NL7906768A - Checking dental occlusion by biting on transparent polymer strip - which is examined in polarised light for stress birefringence - Google Patents

Abstract

A strip of incompletely elastic material, i.e. elastoplastic material is gripped between the teeth to be examined so that indentations are made in the strip. The strip material has to be optically isotropic and offer a birefringence to mechanical stress. The strip pref. has a uniform thickness of between 0.1 and 0.3 mm. and can be made of a polymer such as nylon or polythene. Teeth grip on the strip is maintained long enough to produce semi-permanent indentations. Pref. for between 10-60 seconds. The strip is then released and the indentations examined under polarised light. To simulate biting on food, a separator of deformable or elastic material, pref. between 0.5-3.0 mm thick, can be sandwiched between two strips as previously described.

Description

, N.O. 28,151 1

Method and device for determining the bite characteristics of a set of teeth.

The invention relates to a method and apparatus for examining and determining the bite characteristics of a set of teeth, in particular human teeth.

The invention further relates to a device for examining and determining the bite characteristics of a set of teeth.

The invention also relates to a device in which organs are used after they have been subjected to loading forces.

Both for medical and in particular for dental scientific purposes as well as in the daily practice of doctors and in particular dentists, it is often particularly desirable to determine the actual characteristics of a bite in order to be able to diagnose correctly and choose the right treatment.

In order to obtain accurate information about a bite, it is not only sufficient to make an X-ray of & e-fce examination teeth, mainly involving two opposing jaws in which the teeth and / or prostheses are contained. Nor is it sufficient to make an impression thereof in a suitable mass, which mass is initially plastic and then cures. These known research methods do indeed provide certain data about the structure and properties of a group of teeth. However, they only provide a relatively rough indication as to the actual conclusion properties of the opposing teeth 50 and do not indicate the actual pressure or contact forces occurring between the opposing teeth at all. As noted above, it is particularly important to obtain very accurate information of at least qualitative, but preferably also 55 quantitative nature not only with regard to occlusion, i.e. the normally closed position of the teeth, but also with with regard to the mastic 7906768 'i 2', that is, the characteristics that predominate during the cutting, and also with regard to the incision, that is, the characteristics that predominate during the cutting phase in the biting process.

For such gnathological investigations of dental arches, there is known a method and device in which a piezoelectric converter is used, which is placed between the teeth to be examined and subsequently subjected to the bite force. The pressure-responsive transducer thereby provides an electrical signal which can be displayed or recorded by a suitable instrument that has been previously calibrated to record the force applied to the transducer.

However, these known methods and devices are only able to measure the total applied forces and do not provide information about the distribution of the contact forces between the arcs. For example, it is not possible to arrange a number of such transducers at different locations along an arc and to perform an effective measurement of the predominant contact forces. This is not possible because the piezoelectric converters and the two arcs are relatively stiff. Therefore, a first transducer will absorb the entire mastication force while a second one remains unloaded or is only neglected.

Even if the dental arches deform somewhat elastically in response to the plumbing forces applied to the piezoelectric transducers at various points, this would not result in a fairly accurate representation of the actual characteristics, nor with respect to occlusion, neither with regard to mastification nor with regard to incision.

It will be understood that these drawbacks cannot be overcome by reducing the stiffness of such transducers, for example, by designating these transducers within an elastic rubber enclosure or the like. This is not possible due to the fact that such a configuration is only suitable for measuring local forces with a relatively high inaccuracy, 40 while it is not possible to measure the actual bite force properties, or mastication characteristics at all actual contact points of measure a group of tancien.

Furthermore, with the known configurations it is not possible to differentiate between occlusion and mastionation, and the results obtained with the known devices therefore do not indicate the mechanical-geometric relationships between the opposing protruding elements.

These known devices also do not provide results taking into account the various effects of the mouth movement during the opening and closing of the arches associated with food ingestion, and therefore do not provide information about the dynamic properties.

