AT523132A2 - SCAN BODY WITH LONG ARM - Google Patents

Abstract

The invention relates to a scan body for supporting the measurement of the interior of the mouth, the scan body having a connecting section (1) for connecting to an element firmly connected to the jaw, such as an implant and a main section extending from the connecting section (1) along a main axis (A) (3) and at least one arm (6, 7) at an angle (11) to the main axis (A). The object of the present invention is therefore to provide a scanbody which can be identified as easily as possible by an algorithm and distinguishable from others and at the same time interferes with the creation of the recordings as little as possible. This is achieved in that at least one arm (6, 7) has at least one orientation marking (9).

Description

The invention relates to a scan body to support the measurement of the interior of the mouth, the scan body having a connecting section for connecting to an element firmly connected to the jaw, such as an implant and a main section extending from the connecting section along a main axis and at least one at an angle to the main axis Has arm.

The angle is generally approximately 90 °, preferably exactly 90 ° therewith

the effect of the arms is optimized.

Furthermore, it relates to a method for measuring the interior of the mouth and creating a 3D model, whereby at least one scan body is connected via a connection section to an element firmly connected to the jaw, such as an implant, and recordings are made with an imaging sensor, and an algorithm at least the recordings for a model

a section of the oral cavity can be processed.

The above-mentioned methods are already known for measuring the interior of the mouth and for creating a 3D model of the same that is as true to nature as possible. As a rule, a camera is used as the imaging sensor, which records images at high frequency while it is moved through the oral cavity. Based on these images, an algorithm is used to calculate a 3D model. So that the algorithm can determine the position and angle of each image, the individual images are related to one another based on matching structures. In dentistry, scanbodies are often firmly attached to dental implants in the otherwise mostly soft, round and low-edged oral cavity, which can be clearly recognized and serve as an orientation aid. These scanbodies have sharp edges or other orientation markings through which they can be easily recognized and identified by the algorithm. In particular, it is as true to nature as possible

Representation of the gums and the tissues adjacent to them are important.

Since there are often only a few dental implants in the oral cavity, the scanbodies used should be recognizable for the sensor over the largest possible area in the oral cavity. On the other hand, they must not be too big,

otherwise they cover too many areas of the inside of the mouth and so the number of necessary exposures increases. At the same time, they are otherwise difficult to bring into the mouth. At the same time, the scanbodies must be recognizable and distinguishable as well as possible so that the recognition and assignment can take place without errors

can.

In JP 6208905 B1, scan bodies are described which have arms so that they can be identified more easily and clearly for the camera. An elongated main body is provided with a connecting section and a main section following it. The main section has a cylindrical part and a head part placed thereon, arms being provided on the head part. It is described that the arms can be 0.1 to 1 times the height of the surface of the head on which it is arranged. These arms thus act as additional reference points for recognizing the scanner body. A disadvantage of these scan bodies is that only a small part in the vicinity of the scan bodies can be clearly identified and assigned by them. In areas further away there are no assignable sharp edges or orientation features that can be used by the algorithm as an orientation aid. Making the scanbodies larger has the disadvantage that areas that are too large are covered by them, making measurement more difficult. That too

Attachment in the oral cavity is therefore more uncomfortable and no longer easy.

In a further developed embodiment, the scanbodies have no arms and are connected to one another via glued-in bridges after their arrangement in the oral cavity. The bridges are slightly milled or drilled in order to make the bridges a little thinner and to design the surface of the bridges differently. This makes it easier to assign the images. However, it is disadvantageous that the bridges have to be glued in later, which lengthens and complicates the process. In addition, these bridges must be made quite large, making them large parts of the oral cavity

cover and thus more recordings have to be made.

The object of the present invention is therefore to provide a scan body which can be recognized and differentiated from others as easily as possible for an algorithm over large areas of the interior of the mouth, and at the same time enables the creation of the

Recordings disturb as little as possible.

According to the invention, this object is achieved in that an arm length of at least one arm is at least 30% of a main length of a main section.

It is also achieved in that at least one arm of a scan body, which is at an angle to the main axis, in the connected state up to the immediate

Proximity to another scanbody is sufficient.

The term implant is used to mean an artificial element that is permanently connected to the oral cavity. As a rule, this is a connecting link incorporated into the jaw, which is arranged in the jawbone. It usually has a thread or other connection system in order to be connected to an artificial tooth or an intermediate link. Such implants are therefore firmly connected to the interior of the mouth and therefore represent ideal anchoring points for scanbodies, since they should be as rigid and immobile as possible during the scanning process. It can also concern tooth roots

Trade abutments attached to stumps.

