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1.
Richard A. Mansmann Sarah JamesAnthony T. Blikslager DVM PhD DACVS Kurt vom Orde 《Journal of Equine Veterinary Science》2010
This study deals with the relationship between long toes in the hind feet and pain in the gluteal region in horses, and the remedial value of trimming/shoeing that moves the breakover point back at the toe. Seventy seven client-owned horses were studied, 67 shod riding horses retrospectively and 10 barefoot broodmares prospectively. The 10 mares were evaluated twice, and 24 of the 67 riding horses were re-evaluated at the next shoeing, for a total of 111 observations. Each horse underwent gluteal palpation and lateral radiographs of both hind feet. Toe length was quantified as breakover distance (BD), the horizontal distance between the tip of the third phalanx and the dorsalmost point at which the wall/shoe was in contact with the ground. The BD was then shortened with trimming +/− shoeing to a length of ≤15mm (shod horses) or ≤20 mm (barefoot horses). The 24 riding horses were re-evaluated 4-6 weeks later and the 10 broodmares 1 week after trimming. 相似文献
2.
OBJECTIVE: To develop an objective, accurate method for quantifying forelimb ground reaction forces in horses by adapting a human in-shoe pressure measurement system and determine the reliability of the system for shod and unshod horses. ANIMALS: 6 adult Thoroughbreds. PROCEDURE: Horses were instrumented with a human in-shoe pressure measurement system and evaluated at a trot (3 m/s) on a motorized treadmill. Maximum force, stance time, and peak contact area were evaluated for shod and unshod horses. Three trials were performed for shod and unshod horses, and differences in the measured values were examined with a mixed model ANOVA for repeated measures. Sensor accuracy was evaluated by correlating measured variables to clinically observed lameness and by a variance component analysis. RESULTS: 4 of 6 horses were determined to be lame in a forelimb on the basis of clinical examination and measured values from the system. No significant differences were observed between shod and unshod horses for maximum force and stance time. A significant decrease in peak contact area was observed for shod and unshod horses at each successive trial. Maximum force measurements provided the highest correlation for detecting lameness (r = 0.91, shod horses; r = 1.0, unshod horses). A variance component analysis revealed that 3 trials provided a variance of 35.35 kg for maximum force (+/- 5.78% accuracy), 0.007 seconds for stance time (+/- 2.5% accuracy), and 8.58 cm2 for peak contact area (+/- 11.95% accuracy). CONCLUSIONS AND CLINICAL RELEVANCE: The in-shoe pressure measurement system provides an accurate, objective, and effective method to evaluate lameness in horses. 相似文献
3.
OBJECTIVE: To determine the mechanism that enables horses to partially counteract the shift of the center of pressure under the hoof induced by changes in hoof morphology attributable to growth and wear during a shoeing interval. ANIMALS: 18 clinically sound Warmblood horses. PROCEDURES: Horses were evaluated 2 days and 8 weeks after shoeing during trotting on a track containing pressure-force measuring plates and by use of a synchronous infrared gait analysis system set at a frequency of 240 Hz. All feet were trimmed toward straight alignment of the proximal, middle, and distal phalanges and shod with standard flat shoes. Results-Temporal characteristics such as stance time and the time between heel lift and toe off (ie, breakover duration) did not change significantly as a result of shoeing interval. Protraction and retraction angles of the limbs did not change. Compensation was achieved through an increase in the dorsal angle of the metacarpohalangeal or metarsophalangeal (fetlock) joint and a concomitant decrease of the dorsal angle of the hoof wall and fetlock. There was an additional compensatory mechanism in the hind limbs during the landing phase. CONCLUSIONS AND CLINICAL RELEVANCE: Horses compensate for changes in hoof morphology that develop during an 8-week shoeing interval such that they are able to maintain their neuromuscular pattern of movement. The compensation consists of slight alterations in the angles between the distal segments of the limb. Insight into natural compensation mechanisms for hoof imbalance will aid in the understanding and treatment of pathologic conditions in horses. 相似文献
4.