In order to obtain at least qualitatively useful data, dental clinics often use carbon paper which is applied in strip form between the Doge of a group of teeth which, after biting, provides some qualitative data on the predominant contact forces and the mechanical / geometric relationship between the protruding elements of the opposing natural teeth and / or prostheses. This method is relatively practical because it can be carried out easily and quickly and is therefore useful for clinical purposes. However, it does not provide quantitative data and has only a very low accuracy even in a qualitative sense.

Investigation methods using impressions of the arcs in a plastic material, such as, for example, wax plates or plastic which cures later, 50 have already been briefly mentioned in the foregoing, but such methods cannot obtain data on the contact forces and moreover, it is very difficult to interpret the acquired ® | ives with regard to the relationships between the opposing tooth elements.

Moreover, with such methods no practical records of the observed observations can be provided.

The main object of the invention is now to improve these methods, organs and devices of the type described above and to overcome the associated 4-0 drawbacks and to provide a method and device with which a qualitative and quantitative gnathological examination is possible of the occlusion, mastication and incision of an entire group of teeth. Furthermore, it is preferable to allow separation of the data pertaining to occlusion and mastication and also to provide information regarding the mechanical-geometric relationships between the opposing projections and the dynamic properties during the mastication. Finally, it is desirable not only to obtain the results in a simple manner, but also to be able to record the results.

According to the invention, the above objects are met by arranging between the teeth to be examined at least one strip-shaped segment of a material which is not entirely elastic, is optically isotropic and has a mechanical double refraction. The jaws that hold the teeth to be examined are then pressed against the strip-shaped segment. The strip-shaped segment is deformed by the teeth to be examined and is then removed. The resulting impressions in the strip-shaped segment are then analyzed under polarized light.

Preferably, the strip-shaped segment is held under pressure between the teeth or arches for a predetermined residence time, eg, one minute, after closing the teeth and before removal.

The term "not entirely elastic" material in this specification refers to material that is elastoplastic. Such material responds to a bite-induced impression such that this impression is retained as unaltered as possible for at least a predetermined period of time so that it is possible to analyze this impression and make a registration if desired. .

With the term "optically isotropic" material having 55 a mechanical double refraction "material which does not initially exhibit double refraction due to the fact that it is optically isotropic, but which will exhibit a double refraction under the influence of stress.

As is known, double refraction nor-40 times occurs only in optically aisotropic media, such as crystals 7906768 with non-cubic crystal lattice. In it, an incident beam is divided into two-component beams, which generally have a different group orientation and a different group and phase velocity, and both comply with the conventional refraction laws. If the media are non-absorbent, then both component beams are linearly polarized and mutually perpendicular.

In addition to the natural double refractive property of optically anisotropic crystals described above, there is also the so-called deformation or stress birefraction property, which is caused by external mechanical loading in normally isotropic media.

Such an optically isotropic material that is subjected to a pressure or a stress may behave like a crystal with a single optical axis, which axis is oriented in the direction in which the pressure or stress is applied.

The internal stresses arising under load give rise to a phenomenon known as the mechanical birefraction Tersohijnsel-Qe varying internal stresses may indicate the applied load, provided that the material used has been appropriately calibrated.

0 in order not only to generate the desired mechanical stress birefraction phenomenon but also to retain the load-induced phenomenon for a period sufficient to perform an investigation and, if desired, sufficient to make a record, according to the invention

JO

go from a material that is not entirely elastic. In this context, one speaks of a material with a so-called elasto-plastic memory property.

According to the invention, use is made of an elastoplastic material which is flexible and is used in the form of a foil. It is preferable to start from a foil with a very uniform initial thickness.

Preferred materials are polymers, among which polyamides such as nylon or polyethylene are preferred. However, other materials can also be used 7906768 6.

If a two-sided impression is desired, then preferably a single strip-shaped foil segment is used. This leads to an impression of the one arc on the top surface of a foil and an impression of the opposite arc on the underside of the foil. This is sufficient not only for a quantitative determination of the contact forces, but also for a correlation with the mechanical geometrical properties of the respective teeth. For example, it is possible to determine that the contact force at a given pair of opposed teeth is produced by a protruding upper tooth element cooperating with an arcuate configuration of the protruding parts of the opposing lower tooth and the like.

