NL2017403B1 - Method of digitally designing a finger splint for fixing a finger of a specific patient. - Google Patents

Abstract

Method of digitally designing a finger splint for fixing a finger of a specific patient, comprising the steps of: - measuring the finger to be fixed in a relaxed state; - producing a unique digital design based on the measurement of the finger, which design is suitable for producing the finger splint; wherein - the unique digital design is produced using a digital basic model that is preselected by a designer who performs the method; - wherein the measurement data from the measurement of the finger is digitally combined with the digital basic model to produce the unique digital design for the specific patient.

Description

Method of digitally designing a finger splint for fixing a finger of a specific patient.

The present invention relates to a method of digitally designing a finger splint for fixing a finger of a specific patient.

A finger splint is a type of orthosis that is intended for people with a painful condition on a finger, such as for example for rheumatism, or in the case of a tendon infection or a fracture. With proper adaptation to the specific patient, the finger splint prevents the finger from being bent into positions that provoke or aggravate pain sensations. In addition, the splint supports the stability of the finger, which simplifies daily actions and functioning. Consistent use of the finger splint can prevent the painful condition from increasing, and in many cases can contribute to a complete cure.

The design of the finger splint is such that two or more finger pads of a patient's finger are fixed in a position relative to each other. When followed, the joint that is present between the legs is also fixed. For this purpose, the finger splint comprises at least two mutually connected rings which are in a fixed relationship with each other and wherein the first ring is adapted to a finger bone and the second ring is adapted to a second finger bone, the relationship in which the two rings stand together is adapted to the intended fixation position between the two fingers.

The intended fixation position is assessed by an expert, and is often equal to the mutual position of the finger pads in the relaxed state of the finger. With this fixation position it is therefore achieved that the joint in question is brought and held at a fixation angle.

The finger splint is often made of silver. To this end, the silver is cast into a unique design for the patient in a mold. Titanium is also used as an alternative metal due to its higher strength. Both metals are aesthetically appealing and give the finger splint a fashionable appearance.

Recently, the step has been taken to produce finger splints by means of 3-dimensional printing (3D printing), whereby ABS or titanium is used as material.

The above production methods require a unique digital design that is suitable for producing the finger splint for the specific patient. Such a digital design is also referred to as a CAD-CAM file.

To this end, digitally designing a finger splint for fixing a finger of a specific patient comprises the steps of: measuring the finger to be fixed in a relaxed state; producing a unique digital design based on the measurement of the finger, which design is suitable for producing the finger splint.

In the conventional method according to the state of the art, measuring the finger to be fixed in the relaxed state comprises: - the use of spacers to determine the basic shape of the rings of the finger splint; - measuring the thickness and circumference of the finger pads to be fixed; - the angles between the finger pads to be fixed in side view in the relaxed state of the finger.

The angle between the fingers is often measured with a measuring rod at the height of the joints involved.

By relaxed state, it is meant that the patient holds the finger in a natural position, in which he experiences as little pain as possible.

All of this data is entered into a computer in order to create a unique CAD-CAM file, which is the unique digital design of the finger splint for the specific patient. In the context of the invention, it is noted that the term uniquely expresses that it is a final digital design that is precisely adapted to the specific patient. In theory it is possible that patients with exactly the same dimensions of the finger to be fixed can use the same digital design. In that sense, the term unique does not have absolute meaning.

A drawback of this method used to date is that measuring the various values of the finger to be fixed, as well as subsequently producing the unique digital design on the basis of all measured values, is relatively time-consuming work, for which such one and a half hour is required.

It is an object of the invention to considerably shorten the time duration for digitally designing a finger splint for fixing a finger of a specific patient.

The invention succeeds in this object by providing a method of digitally designing a finger splint for fixing a finger of a specific patient, comprising the steps of: - measuring the finger to be fixed in a relaxed state; - producing a unique digital design based on the measurement of the finger, which design is suitable for producing the finger splint; characterized in that - the unique digital design is produced using a digital basic model pre-selected by a designer who performs the method; - wherein the measurement data from the measurement of the finger is digitally combined with the digital basic model to produce the unique digital design for the specific patient.

In practice, it has been possible for a designer to select a digital basic model for the specific patient on the basis of his experience, whereby on the one hand less data has to be determined by measurement, and on the other hand producing a unique digital design in a computer reduces processing time in takes over.

This design method appears to be ultimately suitable for producing a finger splint that has the same quality in terms of adaptation to the patient as when using the design method according to the prior art.

At the same time, this design method achieves roughly one hour in design time. This time saving is in the step of measuring the finger, as well as in the step of producing the unique digital design.

In the method according to the invention, it is preferred that the finger splint comprises two mutually connected rings, which rings are in a fixed relationship with each other, the first ring being adapted to a finger bump and the second ring being adapted to a second finger bump wherein the fixed relationship in which the two rings stand to each other is adjusted such that an intended fixation position between the two finger pads is achieved in use.

The two fingers are usually directly adjacent to each other, but that does not necessarily have to be the case.

