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New Zealand veterinary journal2005; 52(5); 272-279; doi: 10.1080/00480169.2004.36439

Musculoskeletal responses of 2-year-old Thoroughbred horses to early training. 2. Measurement error and effect of training stage on the relationship between objective and subjective criteria of training workload.

Abstract: To identify the magnitude and sources of error involved in simply quantifying the workload of a group of Thoroughbred racehorses in training. Methods: Data were obtained from seven 2-year-old fillies trained for 13 weeks on sand and grass tracks at various cantering velocities, and at the gallop in the last 4 weeks. Four fillies completed training and comprised a 'high exercise intensity' subgroup; three fillies did not complete all gallops due to lameness or injury and comprised a 'medium exercise intensity' subgroup. The trainer recorded the distance, time, track used, and subjective gait (SG; viz canter, 1/4-pace, 1/2-pace and gallop) of each horse each day. Data were analysed to describe the training programme and sources of variation in workload. A cumulative workload index (CWI) was devised to simply express distance and velocity aspects of the training programme. Results: The magnitude of errors in measurement of timing and distance were small but significant (<0.8%, p=0.01). SG was an inaccurate descriptor of velocity. Mean velocity of 1/2-pace decreased from 8.92 (SE 0.049) in Weeks 6-8 to 6.33 (SE 0.061) m/sec after the start of galloping sessions in Week 9 (p=0.01). Track surface had a significant effect on the velocity of 1/2-pace (p=0.001). The fastest velocity was recorded on the grass (9.06, SE 0.292 m/sec), followed by 'plough' (8.23, SE 0.152 m/sec), and sand (7.90, SE 0.132 m/sec) tracks. The CWI of the horses ranged between 1,085,000 and 1,634,000 (mean=1,428,000; SE 78,000). The average exercise intensity per week was 110,000 (SE 1,048). There were no significant differences between high and medium exercise intensity subgroups for the canter and 1/4-pace. The high exercise subgroup had a greater CWI for the 1/2-pace (839,000 vs 559,000; p=0.004), gallop (71,000 vs 31,000; p=0.001), and total index (1,580,000 vs 1,242,000; p=0.001). Conclusions: The workload history of a horse can be accurately described using an index based on manual measurement of the time and distance worked. Conclusions: Accurate and precise data on the training programme of performance horses are likely to enable greater differentiation of aspects of workload which are associated with both performance and injury.
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Publication Date: 2005-03-16 PubMed ID: 15768123DOI: 10.1080/00480169.2004.36439Google Scholar: Lookup
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  • 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.

The research study seeks to determine the discrepancies and magnitude of errors in quantifying the training workload of racehorses. A notable outcome of the study is the development of a Cumulative Workload Index (CWI) to better define training aspects including distance and velocity.

Methodology

  • The research was conducted on seven 2-year-old female Thoroughbred horses undergoing training for 13 weeks on various terrain including sand and grass tracks.
  • Training velocities varied, including cantering at different speeds and introducing galloping in the final four weeks.
  • Out of the seven horses, four completed training and were categorized as the ‘high exercise intensity’ group whereas three were unable to complete all gallops due to injury, grouped as the ‘medium exercise intensity’.
  • The trainer painstakingly recorded crucial training details such as distance covered, time, track utilized, and the subjective gait of each horse per day.
  • The gathered data was thoroughly analyzed to understand the training program and to identify any divergence in workload.

Findings

  • Tiny yet significant (<0.8%, p=0.01) measurement inaccuracies related to time and distance surfaced during the study.
  • The subjective gait turned out to be an incorrect descriptor of speed.
  • Over time the mean velocity dropped from 8.92 (SE 0.049) in Weeks 6-8 to 6.33 (SE 0.061) m/sec post the initiation of the galloping sessions in Week 9 (p=0.01).
  • The track surface had a consequential impact on speed (p=0.001). The fastest velocity was on the grass track, followed by the ‘plough’ and sand surfaces.
  • The Cumulative Workload Index (CWI) of the horses varied within 1,085,000 to 1,634,000, with a mean value of 1,428,000 (SE 78,000). The average exercise intensity per week was measured as 110,000 (SE 1,048).
  • The ‘high exercise intensity’ group showed greater CWI for certain paces and the overall index.

Conclusions

  • The training workload of a horse can be accurately represented by an index based on manual time and distance measurement.
  • Accurate, detailed information on a performance horse’s training program can better illuminate aspects of workload that are connected with performance and injury.