Heel contraction is an undesired but common condition in domestic horses. Some authors indicate shoeing as a risk factor. There is a correlation between shoeing and a restriction of heel expansion, but the clinical significance is unknown. This study aimed to evaluate the influence of shoeing and other risk factors, such as age, access to paddock, and breed, on heel contraction. This study included 114 horses, 55 of which were barefoot their whole life and 59 had been shod consistently for at least the previous year. The width and length of the frog were measured. Linear mixed-effects models were performed for the width:length ratio, where the fixed effects were age, sex, breed, pasture or paddock time, shoeing and its duration, and limb. The random effects included the horse and the yard. Although heel contraction occurs more often in shod horses compared with barefoot horses, the difference between the two conditions was not statistically significant, when other factors were considered. The most important factors that impacted contraction were individual horse features and breed (P < .001). The effect of age and a yard was noticed (P < 0,5). The sex, paddock time, and the shoeing and its duration were found not to have statistical significance. The study concluded that heel contraction is multifactorial problem, mainly caused by breed and unknown features correlated with individual. It was not confirmed that horseshoeing causes heel contraction. Because of significant difference in incidence of contraction between yards, there is a need to further investigation of environmental factors causing this hoof distortion. 相似文献
5.
Horse racing is a contest between horses, usually held for the purpose of betting. Thoroughbred horse racing is the most diffused form of horse racing throughout the world. Thoroughbred is one of the most versatile of horse breeds and has influenced the development of many other breeds. Thoroughbred horses served as a foundation stock for the development of the light horse breeds. The two types of horse racing are flat racing and jumping races/steeplechases. The measures of racing performance are broadly classified into three categories. They are time and its several variations, handicap or similar performance ratings and earnings. One common measure of the performance of racehorses evaluated genetically is racing time or final time. The heritability estimates differed according to method of estimation, age, sex, track and distance. Time measure generally had a heritability in the range of 0.1 to 0.2 with the higher values for shorter races. For handicap and earning measures the heritabilities reported were generally higher in the range of 0.3 to 0.4; hence these may be considered in genetic evaluation of racing performance of Thoroughbred horses. The average generation interval of Thoroughbred horses was 11.2 ± 4.5 and 9.7 ± 3.8 years for males and females respectively, which limits the genetic progress in racing horses. However, the major advantage is that the racing performance may be evaluated in both males and females and repeated observations can be obtained on the same animal in relatively short periods. These factors coupled with the reasonable heritability of some measures of racing performance, suggest that mass selection based on performance tests would be the selection procedure of choice to improve the racing performance of Thoroughbred horses. In general, the inbreeding at the rate that is usually practised in Thoroughbred population does not enable much gene fixing. However, practice of close inbreeding may be avoided, even though it still fascinates breeders at subconscious level. 相似文献
6.
REASONS FOR PERFORMING STUDY: There is a need to determine accelerations acting on the equine hoof under field conditions in order to better assess the risks for orthopaedic health associated with shoeing practices and/or surface conditions. OBJECTIVES: To measure the acceleration profiles generated in Thoroughbred racehorses exercising at high speeds over dirt racetracks and specifically to evaluate the effect of a toe grab shoe compared to a flat racing plate, using a newly developed wireless data acquisition system (WDAS). METHODS: Four Thoroughbred racehorses in training and racing were used. Based on previous trials, each horse served as its own control for speed trials, with shoe type as variable. Horses were evaluated at speeds ranging from 12.0-17.3 m/sec. Impact accelerations, acceleration on break over and take-off, and temporal stride parameters were calculated. Impact injury scores were also determined, using peak accelerations and the time over which they occurred. RESULTS: Recorded accelerations for the resultant vector (all horses all speeds) calculated from triaxial accelerometers ranged 96.3-251.1 g, depending on the phase of the impact event. An association was observed between shoe type and change in acceleration in individual horses, with 2 horses having increased g on initial impact with toe grab shoes in place. In the final impact phase, one horse had an increase of 110 g while wearing toe grab shoes. Increased accelerations were also observed on break over in 2 horses while wearing toe grab shoes. CONCLUSIONS: Shoe type may change impact accelerations significantly in an individual horse and could represent increased risk for injury. Further work is needed to determine if trends exist across a population. POTENTIAL RELEVANCE: The WDAS could be used for performance evaluation in individual horses to evaluate any component of the horse-performance surface interface, with the goal of minimising risk and optimising performance. 相似文献
7.