The connection section means that part of the scanbody which is used for connection to the permanently connected element such as an implant or an element arranged in or on the implant. This is ideally designed so that it can be connected to implants of various common designs. In this case, the connecting section can have a thread, for example, via which the scan body can be screwed on by turning it. In this case, however, a part of the connecting section carrying the thread can also be freely rotatable relative to the rest of the scan body. For this purpose it can be provided, for example, that the connecting section has a screw which is set up to be screwed into a suitable thread. An adjusting channel, for example in the form of a cylindrical recess, can be provided for operating a screw located in the scan body

be.

The main section refers to that part of the scanbody which, when installed, protrudes from the permanently connected element or intermediate element to which it is attached. As a rule, it is mainly used to detect and recognize the scanbody for the algorithm, with part of the

Main section can also be used to gain distance from the gums. This

usually has sharp edges or orientation markings so that the scanbodies can be easily distinguished from one another and the exact position and angle of the recordings can be determined. The main section usually has an elongated shape and, when connected to the permanently connected element such as the implant, protrudes from the gum and thus protrudes into the

Inside the mouth.

Accordingly, the main length results as the length of the main section. This corresponds to the length of the main section of the permanently connected element

protrudes into the interior of the mouth.

The term arm is understood to mean a mostly elongated part of the scanbody which enlarges the effective area of the scanbody by mainly extending in a different direction in the interior of the mouth than the main section.

The extension of the arm is away from the main section under arm length

meant along an arm axis.

Due to the long design of the arm of at least 30%, the arm can extend into areas which are further away from the main section. The main section can thus be made small, thus enabling the images to be recorded as simply as possible, while at the same time making recognizable corners and edges available to the largest possible area in order to facilitate assignment of the images. Even if the implants are further apart, there can still be a very wide area in the oral cavity

can be assigned quickly and easily.

The arms preferably have a cross section which remains essentially the same along this arm length. In this way, a substantially uniform, for example cylindrical arm base body is formed on which the

Orientation markings can be arranged.

In this sense, it is particularly advantageous if the arm length of the arm is at least 50% of the main length. The arm length can even be longer than the main length or a multiple, for example one and a half times, double or three times the main length.

It is also advantageous if the arm has a thickness which essentially makes up less than 50% of the arm length. This can prevent the arm from being too wide and thus obscuring too much of the surroundings.

It is also particularly advantageous if the arm has at least one orientation marking. By arranging the orientation marking on the arm, not only the arms can be better recognized by the algorithm. Even if recordings only cover parts of the scanbody or only the arm, the assignment can be facilitated by the orientation markings. At the same time, the arms can be made very thin because the orientation markings ensure their assignment. This means that fewer parts of the interior of the mouth are covered. In addition, glued bridges are no longer necessary, which speeds up the scanning process. This means that the arm also has a stronger orientation effect and the main section

can be made smaller.

Orientation marking is understood to mean any type of marking that can be detected by the imaging sensor and recognized by the algorithm. These serve as reference points to correctly assign the recordings and to determine their orientation. The orientation markings can be designed in the most varied of ways, it being advantageous if the orientation features differ from one another so that the assignment can be carried out clearly and easily. This can be achieved, for example, by the shape or size of the orientation markings or also by varying the distances between the orientation markings or the exact position of the orientation markings. It is particularly important that the edges of the orientation markings are sharp and easily recognizable, as they are used to

precise orientation are very important.

It is advantageous if at least one orientation marking is designed as a three-dimensional marking. Three-dimensional markings have the advantage that they can be recognized more easily. This means that the orientation marking stands out from the shape of the arm so that it can be perceived by the algorithm. They can be designed as holes, edges or protruding elements, for example.

It can also be provided that at least one orientation marking is designed as a color marking. These markings have the advantage that they do not change the shape of the scanbody and therefore cannot be a hindrance during the scanning process or reduce the stability of the scanbody. Easily distinguishable and detectable markings can be created using different colors, shapes or arrangements. For example, in the manufacturing process, otherwise essentially uniform scan bodies can be printed differently. This makes them easy to distinguish from one another, but at the same time easy to manufacture.

It is particularly advantageous if at least one orientation marking is designed as a shoulder or elevation. These shoulders or elevations can already be provided during the manufacturing process and represent markings that are particularly easy to grasp, but at the same time can be made small. As a result, they do not interfere with handling the scan bodies. The assignment can be facilitated by different heights, widths, the location on the arm or the distances to other orientation markings. A shoulder or elevation is understood to mean an element protruding from the surface, such as a shoulder, which is preferably elongated over a certain

Length pulls.

