SciELO - Scientific Electronic Library Online

 
vol.68 issue4Reproductive biology of Pêga Jackasses: characteristics of sperm-rich fraction collected using the split-ejaculate method author indexsubject indexarticles search
Home Pagealphabetic serial listing  

Services on Demand

Journal

Article

Indicators

Related links

Share


Arquivo Brasileiro de Medicina Veterinária e Zootecnia

On-line version ISSN 1678-4162

Arq. Bras. Med. Vet. Zootec. vol.68 no.4 Belo Horizonte July/Aug. 2016

https://doi.org/10.1590/1678-4162-8848 

Veterinary Medicine

Biometrics of hoof balance in equids

Biometria do equilíbrio podal de equídeos

A.F. Souza1 

J.R. Kunz2 

R. Laus3 

M.A. Moreira3 

T.R. Muller3 

J.H. Fonteque3 

1Aluno de graduação - Universidade do Estado de Santa Catarina - Lages, SC

2Aluno de pós-graduação - Universidade do Estado de Santa Catarina - Lages, SC

3Universidade do Estado de Santa Catarina - Lages, SC


ABSTRACT

Differences in hoof balance between horses, mules and donkeys were identified in order to form more specific considerations for proper management of the animals. Measurements of the natural dimensions of hooves in sixty animals were used: 20 horses from the Crioulo breed, 20 mules and 20 donkeys from the Pêga breed. Liveweight was estimated using the correlation equations in each species by heart girth. Using a caliper rule, tape measure and hoof gauge, measurements of the length and width of the frog, hoof height, angle of heel, medial and lateral dorsal length, angle of the toe and crown circumference of the hooves of forelimbs and hindlimb were taken. Within each group the hooves of the hindlimbs exhibited narrower measurements than the hooves of the forelimbs and no difference was observed between the hoof angle of both members of groups. The conformation of the hooves of donkeys is shown to be substantially different from that observed in horses, the mules being in an intermediate condition, being smaller, angled and robust frog and proportionally more developed. Similarly, the hooves of donkeys provide greater support area compared to mules and horses, in descending order, even being dimensionally smaller. We conclude that the hooves of horses, mules and donkeys, have specific patterns of geometric balance that must be taken into consideration at the time of trimming and imbalance inferences.

Keywords: equine; mules; donkeys; hoof; shoeing

RESUMO

O objetivo deste trabalho foi determinar o equilíbrio dos cascos de equídeos. Foram utilizados 60 animais, sendo estes: 20 equinos da raça Crioula, 20 muares e 20 asininos da raça Pêga. O peso vivo foi estimado por meio de equações de correlação com o perímetro torácico específico a cada espécie. Utilizando-se paquímetro, fita métrica e podogoniômetro, foram mensurados comprimento e largura da ranilha e do casco, altura e ângulo dos talões medial e lateral, comprimento dorsal e ângulo da pinça e perímetro da banda coronária dos cascos dos membros torácicos e pélvicos. Dentro de cada grupo, observou-se que os cascos dos membros pélvicos exibem-se mais estreitos que os cascos dos membros torácicos, e não houve diferença entre o ângulo das pinças de ambos os grupos de membros. A conformação dos cascos dos asininos mostra-se substancialmente divergente do observado nos equinos, estando os muares numa condição intermediária, sendo aqueles menores, mais angulados e com ranilha robusta e proporcionalmente mais desenvolvida. Da mesma forma, os cascos dos asininos proporcionam maior área de apoio em relação aos muares e equinos, em ordem decrescente, mesmo sendo dimensionalmente menores. Conclui-se que os cascos de equinos, muares e asininos apresentam padrões de equilíbrio geométrico específicos, que devem ser levados em consideração no momento do casqueamento e na inferência de desequilíbrios.

Palavras-chave: equino; muares; asininos; casco; casqueamento

INTRODUCTION

The guidelines of proper hoof trimming are based on observations of the way the hoof is shaped and its adaptation to the pattern of movement carried out by the individual (Davies et al., 2007; Stashak, 2006). Besides genetic orietation, the hoof conformation changes due to variations in the environment, type of pace, nutrition and a large portion of management to which the hooves are subjected, therefore variations within the same species and even more remarkable in different species within the same genus can be identified due to these variables. Classically, the genus Equus had anatomophysiological compensatory adaptations (Senior, 2013; Grosenbaugh et al., 2011), and among them foot balance (Burnham, 2002).

