The embodiments herein relate generally to devices and processes that relate to equine hooves. The domesticate horse has many lameness issues relating to their hooves. These issues will impact their soundness, movement and performance. The horse can suffer from soft soles, medial and lateral imbalance, laminitis, tubular density, founder, navicular, sinking coffin bone, negative plane coffin bone, ring bone, side bone and shod to barefoot transitions. These issues can stem from the repetitive concussion of the hoof. As the hoof initiates contact with the ground elastic deformation begins to change the hoof in the shape and size due to an applied force. The elastic deformation energy is transferred through weight and movement of the horse. Compressive stresses are generated on the hoof tissue. Compressive stress will be applied to both external and internal structures. The ground will be applying forces upwards while the bony column and gravity will be all applying forces downwards. Compressive stress will be absorbed by the hoof bone and the specific hoof tissue structures in between. All of these structures have a yield point or yield strength. As used here, the yield strength or yield point of a material is as the stress at which a material begins to deform plastically, where plastically is the propensity of a material to undergo permanent deformation under load. Prior to the yield point, the hoof will deform elastically. When an applied stress is removed, the tissue returns to its original state. Once the yield point threshold is surpassed, some fraction of the deformation will be permanent and could be irreversible. As the horse approaches the yield point instability occurs prior to hoof failure. In particular, buckling is characterized by a sudden failure of structural hoof tissue subjected to high compressive stress where the actual compressive stress at the point of failure is less than the ultimate compressive stresses that the hoof structure is capable of withstanding.
During movement the horse reacts to input from its external environment. One such input is the vertical ground reaction force (GRF), which occurs during the ground contact phase of each foot. The impact forces that occur at heel strike of the hoof are transmitted to the foot structures both externally and internally. The repetitive mechanical loading creates mechanical waves. During ideal loading condition of the external structures of the foot, (frog, sole and horn are in contact with the ground) patterns of distribution of stimulus created by the mechanical wave. The initial energy input will travel through the structures until all the energy it transferred. This energy transfer consequence is stimulation. Stimulation is mandatory for optimal foot support, health, and function. Typically, these conditions do not exist for the domesticated horse to initiate this energy transferred progression. When the external foot components experience a decrease in ground contact, both external and internal failure commences.
To reverse the lack of ground contact with the structures on the bottom of the foot, a material with the characteristics of the bone must be applied to bottom of the foot to reestablish communication. This material will create pillars or the abutment in the collateral groove to supports the frog ligaments which allow the blood vessels to fill properly. The filling of the blood vessels act like an inner tube to support the hoof structures thus providing support to the ligaments.
The material applied to the hoof must replicate the bone in hardness and porosity. However, horseshoes create mechanical waves and frequencies dissimilar then bone waves and frequencies. The horseshoe applies its loading to the peripheral of the hoof capsule. The hoof capsule does not contain bone. In addition, the horseshoe frequencies produced during impact will hinder all blood vessel function for an extended period of time. Hence, lack of support to foot. The prior art includes: U.S. Patent Application 2010/0288515 issued to Rovelli; U.S. Pat. No. 6,021,851 along with U.S. Pat. No. 6,412,566 and U.S. Patent Application 2009/0173288 issued to Jacobs (collectively Jacobs);
Rovelli teaches using a pad between the horse shoe and the hoof to reduce shock. This creates a weight loading issue that can still result in lameness and is not likely or alleged to resolve existing lameness. Jacobs teaches a composition of matter that is too soft to have a therapeutic effect.
An equine bony column and tissue support is configured to prevent or treat lameness in a hoof of a horse where the lameness is based on a bony column dysfunction or instability. The equine bony column and tissue support includes a hoof bridge which includes a composition of matter with a hardness between Shore A Durometer of 85 and a Rockwell K of 150 bonded to the hoof. The composition of matter provides central loading support that redistributes weight from a perimeter of an outer hoof horn to the bony column and bony tissue to stabilize and realigns the bony column.
