Subscribe to RSS
Please copy the URL and add it into your RSS Feed Reader.
https://www.thieme-connect.de/rss/thieme/en/10.1055-s-00035023.xml
Download PDF
Vet Comp Orthop Traumatol 2003; 16(02): 67-75
DOI: 10.1055/s-0038-1632762
DOI: 10.1055/s-0038-1632762
Original Research
Isolating the effects of equine hoof shape measurements on capsule strain with finite element analysis
Funding was provided by NSERC Grant 0GP0138314 and OMAFRA Grants 17630 and 25650 to JJT.
Further Information
Publication History
Received
19 September 2001
Accepted
25 May 2002
Publication Date:
22 February 2018 (online)
Summary
The shape of the equine hoof capsule affects how weightbearing forces are resisted by the capsule and are transmitted to deeper structures within the hoof. Our aim was to isolate the effects of several measurements describing hoof shape on strains and stresses in the hoof capsule. Multiple finite-element models are constructed with toe angles in the range 42° to 58°, heel angles from 34° to 50°, toe lengths of 8.5 to11.5 cm, and medial and lateral angles from 68° to 83°. Strain at the toe is inversely related to toe angle, and not strongly affected by heel angle; it increases with toe length distally on the toe, but decreases near the coronary border. Varying medial and lateral angles show that more upright walls have less strain at the quarters. This study demonstrates the effectiveness of finite element methods in complementing in vitro and in vivo studies of hoof mechanics.
-
References
- 1 Burn JF, Brockington C. Quantification of hoof deformation using optical motion capture. Equine Vet J Suppl 2001; 31: 50-3.
- 2 Dejardin LM, Arnoczky SP, Cloud GL. A method for determination of equine hoof strain patterns using photoelasticity: An in vitro study. Equine Vet J 1999; 31: 232-7.
- 3 Douglas JE, Biddick TL, Thomason JJ, Jofriet JC. Stress/strain behavior of the equine laminar junction. J Exp Biol 1998; 201: 2287-97.
- 4 Douglas JE, Mittal C, Thomason JJ, Jofriet JC. The modulus of elasticity of equine hoof wall: implications for the mechanical function of the hoof. J Exp Biol 1996; 199: 1829-36.
- 5 Douglas JE, Thomason JJ. Shape, orientation and spacing of the primary epidermal laminae in the hooves of neonatal and adult horses (Equus caballus) . Cells Tissues Organs 2000; 166: 304-18.
- 6 Thomason JJ, Douglas JE, Sears W. Morphology of the laminar junction in relation to the shape of the hoof capsule and third phalanx in adult horses (Equus caballus). Cells Tissues Organs 2001; 168: 295-311.
- 7 Fischerleitner F. Röntgenographische Untersuchungen über den Einfluss der Lageveränderungen des Huf-Strahl und Kronbeines auf die Mechanik der Hornkapsel des Pferdes im Belastungsgerät. Vienna, Austria: Tierarztlichen Hochschule in Wien. Inaugural dissertation; 1974
- 8 Hinterhofer C, Stanek C, Binder K. Elastic modulus of equine hoof horn, tested in wall samples, sole samples and frog samples at varying levels of moisture. Berlin Munich Tierärztl Wochenschr 1998; 111: 217-21.
- 9 Hinterhofer C, Stanek C, Haider H. Belastungssimulation an einem aus finiten elementen konstruierten Computermodell der Hornkapsel des Pferdes. Pferdeheilkunde 1997; 13: 319-29.
- 10 Hogan HA, Wichtmann AD, Hood DM. Finite element analysis of the internal deformation and stresses in the equine distal digit. In: Proceedings of 10th Meeting of the Association of Equine Sports Medicine. 1991. 43. Huiskes R. if bone is the answer, then what is the question? J Anat 2000; 197: 145-56.
- 11 Kane AJ, Stover SM, Gardner IA, Bock KB, Case JT, Johnson BJ, Anderson ML, Barr BC, Daft BM, Kinde H, Larochelle D, Moore J, Mysore J, Stoltz J, Woods L, Read DH, Ardans AA. Hoof size, shape, and balance as possible risk factors for catastrophic musculoskeletal injury of Thoroughbred racehorses. Am J Vet Res 1998; 59: 1545-52.
- 12 Kobluk CN, Robinson A, Gordon BJ, Clanton CJ, Trent AM, Ames TR. The effect of conformation and shoeing: a cohort study of 95 Thoroughbred racehorse. Proc Am Assoc Equine Pract 1989; 35: 259-74.
- 13 Lungwitz A. The changes in the form of the horse’s hoof under the action of the bodyweight. J Comp Pathol Therap 1891; 04: 191-211.
- 14 McClinchey HL, Thomason JJ, Jofriet JC. Mechanism of quarter and heel expansion in the equine hoof investigated by finite-element analysis. Submitted 2002
- 15 Merkens HW, Schamhardt HC, Van Osch GJVM, Van Den Bogert AJ. Ground reaction force patterns of Dutch Warmblood horses at a normal trot. Equine Vet J 1993; 25: 134-7.
- 16 Newlyn HA, Collins SN, Cope BC, Hopegood L, Latham RJ, Reilly JD. Finite element analysis of static loading in donkey hoof wall. Equine Vet J Suppl 1998; 26: 103-10.
- 17 Shahar R. Evaluation of stiffness and stress of external fixators with curved acrylic connecting bars. Vet Comp Orthop Traumatol 2000; 13: 65-72.
- 18 Thomason JJ. Variation in surface strain on the equine hoof wall with shoeing, gait, substrate, direction of travel and hoof shape. Equine Vet J Suppl 1998; 26: 86-95.
- 19 Thomason JJ, Bignell WW, Batiste D, Sears W. Effects of hoof shape, body mass and velocity on surface strain in the wall of the unshod forehoof of Standardbreds trotting on a treadmill. Submitted 2002
- 20 Thomason JJ, Douglas JE, Sears W. Morphology of the laminar junction in relation to the shape of the hoof capsule and third phalanx in adult horses (Equus caballus). Cell Tiss Org 2001; 166: 304-18.
- 21 Thomason JJ, McClinchey HL, Jofriet JC. Analysis of strain and stress in the equine hoof capsule using finite element methods: comparison with principal strains recorded in vivo . Equine Vet J 2002; 34: 719-25.