The embodiments disclosed herein relate generally to prosthetics, and more specifically, to blade shape and base plates for blade-type leg prosthetics.
A variety of prosthetics and limb enhancements have been developed for both aesthetic and functional needs, including leg prosthetics and enhancements to aid wearers in activities such as walking, performing job functions, and playing sports. One group of leg prosthetics in this category includes trans-tibial prosthetics, often referred to as below the knee (BK) leg prosthetics. These have come to include blade-type leg prosthetics, also known as “flex-foot cheetah” prosthetics, for athletic use. Although blade-type leg prosthetics are otherwise satisfactory, wearers of blade-type leg prosthetics may desire improvements in how force is transferred to a ground surface when performing activities.
In one aspect, a blade for a blade-type prosthesis assembly comprises a blade body extending between a blade bottom and a blade top. The blade top is securable to a socket for a limb and the blade bottom defines a convex surface formed by at least one edge of the blade bottom curving toward the blade top.
In another aspect, a base plate for a blade-type prosthesis assembly comprises a base plate top surface securable to a blade bottom of a blade body. The blade body extends from the blade bottom to a blade top securable to a socket for a limb. The base plate further includes a base plate bottom surface opposing the base plate top surface and a plurality of ground-engaging elements extending from the base plate bottom surface.
In another aspect, a blade-type prosthesis assembly comprises a blade body extending between a blade bottom and a blade top. The blade top is securable to a socket for a limb. The assembly further includes a base plate comprising a base plate top surface securable to the blade bottom, a base plate bottom surface opposing the base plate top surface, and a plurality of ground-engaging elements extending from the base plate bottom surface.
These and other aspects will be discussed in additional detail below.
The description herein makes reference to the accompanying drawings wherein like reference numerals refer to like parts throughout the several views, and wherein:
Blade designs and base plates for blade-type leg prosthetics are disclosed herein. The blade or the base plate may include a curved and/or contoured bottom surface to aid in lateral movement. Such blade and base plate designs may allow for improved transfer of energy from a wearer to a ground surface. The base plate may be removable and may be adapted to flex or change orientation as the blade is deformed. The base plate may also include a bottom surface design with various gripping features such as spikes, cleats, cups, nubs, grooves, or scoops in a pattern and location configured to optimize the use of the blade-type leg prosthetic depending on the wearer's activity.
As used herein, the terminology “prosthesis” or “prosthetic” may indicate any artificial limb or limb enhancement, including upper extremity enhancements, lower extremity trans-tibial and trans-femoral prostheses, or other lower extremity enhancements. The non-limiting examples disclosed herein describe blade-type leg prosthetics, but it is contemplated that the features described may be utilized with a variety of prosthetics or enhancements known to those skilled in the art.
Blade 102 may include blade bottom 108, a first inflexion 112, a second inflexion 114, and blade top 116. Blade inflexions 112, 114 may allow blade 102 to compress when a load is applied in certain directions. For example, blade 102 may compress and expand during walking or running. Blade 102 may be constructed from a variety of natural or synthetic materials capable of withstanding forces associated with walking, running, or other wearer activities, such as metal, rubber, and polymer. For example, blade 102 may be made out of a carbon fiber reinforced polymer. Blade 102 may be used either with or without base plate 104.
Base plate 104 may be fixedly attached to blade 102 at a blade bottom 108 or may be capable of being removably attached and detached using a variety of attachment components. For example, base plate 104 may be attachable to blade 102 using an adapter (described below), sliding engagement, bolts, clips, pins, screws, adhesive, or straps. In the example shown in
Removable and interchangeable base plates 104 may allow a wearer to customize prosthesis assembly 100 depending on the wearer's activity type and/or the ground surface characteristics experienced by the wearer during the activity. Further discussed below, base plate 104 may have a bottom surface 110 including shapes and structures designed to provide a desired interaction with the ground surface for a specific activity. Further, base plate 104 can include a hook 192 providing attachment means for a garment or serving as a retaining means for storage of base plate 104.