E. M. Santschi 《Equine Veterinary Education》2021,33(7):386-388
Subchondral lucencies (SCL) occur in the equine medial femoral condyle (MFC) and can cause lameness and impair performance. Treatment of MFC SCL has evolved over the last 40 years from rest alone to cyst injection to several surgical procedures. Horses most commonly develop MFC SCL in the first 18 months of life, and expectations for performance and sales can impact therapeutic decisions. These complications mean that a single treatment plan cannot be applied to every SCL. An additional issue is accurate long-term performance data. Long-term follow-up can also be difficult to obtain due to horse movement, confidentiality issues after sales, and the complexities of finding new owners and getting their cooperation. This short communication reviews available racing information from publications reporting treatment of MFC SCL and provides long-term follow-up racing data on 13 horses treated with a transcondylar screw. Horses receiving a transcondylar screw raced as well as horses treated with other procedures and had longer careers, further supporting the use of this technique in the treatment of MFC SCL. 相似文献
8.
There is limited information documenting hind foot conformation. The objectives of the study were to describe the shape of the hoof capsule of hindlimbs from the lateral aspect in horses of variable breeds, and, within horses, to compare the conformation of the hoof capsule of forelimbs and hindlimbs and determine the orientation of the distal phalanx within the hoof capsule in hindlimbs. Lateral photographs of the fore and hind feet (n = 225) and lateromedial radiographs of the hind feet (n = 29) were obtained. Differences among breed and shoeing status groups were assessed using multivariable mixed-effects linear regression models. Angular parameters and ratios of linear measurements were compared between fore and hind feet; angular radiological variables and photographic parameters of the hind feet were compared. The mean dorsal hoof wall angle for hind feet (50.9°±3.7°) was smaller than forefeet (51.8°±3.9°) (P = 0.04). The mean heel angles for hind feet (36.4°±9.6°) were smaller than forefeet (40.1°±9.3°; P < 0.001). Dorsal hoof wall (P < 0.001) and heel (P = 0.002) angles were larger in unshod than shod feet. In the hind feet, the dorsal hoof wall was parallel to the dorsal aspect of the distal phalanx. The median angle of the distal phalanx to the horizontal (angle S) was 0.6° (interquartile range: −1.4, 2.3°). There was a positive relationship between angle S and the hoof wall angle (W); each 1° increase in angle S was associated with 0.6° increase in angle W (P < 0.001). Angle S was also positively associated with photographic heel angle; each degree increase in the angle S was associated with 1.8° increase in the heel angle (P < 0.001). It was concluded that the angle of the distal phalanx to the horizontal in hindlimbs is smaller than published values for forelimbs. The orientation of the distal phalanx in hindlimbs is correlated with external characteristics of the hoof capsule. 相似文献
9.
REASONS FOR PERFORMING STUDY: Many racing jurisdictions monitor pre-race serum concentration of total carbon dioxide (TCO2) among racing horses. To our knowledge, factors influencing concentration of TCO2 among horses participating in racing have not been systematically evaluated and reported. OBJECTIVES: To determine if characteristics of horses and racing conditions routinely recorded were significantly associated with pre-race concentration of TCO2, while accounting for and estimating effects of trainer and horse. METHODS: Pre-race serum TCO2 concentrations from 5028 starts made by 2,349 horses trained by 287 trainers at 2 racetracks in California during 2005 were examined. Data regarding characteristics of starters and race conditions obtained from a commercial database were recorded for each start. Data were analysed using mixed-effects, with TCO2 concentration as the dependent variable, and trainer and horse nested within trainer as random effects. RESULTS: Sex, class and distance of race, frusemide administration and cloudy weather conditions were significantly (P<0.001) associated with pre-race TCO2 concentration. Horses that finished in the top 3 positions had values that were slightly (0.2 mmol/) but significantly (P<0.001) greater than horses not finishing in the top 3. There were significant effects of trainer on pre-race TCO2 concentration. CONCLUSIONS: A variety of factors may influence pre-race TCO2 concentration in horses. Horses with better performance tend to have higher pre-race TCO2 concentrations. POTENTIAL RELEVANCE: TCO2 concentration is associated with improved performance although the magnitude of effect was quite small. Regulatory programmes based on monitoring should consider the influence of other factors on TCO2 concentration. 相似文献
10.
