Difference between revisions of "Equine Protozoal Myeloencephalitis"

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==Epidemiology==
 
==Epidemiology==
In endemic areas of the United States, around a quarter of referrals for equine neurological disease are attributed to EPM.<ref>Reed, S.M, Granstrom, D, Rivas, L.J, Saville, W.A, Moore, B.R, Mitten, L.A (1994) Results of cerebrospinal fluid analysis in 119 horses testing positive to the Western blot test on both serum and CSF to equine protozoal encephalomyelitis.  In ''Proc Am Assoc Equine Pract'', Vancouver BC, AEEP, Lexington, KY, p199.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  According to the United States Department of Agriculture, the average incidence of the disease is 14 cases per 10,000 horses per year.  However, the challenges of obtaining a definitive diagnosis may mean this figure is an underestimate.<ref name="Furr">Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  The disease has been identified in parts of Central and South America, southern Canada and across most of the USA..<ref name="Furr">Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref> EPM is noted occasionally in other countries, in horses that have been imported from the Americas.<ref>Pitel, P.H, Pronost, S, Gargala, G, Anrioud, D, Toquet, M-P, Foucher, N, Collobert-Laugier, C, Fortier, G, Ballet, J-J (2002) Detection of ''Sarcocystis neurona'' antibodies in French horses with neurological signs, ''Int J Parasitol'', 32:481-485.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref><ref>Goehring, L.S (2001) Sloet van Oldruitenborgh-Oosterbaan MM: Equine protozoal myeloencephalitis in the Netherlands?  An overview, ''Tijdschr Diergeneeskd'', 126:346-351.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  It is likely that these animals underwent transportation carrying a silent but persistent infection.  There have been reports of EPM in horses that have not travelled to or from endemic regions,<ref name="Furr">Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref> although cross-reacting antigens on the immunoblot test may explain this discrepancy. <ref name="Furr">Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  
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In endemic areas of the United States, around a quarter of referrals for equine neurological disease are attributed to EPM.<ref>Reed, S.M, Granstrom, D, Rivas, L.J, Saville, W.A, Moore, B.R, Mitten, L.A (1994) Results of cerebrospinal fluid analysis in 119 horses testing positive to the Western blot test on both serum and CSF to equine protozoal encephalomyelitis.  In ''Proc Am Assoc Equine Pract'', Vancouver BC, AEEP, Lexington, KY, p199.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  According to the United States Department of Agriculture, the average incidence is 14 cases per 10,000 horses per year.  However, the challenges of obtaining a definitive diagnosis may mean this figure is an underestimate.<ref name="Furr">Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  EPM has been identified in parts of Central and South America, southern Canada and across most of the USA.<ref name="Furr">Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref> The disease is noted occasionally in other countries, in horses that have been imported from endemic regions.<ref>Pitel, P.H, Pronost, S, Gargala, G, Anrioud, D, Toquet, M-P, Foucher, N, Collobert-Laugier, C, Fortier, G, Ballet, J-J (2002) Detection of ''Sarcocystis neurona'' antibodies in French horses with neurological signs, ''Int J Parasitol'', 32:481-485.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref><ref>Goehring, L.S (2001) Sloet van Oldruitenborgh-Oosterbaan MM: Equine protozoal myeloencephalitis in the Netherlands?  An overview, ''Tijdschr Diergeneeskd'', 126:346-351.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  It is likely that these animals carried a silent but persistent infection during transportation.  There have been reports of EPM in horses that have not travelled to or from endemic regions,<ref name="Furr">Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref> although cross-reacting antigens in immunodiagnostic tests may explain this discrepancy. <ref name="Furr">Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  
  