Socket 106 may include an open socket top 118 and a closed socket bottom 120. Socket 106 may be substantially hollow, having a uniform or varying thickness. Socket top 118 may be sized accordingly to receive at least a portion of a wearer's limb. Socket 106 may be attached to a wearer during use through a variety of methods. In some embodiments, friction based attachment features may be used such as straps or clips configured to attach to a garment on a wearer. In some embodiments, suction based attachments may be utilized, such as a sock or sleeve designed to extend over socket 106 and a wearer's limb. For example, a method of attachment may include a wearer placing socket 106 at the end of a limb and attaching socket 106 by pulling a compression sock over socket 106 in a direction from socket bottom 120 to socket top 118 and onto the wearer's limb.
In some embodiments, socket 106 may be attachable to blade 102 at blade top 116 using socket attachment members 122. For example, attachment members 122 may be pins or bolts configured to extend through apertures defined in blade top 116. Socket 106 may be constructed out of any natural or synthetic material capable of substantially retaining its shape, such as metals and polymers. For example, socket 106 may be formed from carbon fiber reinforced polymer and may be formed in a custom shape to match a particular wearer's partial limb.
In the example shown in
In addition to twisting, front and rear surfaces of blade 102 may bend, angle, or curve. For example, blade top 116 of blade 102 may curve such that front and rear surfaces produce concave shapes facing a forward and outer direction. This may be best illustrated by the curve in blade top 116 shown in
In addition to curves or twists located near blade top 116, blade 102 may include convex portion 302 at blade bottom 108. Convex portion 302 may be formed by lateral edges of blade bottom 108 curving away from a bottom most portion of blade bottom 108 toward blade top 116. Convex portion 302 may allow blade 102 to have increased contact portions with a ground surface when blade 102 is angled when positioned against the ground surface. In other words, blade bottom 108 having curved convex portion 302 may mimic the human ankle which provides rotation for proper planting of a foot into the ground regardless of the impact angle. This may allow blade bottom 108 to have enough friction and surface area to be used in prosthesis assembly 100 with or without base plate 104.
In the examples of
In some embodiments, blade 102 may be shaped such that axis B does not lie in a common plane. Instead, blade bottom 108 extends further in a lateral direction than blade top 116. That is, blade 102 may be shaped such that the blade bottom 108 may angle either inward or outward in relation to an opposing leg or prosthetic to, for example, improve balance during use. Midpoints of the blade bottom 108 and the blade top 116 are thus spaced from a vertical axis C extending through a midpoint of the blade body during use of the blade-type prosthesis assembly. For example,
The specific optimized shape of the blade 102 for a given wearer may be determined using a computer-based method. In some embodiments, a model is created to represent prosthesis assembly 100 for a wearer. Variables such as length of blade, movements required, particular ground surfaces and a walking or running pattern of the wearer may impact the design of the blade 102. For example, a computer-based model may be created for a wearer that includes simulated walking and running. It may be determined what contours, twists, and concave and convex portions would be ideal for the particular application.
It is contemplated that different shapes and material selections for the base plates may be useful to illicit different desired interactions with the ground surface. In some embodiments, the base plates may be interchangeable depending on the ground surface and wearer activity. For example, ground surfaces such as uneven terrain, tile, carpet, sand, mud, gravel, grass, turf, dirt, rocks, hard track, soft track, and pavement all have unique surface characteristics and certain base plate designs may be chosen for the particular application.