Van Heel MC Moleman M Barneveld A Van Weeren PR Back W 《Equine veterinary journal》2005,37(6):536-540
REASONS FOR PERFORNING STUDY: In order to optimise shoeing and shoeing conditions, it is essential to know how the horse adapts to a common shoeing interval. OBJECTIVES: To measure changes in location of the centre of pressure (CoP) and hoof-unrollment pattern during a shoeing interval and to assess whether these changes in CoP result directly from changes in hoof conformation or are also influenced by compensatory mechanisms. METHODS: Eighteen horses were trotted over a pressure-force measurement system shortly after shoeing and 8 weeks later. The position of the CoP was measured and also predicted using calculations based on changes in hoof conformation. RESULTS: The measured shift in CoP was less than calculated. This difference was largest in the hind feet. The hoof-unrollment pattern stayed basically the same in the front feet, but in the hind feet there was a substantial lateral shift of the trajectory of the CoP. CONCLUSIONS: Horses can compensate, to a certain extent, for changes in hoof conformation that develop during 8 weeks on shoes. As the capacity to compensate is less in the forelimbs, the relative increase in loading of these limbs during a shoeing interval is larger than in the hindlimbs. Potential relevance: This study provides essential basic data for the development of science-based shoeing techniques. 相似文献
11.
Relationships between hoof-acceleration patterns of galloping horses and dynamic properties of the track 总被引:1,自引:0,他引:1
Ratzlaff MH Wilson PD Hutton DV Slinker BK 《American journal of veterinary research》2005,66(4):589-595
OBJECTIVE: To define relationships between hoof-acceleration patterns of galloping horses and dynamic properties of the track. ANIMALS: 8 Thoroughbred horses without lameness. PROCEDURE: Acceleration-time curves were recorded by use of accelerometers attached to each hoof as each horse galloped over the track straightaway. Four sessions were conducted for each horse, with the track surface modified by sequentially adding water before each session. These acceleration-time curves were analyzed to determine peak accelerations during the support phase of the stride. Track dynamic properties (hardness, rebound, deceleration rate, rebound rate, and penetration) were recorded with a track-testing device. Moisture content and dry density were measured from soil samples. Stepwise multiple regression was used to identify relationships between hoof-acceleration variables and track dynamic properties. RESULTS: Track rebound rate was most consistently related to hoof variables, especially through an inverse relationship with negative acceleration peaks for all hooves. Also, rebound rate was related to initial acceleration peak during propulsion of the hooves of the forelimb and the nonlead hind limb as well as to the second acceleration peak during propulsion of the lead hooves of the hind limb and nonlead forelimb. CONCLUSIONS AND CLINICAL RELEVANCE: The inverse relationship between track rebound rate and negative acceleration peaks for all hooves reflects the most important dynamic property of a track. Any factor that reduces negative acceleration of the hooves will increase stride efficiency by allowing smoother transition from retardation to propulsion and therefore may be important in determining the safety of racing surfaces. 相似文献
12.
13.
日粮中添加氨基酸对焉耆马运动性能、血浆抗氧化能力及代谢指标的影响 总被引:2,自引:0,他引:2
试验旨在探讨日粮中添加氨基酸对焉耆马赛后运动性能及抗氧化能力的影响.选取运动成绩、体重、体尺、年龄相近的焉耆马11匹,随机分为3组:对照组(3匹)、试验Ⅰ组(4匹)、试验Ⅱ组(4匹).对照组饲喂基础日粮,试验Ⅰ、Ⅱ组分别在基础日粮中添加不同水平氨基酸.试验开始第20天对各组马匹进行20 km模拟比赛,赛后30 min内测定各组试验马匹的体温、脉搏、呼吸,同时采集各试验马匹血液.结果表明,试验Ⅰ、Ⅱ组焉耆马赛后0 min心率均显著低于对照组(P<0.05),赛后20 min心率、赛后5 min呼吸频率均极显著低于对照组(P<0.01);试验Ⅰ、Ⅱ组焉耆马赛后血浆中GSH-Px、T-SOD活力及GLU浓度分别比对照组高34.41%(P>0.05)、37.02%(P<0.01)、37.41%(P<0.01)和32.06%(P>0.05)、35.46%(P<0.01)、26.98%(P<0.05);试验Ⅰ、Ⅱ组焉耆马赛后血浆中MDA、LA浓度分别比对照组低38.46%(P<0.05)、17.56%(P<0.05)和38.26%(P<0.05)、13.04%(P>0.05).饲料中添加氨基酸,可提高焉耆马运动性能,有利于焉耆马运动后生理机能的快速恢复;可提高运动后焉耆马的抗氧化能力,减缓焉耆马在运动期间的疲劳症状,相比而言,添加0.25%赖氨酸的效果较好. 相似文献
14.