The route of infection remains unconfirmed,<ref name="Pasq">Pasquini, C, Pasquini, S, Woods, P (2005) '''Guide to Equine Clinics Volume 1: Equine Medicine''' (Third edition), ''SUDZ Publishing'', 245-250.</ref> but there is an increased risk associated with a young age (1-4 years)<ref>Saville, W.J.A, Reed, S.M, Granstrom, D.E, Morley, P.S (1997) Some epidemiologic aspects of equine protozoal myeloencephalitis.  ''Proceedings of the Annual Convention of the AAEP'', 43:6-7.</ref>and autumn months.<ref name="NAHMS">NAHMS (2000): ''Equine protozoal myeloencephalitis in the US'', Ft Collins, CO, USDA:APHIS:VS, CEAH, National Animal Health Monitoring System.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  The reported age range for EPM cases is currently 2 months<ref name="EPM8">Gray, L.C, Magdesian, K.G, Sturges, B.K, Madigan, J.E (2001) Suspected protozoal myeloencephalitis in a two-month-old colt.  ''Vet Rec'', 149:269-273.</ref> to 24 years.<ref>MacKay, R.J, Davis, S.W, Dubey, J.P (1992) Equine protozoal myeloencephalitis, ''Compend Contin Educ Pract Vet'', 14:1359-1367.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  Thoroughbreds, Standardbreds and Quarterhorses are most frequently affected across the US and Canada.<ref>Fayer, R, Mayhew, I.G, Baird, J.D, Dill, S.G, Foreman, J.H, Fox, J.C, Higgins, R.J Higgins, Reed, S.M, Ruoff, W.W, Sweeney, R.W, Tuttle, P (1990) Epidemiology of equine protozoal myeloencephalitis in North America based on histologically confirmed cases, ''J Vet Intern Med'', 4:54-57.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  This may relate to a breed predispostion or alternatively, managemental factors associated with these breeds.<ref>Boy, M.G, Galligan, D.T, Divers, T.J (1990) Protozoal encephalomyelitis in horses: 82 cases (1972-1986), ''J Am Vet Med Assoc'', 196:632-634.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  Showing, racing and stress<ref name="Saville">Saville, W.J, Reed, S.M, Morley, P.S, Granstrom, D.E, Kohn, C.W, Hinchcliff, K.W, Wittum, T.E (2000) Analysis of risk factors for the development of equine protozoal myeloencephalitis in horses.  ''J Am Vet Med Assoc'', 217:1174-1180.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref> have been linked to a greater risk of clinical disease.<ref>Saville, W.J.A, Reed, S.M, Morley, P.S (1999) Examination of risk factors for equine protozoal
+
The route of infection remains unconfirmed,<ref name="Pasq">Pasquini, C, Pasquini, S, Woods, P (2005) '''Guide to Equine Clinics Volume 1: Equine Medicine''' (Third edition), ''SUDZ Publishing'', 245-250.</ref> but there is an increased risk associated with a young age (1-4 years)<ref>Saville, W.J.A, Reed, S.M, Granstrom, D.E, Morley, P.S (1997) Some epidemiologic aspects of equine protozoal myeloencephalitis.  ''Proceedings of the Annual Convention of the AAEP'', 43:6-7.</ref>and autumn months.<ref name="NAHMS">NAHMS (2000): ''Equine protozoal myeloencephalitis in the US'', Ft Collins, CO, USDA:APHIS:VS, CEAH, National Animal Health Monitoring System.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  The reported age range for EPM cases is currently 2 months<ref name="EPM8">Gray, L.C, Magdesian, K.G, Sturges, B.K, Madigan, J.E (2001) Suspected protozoal myeloencephalitis in a two-month-old colt.  ''Vet Rec'', 149:269-273.</ref> to 24 years.<ref>MacKay, R.J, Davis, S.W, Dubey, J.P (1992) Equine protozoal myeloencephalitis, ''Compend Contin Educ Pract Vet'', 14:1359-1367.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  Thoroughbreds, Standardbreds and Quarterhorses are most frequently affected across the US and Canada.<ref>Fayer, R, Mayhew, I.G, Baird, J.D, Dill, S.G, Foreman, J.H, Fox, J.C, Higgins, R.J Higgins, Reed, S.M, Ruoff, W.W, Sweeney, R.W, Tuttle, P (1990) Epidemiology of equine protozoal myeloencephalitis in North America based on histologically confirmed cases, ''J Vet Intern Med'', 4:54-57.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  This may relate to a breed predispostion or alternatively, managemental factors associated with these breeds.<ref>Boy, M.G, Galligan, D.T, Divers, T.J (1990) Protozoal encephalomyelitis in horses: 82 cases (1972-1986), ''J Am Vet Med Assoc'', 196:632-634.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  Showing, racing and stress<ref name="Saville">Saville, W.J, Reed, S.M, Morley, P.S, Granstrom, D.E, Kohn, C.W, Hinchcliff, K.W, Wittum, T.E (2000) Analysis of risk factors for the development of equine protozoal myeloencephalitis in horses.  ''J Am Vet Med Assoc'', 217:1174-1180.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref> have been linked to a greater risk of clinical disease.<ref>Saville, W.J.A, Reed, S.M, Morley, P.S (1999) Examination of risk factors for equine protozoal myeloencephalitis.  ''Proceedings of the Annual Convention of the AAEP'', 45:48-49.</ref>  
myeloencephalitis.  ''Proceedings of the Annual Convention of the AAEP'', 45:48-49.</ref>  
 