Historically, mules and donkeys showed enormous contribution to the development of civilizations, with extensive use in various tasks, especially those related to traction, due to its rustic features and great adaptability to different environmental conditions (Clutton-Brock et al., 1992). With the evolution of mechanical engineering the equide was directed to leisure and competition, and horses began to have immense economic value (Grosenbaugh et al., 2011). Scientific research was mainly directed to horses and often extrapolating for other species such as mules and donkeys, which can often be a mistake (Senior, 2013; Burnham, 2002).

Even with clear differences in conformation of the hooves of different equides, the farrier may often establish adjustments based on subjective inferences from the widespread knowledge about horses, which can lead to disastrous consequences in the locomotion of the mules and donkeys. To this end, it is necessary to investigate and to determine the differences in hoof characteristics between these groups of animals in order to make specific recommendations, since the current literature is lacking in foot balance approach for donkeys and mules.

The aim of this study is to identify differences in hoof balance between horses, mules and donkeys, in order to create a more specific and proper management of the hooves of these animals.

MATERIALS E METHODS

The animal use met the requirements of the Santa Catarina State University Animal Ethics Committee (n° 01.05.13). Animal owners gave consent for their inclusion in the study.

The hooves of fore and hindlimbs from 60 equids were measured, divided into three groups; 20 horses from the Crioulo breed, with mean age of 8.3±5.0 years and mean liveweight of 425.32±45.47kg, 65% (13 animals) were females and 35% (seven animals) were males; 20 mules, from crosses predominantly among asses from the Pêga breed with mares of theThoroughbred or Mangalarga Marchador breeds, with mean age of 6.2±2.3 years and mean liveweight of 284.82±31.20kg, being 75% (15 animals) females and 25% (five animals) males, and 20 Pêga donkeys with a mean age of 8.7±8.5 years and mean liveweight of 218.97±37.83kg, 60% (12 animals) females and 40% (eight animals) males. All animals were unshod and with adequate foot conformation, kept in a semiextensive system and feed with natural pasture, hay and ryegrass Tifton, mineral salt, commercial concentrated feed and water ad libitum.

The evaluation of the particulars of the measurement of the hooves was made according to descriptions by Turner (1992), Lazzeri (1992) and Melo et al. (2006), the use of a caliper rule, tape measure and hoof gauge. The measured parameters were: length and width of the hoof, medial and lateral height of heel, toe length, hoof angle, angles of the lateral and medial heel, width and length of the hoof and crown circumference. The weight of the equine was estimated using a tape correlation between the liveweight and heart girth, which takes into account the equation: heart girth (m)3 x 80. The estimated liveweight of mules and donkeys was performed using correlation equations: ((heart girth (cm) x 3.57) - 292) and heart girth (cm)2.65 / 2188, proposed by Kay et al. (2004) and Pearson and Ouassat (1996), respectively. The relationship between liveweight and the area of the hoof to evaluate the size of the hoof to the animal's weight was carried out using the formula ([liveweight x 12,56] / crown circumference2) (Turner, 2003)

T test was used to compare the averages within each group and ANOVA followed by Tukey's test was performed for comparisons between groups, with P<0.05. The Pearson's correlation was used to assess the liveweight across the back toe length and the crown circumference.

RESULTS

Means and standard deviations of the 11 variables measured for forelimbs and hindlimbs of horses, mules and donkeys are shown in Table 1.

Table 1 Means and standard deviations of measurements of the hooves for fore and hindlimbs of horses from the Crioulo breed (n = 20), mules (n = 20), and the Pêga breed donkeys (n = 20) 