On the other hand, however, if for some reason a separate examination of the upper and lower arcs is desired, then preferably two such film segments are used which can be easily separated from each other after the impression has been made.

According to a further embodiment of the invention, a separating element is arranged between two foil strips. This separating element preferably consists of elastic or deformable material and has a thickness between 0.5 and 5 mm. This has the further advantage that the presence of the elastic separating layer can simulate the presence of food between the two arcs.

The analysis of the segments subjected to the bite forces can be performed according to the invention using a white or monochromatic light-emitting light source, a polarization filter serving as a first linear or circular polarization unit, a second linear or circular polarizing unit. filter, serving as an analysis unit, a holder for the segments to be analyzed and magnifying means arranged above the illumination means and the polarizing filters.

Preferably, the segment holder is in the form of a scissor clamp so that the segments can be moved relatively.

40 and a further embodiment of the invention 7906768 * t 7 which allows the use of reflective optics for voltage analysis uses illumination means and a first polarization filter serving as a polarization unit on the same (top) side of the analyte. lysing segment as the second polarizing filter and the magnifiers.

The invention will be explained in more detail below with reference to illustrative embodiments thereof shown in the figures.

Figure 1 schematically shows a cross-section of a device for examining and determining the bite characteristics of a set of human teeth, provided with two parallel foil segments and an elastic separating unit.

^ 5 Figure 2 shows a schematic top view of a device of figure 1 in the direction of the arrow II.

Figure 3a schematically shows an illustration of the device for analyzing the results obtained using light transmission.

Figure 3b schematically shows a device for analyzing the results obtained using light reflection.

Figure 4 schematically shows an enlarged impression of a tooth or protruding portion observed by means of the device of figure 3.

Figure 5 shows the scissor-shaped clamp for holding the segments.

Figure 6 shows in perspective an embodiment of the device for examining the bite 30 according to the invention.

Figure 7 shows in perspective another embodiment of such a device with a holder in front of it.

Figure 8 schematically shows a cross-section through a further embodiment of such a device.

Figure 9 schematically shows a specific manner of use of such a device.

Figure 1 schematically shows a member according to the invention, in which two strip-shaped segments 1 and 2, 40 are positioned in parallel and at a distance from each other with a 7906768% 8 separating layer 3 between the two segments 1 and 2. The segments 1 and 2 are of elasto-plastic material and exhibit a mechanical birefractional property. The two segments 1 and 2 are of flexible foil and have a uniform thickness of, for example, 0.15 mm. The foil material can consist of transparent polyamide, in particular of nylon.

The separating layer 3 consists of an elastic or deformer material, for example rubber, and can have a thickness of, for example, 1.8 mm.

For gnathological examination of occlusion, mastication and incision, the three-layer structure of Figure 1 is inserted between the two dental arches 4 and 5 shown schematically in Figure 1.

The two dental arches 4 and 5 are then moved together and pressed together.

The member of Figure 1 remains in the compressed state between the upper teeth 7 of the upper arch 4 and the lower teeth 8 of the arch 5 for a period of time varying between 10 and 60 seconds. Then the bite is terminated and the organ is removed from the mouth.

The device of Figure 1 used in this manner is then analyzed by means of the devices of Figures 3a or 3b.

The analysis instrument of figure 3a or 3b contains as illumination means a source 9 which emits white light and a glass diffusion plate 10, two linear or circularly polarizing filters 11 and 12 and for holding the film segments 1, 2 to be examined. in the form of a scissor-shaped clamp 15, which allows relative displacement relative to each other.

Above the upper polarization filter 12 there is an eyepiece in the form of a magnifying lens 13. Normally, a three to ten times magnification through the lens 13 is sufficient.

For recording the examination results, a camera 14 can be positioned above the eyepiece 13 and rotatably attached to the support 16. This makes it possible to either perceive or examine the impressions without encountering any interference 7906768 * 9 of the camera 14 · or make a registration by means of a photo.