In some embodiments, the hoof bridge is applied evenly to a full application area. In other embodiments, the hoof bridge is applied in a stacked configuration at various thicknesses across a toe application area, a left quarter application area, a right quarter application area and a frog application area. The composition of matter can include a methacrylic acid, a methyl methacrylate monomer, a chlorosulfonated polyethylene and a carbon tetrachloride that is self-leveling.
The detailed description of some embodiments of the invention is made below with reference to the accompanying figures, wherein like numerals represent corresponding parts of the figures.
By way of example, and referring to
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Rovelli argued for using a rubber layer between horse shoe 14 and hoof 10, however that led to a number of problems. For instance, there was no uniform loading distribution. Rather, the loading was on the outer hoof horn. This could lead to mechanical laminitis by using dynamic loading to push outer hoof wall 70 from coffin bone 58.
Hoof bridge 12 provides uniform load distribution (ULD) and structural support to the bony column and hoof structures by incorporating a non-deforming structural adhesive to produce superior strength and support greater than the present hoof tissues. A large spectrum of materials can accomplish this function as shown in
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By way of example, the rotation of coffin bone 58 away from hoof wall 70 puts an irregular strain on the union between the hoof wall 70 and the sensitive laminae 72. This can cause Ischemia-reperfusion injury by having too much or too little blood flow to laminae 74. Hoof bridge 12, resolves this problem by centrally loading external and internal hoof structures. In particular, hoof bridge 12 provides central loading support that redistributes the weight from the perimeter of the outer hoof horn 30 to the bony column 58, 62, 64 and the bony tissue 22, 36, 38, 68 to stabilize and realigns the bony column 58, 62, 64. This self-leveling composition of matter regulates blood profusion by realigning and replicating bone matter eliminating the irregular strain on outer hoof horn 30.
To use the invention, the user first performs an initial examination of hoof 10. The user should take a photograph to the condition of hoof 10. Next, the user documents physical dimensions of hoof 10. This can be useful in determining which hoof bridge 12 is necessary. The user then balances hoof 10 and prepares for application of hoof bridge 12. The user should obtain additional data on hardness and condition of the hoof as necessary.
After this, the user cleans and removes dirt and debris from hoof 10. The user then utilizes increased temperature to assist and reduce moisture content of the hoof. If necessary the user trims and cleans any bacteria tracks. The user can then preserve a sanitized environment and prepare to begin the process.
The user can then commence application of hoof bridge 12 to toe application area 50, left quarter application area 52, right quarter application area 54 and heel/frog application area 56 or any combination of. The user should mix thoroughly depending on bonding material or materials selected and the set time will be between 1-16 minutes. This includes applying hoof bridge 12 material to sole 36 by pushing both plungers on the cartridge evenly to dispense equal amounts of adhesive and activator. The user should start at apex of the frog 26 begin to outline coffin bone 58 with material. The user must complete mixing and spreading hoof bridge 12 within the set time after which point, hoof bridge 12 is bonded to hoof H. In some embodiments, it may be best to focus the application of the hoof bridge 12 material in the concavity of sole 36.
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Of those materials, the following composition of matter is offered as one embodiment of an effective composition of matter. The composition of matter comprises 5-10% methacrylic acid by weight, 30-60% methyl methacrylate monomer by weight, 30-60% chlorosulfonated polyethylene by weight, and less than 1% carbon tetrachloride by weight. The composition of matter should be self-leveling.
Persons of ordinary skill in the art may appreciate that numerous design configurations may be possible to enjoy the functional benefits of the inventive systems. Thus, given the wide variety of configurations and arrangements of embodiments of the present invention the scope of the invention is reflected by the breadth of the claims below rather than narrowed by the embodiments described above.
This application is a divisional application of U.S. Ser. No. 14/019,753, filed on Sep. 6, 2013, which claims priority to provisional patent application U.S. Ser. No. 61/697,995 filed on Sep. 7, 2012 and U.S. Ser. No. 61/700,834 filed on Sep. 13, 2012, the entire contents of which applications are herein incorporated by reference.
Number | Date | Country | |
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61697995 | Sep 2012 | US | |
61700834 | Sep 2012 | US |
Number | Date | Country | |
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Parent | 14019753 | Sep 2013 | US |
Child | 14870945 | US |