-------- Horses -------- -------- Mules -------- -------- Donkeys --------
Measurements Forelimb Hindlimb Forelimb Hindlimb Forelimb Hindlimb
Frog's length (cm) 8.31±0.71Aa 8.30±0.68Aa 7.83±0,68Ba 7.37±0.61Bb 6.30±0.81Ca 6.03±0.67Ca
Frog's width (cm) 5.60±0.58Ab 6.09±0.59Aa 4.71±0,81Bb 5.59±0.79Ba 5.41±0.55Ab 5.98±0.48Aa
Medial heel length (cm) 5.04±0.53Aa 4.35±0.58Ab 4.66±0,54Ba 4.10±0.39ABb 4.36±0.60Ca 4.02±0.56Bb
Lateral heel length (cm) 5.07±0.52Aa 4.33±0.52Ab 4.75±0,58Ba 3.91±0.47Bb 4.42±0.55Ca 3.73±0.59Bb
Toe length (cm) 8.59±0.69Aa 8.64±0.57Aa 8.46±0,79Aa 8.53±0.90Aa 7.47±0.86Ba 7.70±0.67Ba
Hoof angle (°) 52.46±3.00Ba 51.30±3.13Ca 53.59±4,47Ba 53.89±3.77Ba 59.38±5.10Aa 59.81±5.78Aa
Lateral heel angle (°) 45.63±5.37Ba 43.08±4.25Bb 44.98±6,20Ba 41.73±5.86Bb 51.00±6.69Aa 51.75±6.57Aa
Medial heel angle (°) 45.50±4.09Ba 42.71±3.50Bb 45.08±6,21Ba 43.80±6.02Ba 52.63±6.38Aa 51.70±6.82Aa
Hoof width (cm) 11.69±0.58Aa 11.26±0.60Ab 9.33±0,64Ba 8.81±0.68Bb 8.32±0.76Ca 7.58±0.52Cb
Hoof length (cm) 12.91±0.68Aa 12.79±0.60Aa 12.90±1,07Aa 12.30±1.00Bb 10.87±1.06Ba 10.42±1.02Ca
Crown circumference (cm) 33.89±1.12Aa 33.47±1.15Aa 31.12±1,97Ba 30.74±2.09Ba 29.04±1.55Ca 28.16±1.57Cb

Averages followed by the same upper case letter between groups and lower case letter within a group do not differ by the Tukey test (P<0.05).

Comparisons of measurements between members within each group showed significantly lower differences in the heights of the medial heel and sides and the width of the sole and the largest width of the hoof of the hindlimbs in all groups. The angles of the medial heel and lateral heels were smaller in hind limbs in horses and mules, and in these, the angle of the medial bead showed only numerical difference. The mules exhibit longer frog in the forelimbs accompanied by greater length of the sole. The donkeys have smaller crown circumference of the hind limbs. There was no difference between the angles and dorsal toe length in all evaluated groups.

In comparisons between groups for the forelimbs there were significant differences in the length of the frog, heights of the medial and lateral heel, width of the sole and the crown circumference in descending order respectively for horses, mules and donkeys (p <0.0001). The width of the frog was lower in mules (P<0.0001), toe length (P<0.0001), and the length of the sole were lower in donkeys (P<0.0001) which had greater caliper angles and medial heel and sides (P<0.0001). These variables showed no significant differences in the underlying groups.

The hindlimbs, the variables length of the frog, length and width of the sole and the crown circumference also showed decreasing significant differences for horses, mules and donkeys in this order (P<0.0001). Conversely there was the same configuration as the hoof angle, being consistently higher for donkeys (P<0.0001). The width of the frog was also lower in mules (P=0.0018) and horses had greater heights at medial heel (P=0.0172) and side (P<0.0001), and the angle was larger in donkeys (P<0.0001 ), which also exhibited lower toe length (P<0.0001).

The relationship between liveweight and the area of the hoof reported to be 4.71±0.47kg/cm2, 3.75±0.41kg/cm2 and 3.35±0.46kg/cm2, for horses, mules and donkeys, respectively. This revealed that the donkeys have a larger support area, which gives them more support in rustic to hostile surfaces. A moderate correlation between toe length and the liveweight on the mules (0.66) and weak for horses (0.28) and donkeys (0.30) was identified. The correlation of liveweight to the crown circumference reported to be 0.43, 0.58 and 0.66 in mules to horses and donkeys, respectively.

DISCUSSION

Extreme caution in interpreting results must be taken when using mules as an experimental model because they present strong anatomical and physiological differences due to genetic variance (Burham, 2002). There is a strong correlation between the size of the hoof and the animal's size (Melo et al., 2006). In order to minimize these effects and enable statistical analysis between groups in this work, the formation of groups was based on the closest similarity of body structure.

