How To Repair A Quarter Crack

Editor's Note: The following is reprinted with permission of the author from the 2001 American Association of Equine Practitioners Convention Proceedings. To view reference images, click here.

A successful quarter crack repair should be simple, strong, safe to apply, and durable. The cause of the crack must be addressed to prevent recurrence.

Quarter cracks are a common cause of foot lameness and/or decreased athletic performance in race and sport horses. They typically originate at the coronary band and continue distally (downward). A true quarter crack is full thickness, meaning it extends into the dermis of the hoof, and often leads to instability, inflammation, and/or infection. Quarter cracks can be painful due to infection and/or the instability caused by movement of the hoof wall posterior to (behind) the crack. Vertical movement of the heel bulb on the affected side further complicates this instability. Causes of quarter cracks include trauma to the coronary band, pre-existing damage to the corium from infection, abnormal hoof conformation (especially the long-toe, underrun-heel foot), focal foot imbalances (such as a sheared heel), short shoes, or an abnormal landing pattern when the foot strikes the ground.

Often the problem facing equine practitioners is that many horses that develop quarter cracks must continue to perform. For this to occur, the repair must provide strength and stability to the hoof wall defect, which allows the horse to perform without pain while the quarter crack heals. Various techniques for repairing hoof cracks have been described. They include corrective shoeing, stabilizing the crack by placing implants across the defect, and covering the crack with an acrylic material 1,2,4,7. This report describes a simple, consistent method of repairing a quarter crack that, when combined with appropriate shoeing, gives superior stability.

Correct the Cause

For a successful repair, it is necessary to determine the underlying cause of the quarter crack and to correct it where possible. Horses with long-toe underrun-heel foot conformation appear to be prone to quarter cracks. This type of heel might be weak due to insufficient hoof wall growth and there might be insufficient solar surface to adequately support the rear part of the foot. In addition, there could be increased pressure in the quarter and heel during the stance phase as a result of delayed breakover caused by the long toe.

On the other hand, upright hoof conformation with high heels promotes heel first landing, which increases pressure through the heels and quarters, often leading to a hoof wall defect.

Short shoes leave the heels unsupported and put the weight-bearing surface in front of the vertical axis of the limb. In such instances, a vertical line drawn from the origin of the quarter crack will invariably coincide with the end of the shoe (Figure 1). The use of an aluminum plate with a toe grab as used in racehorses raises the toe, creating a broken-back hoof-pastern axis. This would also appear to increase the pressure in the posterior part of the foot.

Of utmost importance is the landing phase of the stride. Many horses will contact the ground asymmetrically, impacting first on one side of the hoof, then loading the opposite side. This strike pattern is generally related to conformation, but it can also be caused by inappropriate trimming. This type of stride might place excess forces on one side of the hoof wall of the one that lands first, causing the heel bulb to displace proximally, creating a sheared heel (Figure 2). Quarter cracks usually occur over the point of compression. This is the point where the coronary band is deviated proximally (upward) and generally contains the most shear within the hoof wall 3. The landing pattern coupled with abnormal foot conformation can perpetuate quarter cracks caused by trauma to the coronary band or a previous submural hoof abscess.

When infection is present, it is characterized by marked lameness, pain on palpation, and a swollen, discolored coronary band above the defect. Occasionally, exudate can be expressed when digital pressure is applied to the coronet. If infection is present, the crack should be opened and bandaged with 2% iodine (or a similar disinfectant agent) for at least 48 hours before the repair.

Before beginning the quarter crack repair, the shoes should be removed and the feet trimmed appropriately. In horses with long-toe underrun-heel conformation, attempts to move the breakover back is helpful. The hoof wall is lowered, if possible, from the quarter to the heel on the affected side 2. Lowering the hoof wall of the quarter and heel beneath the quarter crack will decrease the amount of load when the foot strikes the ground.

When starting the repair, the hoof wall should be thoroughly cleaned and dried. The quarter crack is explored its entire length using a Dremel tool a with a tungsten carbide bit, being careful (especially near the coronary band) not to create any unnecessary hemorrhage. All loose, undermined horn should be removed from the crack as this undermined horn lacks mechanical strength and can lead to secondary cracks. The hoof surface on either side of the defect should be sanded using the Dremel tool with a coarse grit drum sander. Two sets of paired 3164-inch holes one-quarter inch apart are then drilled across from each other on either side of the crack beginning at least three-eighths of an inch from the margin of the crack and ending within the depths of the trough.