Figure 2 shows very schematically, the impressions 17 of the upper teeth 7 are in the form of a series of dots which can be seen by the naked eye. On the other hand, figure 4- also very schematically shows the image visible to the eye or the camera in the instrument of one of figures 3a or 3b. The irregular surfaces in figure 4- with the different arrangement actually show different colors (isochromatics) . Once the material used for films 1 and 2 has been properly calibrated, it is possible to qualitatively determine the contact forces caused by biting.

Moreover, these impressions provide insight into the 15 mechanical-geometric relationships. It is, for example, possible to determine in which of the places and before which of the protruding parts the contact forces occur between the examined teeth.

The impressions obtained in this way thus reproduce the total force distribution over the entire dental arch.

In the described embodiment, the elastic separation layer 3 dims the state that predominates during the average processing of food.

Corresponding impressions for the teeth 8 of the lower dental arch 5 are present in the segment 2 which can be separated from the segment 1 after the impression has been made. Using suitable alignment means, for example the precisely positioned openings 18, the two segments 1 and 2 can also be placed one above the other and viewed simultaneously. This provides information about the relationships between the turned and interacting protruding parts.

As will be appreciated, with the method, members and devices of the invention, it is not only possible to determine the contact forces of a normal set of teeth, but also the contact forces that occur when implanted support members are used. The invention therefore makes it possible to make the necessary adjustments in order to obtain a relatively uniform load on the implanted support elements or 7906768 V * 10 or the like.

the same, of course, also applies to prostheses, where the determination of the predominant contact forces can avert problems and lead to an almost uniformity in the forces that occur during occlusion and / or mastication and / or incision.

Furthermore, the invention is very well suited for making an official registration, in particular as an addition to fingerprints or other personal identity criteria. The results obtained by means of the invention do not change over a longer period of time or at least do not change to such an extent that an identification of a specific person is no longer possible unless this person has meanwhile undergone a clear change by means of prostheses.

The phenomena employed in using the invention are described in the following.

The materials used for segments 1 and 2 must have certain specific properties. In particular, when a thin strip of such material is subjected to a local stress, as is the case when the opposing teeth or arcs act on it, this results in a local stretch. This rack can be visually observed by means of the instruments shown in Figure 3. It manifests itself through the so-called "defraction bands" around the stressed area. This is also referred to as the photo-elastic effect and materials that exhibit such an effect are therefore known as photo-elastic materials.

Not only this photo-elastic effect is used for the present invention, but also a further derivation thereof. This is due to the fact that in certain materials and in physical configurations of such materials, the strain resulting from the application of a stress varies more or less proportional to the stress over an initial range of stresses applied, but no longer does when a certain threshold is exceeded. Beyond this threshold, the proportional re-4-0 relationship is no longer valid and the material does not fully recover from the elongation produced therein even though the tension is completely released. This retention of strain even after tension removal is known as the "photo-elastic memory property" referred to as "photo memories" for short. This residual stretch which causes the photo memory is now used according to the invention.

The strip-shaped segments such as segments 1 and 2 already mentioned above may, for example, consist of photo memory bands. B3J applying a bite force through a set of teeth as described above, the local stress generated at the contact points between the opposing teeth will cause local stretch in the photo memory belt (or bands if more then one is used) 15 The type of material and its thickness, as well as other parameters still to be discussed, are chosen under practical conditions such that the degree of local stress and the resulting elongation ensures that the material has a corresponding permanent photo-20 exhibits memory property. The period of time during which the bite conditions are maintained and therefore the pressure is maintained can vary from, for example, two seconds to more than a minute, depending on the type and thickness of the material used.

After removal of the organ from the teeth or dental arches to be examined, this permanent photo memory is then visualized by means of the instruments already described.

It will be clear that these devices per se are somewhat similar to the known transmission type polariscopes for Figure 3a and the reflection type for Figure 3b. However, to date, polariscopes have never been used to investigate bite phenomena in teeth, and have never been used to visualize residual photo memory phenomena in photo memory bands used for bone research.