Analyzing hoof arquitecture, it is observed that all groups showed more rounded hooves of forelimbs, justified by the greater width of the hoof accompanied closely by frog. In contrast, the hooves of the hindlimbs showed more oval conformation due to smaller width culminating in a larger base of the frog. These results agree with the statements of Stashak (2006) and Dyce et al., (1997) which incriminate the location of the center of gravity of the forelimbs associated with support of about 60-65% of liveweight of the animal, generating greater impact during locomotion, facilitating the expansion of hooves compared to the hindlimbs.

There was a lack of parallelism of the guidelines for angles between the toe and heels in all groups, wherein the heels had average values greater than the margin commonly regarded as ideal, a variation up to five degrees in relation to the hoof angle (Turner, 2003). This difference comes from heel's lengths lugs having a third of the toe length as ideal as described by Lazzeri (1992) and Turner (2003). The magnitude of these differences was higher in donkeys, followed by mules. A more accurate visual analysis identifies that the donkeys had the angular relationship hoof:pastern prone to positive, with the base of the frog surpassing the points marked by the medial angles and side of the sole and with a higher width:length ratio, making it possible to promote greater frog contact ability with the ground and can be a cause or a consequence of a possible palmar/plantar position more poportional to the center of gravity in relation to the set in horses with even greater verticalisation of the hoof (Figure 1).

Figure 1 Respective dorsal, lateral and solear views of donkey hooves (A, B and C) mule (D, E and F) and horse (G, H and I). Obvious differences are observed in the structure and proportions of the different component parts of the hoof. 

The center of gravity in the equine hoof, also known as Duckett's Dot, is located in the palmar/plantar true apex of the frog at about 0.95 to 1.90cm, and under it is the insertion point of the deep digital flexor tendon on the surface flexion of the distal phalanx (Sampaio et al., 2014).

Establishing the length: breadth of the hoof, it is observed that this is higher in donkeys and mules, just by measuring regardless of the base of the frog, which in these animals protrudes more palmar/plantar. Associated with a larger width thereof, which leads to a higher relation with the soil, which may have more oblique conformation contribution to the heels. Whereas the frog has, among other functions, to act as a buffer component of the impact on the hooves and assist as driver of vascular return (Andrade, 1986; Stashak, 2006), that more robust configuration gives the animals more adequacy when exposed to surfaces that offer greater impact.

The hoof angle has intrinsic influence on the trajectory and landing of the hoof. In smaller angle conditions there is a tendency to support primarily the dorsal portions of the hoof, and the opposite is also true (Stashak, 2006). Thus the donkeys, since they expose much more upright hooves, tend to have a natural shortening of the cranial stage as well as the entire arch and require an increased number of steps to move through the same distance when compared to a horse with straight foot-pastern axis. The angle also influences the graft in digit, and the higher the lowest angle graft. The hoof angle also influences the impact of the digit, and the higher the lowest angle impact (Frandson et al., 1978; Clayton, 1987; Barey, 1990).

The establishment of the most appropriate hoof angle of the horse is much discussed (Bushe et al., 1987; Stashak, 2006; Andrade, 1986). This essentially depends on the conformation and activity performed by the animal, presenting variations between the fore and hindlimbs. Angulation of 45° to 50° forelimbs and 50° to 55° for pelvic, were believed for a long time, but now it is known that they are not suitable. Such a determination must be made individually, taking into account the whole conformation of the distal member portion, with greater attention to orientation of the pastern (Melo et al., 2006; Balch et al., 1995).

Observations of foot characteristics of horses living in natural conditions show values hoof angles around 54°, which seems to be the most suitable; lower values cause high stress on the flexor apparatus, with various pathological effects, and predisposes the heel's contracture and delayed breakover (Melo et al., 2006). Higher values do not seem to be as problematic if they can lead to suspensory apparatus diseases. A recent study of wild horses showed a mean of 52.8±2.6° in the forelimbs (Hampson et al., 2013).

