Dynamic orthosis for foot drop

Abstract

Dynamic orthosis for drop foot, with a vertical flat, rigid bar connected to a collar of a patient's leg, and whose lower free end is connected to a bearing which is positioned in front of the internal malleoulus of the user and to constitute the joint of a cantilevered arm whose free end is connected to a bracket for the foot, and whose motion required for lifting the foot during deambulation is obtained by the force generated by a magnetic spring with the interposition of a rod, wherein the required lifting force are produced by a plurality of magnets, vertically aligned in a cylindrical sheath, and with the same polarity being juxtaposed to allow using their mutual repulsive forces.

Claims

1. A dynamic orthosis for treatment of a drop foot of a wearer, comprising: a flat, vertically oriented bar; a collar adapted to extend about a wearer's leg, wherein an upper end of the bar is connected to the collar; a rolling bearing, wherein a lower end of the bar is connected to the rolling bearing; an arm; wherein the rolling bearing is adapted to extend in a vertical plane proximate to a surface of a malleolus of the wearer's leg, and forming an articulation with the arm extending in a plane parallel to that of the bar and oscillating in both directions; a flat, horizontally oriented bracket; wherein the arm is connected to the bracket and is operable to lift the drop foot from below by a clockwise rotation of the arm thus lifting up the bracket; a magnetically moveable spring whose lifting force Fs is obtained by a plurality of magnets, each of the magnets being equal to each other and having a same juxtaposed polarity; and wherein the magnetically moveable spring comprises: a cylindrical sheath articulating with an upper portion of the bar by means of a first bush, wherein the plurality of magnets are contained completely within the cylindrical sheath; and a piston vertically movable on top of a rod articulating with the rolling bearing by means of a second bush.

2. The orthosis according to claim 1, wherein forced movement of each of the magnets close to each other for obtaining loading of the magnetically moveable spring is operated by the wearer through his or her leg with drop foot and body weight upon a final stage of a step, that is, with a foot under compression onto the ground.

3. The orthosis according to claim 1, wherein the lifting force Fs is in its release stage upon a foot detachment from the ground, increases with an acceleration 50 times less than that of a steel spring and allows the foot to be lifted in a physiologic manner.

4. The orthosis according to claim 1, wherein the rod of the magnetically moveable spring is provided with an adjustment element.

5. The orthosis according to claim 1, wherein the bracket is adapted to extend over a length not including toes of a foot, a lifting of the toes during walking being provided by an insole superimposed to the bracket and made up of a polyethylene lamina extending throughout a sole of the foot.

6. The orthosis according to claim 1, wherein the bracket is adapted to extend over a foot's whole length and is molded in nylon, with sections of various thickness or formed with different operating modalities so as to result in being rigid on a back foot and midfoot portion of the foot, but elastic on a forefoot portion of the foot.

7. The orthosis according to claim 1, wherein the lower end of the bar is provided with a disc of soft-elastic material that is adapted for protection of the malleolus.

8. The orthosis according to claim 1, wherein the collar is adapted to be fixed to the wearer's leg, above a calf portion of the leg, by automatic means.

9. The orthosis according to claim 1, wherein the arm and bracket for the drop foot are of such dimensions as to allow introduction thereof into a shoe.

Description

DETAILED DESCRIPTION OF ONE EMBODIMENT OF THE INVENTION

(1) The orthosis of the present invention is shown for reference in the accompanying drawings, wherein:

(2) FIG. 1 is an ensemble front view of the orthosis in the state of use;

(3) FIG. 2 is a vertical section taken on line A-A of FIG. 1;

(4) FIG. 3 shows the primary joint for moving the foot;

(5) FIG. 4 shows the orthosis with the bracket in a state of maximum lifting;

(6) FIG. 5 shows the elastic device;

(7) FIG. 6 shows a diagram of the elongation curve of a magnetic spring comprised in the device of the invention;

(8) FIG. 7 shows a diagram of a elongation curve of a standard steel spring.

(9) Reduced to its essential construction, the orthosis comprises: a vertical, substantially flat bar (1), whose upper end (10) is anchored to a collar (2) to be fastened by common automatic means to the leg (3) above the user's calf, and fixed to the lower end of said bar is a rolling bearing (4) to which a flat cantilevered arm with curvilinear profiled arm (5) is hinged to be oscillated perpendicular to the leg at the level of the internal malleolus, that is, the protuberance belonging to the tibiotalar of the foot and projecting from the leg up to a higher and forward position with respect to the external malleolus.