Moreover, hitherto a construction using scissors-shaped clamps 15 has never been used. This construction makes it possible for segments 1 and 2 with the 40 respective futo memory phenomena caused by 7906768 * \ 12 to hold the bite forces exerted by the upper and lower arches and simultaneously visualize both in the same geometric alignment that prevailed with the actual group of examined teeth.

5 For example, if a protruding portion of a tooth that is part of one dental arch fits snugly into a corresponding hollow in an opposing tooth, then the local permanent elongation created during biting will be very uniform and give 10 corresponding corresponding deformation patterns. . On the other hand, if there is a local misalignment or an unintended projection on one side or the other, this will result in more intensive and concentrated local permanent stretching phenomena in the belt that become visible as local disturbances or places with an intensification of the defraction effect.

With some experience in observing these visual phenomena, it becomes possible to interpret these phenomena quickly and accurately on the basis of the necessary corrections in the bite pattern indicated thereby. In addition, by calibrating the memory bands in advance using known forces, quantitative information with respect to the local forces can be derived from the visualization by counting and measuring the defraction bands and defraction regions. In this respect, the method is analogous to the conventionally used methods with polariscopes.

Moreover, by moving the bands 1 and 2 more or less towards each other, a visual phenomenon can be observed which is highly lifelike and represents the changes that actually take place during the movement of the dental arches towards or from each other. each other ai. This provides valuable clinical insight into the relationships that predominate in the group 55 of teeth examined.

Preferably, the polarizing filters 11 and 12 are mounted so that they are moved together with the memory bands 1 and 2, for example, for which the filters are attached to the scissor-shaped clamps, so that they are also moved with a movement of the scissor-shaped 7906768 * clamps 15 .

It is generally desirable to apply a protective layer (in the form of a separate layer or a coating) to each surface of a photo memory tape 1 or 2 that is exposed to contact with external objects, for example the teeth to be examined. of a material that does not exhibit a photo memory phenomenon to any appreciable degree. This aims to prevent scratches and other undesired deformation of the photo memory tape itself. This band should only be "activated" by the desired bite forces.

When a single band 1 or 2 is used, the protective coating is preferably present on both surfaces of the band.

If a layered configuration of belts 1 and 2 is used with a separating element 3, the protective covering is only present on the exposed sides of the belts 1 and 2, respectively.

The protective layer material may, for example, consist of polyvinyl chloride and have a thickness between 0.01 mm and 1 mm.

As already noted, the separating layer 5 may consist of, for example, rubber or a foam-like, sponge-like, pasty or wax-like non-elastic material * The thickness preferably varies between about 0.3 and 3 mm .

It will also be appreciated that, although photo memory tapes are preferably isotropic before being exposed to biting forces, initially anisotropic tapes may also be used provided this property is substantially uniform throughout the band.

In such a case, a pattern will appear which will be visible against a substantially uniformly colored background.

The photo memory tape according to the invention can also be provided with a coating or a foil of carbon-like material. Therefore, the method according to the invention can in fact be combined with known techniques, which, as already noted above, refer to carbon paper to determine 7906768 w S · 14 certain aspects of a bite. In such cases, the carbon film can also serve as a protective layer for the photo memory tape as described above. If this carbon foil is opaque then it must be removed before the photo memory tape is analyzed. However, a thin coating of carbonaceous material can also be applied which is sufficiently transparent to light so that no post-treatment is required to carry out the analysis, optionally the carbonaceous layer can be removed with the aid of solvents, water or other liquids. cycle carbon-like materials consist of a paint of arbitrary color, which leaves a colored trace on the teeth which are brought into contact with each other.

As further shown in Figure 8, a reflective paint layer 23 can be applied to the photo memory tape 24 with a carbon layer 25 on top of the reflective layer 25. Such a member can be analyzed by means of a reflection polariscopp without the carbon-20 layer 25 need to be removed.