Available foot support area is a relentlessly important factor in the health and capacity of the foot, but little discussed among professionals. The values obtained for the mule largely explains the low occurrence of foot problems, presented by larger area. According to the description by Turner (1992), for values above 5.5kg/m² or 78 lb/inch² the hoof is considered small, a common problem in animals of Quarter Horses, and it can be a cause or aggravating factor in cases of lameness. Values that are above this limit must receive the recommendation to reduce liveweight and/or the application of measures that promote the expansion of the hoof. Studies have shown the influence of different hoof shapes on the weight forces applied to the capsule and its deep structures (Mcclinchey et al., 2003; Thomason, 1998). A proper estimate of the liveweight is crucial for that assessment. Stachurska et al., (2011) discussed the inaccuracy of the methods of estimating the equine liveweight through correlations with heart girth, based on variations in body conformation that different breeds may have when in the same weight, such effect must be considered when performing similar comparisons. In the present work, the composition of groups per equivalent animal body structure, besides the use of appropriate equations for each group, minimized this effect.

A relationship between the toe length and the liveweight was proposed by Balch et al. (1991), which limits the maximum toe length according to the weight category. This assessment is more striking in mules, with moderate correlation, which is weak for horses and donkeys. This parameter is intended to serve as a guide for trimming the hoof in horses and not to infer in factors that can influence the capsule growth. There was a more suitable interrelation of weight with the crown circumference, which in all groups obtained moderate positive correlation. Decurnex et al. (2009) investigated the training effect of crown circumference in young Thoroughbred horses, noting that there is a downward trend circumference when training with consequent expansion when kept at rest. All animals used in this study had similar activity conditions, and this effect is ignored.

The scope of the perfect harmony static and dynamic hooves is virtually impossible due to the complexity of locomotion, the interactions between structures that involve the distal equine digit associated with environmental influences, as well as the individual variations.

CONCLUSIONS

There is marked difference in the balance of the hooves of horses, mules and donkeys, with donkeys presenting more upright hooves, with more robust frog and a larger area of support in relation to horses and as expected, the mules are an intermediate condition, confirming the misconduct of adopting the trimming parameters established for horses in donkeys and mules. Therefore, studies for specific knowledge training for proper evaluation and imbalances of inferences that can form solid guidelines for proper trimming of hooves in these species are needed.

REFERENCES

ANDRADE, L. S. O condicionamento do equino no Brasil. Recife: Equicenter, 1986. 201 p. [ Links ]

BALCH, O.; BUTLER, D.; WHITE, K; METCALF, S. Hoof balance and lameness -improper toe length, hoof angle, and mediolateral balance. Comp. Cont. Educ. Pract. Vet., v.17, p.1275-1283. 1995. [ Links ]

BALCH, O.; WHITE, K.; BUTLER, D. Factors involved in the balancing of equine hooves. J. Am. Vet. Med. Assoc., v.198, p.1980-1989, 1991. [ Links ]

BARREY, E. Investigation of the vertical hoof force distribution in the equine forelimb with an instrumented horseboot. Equine Vet. J., v.22, supl. 9, p.35-38, 1990. [ Links ]

BURNHAM, S. L. Anatomical differences of the donkey and mule. In: ANNUAL CONVENTION OF THE AMERICAN ASSOCIATION OF EQUINE PRACTITIONERS, 48., Orlando, Flórida, 2002. Proceedings... [s.l.]: AAEP, 2002. p.102-109. [ Links ]

BUSHE, T.; TURNER, T.; POULOS, P.; HARWELL, N.M. The effect of hoof angle on coffin, pastern, and fetlock joint angles. In: ANNUAL CONVENTION OF THE AMERICAN ASSOCIATION OF EQUINE PRACTITIONERS, 33. Proceedings..., [s.l.]: AAEP, 1987. p.729-737. [ Links ]

CLAYTON, H.M. Comparison of the stride of trotting horses trimmed with a normal and a broken back hoof-pastern axis. In: ANNUAL CONVENTION OF THE AMERICAN ASSOCIATION OF EQUINE PRACTITIONERS, 33. Proceedings..., [s.l.]: AAEP, 1987. p.289-298. [ Links ]

CLUTTON-BROCK, J. Horse power: history of the horse and the donkey in human societies. Massachusetts: Harvard University Press., 1992. [ Links ]