Stainless steel (21-gauge) wire is bent in a "hair pin" shape 2.5 inches long and a small steel tab is placed on each wire unit (Figure 3). One wire unit is passed through the holes from rear to front direction and another wire unit is passed through the opposing holes from front to rear direction into the depth of the crack. The ends of the wires are pulled tight and bent outward (Figure 4). The tab placed on the wire unit will now lie against the outer hoof wall. This prevents the wires from cutting into the hoof wall. Additional sets of these wire units can be used according to the length of the defect or until the desired stabilization is achieved.

The internal length of the crack usually exceeds the external length, so it cannot be completely eliminated. In such cases, a drain must be placed before it is covered with the composite 7. To place a drain, a small amount of medicated putty b is rolled into a tubular shape the length of the trough and placed within the debrided crack. One-eighth-inch hollow rubber flexible tubing is pressed into the putty. The tubing will exit at the coronary band and below the crack to form the drain. The ends of all the opposing wires are now joined together and twisted until resistance is felt. The excess wire in front of the twist is cut off within the defect (Figure 5). There should be no movement in the hoof wall on either side of the crack when digital pressure is applied.

Next, elastic adhesive tape is placed around the coronary band to prevent irritation from contact with the composite. Three 2x3 inch sections of a strong structural fabric that resembles fiberglass, called Spectra c, are cut. The previously sanded hoof is rinsed with free-flowing denatured alcohol. The polymethylmethacrylate (PMMA) composite d is mixed thoroughly and a layer applied to the prepared area of the foot, being sure to fill the quarter crack 4. The Spectra fabric is thoroughly impregnated with the PMMA composite and a section is placed over the prepared area followed by another layer of composite. This procedure is repeated until three sections of fabric have been placed over the defect. Finally, the hoof wall is covered with plastic wrap and an elastic adhesive bandage is pulled tightly around hoof wall, compressing the fabric. Upon completion of the cure cycle, which takes two to three minutes, depending on the ambient temperature, the rubber drain is removed and the repair is sanded to remove excess composite.

Choice of Shoes

Any horse with a full-thickness quarter crack that warrants repair should be placed in a bar shoe if possible. Various configurations of bar shoes--such as a straight-bar, egg-bar, heart-bar, or Z-bar--can be used. All of these shoes effectively increase the bearing surface of the foot, provide support to the rear of the foot, and decrease the independent vertical movement at the bulbs of the heels. No nails are placed palmar to the defect between it and the heels in the repaired area of the foot.

Recently, this author has glued the shoes on most horses with quarter cracks. Gluing the shoe offers several advantages. First, it allows the foot to be trimmed and shod to a more suitable foot conformation. Second, gluing on the shoe allows for more expansion to be provided under the quarter and heel of the affected side to increase support. Finally, when shoes are glued on, there is no concern with nail placement in the affected quarter (Figure 6) 6.


The technique described here for quarter crack repair has been performed on 25 horses over the past two years. This repair has produced consistent results when compared to previous methods used by this author, and there have been no recurrences reported following the repair. Horses treated in this manner become sound almost immediately and are able to return to successful competition following the repair with no infection or bond failures being noted. Some of the cases presented with quarter cracks had been previously repaired using only a composite. With those repairs, the crack had repeatedly ruptured at the coronary band, indicating instability of the repair. When the composite was removed, it was noted that many of those defects continued to bleed under the repair.


The use of a composite (with fiberglass) alone might not provide sufficient stability for a quarter crack repair. Combining an implant (the wires) with the composite in repairing a quarter crack increases the strength and durability of the repair. Types of implants described previously include fiberglass and screws, screws and wires, various suture patterns, and clamps that apply tension across the crack 1,2,4,5,7. These methods have been somewhat cumbersome; the screws present a risk as they often impinge on the dermis and uniform tension is rarely achieved across or within the crack.

