FREE SHIPPING over $40
OVER 10000 FIVE-STAR REVIEWS
5% OFF ALL SUBSCRIPTIONS
100% HAPPINESS GUARANTEE
Analyze Diet
0
Equine veterinary journal. Supplement2007; (36); 393-399; doi: 10.1111/j.2042-3306.2006.tb05575.x

Functional anatomy of the caudal thoracolumbar and lumbosacral spine in the horse.

Abstract: Research in spinal biomechanics and functional anatomy has advanced back pain research in man. Yet, despite the performance limiting nature of back pain in horses, there are few data for the equine spine. Objective: To describe aspects of functional anatomy of the equine thoracolumbar and lumbosacral (LS) spine and potential effects on performance. Methods: The first study investigated variations in LS vertebral formula by post mortem examination of 120 horses. Midline vertebral transection was carried out on 65 Thoroughbred (TB), 24 Standardbred (SB) and 31 other breeds. The second study investigated morphology and biomechanics of the deep stabilising epaxial muscles of 13 horses using MRI (n = 3), anatomical dissection (n = 11) and biomechanical analysis (n = 6). The spinous process angular orientation relative to the vertebral body, was analysed at vertebrae T13, T18, L3, L5, L6 and S1. Results: LS variations were found in 33.3% of the total group, 40.0% TB and 45.2% others, but 0% SB. Sacralisation of lumbar vertebra (L) 6 with LS motion between L5 and L6 occurred in 32.3% TB and 29.0% others. Five segmental multifidus fascicles were identified originating from spinous processes and vertebral laminae running craniocaudally onto the mammillary processes and lateral border of the sacrum, crossing between 1-5 intervertebral discs. Sacrocaudalis dorsalis (SCD) lateralis muscle was an extension of multifidus from L4, L5 and L6 depending on the vertebral formula whereas SCD medialis mm originated from S3. Both inserted on caudal vertebrae. Based on the location and direction of fibres, the principal action of the deep epaxial muscles was dorsoventral sagittal rotation. This action was dependent on vertebral spinous process/body orientation. We hypothesise that equine multifidus and SCD lateralis muscles act as caudal sagittal rotators of their vertebra of origin, as is the case in man, allowing dynamic stabilisation during dorsoventral motion. Conclusions: Equine multifidus anatomy and function are comparable to that of man. The high prevalence of anatomical variations in the LS spine may affect maximal dorsoventral motion, the stability of the LS joint and, therefore, have consequences for athletic performance. Further studies of these structures are warranted in appropriately selected poorly performing horses.
Get Full Text
Publication Date: 2007-04-04 PubMed ID: 17402454DOI: 10.1111/j.2042-3306.2006.tb05575.xGoogle Scholar: Lookup
The Equine Research Bank provides access to a large database of publicly available scientific literature. Inclusion in the Research Bank does not imply endorsement of study methods or findings by Mad Barn.
LinkedInCopy
  • Journal Article

Summary

This research summary has been generated with artificial intelligence and may contain errors and omissions. Refer to the original study to confirm details provided. Submit correction.

This research focuses on the functional anatomy of the thoracolumbar and lumbosacral spine in horses, studying variations and how these variations might affect a horse’s performance. The study discovered that the anatomy and function of the equine multifidus — a muscle significant for spinal stability — is comparable to that of a human’s.

Study Design

  • The research comprised two separate studies in which 120 horses’ spinal structures were investigated.
  • In the first study, post-mortem examinations were conducted on Thoroughbred (TB), Standardbred (SB), and other breeds of horses to explore variations in the lumbosacral (LS) vertebral formula.
  • The second research segment studied the morphology and biomechanics of the deep stabilising epaxial muscles of horses. This included the use of MRI imaging, anatomical dissection, and biomechanical analysis.
  • The angular orientation of the spinous process in relation to the vertebral body was examined at multiple vertebrae.