Furthermore, with the designation "a second finger" is not meant a specific finger in the medical anatomical sense; in this context, the designation "second" is used purely to distinguish the two different fingers that are fixed relative to each other.

Medically anatomically, a fingertip is referred to as phalanx (plural: falangen). The three different falangen of a finger are successively referred to from the mid-hand leg as proximal, medial and distal. Sometimes these are numbered from the middle-hand leg as the first, second and third phalanx. Because this numbering has a specific meaning that is not intended in the context of the invention, this anatomical numbering will not be used further.

The joint between the proximal and medial phalanx is referred to as a PIP (proximal interphalangeal) joint, and between the medial and distal phalanx as a DIP (distal interphalangeal) joint.

In practice, the finger splint is often used to fix the proximal phalanx with the medial phalanx, keeping the PIP joint at an intended fixation angle.

The intended fixation angle achieved with the finger splint need not exactly correspond to the measured angle between the finger pads when measured in a relaxed state. The intended fixation angle may, for example, be larger or smaller than the measured angle in the relaxed state, and is assessed by a person skilled in the art.

Furthermore, in the method according to the invention, it is preferred that the finger splint comprises additional connecting pieces between the two rings.

Depending on the patient, such connecting pieces are anatomically necessary to achieve a good fit. In addition, the connecting pieces can serve to reinforce two rings that are directly connected to each other.

With the method according to the invention, it is particularly sufficient if the measurement data which are digitally combined with the digital basic model comprise the following values: the thickness of the finger pads to be fixed and the angle between these finger pads to be fixed.

In practice, these values appear to be sufficient to produce a good finger splint that has the same quality in terms of adaptation to the patient as when using the design method according to the prior art.

Furthermore, in the method according to the invention, it is preferred that the digital base model is selected from a set of digital base models, which set preferably comprises previously produced digital designs.

A collection of digital basic models makes it possible for the designer to perform the selection process simpler and faster using a computer. Moreover, by including previously produced digital designs in this collection, applying the method will continuously further develop itself, which further improves the selection process. Thus a library of designs is created that serves the designer.

In particular, the invention relates to a method in which the digital basic model is selected by the designer on the basis of the required shape and strength of the rings, and the nature of the required fixed relationship in which the two rings stand together.

The designer recognizes these required - somewhat global - design requirements based on his experience. Moreover, if the selection process is supported by a computer, this can be carried out relatively quickly.

According to a special embodiment of the method according to the invention, the measurement of the finger to be fixed in the relaxed state is carried out on the basis of a photographic recording of the finger in the relaxed state in side view.

In practice, this appears to give better measurement results than direct measurement.

It is then preferred that a photographic recording of the finger be made in a relaxed state, while the finger rests on a finger support, which is preferably provided with a millimeter scale. The measurement is reliable and easy to perform with a finger rest. In addition, the fingerrest improves the quality of the photographic image, while the centimeter scale simplifies the determination of the values to be measured.

In that regard, it is particularly preferred that the finger support is provided with a rear wall on which one or more rulers are mounted, which are preferably rotatably mounted on the rear wall.

Such rulers can easily be used to determine the thickness of the finger pads in side view, with a rotatable attachment allowing the rulers to be directed exactly in the transverse direction on the finger pads.

In a general sense, it is preferred that the method according to the invention comprises a subsequent step of producing the unique digital design, preferably by 3D printing.

Thus, the advantages described above are achieved from a faster and simpler design method, while the fingerprint produced has the same quality in terms of adaptation as when using the design method according to the prior art. 3D printing is preferred because this is a suitable and relatively fast technique for producing the finger splint. The finger splint can for example be made from 3D-printed ABS or titanium. Other materials are also possible such as stainless steel, brass, and silver.

It is thereby advantageous if the material from which the finger splint is made has a thermoplastic quality, which allows it to be adjusted afterwards in the heated state. This is advantageous, for example, when the patient experiences some anatomical changes in the finger during the period of use, for example in the thickness of the legs. Moreover, the intended fixation angle can thus be adjusted during the period of use if this appears to be desirable after evaluation by an expert.

In a second respect the invention relates to a finger support suitable for measuring a finger to be fixed with a finger splint in the relaxed state, comprising - a vertically upright rear wall designed as a flat plate, - a base on which the rear wall is arranged, - a support block arranged on the face of the back wall, which is suitable for resting the fingertip of the finger of a patient to be fixed.

In the finger support according to the invention, rulers are preferably arranged on the surface of the rear wall and on the side of the supporting block, which rulers are preferably rotatably arranged on the surface.

With this finger support, the values of the quantities of the finger to be measured can be determined simply and relatively quickly for the method according to the invention. In particular, the finger support offers the possibility to determine simply and reliably from a photographic image: the thickness of the finger pads to be fixed and the angle between these finger pads to be fixed.

The invention is further explained below with reference to the accompanying figures, in which:

Figures 1A and 1B show in perspective two embodiments of a finger splint, such as can be produced according to the method according to the invention; Figure 2 shows a side view of a finger of a patient fixed with a finger splint; Figure 3 shows in perspective a finger of a patient to be fixed, which finger rests on a finger support according to the invention.

