ES1301004U - DEVICE KIT FOR PERFORMING BIOMECHANICAL TESTS ON THE FOOT (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Kit of devices for carrying out biomechanical tests on the foot for the prescription of personalized orthopedic insoles, characterized in that it comprises: - a device for carrying out biomechanical tests on the foot, made of polyamide, angular and rectangular, adjusted to the size of the heel with an angulation range of 0°-5° with rounded edges in which the main body (1) is made of a single piece, - a device for performing biomechanical tests on the foot made of polyamide, angular and adjusted rectangular tailored to the heel with an angulation range of 6°-10°, with rounded edges in which the main body (2) is made up of a single piece, - a device for carrying out biomechanical tests on the foot made of polyamide, angular and rectangular, adjusted to fit the heel with an angulation range of 11°-15°, in which the main body (3) is made up of a single piece, - a device for performing biomechanical tests on the foot made of polystyrene, angular and rectangular adjusted to the size of the first toe, with an angulation range of 0°-10°, in which the main body (5) consists of a single piece, - a device for performing biomechanical tests on the foot, made of polystyrene, angular and rectangular, adjusted to the size of the first toe, with an angulation range of 11°-15°, in the that the main body (6) is made up of a single piece, - A device for performing biomechanical tests on the foot made of polystyrene, angular and rectangular, adjusted to the size of the first toe, with an angulation range of 16°-20°, in which the main body (7) is consisting of a single piece and - a device for performing biomechanical tests on the foot, made of polystyrene, angular and rectangular, adjusted to the size of the first toe, with an angulation range of 21°-40°, in which the main body (8) is made up of a single piece. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

KIT OF DEVICES FOR CARRYING OUT BIOMECHANICAL TESTS IN

THE FOOT

TECHNIQUE SECTOR

The present invention belongs to the field of podiatry, biomechanics and orthopedics, more specifically to devices for carrying out biomechanical tests for the prescription of personalized insoles.

The main object of the present invention refers to a kit of devices for carrying out biomechanical tests on the foot, at the level of the heel and the first toe (hallux). This kit allows the professional to know the necessary degree of elevation that must be incorporated into the personalized orthopedic insole at the heel level to allow the flexion of the first toe to activate the elevation of the plantar arch. On the other hand, at the level of the first finger, the use of the device allows Jack's biomechanical test to be carried out objectively, thus knowing the necessary graduation with respect to optimal dorsiflexion to activate the patient's Windlass Mechanism. In this way, the use of the kit allows a prescription to be made with very precise indications about the corrections to be applied to the personalized insole with the aim of improving the biomechanical function of the patient.

BACKGROUND OF THE INVENTION

The biomechanical evaluation of the function of the foot in terms of the activation of the plantar ligaments and musculature is based on the visual verification of the anatomical changes that occur in the plantar vault of the foot through the Jack Test. This occurs after mobilizing the first finger, generating a dorsiflexion of the same (elevation of the hallux), while the patient is in a standing position.

Sometimes, depending on the biomechanical condition of the foot, to activate the function of the muscles and ligaments that raise the plantar arch, it is necessary, in addition to flexing the first toe with certain degrees (which are variable depending on the patient). ), place an elevation on the inner side of the heel to improve the position of the subtalar joint and thereby provide a mechanical advantage to the plantar-attached muscles and ligaments in the foot so that they can be activated.

Custom treatments for orthopedic insoles base part of their operation on the incorporation of angled planes in the heel area, which improves the biomechanical function of the foot.

Currently in the clinic, quantifying the graduation to be incorporated into the personalized insole in the heel area is done subjectively, since there is no device that performs this function. In this line, there is also no device available that helps to know in a quantitative and objective way the necessary flexion produced by the activation of the Windlass mechanism through the Jack Test, one of the most used clinical maneuvers in the biomechanical examination of the foot. which is performed with the patient standing, exercising, with the hand of the professional, a dorsiflexion of the first toe without muscular collaboration on the part of the patient. This test is valued in a non-objective way, so the present invention offers to solve this problem and give the professional precise and above all quantifiable information about the necessary degrees of dorsiflexion of the first toe, which is of special interest. when the plantar mold is taken to make the personalized insole optimally.