Findings

  • Lumbosacral variations were detected in one-third of the total horse population, with higher occurrences in Thoroughbreds and other breeds, and none in Standardbreds.
  • About a third of Thoroughbreds and others underwent sacralisation of the lumbar vertebra, with LS motion occurring between L5 and L6.
  • Five part fascicles of the multifidus muscle were recognised, which originated from the spinous processes and vertebral laminae and stretched onto the mammillary processes and lateral border of the sacrum.
  • The sacrocaudalis dorsalis lateralis muscle was found to be an extension of the multifidus from certain lumbar vertebrae.
  • Based on fibre location and direction, the study concluded that the key function of the deep epaxial muscles was dorsoventral sagittal rotation.

Implications and Conclusions

  • A significant conclusion was that the anatomy and function of the equine multifidus muscle was similar to that in humans.
  • The research indicated that the prevalent anatomical variations in the lumbosacral spine could influence the stability of the lumbosacral joint, the capacity for maximal dorsoventral motion, and consequently, a horse’s athletic performance.
  • These findings highlighted the need for further exploration of these structures, particularly in horses that perform poorly.

Cite This Article

APA
Stubbs NC, Hodges PW, Jeffcott LB, Cowin G, Hodgson DR, McGowan CM. (2007). Functional anatomy of the caudal thoracolumbar and lumbosacral spine in the horse. Equine Vet J Suppl(36), 393-399. https://doi.org/10.1111/j.2042-3306.2006.tb05575.x

Publication

Equine veterinary journal. Supplement
NlmUniqueID: 9614088
Country: United States
Language: English
Issue: 36
Pages: 393-399

Researcher Affiliations

Stubbs, N C
  • The University of Queensland, Australia, University of Sydney, Australia.
Hodges, P W
    Jeffcott, L B
      Cowin, G
        Hodgson, D R
          McGowan, C M

            MeSH Terms

            • Animals
            • Biomechanical Phenomena
            • Cadaver
            • Horses / anatomy & histology
            • Horses / physiology
            • Lumbar Vertebrae / innervation
            • Lumbar Vertebrae / physiology
            • Lumbosacral Region / physiology
            • Magnetic Resonance Imaging / veterinary
            • Muscle, Skeletal / innervation
            • Muscle, Skeletal / physiology
            • Physical Conditioning, Animal / physiology
            • Spine / anatomy & histology
            • Spine / innervation
            • Spine / physiology