The memory belts have a shape sufficient to overlap the area of the dental arches to be examined. Preferably, the entire dental arch is covered by the belt. Figure 6 shows a possible configuration of such a strap 20. Figure 7 shows a further configuration of a strap 21, which strap 21 is inserted in a holder 22 by means of which it can be easily inserted and held in place between the dental arches to be examined. It is further noted that the holder 22 is sized such that the photo memory band 21 is slightly curved. This has been found desirable to obtain a good fit between the dental arches and also provides space for the tongue when the organ is used in the human mouth.

55 It is further possible to apply a printed line grid on the photo memory tape itself as a suitable geometric reference for the visible phenomena that become visible during the use of the tape, but it is also possible to provide other relevant information, such as a dental map.

7906768 * φ15

It is pointed out that the visualization and analysis of the photo memory bands according to the invention will normally be performed after removal from the space between the dental arches to be examined. However, it is also possible to perform such an in situ analysis by opening the dental arches and using a reflective polariscopic instrument. Preferably, an organ as shown in Figure 8 is used for this purpose. the reflective layer 23 provides the reflective properties needed when using a reflective polariscopic instrument The use of a carbon layer 25 is not necessary as far as the polar polar analysis itself is concerned.

In order to obtain a permanent record of the better prints in the photo memory tape itself, the tape itself can be preserved and the impression pattern can be visualized again if necessary by means of a polariscopic instrument. It is also possible to take a picture of the observed pattern as already described above. The visualized pattern can also be recorded using a xerographic method as illustrated in figure 9 · In that case, the photo memory belt 26 is provided with a reflective coating 27 · The tape is then placed on the support surface of a xerographic machine the belt 26 faces this support surface and with a polarizing filter 29 between the belt 26 and the support surface 28.

The filter 29 can be a linear polarizing filter but is preferably circularly polarized, if the band 26 is exposed in the initial phase of the xerographic process then the stretch pattern will become visible and recorded xerographically at the same time. Other optical recording techniques can be applied correspondingly.

55 The visualized dFraction pattern can also be enlarged and projected onto a screen.

It can then be photographed from the screen and also further magnified using an appropriate eyepiece or microscope. For example, the screens used 4-0 may be screens for displaying slides or films or the like.

7906768

Claims (65)