It can also be provided that at least one orientation marking is designed as a recess or notch. These can also be provided directly before or after the scanbodies are arranged on the implant. A recess or notch is understood to mean a depression in a surface,

which is preferably elongated over a certain length.

It is also advantageous if the arm has at least three orientation markings and the orientation markings are at least partially arranged at irregular distances from one another along an arm axis of the arm. This irregularity can be used to better identify the arm or the scanbody

serve.

So that an expansion of the effective area of the scan body along the gums is possible, it can be provided that arm axes of at least two arms of the scan body are arranged parallel to one another. This can

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the scanbodies are arranged so that the arms are distal and mesial, i.e.

extend along the dental arch.

It is therefore also advantageous if the arm axes of at least two arms of the scanbody, projected onto a transverse plane that is transverse to the main axis, are arranged at an arm angle between 90 ° and 160 °, preferably 135 °, to one another. Such embodiments are particularly advantageous in the case of implants in the area of the canine teeth, since they are located roughly along the dental arch

and lie in the areas that are particularly important for the scanning process.

Furthermore, it can be provided that at least one arm axis of at least one arm of the scan body is at an angle to a transverse plane that is transverse to the main axis. What is meant here is that the angle between the arm and the transverse plane is greater or less than 90 °, in other words, the arm faces

Main axis has an acute or an obtuse angle.

Furthermore, it can be provided that, in the case of at least two arms, the points of intersection of the arm axes coincide with the main axis. This causes the arms to rise at the same height as the scanbody.

It can also be provided that, in the case of at least two arms, the points of intersection of the arm axes with the main axis are spaced apart from one another. This different height of the arms can also serve as a distinguishing feature

and lead to an improved assignment of the images.

It can be provided that the scan body is at least partially plastic

is designed to be deformable.

It can particularly preferably be provided that at least one arm is plastically deformable or that the connection between the arm and the rest of the scan body is plastically deformable.

This allows the scanbody to be adapted to the current requirements, circumstances and position shortly before installation or when it is already installed

become.

It is advantageous if the scan body has a rounded head part at the end opposite the connecting section. The scan body usually has an elongated shape on which the preferably irregularly shaped head part with many edges is arranged. This irregular shape or the edges can improve the detection of the scanbody.

It is particularly advantageous if the connecting section is designed to be connected to an intermediate member. Accordingly, it is also advantageous if at least one scan body is connected to an intermediate member screwed into the implant. The intermediate member can, for example, be a base or abutment screwed into the implant. As a result, the connecting section can be made simple, since it only has to fit onto the intermediate link. Various intermediate members can be provided which fit together with implants of the most varied of designs and which provide the connecting section with a standardized counter-connecting section. The connection between the scan body and the intermediate member can be designed to be movable in order to bring the scan body into an optimal position

can.

Furthermore, a kit can be provided to support the measurement of the interior of the mouth, which includes at least two of the described,

Has scanbodies according to the invention.

It can be provided that at least one scanbody has at least one arm and that the arm is set up to reach into the immediate vicinity of an adjacent scanbody in the installed state. With immediate proximity it is meant that the distance between the arm and the neighboring scanbody corresponds at most to the thickness of this arm. Thereby

an allocation of the recordings as comprehensive as possible can be achieved.

In a preferred embodiment it is provided that at least two scanbodies each have at least one arm and the arms are set up to touch the arm of an adjacent scan body in the installed state. This even better prevents the appearance of essential areas that are bad

are assignable.

In this sense it is also advantageous if the arm of the scanbody at least

touches one arm of the other scanbody.

The scanbodies can be designed in such a way that at least one first scanbody is arranged at least two arms of the scanbody along a transverse plane at an angle between 90 ° and 160 °, preferably 135 °, and at least one second scanbody is arranged at least two arms of the scanbody along a transverse plane are arranged transversely to the main axis parallel to one another. As a result, the interior of the mouth to be measured can be optimally equipped with scan bodies with this kit, regardless of the positions and the number of implants

become.

Such kits can also contain scanbodies that do not have arms

exhibit.

A kit can also be provided in which at least one arm of a third scan body is arranged at a different height along the main axis than an arm of a fourth scan body. Depending on the position of the implants and the surrounding tissue, the optimal scan body can be found

to be selected.

It is particularly advantageous if the scan bodies are arranged in such a way that the arms of at least two scan bodies touch one another in the connected state with the permanently connected element. This can ensure that when the sensor moves through the interior of the mouth, scan bodies are available without gaps for orientation and assignment of the recordings. This means that the essential areas can be optimally and completely measured and as a 3D model

be reconstructed.