DAVIES, H. M.; MERRITT, J.; THOMASON, J. Biomechanics of the equine foot. In: FLOYD, A. E.; MANSMANN, R. Equine podiatry. Missouri: Saunders,. 2007, p.42-53. [ Links ]

DECURNEX, V.; ANDERSON, G.A.; DAVIES, H.M.S. Influence of different exercise regimes on the proximal hoof circumference in young Thoroughbred horses. Equine Vet. J., v.41, p.233-236, 2009. [ Links ]

DYCE, K.M.; SACK, W.O.; WENSING, C.J.G. Tratado de anatomia veterinária. 3.ed. Rio de Janeiro: Guanabara Koogan, 1997, p.446-475. [ Links ]

FRANSDON, R.D.; LEBEL, J.L.; SLADE, C.M.; BARBALANCE, R.C. Effect of slope of equine hoof on concussion and phalangeal angulation. Am. Farrier's J., p.72-73, 1978. [ Links ]

GROSENBAUGH, D.A.; HOOD, D.M. Keratin and associated proteins of the equine hoof wall. Am. J. Vet. Res., v.53, p.1859-1863, 1992. [ Links ]

GROSENBAUGH, D.A.; REINEMEYER, C.R.; FIGUEIREDO, M.D. Pharmacology and therapeutics in donkeys. Equine Vet. Educ., v.23, p.523-530, 2011. [ Links ]

HAMPSON, B.; DE LAAT, M.; MILLS, P.; POLLITT, C.C. The feral horse foot. Part A: observational study of the effect of environment on the morphometrics of the feet of 100 Australian feral horses. Aust. Vet. J., v.91, p.14-22, 2013. [ Links ]

KAY, G.; PEARSON, R.A.; OUASSAT, M. Estimation of the liveweight of working mules in Morocco from their body measurements. Vet. Rec., v.154, p.85-88, 2004. [ Links ]

LAZZERI, L. Lições de podologia equina. Belo Horizonte EV-UFMG,. 1992, 224p. [ Links ]

MCCLINCHEY, H.L.; THOMASON, J.J.; JOFRIET, J.C. Isolating the effects of equine hoof shape measurements on capsule strain with finite element analysis. Vet. Comp. Orthop. Traumatol., v.16, p.67-75, 2003. [ Links ]

MELO, U.P.D.; FERREIRA, C.; SANTIAGO, R.M.F.W. et al. Equilíbrio do casco eqüino: uma revisão. Cienc. Anim. Bras., v.7, p.389-398, 2006. [ Links ]

PEARSON, R.A.; OUASSAT, M. Estimation of the liveweight and body condition of working donkeys in Morocco. Vet. Rec., v.138, p.229-233, 1996. [ Links ]

SAMPAIO, B.F.B., SHIROMA, M.Y.M., BERTOZZO, B.R. et al. Equilíbrio do casco equino. Rev. Electron. Vet., v.15, p.1-11, 2014. [ Links ]

SENIOR, J.M. Not small horses: improving treatments for donkeys. Vet. Rec., v.173, p.292-293, 2013. [ Links ]

STACHURSKA, A.; KOLSTRUNG, R.; PIETA, M.; SILMANOWICZ, P. Hoof size as related to body size in the horse (Equus caballus). Anim. Sci. Pap. Rep., v.29, p.213-222, 2011. [ Links ]

STASHAK, T.S. Claudicação em equinos segundo Adams. 5.ed, São Paulo: Roca, 2006. 1093p. [ Links ]

THOMASON, J.J. Variation in surface strain on the equine hoof wall at the midstep with shoeing, gait, substrate, direction of travel, and hoof shape. Equine Vet. J., v.30, supl.26, p.86-95, 1998. [ Links ]

TURNER, T.A. Examination of the equine foot. Vet. Clin. N. Am. Equine Pract., v.19, p.309-332, 2003. [ Links ]

TURNER, T.A. The use of hoof measurements for the objective assessment of hoof balance. ANNUAL CONVENTION OF THE AMERICAN ASSOCIATION OF EQUINE PRACTITIONERS, 38. Proceedings..., [s.l.]: AAEP, 1992. p.389-395, 1992. [ Links ]

Received: October 29, 2015; Accepted: December 10, 2015

Creative Commons License This is an open-access article distributed under the terms of the Creative Commons Attribution License