EXPLANATION OF THE INVENTION

The Windlass Mechanism is a system that allows movements such as walking or running, thus helping to propel the body forward. This movement starts under the first toe, rising up. From this moment on, the plantar fascia is tightened, which consequently raises the longitudinal arch of the foot, increasing the plantar arch. This new structure transmits the force of the muscles to the ground, in this way, they can propel us forward with greater force. Continuing through the heel, the Windlass Mechanism tightens the Achilles tendon, externally rotating the tibia, which in turn transmits force to the femur, hip, and trunk, thus involving a large number of structures. The impediment of a good functioning in this system can indicate the presence of an injury (plantar fasciitis, Achilles tendinitis, stress fractures in the ankles). metatarsals, discomfort and injuries in knees, hips and lower back). The use of orthopedic insoles is a solution to improve and avoid aggravating a large part of these injuries. The insoles must have a personalized structure that solves the pathologies or discomfort of the patient through angulations that allow the Windlass Mechanism to be activated to solve the problem, both in the hallux area and in the heel area. Currently, the measurement to determine the degree of this elevation when the mold of the personalized insole is taken is literally done manually, since the podiatrist or orthopedic specialist raises the patient's first finger with his own hand. to activate the Windlass Mechanism and position the heel to “estimate by sight” the degree of elevation to apply on the insole. This point raises doubts for the professional about the type of intrinsic medial control to apply in this, since they do not know the exact angulation that the patient's foot requires at the heel level and neither does he apply an objective graduation at the level of the first toe when taking the mold. In this sense, the main advantage of this invention is summarized as follows:

• The use of the devices on the first finger (hallux) when performing the Jack Test and taking the mold to make the personalized insole, allows to know quantitatively the degrees at the dorsal level that manage to activate the Windlass mechanism, to subsequently apply sufficient correction when taking the mold to make the template.

• The orthopedic or podiatric specialist objectively defines in the biomechanical study the necessary amount of correction in degrees that must be incorporated at the level of the corresponding area of the heel in the customized orthopedic insole through an objective intrinsic medial control.

• The use of the present invention in biomechanical studies for the prescription of personalized orthopedic insoles allows the obtained insole to improve the propulsion of the human gait phase and the heel toe-off phase, consequently solving various foot pathologies due to that the angulation in the heel area of the insole is optimal for biomechanical functionality.

The kit of devices for carrying out biomechanical tests on the foot of the personalized orthopedic insole object of the invention comprises a total of seven angular pieces that cover different graduation ranges: from 0° to 10°, from 11° to 15°, from 16° to 20° and from 21° to 40° for those of the first toe, and for those of the heel area from 0° to 5°, from 6° to 10° and from 11° to 15°, the entire set of parts makes up the kit. The devices for performing biomechanical tests on the heel foot are made up of three pieces of 3D-printed polyamide and contain a solid structure, with the internal face of the angulation partially empty to save material at the time of printing. On the other hand, each device for performing biomechanical tests of the first finger is made up of a 3D-printed piece of polystyrene and contains a structure with 50% filling inside. The kit of devices for carrying out biomechanical tests on the foot is placed under the first toe and under the inner part of the heel to observe which graduation for each anatomical region is the one that manages to raise the patient's plantar arch. The use of the devices to carry out biomechanical tests on the foot of the first toe will determine the phase of taking the mold since it has been designed so that the taking of the foot mold is carried out with the application of the device. On the other hand, the device for carrying out biomechanical tests on the foot at heel level will condition the design phase of the insoles since, once the graduation at heel level is obtained thanks to the present invention, the specialist will be able to prescribe the type of intrinsic medial control more convenient to apply on the insole. Intrinsic medial control is a common treatment used in podiatry that consists of intrinsic wedges in the rearfoot of the insole that make the moment of reactive forces of the ground greater, being its more effective function, is what is also known as " medial heel skive". The type of control required by the insole at the heel level correlates with the arrangement of the angle of the device for performing biomechanical tests on the foot: low, medium and strong intrinsic medial control, respective to the graduation range. that covers the device 0°-5°, 6°-10° and 11°-15°.The invention designed for the heel area serves any type of existing custom insole manufacturing methodology (plaster, 3D printing, among others) ) since it is independent of the manufacturing method of these.However, the use of the invention designed for the first toe will be exclusive for taking the mold provided that this is done through a plantar scanner methodology.

BRIEF DESCRIPTION OF THE DRAWINGS

To complement the description that is being made and in order to help a better understanding of the characteristics of the invention, a set of drawings is attached as an integral part of said description, where the following has been represented for illustrative and non-limiting purposes :

Figure 1.- shows a schematic drawing in sagittal view of the devices that make up the part at heel level of the kit of devices for carrying out biomechanical tests on the foot object of the invention, with the polyamide folded to the different ranges of graduations , 0°-5° (1), 6°-10° (2) and 11°-15° (3).

Figure 2.- shows a schematic drawing in plan view of the different polyamide devices with the different ranges of angulations, 0°-5° (1), 6°-10° (2) and 11°-15° (3). , which make up the kit of devices for performing biomechanical tests on the foot at heel level, object of the invention.

Figure 3.- shows a schematic drawing in sagittal view of how the device would look for performing biomechanical tests on the foot in the heel area with the angulation range of 0°-5° (1) coupled to the foot (4) .

Figure 4.- Shows a front view schematic drawing of how the device would look for performing biomechanical tests on the foot with an angulation range of 6°-10° (1) coupled to the heel of the foot (4).

Figure 5.- shows a schematic drawing in sagittal view of the devices for performing biomechanical tests on the foot for the first toe object of the invention, with the polystyrene folded to the different graduation ranges, 0°-10° (5 ), 11°-15° (6), 16°-20° (7) and 21°-40° (8).