The present invention is explained in more detail below with reference to the embodiment variant according to the invention shown in the figures. Show it:

1 shows a side view of an embodiment of a scan body according to the invention;

Fig. 2 is a plan view of the embodiment;

The embodiment shown in Figures 1 and 2 has a

Connecting section 1, which has a screw 13 along a main axis A.

and which is used to connect to an implant. The connecting section is arranged in the interior of a main section 3, which extends from an underside, on which it is on the implant or possibly arranged intermediate member, to an upper end. On the underside it has a conical notch 2, which can be placed on a matching intermediate member (not shown) screwed into an implant after the screw 13 has been removed. This results in versatile applicability. Alternatively, only one thread can be provided so that the scan body can be screwed directly into implants. This underside is at the same time one end of the scanbody. In the following, this end of the scanbody is referred to as the lower end, and in the case of directions such as above or below it is assumed that the lower end is arranged below.

Starting from the underside, that is to say the end of the connecting section 1 opposite the lower end, the main section 3 is arranged, which has a cylindrical main body 8 with a diameter that is approximately 35% larger than that of a cylindrical spacer section 14. The cylindrical spacer section 14 is arranged between the bottom and the main section 3 and is mainly used to build up a distance to the fixed element. The main body 8 and the spacer section 14 also extend along the main axis A. Above the main body 8, a head part 4 is arranged, which has a cylindrical neck and a spherical head. The vertex of the head represents the upper end of the scanbody. The neck is also cylindrical and has essentially the same diameter as the spacer section 14. The main body 8 thus has end edges 5 which are designed to be sufficiently pointed to be well recognized by an algorithm and their position

to be precisely determined in an image.

The main section 3 thus extends along the main axis A with a main length LH which corresponds approximately to five times the diameter D of the main body 8. In the interior of the scan body, a cylindrical recess in the form of a bore is provided from the upper end to the lower end, which recess extends along the main axis A. A screw or a similar securing element can be actuated through the recess and thus the scan body can also be actuated

element firmly connected to the jaw.

On two opposite sides of the main body 8, the latter has an arm 6, 7 each, with a first arm 6 being slightly shorter than the other. The first arm 6 extends along a first arm axis V1 from the main body 8 of the main section 3 with a first arm length L1 of approximately 115% of its diameter D, while a second arm 7 extends along a second arm axis V2 a second arm length L2 of approximately 165% of the diameter Has diameter D of the main body 8. The first arm length L1 thus makes up about 55% and the second arm length L2 about 75% of the main length LH. Both arms 6, 7 have substantially cylindrically shaped arm main bodies. The first arm 6 has a total of three and the second arm 7 has four orientation markings 9 on their arm main bodies, one orientation marking 9 each being arranged on the end of the arm 6, 7 facing away from the main body 8. The orientation markings 9 are designed as shoulder-like elevations and thus as three-dimensional markings which extend normally - the angles 12 are 90 ° - from the surface of the arms 6, 7 and have a small thickness of about 1/7 the length of the first arm 6 . They extend in a ring shape over the entire diameter of the arms 6, 7 and have sharp edges. The distances between the surface markings 9 of the second arm 7 are selected to be different, which contributes to better assignment and identification of the scanbody. If the embodiment shown is used for a measurement, preferably only one scan body of this embodiment is used together with others which have a different number of arms 6, 7 or a different number, design or arrangement of orientation markings 9. This makes it easier for the algorithm to assign the images by clearly identifying the scanbody.

The first and second arm axes V1, V2 are arranged along the main axis A at different heights and extend normal to the main axis A. As can be seen in FIG. 2, the arm axes V1, V2 are arranged radially to the main axis A and thus to the main body 8, and are projected onto a transverse plane to the main axis A at an arm angle 10 of 180 ° on one another and are thus parallel to one another. In other embodiments it can be provided that one or more arm axes V1, V2 are eccentric to the main axis or tangential to the

Main body 8 are arranged.

It can be provided that the arm is designed to be separable from the main section. In other words, it can be provided that the arm is designed to be removable from the main section in a non-destructive manner. This can be done by arm and main section

Have binding portions for connecting to one another.

It can be provided that the binding sections of the arm and main section

are designed to be interlocked with each other.

It can be provided that the main section has a recess and the arm has a binding extension, the binding extension preferably being insertable into the recess in a form-fitting manner.