            Citations

            This article has been cited 16 times.
            1. Scilimati N, Angeli G, Di Meo A, Dall'Aglio C, Pepe M, Beccati F. Post-Mortem Computed Tomographic Features of the Most Caudal Lumbar Vertebrae, Anatomical Variations and Acquired Osseous Pathological Changes, in a Mixed Population of Horses. Animals (Basel) 2023 Feb 19;13(4).
              doi: 10.3390/ani13040743pubmed: 36830530google scholar: lookup
            2. Ursini T, Shaw K, Levine D, Richards J, Adair HS. Electromyography of the Multifidus Muscle in Horses Trotting During Therapeutic Exercises. Front Vet Sci 2022;9:844776.
              doi: 10.3389/fvets.2022.844776pubmed: 35692292google scholar: lookup
            3. Hausberger M, Lesimple C, Henry S. Detecting Welfare in a Non-Verbal Species: Social/Cultural Biases and Difficulties in Horse Welfare Assessment. Animals (Basel) 2021 Jul 30;11(8).
              doi: 10.3390/ani11082249pubmed: 34438708google scholar: lookup
            4. Spoormakers TJP, Veraa S, Graat EAM, van Weeren PR, Brommer H. A comparative study of breed differences in the anatomical configuration of the equine vertebral column. J Anat 2021 Oct;239(4):829-838.
              doi: 10.1111/joa.13456pubmed: 33991425google scholar: lookup
            5. Dietrich J, Handschuh S, Steidl R, Böhler A, Forstenpointner G, Egerbacher M, Peham C, Schöpper H. Muscle Fibre Architecture of Thoracic and Lumbar Longissimus Dorsi Muscle in the Horse. Animals (Basel) 2021 Mar 23;11(3).
              doi: 10.3390/ani11030915pubmed: 33806991google scholar: lookup
            6. Stomp M, d'Ingeo S, Henry S, Lesimple C, Cousillas H, Hausberger M. EEG individual power profiles correlate with tension along spine in horses. PLoS One 2020;15(12):e0243970.
              doi: 10.1371/journal.pone.0243970pubmed: 33315932google scholar: lookup
            7. Ericson C, Stenfeldt P, Hardeman A, Jacobson I. The Effect of Kinesiotape on Flexion-Extension of the Thoracolumbar Back in Horses at Trot. Animals (Basel) 2020 Feb 13;10(2).
              doi: 10.3390/ani10020301pubmed: 32069962google scholar: lookup
            8. García Liñeiro JA, Graziotti GH, Rodríguez Menéndez JM, Ríos CM, Affricano NO, Victorica CL. Parameters and functional analysis of the deep epaxial muscles in the thoracic, lumbar and sacral regions of the equine spine. J Anat 2018 Jul;233(1):55-63.
              doi: 10.1111/joa.12818pubmed: 29708263google scholar: lookup
            9. García Liñeiro JA, Graziotti GH, Rodríguez Menéndez JM, Ríos CM, Affricano NO, Victorica CL. Structural and functional characteristics of the thoracolumbar multifidus muscle in horses. J Anat 2017 Mar;230(3):398-406.
              doi: 10.1111/joa.12564pubmed: 27861847google scholar: lookup
            10. Hyytiäinen HK, Mykkänen AK, Hielm-Björkman AK, Stubbs NC, McGowan CM. Muscle fibre type distribution of the thoracolumbar and hindlimb regions of horses: relating fibre type and functional role. Acta Vet Scand 2014 Jan 27;56(1):8.
              doi: 10.1186/1751-0147-56-8pubmed: 24468115google scholar: lookup
            11. Boado A, Pollard D, Lopez-Sanroman FJ, Dyson S. Orthopaedic Injuries in 272 Dressage Horses: A Retrospective Study. Animals (Basel) 2025 Oct 14;15(20).
              doi: 10.3390/ani15202972pubmed: 41153899google scholar: lookup
            12. Ogden NKE, Winderickx K, Stack JD. Computed tomography of the equine caudal spine and pelvis. Pathological findings in 56 clinical cases (2018-2023). Equine Vet J 2025 Sep;57(5):1279-1289.
              doi: 10.1111/evj.14426pubmed: 39428125google scholar: lookup
            13. Ogden NKE, Winderickx K, Bennell A, Stack JD. Computed tomography of the equine caudal spine and pelvis: Technique, image quality and anatomical variation in 56 clinical cases (2018-2023). Equine Vet J 2025 Sep;57(5):1265-1278.
              doi: 10.1111/evj.14422pubmed: 39390752google scholar: lookup
            14. Bonilla Lemos Pizzi GL, Holz K, Kowalski ÉA, Fonseca Ribeiro P, Blake R, Ferreira Martins C. 2D Kinematic Analysis of the Esbarrada and Volta Sobre Patas Manoeuvres of Criollo Breed Horses Competing in Freio de Ouro. Animals (Basel) 2024 Aug 20;14(16).
              doi: 10.3390/ani14162410pubmed: 39199944google scholar: lookup
            15. Baudisch N, Singer E, Jensen KC, Eichler F, Meyer HJ, Lischer C, Ehrle A. Influence of surgical intervention at the level of the dorsal spinous processes on the biomechanics of the equine thoracolumbar spine. Equine Vet J 2025 Mar;57(2):492-501.
              doi: 10.1111/evj.14123pubmed: 38934728google scholar: lookup
            16. Domańska-Kruppa N, Wierzbicka M, Stefanik E. Advances in the Clinical Diagnostics to Equine Back Pain: A Review of Imaging and Functional Modalities. Animals (Basel) 2024 Feb 23;14(5).
              doi: 10.3390/ani14050698pubmed: 38473083google scholar: lookup
            Subscribe to our newsletter
            Join 99,727 horse owners like you who receive our email updates on horse health and nutrition.