Method for examining and determining the properties of a group of teeth, in particular the human teeth, characterized by applying at least one strip-shaped segment of a material which is not entirely elastic (i.e. (say elasto-plastic material) and is optically isotropic and has a mechanical birefraction property (ie, which acts as a bondage to stresses), pressing the jaws in which the teeth to be examined are against the strip-shaped segment, removing of the strip-shaped segment deformed by the teeth to be examined, and studying the impressions formed in the strip-shaped segment under polarized light. 2. Method according to claim 1, characterized in that the strip-shaped segment remains under load between the teeth to be examined for a predetermined period of time. 3. A method according to claim 2, characterized in that said duration varies between 10 and 60 seconds. 4. A method according to claim 1, characterized in that the material is pre-calibrated with regard to the birefringent properties under the provision of various loads. 5. Method for examining and determining the properties of pen group of teeth and in particular human teeth, characterized by the use of a strip-shaped segment of a material which is not entirely elastic, is optically isotropic and mechanically exhibits birefractional properties (i.e. birefractional stretching properties). 6. Method according to claim 5, characterized in that the material is flexible. 7. Method according to claim 6, characterized in that the material has the form of a foil. 8. Method according to claim 7, characterized in that the material has a very uniform thickness 4-0. 7906768. V has. 9. A method according to claim 8, characterized in that the thickness varies between about 0.1 and 0.3 mm. 10. Process according to claim 5, characterized in that the material is a polymer. 11. A method according to claim 10, characterized in that the polymer is a polyamide such as nylon. 12. Process according to claim 10, characterized in that the polymer consists of polyethylene. 13. Device for examining and determining the properties of a group of teeth, in particular the human teeth, characterized by at least a generally strip-shaped segment of a material which is not entirely elastic, optically isotropic and mechanically irefractive properties. shows. Method according to claim 13, characterized in that the material is flexible. 15. A method according to claim 14, characterized in that the material is in the form of a foil. 16. A method according to claim 15, characterized in that the material has a very uniform thickness. Method according to claim 16, characterized in that the thickness is between 0.1 and 0.3 mm. A method according to claim 13, characterized in that the material is a polymer. A method according to claim 18, characterized in that the polymer is a polyamide such as nylon. 20. Process according to claim 18, characterized in that the polymer consists of polyethylene. 21. Organ according to claim 13, characterized in that it contains only a single segment. Organ according to claim 13, characterized in that it contains two segments. 23. Device as claimed in claim 22, characterized in that a separating element is arranged between the two segments. 79 0 67 6 8 ν '* Organ according to claim 23, characterized in that the sheathing element consists of elastic or deformable material. 25. Device as claimed in claim 23, characterized in that the separating element has a thickness between 0.5 and 3 mm. 26 Instrument for analyzing segments of material which is not entirely elastic, is optically isotropic and exhibits mechanical birefractional properties 10 and which is subjected to bite forces, which instrument is characterized by exposure means, a first linear or circular polarizing filter for realizing of a polarization, a second linear or circular filter for realizing the analysis, means for holding the segments to be analyzed and magnifying means arranged above the illumination means and the polarizing filters. 27. Instrument according to claim 26, characterized in that the illumination means and the first polarizing filter are mounted on the same top side of the segments to be analyzed as the second polarizing filter and the magnifying means. 28. Instrument as claimed in claim 26, characterized in that the holding means consist of a scissor-shaped clamp with which it is possible to perform a reciprocal movement in order to enable an analysis of the static and the dynamic bite characteristics. 29. Instrument according to claim 26, characterized in that the exposure means consist of a conventional light source and a frosted glass or diffuse glass plate. Instrument according to claim 29, characterized in that the light source emits monochromatic or white light. The instrument of claim 26, further characterized by phase-shifting or retarding means interposed between the segments to be analyzed, the birefractional properties recorded in the tape being offset against the birefractional properties 40 of a calibrated scale or compensated by rotation of one of the polarizing elements 7906768 . An instrument according to claim 26, characterized by phase-shifting or delaying means arranged between the segments to be analyzed. An instrument according to claim 26, characterized by optical recording means co-operating with the magnifying means. 33. Instrument according to claim 32, characterized in that the recording means consist of a photographic camera. An instrument according to claim 26, characterized in that the magnifying means comprise a magnifying lens or an accelerating lens or an eyepiece. Instrument according to claim 13, characterized in that the strip-shaped segment consists of transparent material * 36. Organ of a material for use in any of the methods or devices of the preceding claims, wherein the bite of opposing and a group of teeth is examined and evaluated by first inserting an organ between said teeth from the group of teeth, after which the dental arches are closed to the said material and cause a bite pattern therein, and then the resulting patterned material is subjected to a polarisopic observation, which member is characterized by at least a layer of a matter which has photo memory properties under the bite conditions. Organ according to claim 36, characterized in that at least one surface of the layer is covered by a protective layer which does not exhibit appreciable photo-memory properties under the conditions prevailing in a bite. The organ of claim 36, further characterized by a second layer of a material exhibiting said photo memory properties. The organ of claim 38, further 4-0 characterized by a separating layer between the first and second layers, which separating layer is soft and spongy. 