Claims (1)

PATENT CLAIMS Scanbody for supporting a measurement of the interior of the mouth, the scanbody having a connecting section (1) for connecting to an element firmly connected to the jaw, such as an implant and a main section (3) extending from the connecting section (1) along a main axis (A) and has at least one arm (6, 7) at an angle (11) to the main axis (A), characterized in that an arm length (L1, L2) of at least one arm (6, 7) is at least 30% of a main length (LH) of a Main section (3). Scanbody according to Claim 1, characterized in that the arm length (L1, L2) of the arm (6,7) is at least 50% of the main length. Scanbody according to claim 1 or 2, characterized in that the Arm (6, 7) has at least one orientation marking (9). Scanbody according to Claim 3, characterized in that at least one orientation marking (9) is designed as a three-dimensional marking. Scanbody according to Claim 3 or 4, characterized in that at least one orientation marking (9) is designed as a color marking is. Scanbody according to one of Claims 3 to 5, characterized in that at least one orientation marking (9) as a shoulder or elevation is trained. Scanbody according to one of claims 3 to 6, characterized in that at least one orientation marking (9) as a recess or Notch is formed. Scanbody according to one of Claims 3 to 7, characterized in that the arm (6, 7) has at least three orientation markings (9) and the orientation markings (9) at least partially in irregular 11. 12th 13th 14th 15th 16. 14th Distances to each other along an arm axis (V1, V2) of the arm (6, 7) are arranged. Scanbody according to one of Claims 1 to 8, characterized in that the arm axes (V1, V2) of at least two arms (6, 7) of the scanbody are arranged parallel to one another. Scanbody according to one of claims 1 to 9, characterized in that the arm axes (V1, V2) of at least two arms (6, 7) of the Scanbody projected onto a transverse plane that is transverse to the main axis (A), at an arm angle (10) between 90 ° and 160 °, preferably 135 ° are arranged to each other. Scanbody according to one of Claims 1 to 10, characterized in that with at least two arms (6, 7) the points of intersection of the arm axes (V1, V2) coincide with the main axis (A). Scanbody according to one of Claims 1 to 11, characterized in that with at least two arms (6, 7) the points of intersection of the arm axes (V1, V2) with the main axis (A) are spaced from one another. Scanbody according to one of Claims 1 to 12, characterized in that the scanbody is located opposite one another on the connecting section (1) Has a rounded head part (4) at the end. Scanbody according to one of Claims 1 to 13, characterized in that the connecting section (1) for connection to an intermediate member is trained. A kit for supporting the measurement of the interior of the mouth, which has at least two scanbodies according to one of claims 1 to 14, characterized in that at least one scan body has at least one arm (6, 7) and the arm is set up for this, in the installed state up to immediately Close to an adjacent scanbody. Kit according to claim 15, characterized in that at least two Scanbody each has at least one arm (6, 7) and the arms for it 18th 19th 20th 21. 15th is set up, when installed, the arm of an adjacent one Touching the scanbody. A kit according to claim 15 or 16 or a kit to support the measurement of the interior of the mouth, which has at least two scan bodies according to one of claims 1 to 14, characterized in that, in the case of at least one first scan body, at least two arms (6, 7) of the scan body along a transverse plane are arranged at an arm angle (10) between 90 ° and 160 °, preferably 135 ° to each other and with at least one second scan body at least two arms (6, 7) of the scan body are arranged parallel to each other along a transverse plane transverse to the main axis are. A kit according to one of claims 15 to 17 or a kit to support the measurement of the interior of the mouth, which has at least two scan bodies according to one of claims 1 to 14, characterized in that at least one arm (6, 7) of a third scan body at a different height along the Main axis (A) is arranged as an arm (6, 7) of a fourth Scanbody. Method for measuring the interior of the mouth and creating a 3D model, whereby at least two scan bodies are connected via a connecting section (1) each with an element firmly connected to the jaw, such as an implant, and recordings are made with an imaging sensor, and an algorithm is used to record the recordings processed into a model of at least one section of the interior of the mouth, characterized in that at least one arm (6, 7) of a scan body in the connected state, which is at an angle (11) to the main axis (A), extends into the close proximity to another scanbody is sufficient. Method according to claim 19, characterized in that the arm (6,7) of the scanbody in the connected state at least one arm (6,7) of the touches another scanbody. Method according to Claim 19 or 20, characterized in that at least one orientation marking (9) arranged on an arm (6, 7) used by the algorithm. 22. The method according to any one of claims 19 to 21, characterized in that at least one scan body is screwed into one in the element Intermediate link is connected. 23. The method according to any one of claims 19 to 22, characterized in that the scan bodies are arranged in such a way that the arms (6, 7) of at least two scan bodies in the connected state with the fixed connected element touch each other. October 29, 2019 MT