above for a generic surgical template <NUM>.

Preferably, both the positioning template <NUM> and the osteoctomy template <NUM> are provided with the aforementioned centering elements <NUM>, and therefore with the respective mounting seats <NUM>, and even more preferably they have an arm structure of the type described above which, of the differences shown below, has at least two main arms <NUM> and at least two connecting arms <NUM>. Advantageously, the positioning template <NUM> comprises guide bushings <NUM> in a number equal to the number of the fixing holes <NUM> of the subperiosteal implant <NUM>.

Advantageously, the positioning template <NUM> is adapted to allow all the mounting holes to be made for the subperiosteal implant <NUM>.

Advantageously, the subperiosteal implant <NUM> comprises at least three fixing holes <NUM> and the positioning template <NUM> therefore comprises at least three guide bushings <NUM>.

According to the preferred embodiment, the subperiosteal implant <NUM> comprises seven fixing holes <NUM> and the positioning template <NUM> comprises seven guide bushings <NUM>.

Advantageously, the second frame <NUM> of the osteoctomy template <NUM> is provided with at least one through grinding window <NUM>, which, when the osteoctomy template <NUM> is fixed to the maxillary or mandibular bone O, is placed at a corresponding support area of the support surface of the maxillary or mandibular bone O, to allow the corresponding support area to be grinded, by means of a grinding tool, before installing the subperiosteal implant <NUM>.

Advantageously, the grinding window is delimited between the main arms <NUM> and the at least one connecting arm <NUM> of the second frame <NUM>. Preferably, the grinding window is delimited by two main arms <NUM> and by two connecting arms <NUM> of the second frame <NUM>.

Advantageously, the grinding window <NUM> is laterally delimited, along the first direction of development X, by the connecting arms <NUM>, and along the second direction of development Y by the main arms <NUM>.

According to the preferred embodiment illustrated in the accompanying figures, the osteoctomy template <NUM> comprises four connecting arms <NUM>, which delimit three separate grinding windows <NUM> between them.

Preferably, the grinding window <NUM> has a substantially polygonal section, and even more preferably it has a main development substantially orthogonal to the first development direction X.

Advantageously, each grinding window <NUM> is intended to allow an easy osteoctomy operation by an operator, and for this purpose it is preferably provided with a dimension of at least <NUM><NUM>.

As explained above, the subperiosteal implant <NUM> is provided with several support arms, which are intended to be rested against the maxillary or mandibular bone of a patient.

In particular, the aforesaid support arms define the support portions <NUM> on the maxillary or mandibular bone O.

Advantageously, therefore, each grinding window <NUM> of the osteoctomy template <NUM> is placed, when the osteoctomy template <NUM> is fixed to the maxillary or mandibular bone O, at at least part of a support arm of the first frame <NUM> of the subperiosteal implant <NUM>.

In this way, it is possible to carry out an osteoctomy operation exactly at the support points of the subperiosteal implant <NUM>, guaranteeing an even more precise and intimate support of the same subperiosteal implant <NUM> on the patient's bone O.

Advantageously, the osteoctomy template <NUM> is adapted to allow an osteoctomy operation to be carried out on the alveolar crest C of a patient. Advantageously, this osteoctomy process is preliminary to the installation of the subperiosteal implant <NUM> and is preferably carried out after the milling process performed using the positioning template <NUM>, to make the mounting holes.

Of course, without thereby departing from the scope of protection of the present invention, the osteoctomy process may also be performed after the aforementioned milling process, as better illustrated below.

Advantageously, the osteoctomy template <NUM> comprises guide bushings <NUM> in a lower number than the number of fixing holes <NUM> of the subperiosteal implant <NUM>, and therefore preferably in a lower number than the number of guide bushings <NUM> of the positioning template <NUM>.

Advantageously, the osteoctomy template <NUM> comprises a maximum of five guide bushings <NUM>, and preferably a maximum of three guide bushings <NUM>.

According to the preferred embodiment, the osteoctomy template <NUM> comprises three guide bushings <NUM>.

Advantageously, when the osteoctomy template <NUM> is positioned on the patient's bone O, the corresponding guide bushings <NUM> are intended to be placed in positions coinciding with at least part of the guide bushings <NUM> of the positioning template <NUM>, when the latter is placed on the patient's bone O.

In this way, irrespective of the mounting order of the two templates <NUM>, <NUM>, it is possible to reuse at least part of the mounting holes obtained by means of the guide bushings <NUM> of one of the two templates <NUM>, <NUM> also for the other template <NUM>, <NUM>.

For example, according to the preferred embodiment in which the osteoctomy process is subsequent to the drilling of the bone O, the guide bushings <NUM> of the osteoctomy template <NUM> are configured to be placed aligned with the mounting holes which have been obtained by the cutter F using the positioning template <NUM>.

Advantageously, in the case in which, as explained above, the templates <NUM>, <NUM> have centering elements <NUM> provided with respective housing seats <NUM> which extend between a lower opening and an opposite upper opening, the lower openings of the centering elements <NUM> of the second frame <NUM> of the osteoctomy template <NUM> are placed in positions coinciding with at least part of the lower openings of the centering elements <NUM> of the second frame <NUM> of the positioning template <NUM>.

Advantageously, at least the bushings <NUM> of the osteoctomy template <NUM> are fixed at the main arms <NUM> of the respective second frame <NUM>.

Preferably, the bushings <NUM> of the positioning template <NUM> are also fixed at the main arms <NUM> of the respective second frame <NUM>.

Advantageously, the subperiosteal implant <NUM> is provided with several stumps <NUM>, which are fixed to the first frame <NUM> at at least one of the support portions <NUM>.