A retrospective study was carried out to identify factors which predisposed Thoroughbred horses to severe injuries, as compared to less severe injuries, while racing on New York Racing Association (NYRA) tracks during the period of January 1986 to June 1988. A severe injury was defined as an injury which led to humane destruction of the horse. A less severe injury was defined as a horse which didn't race within 6 months following a muscular, ligament, tendon, or skeletal injury on the racetrack. The data were obtained from the Horse Identification Department records kept by the Chief Examining Veterinarian of NYRA and included 55 severely injured horses and 245 less severely injured horses. Multiple logistic regression analysis was used to identify factors associated with the risk of severe injuries compared to less severe injuries in those horses. There was a significant association between track and the risk of severe injury (horses raced on Belmont and Saratoga were more likely to develop a severe injury compared to horses raced on Aqueduct Main). The track surface was also associated with the risk of severe injury (horses raced on a firm turf had a significantly lower risk of severe injury associated with the track was significantly modified by the track condition (horses raced at Belmont when it was muddy had a significantly increased risk compared to Aqueduct dirt). Horses were more likely to experience severe injury in the early part of the race (less than or equal to 6 furlongs) than the latter part of the race (greater than 6 furlongs). The risk of severe injury decreased with the age of the horse. 相似文献
15.
SUMMARY The presence of abnormal T waves in three or more electrocardiographic leads has been used to diagnose the cause of poor race performance in horses. This study investigated the relationship between previous racing performance in Standardbred horses and T waves, and the effect of training on the T wave. Thirty-two horses were electrocardiographed in two Sydney racing stables. Sixteen horses (50%) had ECGs with three or more leads with abnormal T waves, and these horses had won more races, had a greater ratio of wins per start and a greater number of dollars earned per start than horses with less than three abnormal T waves (P < 0.05). Horses with abnormal T waves also had significantly faster racing times (P < 0.01). There were significant (P < 0.01) correlations between the number of abnormal T waves and both number of wins (R = 0.47) and dollars earned per start (R = 0.45). Fastest winning mile rate was also negatively correlated with number of leads with abnormal T waves (R =?0.52, P < 0.01). Twenty two horses were also electrocardiographed within seven days of good racing performance. The mean number of abnormal T waves was 2.7 ± 0.41, and the mean T wave amplitude in the four chest leads (CV, CR, CL, CF) was 0.9 ± 0.15 mV. Thirteen horses (59%) had abnormal T waves in three or more leads. The effect of training on the T wave was also investigated in nine previously untrained and unraced Standardbred racehorses. There were significant effects of training (P < 0.01) on the number of abnormal T waves and mean chest lead T wave amplitude. These increases occurred in the second phase of training during which faster exercise, race trials and racing were conducted. We concluded that abnormal T waves are a common finding in the race-fit Standardbred horse, and can be found in more than 50% of horses currently performing well in races. In addition, chest lead T waves become more positive after training. 相似文献
16.
Information on the incidence of injury, illness, and unexplained loss of athletic performance of 2345 Standardbred racehorses was gathered from a telephone survey of 177 trainers during the 1996-1997 season. Trainer-reported incidence of infection and illness (18%) was higher than the incidence of musculoskeletal problems (10%) or unexplained athletic performance loss (6%). Older horses (>5 years) were more likely to develop musculoskeletal problems (odds ratio [OR] = 3.9; confidence interval [CI] = 1.8-8.2) and performance loss OR = 2.3, CI = 1.1-5.2) than 2-year-old horses. Horses were more likely to suffer musculoskeletal problems if fast-worked on tracks or surfaces with no banking compared with those fast-worked on tracks with banking similar to commercial racetracks OR = 4.6, CI = 2.0-9.9). Horses given no warm-up before high-intensity exercise were more likely to suffer a musculoskeletal problem than horses given a light warm-up of 1 to 9 minutes OR = 2.5, CI = 1.5-4.4). Horses trained for more than 164 min·wk−1 were more likely to suffer musculoskeletal problems OR = 1.7, CI = 1.1-2.8) and athletic performance loss OR = 2.5, CI = 1.4-4.4) than horses trained for shorter periods. Horses given a moderate weekly exercise duration (132-148 min·wk−1) had the lowest rates of infection and illness, but short (114-131 min·wk−1) or very long (>164 min·wk−1) weekly exercise duration increased the risk of horses suffering infection and illness OR = 1.6, CI = 1.1-2.2 and OR = 1.3, CI = 1.0-1.9, respectively). We conclude that Standardbred trainers could avoid many training and health problems by using well-banked tracks, providing a proper warm-up, and avoiding excessive training.