Figure 6.- shows a schematic drawing in plan view of the different polystyrene devices with the different ranges of angulations, 0°-10° (5), 11°-15° (6), 16°-20° (7). and 21°-40° (8), which make up the kit of devices for performing biomechanical tests on the foot at the level of the first toe, object of the invention.

Figure 7.- shows a schematic drawing in sagittal view of how the device would look for performing biomechanical tests on the foot with the angulation range of 0-10° (5) coupled to the first toe (4).

Figure 8.- Shows a front view schematic drawing of how the device would look for performing biomechanical tests on the foot with an angulation range of 0-10° (5) coupled to the first toe (4).

Figure 9.- shows an overview of the devices for performing biomechanical tests on the foot at heel level with the different ranges of cancellations, of 0°-5°, 6-10° and 11-15° in three dimensions (3D).

Figure 10.- shows an overview of the devices for performing biomechanical tests on the foot at the level of the first toe with the different ranges of cancellations, from 0°-10°, from 11°-15°, from 16°- 20° and 21°-40° in three dimensions (3D). Figure 11.- shows a schematic drawing in sagittal view of how both devices would look for performing biomechanical tests on the foot for the first toe (5) and for the heel (1), both coupled to the foot (4).

PREFERRED EMBODIMENT OF THE INVENTION

In view of the aforementioned figures, and in accordance with the numbering adopted, an example of a preferred embodiment of the invention can be seen in them, which comprises the elements indicated and described in detail below. Thus, as can be seen in figures 1 and 2, the kit of devices for performing biomechanical tests on the foot that is the object of the invention is made up of three pieces of 3D printed polyamide 2 mm thick folded in a range of graduations of 0°-5° (1), 6°-10° (2) and 11°-15° (3) on its flexion axis in the distal direction, which is empty on the inside. In this preferred embodiment, as can be seen in figures 1 and 2, the main body of each of the angulations, 0°-5° (1), 6°-10° (2) and 11°-15° ( 3) is complete, that is, it comprises a single piece. The polyamide has a general thickness of 2 mm, the millimeters of thickness of the lateral zone will depend on the angle of the piece, its degree of density is 1.04 g/cm3 and it is black. The piece is designed rectangular so that it covers the area of the heel of the foot (4). It should be noted that at no time will the element of the invention be used as an element of the insole, but rather it will be used in the first phase of the biomechanical study of the patient, prior to the request for the design of the orthopedic insole.

On the other hand, as can be seen in figures 5 and 6, the kit of devices for performing biomechanical tests on the foot that is the object of the invention is also made up of four pieces of 3D-printed polystyrene, the common thickness that corresponds to the step prior to the inclination is common to all measures 6 mm, the lateral thickness depends on the inclination of each of the pieces, this being different for each of the 0°-10° graduations (5), of 11°-15° (6), 16°-20° (7) and 21°-40° (8) on its axis of flexion in the distal direction. Each piece has a 50% filling inside. In this preferred embodiment, as can be seen in figures 5 and 6, the main body of each of the angulations, 0°-10° (5), 11°-15° (6), 16°-20° (7) and 21°-40° (8) is complete, that is, it comprises a single piece. The degree of density of polystyrene is 1.03 g/cm3 and it is black in color. The piece is designed rectangular so that it covers the entire area of the first toe (4). At no time will the element of the invention be used as an element of the insole, but rather it will be used in the first phase of the patient's biomechanical study, prior to requesting the design of the orthopedic insole for taking the mold through of the plantar scanner.

Claims (1)

1. Kit of devices for carrying out biomechanical tests on the foot for the prescription of personalized orthopedic insoles characterized by the fact that it comprises: - a device for carrying out biomechanical tests on the foot, made of polyamide, angular and rectangular, adjusted to fit the heel with an angulation range of 0°-5° with rounded edges, in which the main body (1) is made up for one piece, - a device for performing biomechanical tests on the foot made of polyamide, angular and rectangular, adjusted to fit the heel with an angulation range of 6°-10°, with rounded edges in which the main body (2) is made up of a single piece - a device for carrying out biomechanical tests on the foot made of polyamide, angular and rectangular, adjusted to fit the heel with an angulation range of 11°-15°, in which the main body (3) is made up of a single part, - a rectangular and angular polystyrene device for performing biomechanical tests on the foot adjusted to the size of the first toe, with an angulation range of 0°-10°, in which the main body (5) is made up of a single piece - a rectangular and angular polystyrene device for performing biomechanical tests on the foot adjusted to the size of the first toe, with an angulation range of 11°-15°, in which the main body (6) is made up of a single piece - A device for performing biomechanical tests on the foot made of polystyrene, angular and rectangular, adjusted to the size of the first toe, with an angulation range of 16°-20°, in which the main body (7) is made up of a single piece and - a device for performing biomechanical tests on the foot made of polystyrene, angular and rectangular, adjusted to the size of the first toe, with an angulation range of 21°-40°, in which the main body (8) is made up of a single piece.