In some examples, such as the embodiments shown in
In some embodiments, such as the embodiment shown in
In some embodiments, such as the embodiments shown in
In some embodiments, such as the embodiments shown in
Ground-engaging elements 404 may be fixed or may be removable, such as through a threaded interaction with the bottom surfaces of the base plates or other attachment means. Ground-engaging elements 404 may be formed from a variety of materials, such as metals and polymers. Ground-engaging elements 404 may be formed in a variety of shapes and sizes. For example, ground-engaging elements 404 may be spikes or nubs as in
In some embodiments, such as the embodiments shown in
In some embodiments, top surfaces of the base plates may be shaped to interface, for example, with a substantially flat surface such as is present on blade bottom 206 of blade 200 or with a convex surface such as is present on blade bottom 108 of blade 102. The top surfaces of the base plates may also be designed such that an adapter, such as the adapters described below in reference to
As illustrated in
The basic structure of base plate 500 may vary depending on the particular application, and several natural and synthetic materials known by those skilled in the art may be used. In some embodiments, base plate 500 may be at least partially formed from natural rubber, polyurethane, or polyvinyl chloride (PVC) compounds. Different portions of base plate 500 may have different material characteristics. For example, first and third layers 502, 506 of base plate 500 may be composed of high durometer polymer or rubber to ensure durability, while second layer 504 may be less dense or formed of lower durometer foam to cushion or absorb energy resulting from impacts with a ground surface. The durometer of the various layers 502, 504, 506 can vary depending on the activity for which the base plate 500 is designed.
It is contemplated that the shape and structure of base plate 500 may vary depending on application. In some embodiments, second layer 504 may include gaps, channels, spaces, apertures, or other voids to reduce weight or increase compliance or cushioning. For example, second layer 504 may comprise a collection of conically shaped stems 520 extending from third layer 506 to first layer 502. In some embodiments, a bottom surface of base plate 500 may be non-planar, curved, or angled. For example, the bottom surface of base plate 500 may follow the contour of either blade 102 or blade 200. In some embodiments, the bottom surface of base plate 500 may be curved or angled in lateral directions as well.
Adapter top surfaces 608, 610 may be generally flat surfaces such that edges of adapter top surfaces 608, 610 lie within an adapter top surface plane. The adapter top surface plane may follow the contour of front face 202 of blade 200 in the case of adapter 600 or rear face 204 of blade 200 in the case of adapter 602. Have generally flat adapter top surfaces 608, 610 allows for ease of attachment to the generally flat front face 202 or rear face 204 of blade 200.
Adapter bottom surfaces 612, 614 may be convex surfaces formed by the edges of the adapter bottom surfaces 612, 614 curving toward blade top 208 of blade 200 during use of the prosthesis assembly 100. Having generally flat adapter top surfaces 608, 610 and generally curved or convex adapter bottom surfaces 612, 614 allows adapters 600, 602 to be used to affix curved or convex base plates 604, 606 to generally flat blade 200.
Adapters 600, 602 may be affixed to blade 200 using a variety of attachment elements 616. In
The above-described embodiments have been described in order to allow easy understanding of the invention and do not limit the invention. On the contrary, the invention is intended to cover various modifications and equivalent arrangements included within the scope of the appended claims, which scope is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structure as is permitted under the law.
This application claims priority to U.S. Provisional Application Ser. No. 62/036,835 filed Aug. 13, 2014, U.S. Provisional Application Ser. No. 62/036,837 filed Aug. 13, 2014, U.S. Provisional Application Ser. No. 62/036,840 filed Aug. 13, 2014, U.S. Provisional Application Ser. No. 62/036,842 filed Aug. 13, 2014, and U.S. Provisional Application Ser. No. 62/036,843 filed Aug. 13, 2014 which are all incorporated herein by reference in their entirety. This application is related to co-pending application Ser. No. 14/824,386 filed Aug. 12, 2015 (Attorney Docket No. AEI-390-B) entitled “BLADE SHROUD DESIGN FOR A LEG PROSTHETIC” and to co-pending application Ser. No. 14/824,419 filed Aug. 12, 2015 (Attorney Docket No. AEI-392-B) entitled “SUIT DESIGN FOR A LEG PROSTHETIC” which are both incorporated herein by reference in their entirety.
Number | Date | Country | |
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62036835 | Aug 2014 | US | |
62036837 | Aug 2014 | US | |
62036840 | Aug 2014 | US | |
62036842 | Aug 2014 | US | |
62036843 | Aug 2014 | US |