Introduction
Racehorses suffer from a variety of health and training problems that may result in poor performance. Musculoskeletal injury is a major problem in Thoroughbred racehorses, accounting for as much as 53% of the lost training and racing days.[1 and 2] Thoroughbreds that race too often, [2 and 3] have insufficient training before racing, [4] or perform too much high-speed work [5] have a greater risk of musculoskeletal problems. Performance may also be affected by respiratory infection, which is responsible for 12% of lost training or racing days. [1]Poor performance can also develop in an otherwise apparently healthy horse. Such unexplained loss of athletic performance may arise from undiagnosed health problems or from too much training.[6] Overtraining described as a state of prolonged fatigue caused by too much training or insufficient recovery [7] has been demonstrated in horses in both cross-sectional and longitudinal studies, [8 and 9] but the incidence of athletic performance loss because of overtraining in the population is unknown. Recently reported prospective studies that used the same group of horses has found that overtraining appeared to be difficult to induce in horses, [10, 11, 12 and 13] which may indicate that overtraining accounts for little of the loss in athletic performance suffered by Standardbred racehorses.It is thought that lameness is the most important cause of poor racing performance in Standardbreds[14]; however, the incidence of musculoskeletal problems causing lameness in Standardbreds is lacking. There is also little information on the incidence of respiratory disease or athletic performance loss in Standardbreds. The purpose of this study was to determine the trainer-reported incidence of these problems in Standardbred racehorses and to reveal any association with factors such as sex, age, ability, training, track surface, and track design.Materials and methods
A survey was administered by telephone to 177 Standardbred racehorse trainers randomly selected from a list of 300 trainers compiled by Harness Racing New Zealand. The survey was administered at the end of the 1996-1997 racing season, which lasts from about September through June, and questions asked during the survey related to the 1996-1997 racing season. Trainers were asked to recall the total number of horses that experienced an unexplained and consistent loss of athletic performance (“performance decrease that lasted for at least two weeks, which was not obviously as a result of tying up, infection, illness, or musculoskeletal problems”). Trainers were also asked for the total number of horses that suffered infection or illness (viral and bacterial infections and respiratory diseases but not bleeding from the lungs), and musculoskeletal problems (lameness caused by muscle, tendon, bone, or back injuries that resulted in lost training days). Pilot work involved testing the questionnaire on 10 local horse trainers; from their feedback and that of other colleagues and horse trainers, more than 11 revisions were made. The interview consisted of 65 questions and lasted approximately 20 minutes. The incidences of performance loss and health problems detailed in this study are trainer-diagnosed; however, in the majority of cases (80%), the horses were also examined by a veterinarian and their diagnosis was consistent with the trainer's. Unfortunately, full details of the veterinary examination were not obtained during this study.To examine the influence of track design and banking, trainers were asked to compare the banking of their training tracks to the banking of a commercial racetrack (Forbury Park Raceway, Dunedin, New Zealand, which had a banking angle of approximately 2.3 degrees). Trainers had to decide whether the banking of their track was more, less, or about the same as the banking of the commercial track. Because of the need to keep the questionnaire to a reasonable size, in-depth training data was collected on only one particular group of horses—qualified maidens. Qualified maiden racehorses (previously raced but unplaced) represent the largest group of racehorses in training in New Zealand. Trainers were also asked whether they trained their other horses (faster, slower, unqualified, 1-7, or >7 wins) any differently from the qualified maidens. Information on training type, duration, and intensity were gathered for each day of a typical training week. Exercise duration and total training workload was divided into quintiles (5 equal sections) and contrasts between the quintiles were then examined. Trainers were specifically asked about the duration of the warm-up, which was not included in the total training time. Warm-up was defined as the initial preparatory phase of a training session in which the horse is slowly accustomed to low-intensity exercise and prepared for further high-intensity exercise.Although it is acknowledged that career wins is a crude method of assessing racing ability, it was the most appropriate method available to the researchers during a phone interview that gave some indication of horses' ability. Trainers were therefore asked about the number of wins for each horse and horses were grouped according to the total number of career wins. The Human Ethics Committee of the University of Otago reviewed and approved this project (reference number 97/049).The survey data were analyzed using a repeated-measures general modeling procedure (Proc Genmod, SAS Institute, Cary, NC), which estimated the effect