Figure 1A shows a finger splint 1 which is made up of two rings 3 and 4 connected to each other, which rings are in a fixed relationship with each other via a common connecting part 5.

Figure 1B shows a finger splint 1 which is made up of two rings 3 and 4 connected to each other, which rings are in a fixed relationship with each other via a number of additional connecting pieces 7 between the two rings.

The choice between the two types of finger splint of Figs. 1A and 1B is made by an expert based on the specific anatomy of the patient's finger to be fixed.

Figure 2 shows a side view of a patient's finger fixed with a finger splint in Figure 1A. The first ring 3 is adapted in size and shape to the middle finger bone 12 (medical: the medial phalanx) and the second ring 4 is adapted in size and shape to a neighboring finger bone 10 (medical: the proximal phalanx). The connecting part 5 between the two rings 3 and 4 determines the angle at which the rings face each other in side view. This angle simultaneously determines the intended fixation position between the two finger pads 10 and 12 is achieved in use. Schematically, the PIP joint 16 is shown as a point of rotation between the dashed center lines of finger pads 10 and 12.

Similarly, the DIP joint 18 is shown between the medial phalanx 12 and the distal phalanx 14. This joint is therefore not splinted.

The bent arrows 20 and 22 show how the joint angle can be determined per joint, i.e. by angle measurement between the undersides of the legs, resp. by angle measurement between the center lines of the legs.

Figure 3 shows a perspective view of a patient's finger to be fixed, i.e. a left-hand ring finger resting on a finger support 30 according to the invention.

The finger support 30 is a rigid structure of suitable material, for example wood or plastic, which consists of a flat plate 32 arranged vertically on a base 34. A support block 36 is arranged in the middle of the plate 32, on which a patient places his fingertip 14 can rest. Rotatable rulers 38 and 40 are provided on the surface of plate 32 by means of pins 42. The rulers can thus be positioned exactly in transverse direction on the finger pads 12 and 10 for a correct measurement of the thicknesses of the respective finger pads.

In the situation shown, the patient holds his finger in a relaxed state, and a photographic image is made perpendicular to the plane of the plate 32 which functions as a back wall. The angle between the finger pads 10 and 12 to be fixed, as well as the thickness of the finger pads, is determined from the photographic image. With the situation shown in Fig. 3, a finger splint is thus measured which fixes the PIP joint, an example of which is shown in Fig. 2.

In a variant of this finger support 30, a third ruler could be provided on the plate 32, for a measurement of the distal phalanx 14.

Claims (12)

Method of digitally designing a finger splint for fixing a finger of a specific patient, comprising the steps of: - measuring the finger to be fixed in a relaxed state; - producing a unique digital design based on the measurement of the finger, which design is suitable for producing the finger splint; characterized in that - the unique digital design is produced using a digital basic model pre-selected by a designer who performs the method; - wherein the measurement data from the measurement of the finger is digitally combined with the digital basic model to produce the unique digital design for the specific patient. A method according to claim 1, wherein the finger splint comprises two rings connected to each other, which rings are in a fixed relationship with each other, wherein the first ring is adapted to a finger sock and the second ring is adapted to a second finger sock with the fixed seam wherein the two rings are aligned to each other is adjusted such that an intended fixation position between the two finger pads is achieved in use. The method of claim 2, wherein the finger splint comprises additional connecting pieces between the two rings. Method according to one of the preceding claims, wherein it is sufficient for the measurement data that is digitally combined with the digital basic model to comprise the following values: the thickness of the finger pads to be fixed and the angle between these finger pads to be fixed. The method according to any of the preceding claims, wherein the digital base model is selected from a set of digital base models, which set preferably comprises previously produced digital designs. A method according to any one of the preceding claims, wherein the digital basic model is selected by the designer based on the required shape and strength of the rings, and the required fixed relationship in which the two rings stand together. Method according to one of the preceding claims, wherein the measurement of the finger to be fixed in the relaxed state is carried out on the basis of a photographic recording of the finger in the relaxed state in side view. A method according to claim 7, wherein a photographic recording of the finger is made in a relaxed state, while the finger rests on a finger support, which is preferably provided with a centimeter scale. Method according to claim 8, wherein the finger support is provided with a rear wall on which one or more rulers are mounted, which are preferably rotatably mounted on the rear wall. A method according to any one of the preceding claims, further comprising a subsequent step of producing the unique digital design, preferably by 3D printing. 11. Finger support suitable for measuring a finger to be fixed with a finger splint in relaxed state, comprising - a vertically upright rear wall designed as a flat plate, - a base on which the rear wall is arranged, - a support block arranged on the plane of the back wall, and which is suitable for resting the fingertip of a patient's finger to be fixed. 12. Finger support according to claim 11, wherein on the surface of the rear wall and on the side of the support block, rulers are arranged, which are preferably rotatably arranged on the surface.