The advantage of the method described in this report is that the procedure is exceptionally strong while being relatively simple and easy to learn. Second, the wires are placed from opposing sides of the defect and joined together within the defect creating uniform tension within the crack. The wires are also incorporated into the composite as part of the repair. Another advantage of this technique is that since the implant is contained within the hoof wall, there is very little metal on the surface of the hoof wall to interfere with the adhesion of the composite.

Failures in quarter crack repair appear to be the result of three factors: 1) Repair with a composite alone which might not provide adequate strength and stability; 2) utilization of relatively rigid acrylics; and 3) materials with poor bonding capabilities. A consistent bond and relative flexibility of the repair material are essential to maintain stability, which allows the subsequent horn growth to be free of the defect. The polymethylmethacrylate used in recent years has excellent adhesive characteristics with the horn wall, while having a flexibility that approximates that of the hoof itself, thus more closely approximating normal function 8. The addition of Spectra to the composite, instead of fiberglass, increases the strength of the overall repair due to its high tensile strength. Placement of a drain effectively decreases the risk of infection under the repair.

The importance of determining the underlying cause, proper trimming of the feet and applying the correct shoe cannot be overemphasized when repairing a quarter crack. Correcting any existing hoof imbalance along with palmar/plantar support provided by the appropriate shoe is as important as the repair itself. 


Special thanks to Mr. Ian McKinley and his late father for bringing the wire technique described in this paper to the author's attention.


1. Moyer, W. Repairing hoof cracks in the horse: A review and a report of a new technique. Comp. Cont. Ed. 1983; 5:495-497.
2. O'Grady, S.E. Quarter Crack Repair. American Farriers Journal 1991, 26-31.
3. Snow, V.E.; Birdsall, D.P. Specific parameters used to evaluate hoof balance and support. Proceedings 36th Annu. Conv. Am. Assoc. Equine Practnr. 1990, 299-311.
4. Moyer, W. Management of proximal incomplete quarter cracks in Standardbred racehorses. Proceedings 34th Annu. Conv. Am. Assoc. Equine Practnr. 1988, 329-331.
5. Moyer, W.; Sigafoos, R. Preliminary experience and uses of composite hoof wall repair. Proceedings 37th Annu. Conv. Am. Assoc. Equine Practnr. 1991; 681-686.
6. O'Grady, S.E.; Watson, E. How to glue on therapeutic shoes. Proceedings 45th Annu. Conv. Am. Assoc. Equine Practnr. 1999; 115-119.
7. Butler, J. The repair of hoof cracks using fiberglass and screws. Proceedings 22nd Annu. Conv. Am. Assoc. Equine Practnr. 1976; 235-237.
8. Blackford, J.T.; Blackford, L.A.W.; Latimer, F.G. Adjustable tension band stabilization of hoof cracks in horses. Proceedings 37th Annu. Conv. Am. Assoc. Equine Practnr. 1991; 497-512.
9. Moyer, W.; Sigafoos, R. Equine hoof wall repair. Trenton: Veterinary Learning Systems, 1993, 6.


a. Dremel--Dremel Tool Co. Emerson Electric, 4915 21st, Racine, WI 53401
b. Keratex putty--Advance Equine, P.O. Box 54, Versailles, KY 40383
c. Spectra--Equilox Int'l, 110 NE 2nd Street, Pine Island, MN 55963
d. Equilox--Equilox Int'l, 110 NE 2nd Street, Pine Island, MN 55963

Dr. O'Grady can be reached at Northern Virginia Equine, 7135 Mt. Eccentric Rd., The Plains, VA 20198;

About the Author

Stephen E. O'Grady, DVM, MRCVS

Stephen E. O'Grady, DVM, MRCVS, was a professional farrier for 10 years prior to obtaining his degree in veterinary medicine. He learned farriery through a formal apprenticeship under Hall of Fame farrier Joseph M. Pierce of West Chester, Penn. After graduating from veterinary school, O'Grady did an internship in Capetown, South Africa. Then he joined Dan Flynn, VMD, at Georgetown Equine Hospital in Charlottesville, Va., as an associate for five years. Since that time, he has operated a private practice in Virginia and South Africa, with a large portion of the practice devoted to equine podiatry. He has published numerous articles and lectured extensively on equine foot problems. His web site is

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