of age, sex, gait, number of wins, warm-up, track design, training duration, and workload as odds ratios ORs). The OR is a way of comparing whether the probability of a certain event is the same for two groups. An OR of 1 implies that the event is equally likely in both groups, whereas an OR of more than one implies that the event is more likely in the first group compared with the second. For example, the odds of a horse suffering a musculoskeletal injury if fast-worked on tracks with no banking is 0.52 (cases/noncases = 12 injured/23 noninjured), whereas the odds of a horse suffering a musculoskeletal injury on well-banked tracks is 0.11 (37 injured/329 noninjured). Therefore, the OR is 4.6 and is interpreted as: 4.6 horses suffer a musculoskeletal injury if fast-worked on an unbanked track compared with every 1 horse that suffers the same injury when fast-worked on well-banked tracks. Proc Genmod (SAS Institute) analyzed the total number of horses in a particular subgroup and the total number of problems in the same subgroup for each trainer. A type I error of 5% was chosen for declaration of statistical significance; precision of estimates was represented by the 95% confidence interval (CI), the likely range of the true value.To estimate the reliability of the trainer's responses, a second questionnaire identical to the first was administered to 17 randomly selected trainers from the same sample 8 months after the original survey. The trainers' responses to the same questions from separate surveys given 8 months apart were used to gauge reliability of the survey. Questions on the sex, gait, and number of race wins of the horses under the trainers' care that suffered health and training-related problems were analyzed. These variables represented population characteristics of the horses that could change with time as horses entered or left the trainers stables, and therefore affect the reliability of the reported data. Survey reliability was found by comparing the empirical standard error of the odds ratio from the initial (Main) and second (Rely) surveys after adjustment for sample size. When the empirical standard error was similar (within one decimal place) between studies, then reliability was considered low, but when the empirical standard error was smaller in the Rely survey compared with the Main survey, then the reliability of the survey was acceptable.Results
Overall training and health problems
Horses were 2.1 times more likely to suffer from infections and illness than from musculoskeletal problems (CI = 1.4-2.8, P < .001) and musculoskeletal problems were 1.7 times more likely to occur than athletic performance loss (CI = 1.2-2.3, P < .001). Horses that had no recognized problems raced 12 ± 6 times (mean ± SD) over the main racing season (September 1996-June 1997).Athletic performance loss
Sixty-eight trainers reported that a total of 146 horses developed a decrease in athletic performance not readily associated with musculoskeletal injury, illness, or tying-up during the season (6% of the 2345 horses sampled). Most horses (78%) that suffered athletic performance loss required at least 6 weeks to recover to normal form; the remaining 22% recovered within 4 weeks. In general, the decrease in athletic performance occurred towards the middle and end of the racing season. The incidence of athletic performance loss in the various subgroups of horses is shown in Table 1, and the ORs and confidence limits for statistically significant differences in incidence within each subgroup are shown in Table 2. 相似文献17.
P.W. Physick‐Sheard M.K.J. McGurrin 《Journal of veterinary internal medicine / American College of Veterinary Internal Medicine》2010,24(5):1158-1166
Background: A lack of information on normal heart rhythm at maximal effort hampers investigation of poor performance and sudden death in Standardbred racing. Hypothesis/Objective: To characterize rhythm variations during scheduled racing in clinically normal Standardbred horses. Animals: Two hundred and eighty‐eight Standardbred horses competing in 40 scheduled races at a Southern Ontario racetrack. Methods: Observational study, convenience sampling: Heart rhythm was monitored by ECG from harnessing to postrace recovery and assessed visually and by examining heart rate intervals. Rhythm variations were used as response variables in multivariate analysis of race records detailing signalment, race, and race outcome. Results: Monitoring involved 345 individual horse or race events. Occasional, isolated premature cycles, only, occurred during the race. Postrace, sudden cardiac slowing (punctuated deceleration [PD]) appeared in 42 events (12.2%). Only premature ventricular complexes were exhibited in 40 events postrace (11.6%), whereas 55 (15.9%) exhibited complex ventricular arrhythmias (CVA) including torsades‐like polymorphic ventricular tachycardia, 34.5% of these being closely associated with PD (odds ratio = 8). Predispositions to CVA were found for horses parked at the 1/2 mile (odds ratio = 3), and trotters breaking in the stretch (odds ratio = 38). Horses spontaneously reverted to sinus rhythm and no sudden death events were encountered. Conclusions and Clinical Importance: Arrhythmias occur frequently in racing Standardbreds during cardiac deceleration, often associated with sudden, rapid increases in vagal tone. Circumstances imposing unusual demand and racing at the trot appear to predispose. Findings provide insight into possible mechanisms of sudden death. 相似文献
18.
