The present disclosure generally relates to orthopedic devices, particularly to orthopedic shoes for improving stability of a foot during standing and/or ambulation.
When a person ambulates or walks, the foot first lands in a supinated position and then moves to a more pronated position to absorb the shock of contacting the ground. The pronated phase is followed by a final supinated phase, in which the foot pushes off into the next stride. In the pronation phase, the foot contacts the ground, and then the arch lowers to act as body's shock absorber. In the supination phase, the bones in the foot form a rigid lever to push off into the next step.
Pronation involves rotation of a joint or part in a forward direction or toward the midline of the body, while supination involves rotation of a joint or part in an outward direction or away from the midline of the body. When a person over-pronates or places too much force on the inside of a foot, excessive mobility of the medial arch area of the foot can result. A foot that stays pronated throughout the walking stance is inefficient at propelling the body forward. The instability resulting from over-pronation can lead to arch, foot, ankle, and/or leg pain, as well as postural problems due to excessive internal rotation of the leg. To propel the body forward in an efficient manner, the foot would supinate in late midstance and become rigid with the joints assuming a closed packed position.
In order for normal pronation and supination to occur, there needs to be proper motion of the big toe joint (first metatarsal phalangeal joint), (MTPJ) in extension as one moves forward through the foot normally in the course of ambulation. If this motion is blocked by an abnormally stiff shoe, or improper osseous and ligamentous alignment in the feet, the normal function of the foot will be disrupted. The foot will also not engage the windlass mechanism. This mechanism provides for the plantar fascia to help to accentuate the medial longitudinal arch and provides stability of the forefoot in propulsion. This is necessary for normal foot function.
While orthopedic appliances are effective means for correcting improper pronation and supination, there are still various limitations to the orthopedic appliances.
This summary is provided to introduce a selection of concepts that are further described below in the detailed description. This summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended to be used as an aid in limiting the scope of the claimed subject matter.
In one aspect, embodiments of the present disclosure are directed to an orthopedic shoe that includes a shoe having an upper and a sole, the upper having a multi-compartment toe box at a forefront of the shoe, the multi-compartment toe box including a separate compartment for the big toe; and an elevating portion in an interior of the shoe extending from the sole towards the upper at a location corresponding to a big toe.
In another aspect, embodiments of the present disclosure are directed to an orthopedic shoe that includes a shoe having an upper and a sole; and an elevating portion in an interior of the shoe extending from the sole towards the upper at a location corresponding to a big toe, wherein an outsole of the sole has a groove formed therein at a location corresponding to a base of the elevating portion which contacts the sole at the location where the big toe bends.
In another aspect, embodiments of the present disclosure are directed to an orthopedic shoe that include a shoe having an upper and a sole; and an elevating portion in an interior of the shoe extending from the sole towards the upper at a location corresponding to a big toe, wherein the upper comprises a toe box, and wherein the toe box has a peak height above the sole at a location above the elevating portion.
Other aspects of the invention will become evident from the following drawings and description.
Embodiments of the present disclosure relate to orthopedic shoes for improving stability of a foot during standing and/or ambulation. In accordance with one or more embodiments, an orthopedic shoe may comprise a shoe having an upper and a sole; and an elevating portion in an interior of the shoe extending from the sole towards the upper at a location corresponding to a big toe. Conventional orthopedic appliances that fit under the big toe cannot fit in certain shoes. In particular, incorporation of the appliance into a shoe may require modification of the shoe toebox to accommodate the elevated big toe. Further, when an insole is placed inside a regular shoe, the upper of the shoes, over time, will be worn out due to the excess pressure on the big toe and toenail from the elevated big toe. Moreover, most shoes have rigid outsoles. When such shoes have insole placed inside, they would result in uncomfortable walking. Therefore, current shoes cannot satisfy these requirements and have a lot of disadvantages. Thus there is a need for development of an orthopedic shoe for efficiently and easily correcting improper pronation and supination.
Referring now to the drawings, and more particularly
Shoe 1 to be worn by a foot 5 includes a sole 20 and an upper 30 attached to the sole 20. Shoe 1 also includes an elevating portion or wedge 10 configured to elevate the big toe 40 of foot 5. Thus, the wedge 10 is located in an interior of the shoe 1 extending from the sole 20 towards the upper 30 at a location corresponding to a big toe 40. The wedge 10 provides a means to elevate the big toe up 40 from the top surface 50 of the sole 20 and thus up from the floor. In one or more embodiments, sole 20 may include an insole 24, a midsole 26 and an outsole 27. Further, it is understood that insole 24 may optionally be removable from shoe 1. In one or more embodiments, wedge 10 may be a part of insole 24, for example, a removable insole 24 shown in
The overall length and the overall width and overall height of the wedge 10 can vary dependent upon the individual big toe 40 to be elevated. The wedge 10 may function to stabilize the first metatarsal against ground reactive forces and limit the displacement of the first metatarsal upward. Thus, when a person is wearing the shoe of the present disclosure, the first metatarsal will plantarflex more easily through the terminal midstance and active propulsive phases of gait. By placing the plantar aponeurosis on stretch, there will result a retrograde effect at stabilizing the joints more proximally referred to as the first ray, midtarsal joint and the subtalar joint with improved joint congruity and alignment of the foot in relationship to the leg during ambulation. When the first metatarsophalangeal join is able to dorsiflex 20-30 degrees, normal plantarflexion of the first metatarsal is possible. As further dorsiflexion occurs, further plantarflexion of the first metatarsal is possible, and additional stability of the foot is achieved. Therefore, the degree of dorsal displacement of the toe will dictate the stability of the foot desired and can be changed depending on the foot type or activity being performed. In some situations, a more compliant foot may be desirable, and in others a more stable foot may be required, particularly as related to athletic performance. The wedge 10 will allow for as much elevation of the big toe as desired
The relation between the sole 20 and the wedge 10 is defined by an angle y, which may most easily be measured by comparing a plane at the surface of sole 20 under the second to fifth toes relative to the surface of wedge 10 under the big toe. The angle y may be in the range of from 3-90 degrees for normal ambulation. The angle y can be either increased or decreased depending upon the amount of correction desired for the specific activity and the heel height of the shoe, for example.
In
The relation between the sole 20 and the lever 112 of the cam mechanism 111 is defined by an angle, which may be in the range of from 3-90 degrees for normal ambulation. The angle can be either increased or decreased depending upon the amount of correction desired and the heel height of the shoe.
The relation between the sole 20 and the plate 122 is defined by an angle that may range of from 3-90 degrees for normal ambulation. The angle can be either increased or decreased depending upon the amount of correction desired and the heel height of the shoe.
As shown in
In one or more embodiments, as shown in
Referring now to
While the invention has been described with respect to a limited number of embodiments, those skilled in the art, having the benefit of this disclosure, will appreciate that other embodiments that do not depart from the scope of the invention as disclosed herein can be devised. Accordingly, the scope of the invention should not be limited only by the attached claims.
Number | Date | Country | |
---|---|---|---|
62679512 | Jun 2018 | US |