Preferably, each abutment <NUM> is fixed to a support arm of the first frame <NUM>, and the grinding window <NUM> of the osteoctomy template <NUM> is placed, when the osteoctomy template <NUM> is fixed to the maxillary or mandibular bone O, at at least one corresponding abutment <NUM> of the subperiosteal implant <NUM>.

In this way, it is possible to carry out an osteoctomy operation exactly at the stumps <NUM> of the subperiosteal implant <NUM>, guaranteeing an even more secure support of the subperiosteal implant <NUM> at the stumps <NUM>, which define critical points for the sealing of the entire subperiosteal implant.

Furthermore, the object of the present invention is a method for designing the subperiosteal surgical kit <NUM> of the type described above, and of which the same reference numerals will be maintained for simplicity of explanation.

The method provides for an acquisition step, wherein at least one three-dimensional image of a site for a subperiosteal implant <NUM> of a patient is acquired, at a mandibular or maxillary bone O.

Preferably, the acquisition step provides for a scan operation of the patient's skull, for example by means of a computerized tomography or similar computerized scanning technique, so as to acquire a first set of data of the bone portion of the patient to be treated. Following scanning, said dataset is advantageously converted into a 3D data set in a format suitable for being read by a CAD viewer, for example in "stl" format. The 3D dataset is advantageously imported into a computer to allow for the subsequent digital design step.

The method further comprises a first design step, wherein a 3D model of the subperiosteal implant <NUM> is designed on the basis of the three-dimensional image of the patient's site.

The method further comprises an identification step, wherein a spatial distribution of the fixing holes <NUM> of the first frame <NUM> of the subperiosteal implant <NUM> is defined, as a function of at least the three-dimensional image of the site, and preferably also of the 3D model of the subperiosteal implant <NUM>.

Of course, this first design step and such identification step are not necessarily to be carried out in this order but may also be reversed, providing for example to preliminarily identify the fixing holes <NUM> of the first frame <NUM>, for example on the basis of clinical analyzes of the patient's bone atrophy, and then design the rest of the subperiosteal implant <NUM>.

The method further comprises a second design step, wherein a 3D model of at least one surgical template <NUM> is designed with the guide bushings <NUM> placed according to the defined spatial distribution of the fixing holes <NUM>.

Advantageously, the identification step also provides for identifying, by means of the three-dimensional image of the site, support areas on the maxillary or mandibular bone O and, as a function of these identified support areas (and the first 3D model of the subperiosteal implant <NUM>), the spatial distribution of corresponding support portions <NUM> of the first frame <NUM> of the subperiosteal implant <NUM>, configured to be placed at the support areas, is identified.

Advantageously, in the design step a 3D model of the positioning template <NUM> is also designed, with a number of guide bushings <NUM> equal to the number of fixing holes <NUM> of the subperiosteal implant <NUM> and placed according to the spatial distribution of the fixing holes <NUM>.

Advantageously, a 3D model of the osteoctomy template <NUM> is also designed in the design step, with at least one grinding window <NUM> placed according to the spatial distribution of corresponding support portions <NUM> of the first frame <NUM> of the subperiosteal implant <NUM>.

Advantageously, at the end of the design step, the 3D file of the surgical template <NUM> is sent to a rapid prototyping machine, for example SLS (selective laser sintering), 3D printer or alternative rapid prototyping techniques, which produces the surgical template <NUM> based on the digital design obtained from the program.

Advantageously, moreover, at the end of the design step, the 3D file of the subperiosteal implant <NUM> is sent to a rapid prototyping machine, for example SLS (selective laser sintering), 3D printer or alternative rapid prototyping techniques, which produces the subperiosteal implant <NUM> based on the digital design obtained from the program.

In this way, it is possible to obtain subperiosteal surgical kit <NUM> by means of a totally digital process, which therefore allows a highly customizable kit <NUM> to be obtained for the user and highly comfortable both to use for the surgeon and from the point of view of invasiveness for the client, as it allows the interaction between the kit <NUM> and the portions of bone or soft tissue not to be touched or stressed during the surgical step to be minimized.

Claim 1:
Subperiosteal surgical kit (<NUM>), which comprises:
- a subperiosteal implant (<NUM>) fixable to the maxillary or mandibular bone (O) of a patient and comprising a first frame (<NUM>), which is arranged to rest on an external surface of the patient's maxillary or mandibular bone (O) and is provided with several through fixing holes (<NUM>), each fixing hole (<NUM>) is provided with a corresponding first axis and is arranged to receive a corresponding bone screw (V) to fix said subperiosteal implant (<NUM>) to the patient's maxillary or mandibular bone (O);
wherein said first frame (<NUM>) is counter-shaped to said maxillary or mandibular bone (O) of the patient on which said first frame (<NUM>) must rest;
- at least one surgical template (<NUM>), which comprises:
• a second frame (<NUM>), which is arranged to rest on the external surface of the patient's maxillary or mandibular bone (O), and which is counter-shaped to said maxillary or mandibular bone (O) of the patient on which said second frame (<NUM>) must rest; and
• several guide bushings (<NUM>) fixed to said second frame (<NUM>) and each internally defining a corresponding guide channel (<NUM>), which is provided with a corresponding second axis and is arranged to receive and guide a surgical drill to make a corresponding mounting hole in the patient's maxillary or mandibular bone;
wherein each said guide channel (<NUM>) is a through channel, which extends along the corresponding said guide bushing (<NUM>), along an extension direction (Z), coinciding with said second axis, between an upper insertion opening and a lower outlet opening, opposite said insertion opening;
the second axes of the guide channels (<NUM>) of said at least one surgical template (<NUM>) having the same spatial distribution as the first axes of corresponding said fixing holes (<NUM>) of said subperiosteal implant (<NUM>) to fix the bone screws (V) of said subperiosteal implant (<NUM>) on corresponding said mounting holes (<NUM>).