40. Device according to claim 39, characterized in that the separating layer consists of rubber, foam-like or sponge-like material or paste or wax-like material. 41. An organ according to claim 39, characterized in that the exposed surfaces of both the first and the second layer are covered with a protective layer which does not exhibit appreciable photo-memory properties under the conditions prevailing with a bite. 4-2. Organ according to claim 36, characterized in that the organ has a configuration and dimensions such that the whole group of teeth is included. 43. The organ of claim 42, characterized in that an edge of the organ is curved such that the arc of a group of teeth is generally followed. 44. The device of claim 43, characterized in that the member generally has a crescent shape with two curved edges generally following said dental arch shape. • Body according to claim 44, characterized in that one of the edges runs along a line connecting the end points of the curved edge. 46. Device according to claim 45, characterized in that the member fits into holding means which are designed such that the member is held along its curved edge. 47. Combination from claim 46, characterized in that the holding means are provided with a handle extending from the curved edge side. 48. Combination according to claim 46, characterized in that the holding means are designed such that the member is bent out of the plane of the curved edge when it is in the holding means. 49. The device of claim 26, characterized in that the material is substantially isotropic before being subjected to the bite conditions. 50. The organ of claim 36 wherein the matter is substantially uniformly anisotropic before being exposed to the bite conditions. 51. An organ according to claim 36, characterized in that at least one surface of the layer is covered with a carbonaceous coating or a transparent paint or foil. 52. An organ as claimed in claim 51, characterized in that the cabon-like coating consists of a foil and that said foil also forms the protective coating for said layer. Organ according to claim 51? characterized in that the carbon-like coating is impermeable to light and can be removed from the layer before the layer is subjected to polariscopic observation. 54. Device according to claim 51, characterized in that the carbon-like material is sufficiently transparent that the layer can be subjected to polariscopic observation without the carbon-like material having to be removed. Organ according to claim 51, characterized in that between the carbon-like material and said layer there is a material which is slightly reflective at least on the side facing the layer. 56. Body according to claim 55? characterized in that the light-reflecting material consists of an aluminum coating. 57. The device of claim 36, characterized in that a surface of the layer is coated with a material that reflects light on at least the side facing said layer. 58. A folariscopic instrument for use in the method of any preceding claim for examining and evaluating the bite of opposed teeth or groups of teeth wherein, first of all, 4-0 between said teeth or groups of teeth is an organ 7906768 v-r is placed from a material exhibiting photo-memory properties, after which the dental arches are closed to the material and a photo-memory pattern of the bite is pressed therein, and then the resulting patterned material is observed by means of said polariscopic instrument, which instrument is characterized by means for holding the observation means, which holding means is constructed such that the photoshoot pattern depressed in the material by the bite is not disturbed by the holding means. 59. Instrument according to claim 58, characterized in that the holding means are constructed in such a way that the member is not subjected to an additional photo-memory depression during holding. 60. Instrument according to claim 58, characterized in that the holding means are provided with two components, respectively, for holding two separate layers of the member, which are respectively pressed in with a photo memory pattern of the upper teeth and the lower teeth. 61. Instrument according to claim 60, characterized in that the components of the holding means can be displaced relative to each other. 62. Instrument according to claim 61, characterized in that the polarization filters of the instrument are mounted such that they can be moved together with the components of the holding means. 3 ° 63. Instrument according to claim 61, characterized in that said components belong to a scissor-like construction. 64. An organ of a material as defined in claim 36, which member is subject to the bite prevailing conditions after which said member exhibits a photo memory pattern of the forces characterizing the bite conditions. 65. Permanent recording of the photo memory pattern of claim 64, manufactured ...... by means of a 7906768-% method, characterized by displaying the photo memory pattern in a polariscopic instrument and recording this visible photo memory pattern. 66. Registration according to claim 65, characterized in that the registration takes place in a photographic manner. 67. Registration according to claim 65, characterized in that the registration takes place in xerographic manner. 68. A method according to claim 2, characterized in that the period varies between about 2 seconds and about 1 minute. 69. A method according to claim 1, characterized in that the segment is provided on one side with a reflective coating and the segment is exposed from the side opposite to the side with the reflective layer. 70. Method according to claim 69, characterized in that the exposure takes place via a linear or circular polarizing filter. 71. A method according to claim 70, characterized in that the exposure takes place by means of xerographic reproduction means. 72. A method according to claim 70, characterized in that a photographic registration of the reflected exposed image is obtained via a filter. A method according to claim 69, characterized in that the strip-shaped segment is not removed but exposed in place after the jaws have been opened to allow the segment to be exposed. ******** 7906768