Cite This Article

APA
Rogers CW, Firth EC. (2005). Musculoskeletal responses of 2-year-old Thoroughbred horses to early training. 2. Measurement error and effect of training stage on the relationship between objective and subjective criteria of training workload. N Z Vet J, 52(5), 272-279. https://doi.org/10.1080/00480169.2004.36439

Publication

New Zealand veterinary journal
ISSN: 0048-0169
NlmUniqueID: 0021406
Country: England
Language: English
Volume: 52
Issue: 5
Pages: 272-279

Researcher Affiliations

Rogers, C W
  • Epicentre, Institute of Veterinary Animal and Biomedical Sciences, Massey University, Private Bag 11222, Palmerston North, New Zealand.
Firth, E C

    Citations

    This article has been cited 10 times.
    1. Siegers E, van Wijk E, van den Broek J, Sloet van Oldruitenborgh-Oosterbaan M, Munsters C. Longitudinal Training and Workload Assessment in Young Friesian Stallions in Relation to Fitness: Part 1. Animals (Basel) 2023 Feb 16;13(4).
      doi: 10.3390/ani13040689pubmed: 36830476google scholar: lookup
    2. Legg K, Cochrane D, Gee E, Macdermid P, Rogers C. Physiological Demands and Muscle Activity of Jockeys in Trial and Race Riding. Animals (Basel) 2022 Sep 8;12(18).
      doi: 10.3390/ani12182351pubmed: 36139208google scholar: lookup
    3. Morrice-West AV, Hitchens PL, Walmsley EA, Tasker K, Lim SL, Smith AD, Whitton RC. Relationship between Thoroughbred workloads in racing and the fatigue life of equine subchondral bone. Sci Rep 2022 Jul 7;12(1):11528.
      doi: 10.1038/s41598-022-14274-ypubmed: 35798766google scholar: lookup
    4. Crawford KL, Finnane A, Greer RM, Barnes TS, Phillips CJC, Woldeyohannes SM, Bishop EL, Perkins NR, Ahern BJ. Survival Analysis of Training Methodologies and Other Risk Factors for Musculoskeletal Injury in 2-Year-Old Thoroughbred Racehorses in Queensland, Australia. Front Vet Sci 2021;8:698298.
      doi: 10.3389/fvets.2021.698298pubmed: 34796223google scholar: lookup
    5. Crawford KL, Finnane A, Greer RM, Phillips CJC, Bishop EL, Woldeyohannes SM, Perkins NR, Ahern BJ. A Prospective Study of Training Methods for Two-Year-Old Thoroughbred Racehorses in Queensland, Australia, and Analysis of the Differences in Training Methods between Trainers of Varying Stable Sizes. Animals (Basel) 2021 Mar 25;11(4).
      doi: 10.3390/ani11040928pubmed: 33805873google scholar: lookup
    6. Palmer AL, Rogers CW, Stafford KJ, Gal A, Cochrane DJ, Bolwell CF. Cross-Sectional Survey of the Training Practices of Racing Greyhounds in New Zealand. Animals (Basel) 2020 Nov 4;10(11).
      doi: 10.3390/ani10112032pubmed: 33158103google scholar: lookup
    7. Flash ML, Wong ASM, Stevenson MA, Gilkerson JR. Barriers to entering race training before 4 years of age for Thoroughbred horses born in the 2014 Australian foal crop. PLoS One 2020;15(8):e0237003.
      doi: 10.1371/journal.pone.0237003pubmed: 32756576google scholar: lookup
    8. Rogers CW, Bolwell CF, Gee EK. Proactive Management of the Equine Athlete. Animals (Basel) 2012 Dec 19;2(4):640-55.
      doi: 10.3390/ani2040640pubmed: 26487168google scholar: lookup
    9. Firth EC. The response of bone, articular cartilage and tendon to exercise in the horse. J Anat 2006 Apr;208(4):513-26.
      doi: 10.1111/j.1469-7580.2006.00547.xpubmed: 16637875google scholar: lookup
    10. Best R, Williams JM, Pearce J. The Physiological Requirements of and Nutritional Recommendations for Equestrian Riders. Nutrients 2023 Nov 30;15(23).
      doi: 10.3390/nu15234977pubmed: 38068833google scholar: lookup
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