(10) More particularly, said bar (1) exhibits its lower part (11) integral to the fixed part (4a) of the bearing (4), has a decreasing width as it gets closer to the bearing (4), and is provided with a disc of soft-elastic material (14) for the protection of the malleolus (30). Moreover, said arm (5) has its upper end (52) shaped as a zee projecting transversally from the arm (5) and intended for connection with the rotating part (4b) of the bearing (4), while its lower end (53) is integral to the bracket (8) for a user's foot and forming a right angle therewith.

(11) In particular, said bracket (8) extends lengthwise only for the region of the hind-foot and mid-foot, thus leaving the toes free, the elastic lifting of the latter being adequately provided by a polyethylene lamina (80) extended throughout the sole of the foot and fixed to the bracket (8).

(12) Alternatively, said bracket (8) is possibly made of nylon by molding, for example, along the whole length of the foot, with sections of different thickness or made by different operating modes so as to result rigid in the region of hind-foot and mid-foot but elastic in the region of the toes.

(13) In addition, the bracket (8) can be extended up to partially wrap the heel and the outer side of the foot. In this way the bracket houses the foot and is better bound to it with advantages for the comfort of the orthosis.

(14) Moreover, in addition to the collar (2), further fastening means for fastening the orthosis to the leg could be provided. For instance, for some spastic paralysis a VELCRO fastening member can be arranged at the level of the ankle.

(15) Obviously, this kind of devices have to be light-weighted and comfortable to wear, so in preferred embodiments of the invention the various members, such as the flat bar (1), the rolling bearing (4), the profiled arm (5) and the bracket (8) are shaped and sized so as to be as far as possible not bulky and weighty. In this view also the material of the above members becomes important and it is preferably chosen among composite materials such as materials of carbon fiber.

(16) The elastic device (9) used for the present orthosis is a magnetic spring which utilizes the repulsion force of a plurality of magnets whose total magnetic field is equal, according to the principle of superimposition of effects, to the sum of the individual magnetic fields.

(17) More in particular, and reference being made to the accompanying drawings, said magnetic spring comprises:a cylindrical sheath (90) articulated on top by means of an extension (91) and a bush (102) of bar (1), made of any non-ferromagnetic material, and intended to hold a plurality of magnets (92) equal to each other, piled up with the same juxtaposed polarity and suitably spaced apart, which magnets have the function of generating the force Fs necessary to lift the drop foot during the ambulation: their subsequent loading being achieved by a forced mutual approach, during the same ambulation, through a piston (93) axially movable within said sheath and disposed on top of a rod (94) coming out of the bottom of the sheath and being in turn articulated to the bush (51) of said arm (5) with the interposition of an adjustment element (95) having the length of the rod (94).

(18) The Operation is as Follows

(19) The approach phase of magnets (92) takes place when, during walking, at the end of each step, the patient's foot is in the compression phase onto the ground, which corresponds to the maximum moment onto the malleolus (30).

(20) In this state, the rod (94) and the piston (93) therewith will cause a compression for the mutual approach of magnets (92) (FIG. 1).

(21) The subsequent elongation phase, that is, the mutual and spontaneous moving of the magnets away from each other, takes place as soon as the patient's foot is detached from the ground, that is, when the moment on the malleolus is minimum. In this state, the arm (5) forced by the rod (94) to rotate clockwise, lifts up the bracket (8) along with the foot (FIG. 4).

(22) Technical Characteristics of the Magnetic Spring

(23) The magnetic spring of the elastic device (9) is made up of 13 disc-shaped magnets (92) having a diameter d=12 mm and thickness s=6 mm, and intended to exert a magnetic force Fm=3900 g in order to provide a lifting force F.sub.SO=2600 g for the drop foot corresponding to the sum of Fp (weight of the foot)+Fs (weight of the shoe)+Fm (weight of the muscle component)+Fo (weight of the orthosis).

(24) Said magnets are obtained in the axial magnetization direction from a material of neodymium-iron-boron by sinterization of N 48 quality. For a fine adjustment of the lifting force, Fso, the element (95) allows varying the useful length of the rod (94), thereby varying the distance of the magnets from each other.

(25) The elongation curve of said magnetic spring is shown in FIG. 6.

(26) By comparing it with the curve relevant to the elongation of a steel spring, shown in FIG. 7, and comparing the 10 units of time of this figure with the travel in mm of FIG. 6, it can be observed that, while in the steel spring, 60% of the release force takes place in 1/100 of unit of time, in the present magnetic spring the same 60% of Fs which lifts the drop foot takes place in half the unit of time and, therefore, with an acceleration which is 50 times lower.

(27) This is the reason why the lifting movement of the drop foot obtained by the present orthosis results truly physiological.