J B Woodie A J Ruggles A L Bertone J Hardy R K Schneider 《Journal of the American Veterinary Medical Association》1999,214(11):1653-1656
OBJECTIVE: To determine whether fracture fragment dimensions, suspensory ligament damage, and racing status at the time of injury were associated with outcome in Standardbred horses with apical fracture of the proximal sesamoid bone. DESIGN: Retrospective study. ANIMALS: 43 Standardbred racehorses. PROCEDURE: Medical records, racing records, and radiographs were reviewed, and ultrasonographic findings were scored. Measurements of the fractured portion of the proximal sesamoid bone were made. RESULTS: Seventy-four percent (32/43) of horses were pacers, and 26% (11/43) were trotters. Statistical differences between trotters and pacers regarding ability to start, number of starts, or amount of money earned after injury were not detected. Females earned significantly more money per start after injury than males. Eighty-six percent (37/43) of fractures involved hind limbs and 14% (6/43) involved forelimbs. Horses with forelimb injuries earned less money per start. Severity of suspensory ligament damage did not affect postinjury racing performance. A higher proportion of horses that had raced before injury returned to racing after surgery than horses that had not raced before injury, although a significant difference between these groups was not detected. Eighty-eight percent of horses that raced before injury raced after injury. Fifty-six percent of horses that did not race before injury raced after injury. Fracture fragment dimensions did not affect outcome. CLINICAL IMPLICATIONS: Dimensions of the apical fracture fragment of the proximal sesamoid bone in Standardbred horses and degree of suspensory ligament damage did not affect outcome. Prognosis for return to racing soundness is good in horses that had raced before injury and fair in horses that had not raced before injury. 相似文献
19.
The objective of this study was to report recovery time, retirement rate, racing performance, and presence of compensation pattern after musculoskeletal injuries (MSIs) in Standardbred racehorses (STBRs). This is a retrospective single open-cohort study, enrolling 356 STBRs in training in a single racetrack. Musculoskeletal injury was defined as any training-related injury after which the horse did not train for at least 15 days. The first and second MSIs encountered during the horse’s racing career were considered. Medical records, training logbooks, and racing data were reviewed to determine recovery time, retirement rate, racing performance, and compensation pattern after MSIs. Kaplan–Meier estimators considered the return to activity as primary endpoint. The hazard ratio (HR) for return to activity was determined using Cox proportional hazard models, after classifying horses based on the injury type. A total of 543 MSIs were considered. The 33.6% (95% confidence limits [CL]: 29.5, 37.8) of STBRs suffering from MSI had to be retired as consequence of that. The median recovery time after MSI was 119 days (95% CL: 47, 179). Horses with traumatic osteoarthritis had a greater likelihood of returning to athletic activity compared with horses with stress fractures (HR = 4.8, 95% CL: 3.5, 6.7) and tendon/ligament strains (HR = 4.1, 95% CL: 3.1, 5.4). Increased racing speed was recorded after injuries. The second MSI was more often localized to the contralateral limb compared with the first injury (odds ratio (OR) 6.35, 95% CL: 4.29, 8.51), diagonal (OR 4.59, 95% CL: 3.05, 6.27) and to the same limb (OR 3.17, 95% CL: 2.03, 4.47) than to the ipsilateral limb. 相似文献
20.
High-speed cinematography was used to examine the relationship between velocity and linear and temporal ground contact variables of the equine transverse gallop gait. The stride characteristics of four Quarter horse fillies were used as a model. Horses were approximately thirty months of age and had been raised and trained similarly. Horses were filmed by two cameras simultaneously (243 frames/second) while galloping under the standardized conditions of a specially constructed 1.5m-wide track. Horses were all ridden with the same saddle and bridle by one person. Kinematic variables determined for sixty-two strides included stride length, step lengths and stride frequency as well as contact and non-contact periods of single limbs and combinations of limbs. Galloping velocity (10.0 to 15.0 m/sec) was strongly influenced by stride frequency (2.16 to 3.04 sec−1) and to a lesser extent by stride length (4.41 to 5.56 m). Stride length and stride frequency were independent. Variations in velocity were not associated with any detectable variations in absolute or relative distances between successive limb impacts. Increases in stride length at constant stride frequency were accomplished by increasing the distance between fore limb impacts and also the distance between fore leading limb impact and the subsequent hind trailing limb impact. Decreases in stride duration with increased galloping velocity occurred at the expense of hind trailing limb unipedal contact, fore leading limb unipedal contact and the airborne phase duration. 相似文献