  
 
Increasing age and environmental temperature have been associated with an increased seroprevalence of ''S. neurona''.<ref>Tillotson, K, McCue, P.M, Granstrom, D.E, Dargatz, D.A, Smith, M.O, Traub-Dargatz, J.L (1999) Seroprevalence of antibodies to ''Sarcocystis neurona'' in horses residing in northern Colorado, ''J Equine Vet Sci'', 19:122-126.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  Seroprevalence for this species is typically higher than for ''N. hughesi''.<ref name="Furr">Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>Other risk factors for EPM include the presence of opossums, rats, mice and woodland, increased population density of humans and horses, bedding horses on shavings or wood chips and the use of purchased grain.<ref name="Furr">Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>Case clustering may operate where all the risk factors occur, but the majority of cases appear in isolation.<ref name="Furr">Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>
 
Increasing age and environmental temperature have been associated with an increased seroprevalence of ''S. neurona''.<ref>Tillotson, K, McCue, P.M, Granstrom, D.E, Dargatz, D.A, Smith, M.O, Traub-Dargatz, J.L (1999) Seroprevalence of antibodies to ''Sarcocystis neurona'' in horses residing in northern Colorado, ''J Equine Vet Sci'', 19:122-126.  In: Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>  Seroprevalence for this species is typically higher than for ''N. hughesi''.<ref name="Furr">Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>Other risk factors for EPM include the presence of opossums, rats, mice and woodland, increased population density of humans and horses, bedding horses on shavings or wood chips and the use of purchased grain.<ref name="Furr">Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>Case clustering may operate where all the risk factors occur, but the majority of cases appear in isolation.<ref name="Furr">Furr, M (2010) ''Equine protozoal myeloencephalitis'' in Reed, S.M, Bayly, W.M. and Sellon, D.C (2010) '''Equine Internal Medicine''' (Third Edition), ''Saunders'', Chapter 12.</ref>

Revision as of 12:42, 21 July 2010




Also known as: EPM

Equine protozoal myelitis
Equine protozoal encephalomyelitis


Description

A progressive, infectious,[1]neurological disease of horses, endemic in the USA[2] and only encountered elsewhere in equids that have travelled in the Americas.[3] Equine protozoal myeloencephalitis (EPM) is one of the most frequently diagnosed neurological conditions in the Western Hemisphere[4] and the principal differential for multifocal, asymmetric progressive central nervous system (CNS) disease.[1] The disease is not contagious.[1]

Aetiology

EPM results from infection of the CNS by the apicomplexan parasite Sarcocystis neurona or, less frequently, its close relative Neospora hughesi.[5][6] These protozoans develop within neurons[4] causing immediate or inflammatory-mediated neuronal damage. The organisms migrate randomly through the brain and spinal cord causing asymmetrical lesions of grey and white matter and thus multifocal lower and upper motor neuron deficits.[1]

Epidemiology

In endemic areas of the United States, around a quarter of referrals for equine neurological disease are attributed to EPM.[7] According to the United States Department of Agriculture, the average incidence is 14 cases per 10,000 horses per year. However, the challenges of obtaining a definitive diagnosis may mean this figure is an underestimate.[4] EPM has been identified in parts of Central and South America, southern Canada and across most of the USA.[4] The disease is noted occasionally in other countries, in horses that have been imported from endemic regions.[8][9] It is likely that these animals carried a silent but persistent infection during transportation. There have been reports of EPM in horses that have not travelled to or from endemic regions,[4] although cross-reacting antigens in immunodiagnostic tests may explain this discrepancy. [4]

The route of infection remains unconfirmed,[1] but there is an increased risk associated with a young age (1-4 years)[10]and autumn months.[11] The reported age range for EPM cases is currently 2 months[2] to 24 years.[12] Thoroughbreds, Standardbreds and Quarterhorses are most frequently affected across the US and Canada.[13] This may relate to a breed predispostion or alternatively, managemental factors associated with these breeds.[14] Showing, racing and stress[15] have been linked to a greater risk of clinical disease.[16]

Increasing age and environmental temperature have been associated with an increased seroprevalence of S. neurona.[17] Seroprevalence for this species is typically higher than for N. hughesi.[4]Other risk factors for EPM include the presence of opossums, rats, mice and woodland, increased population density of humans and horses, bedding horses on shavings or wood chips and the use of purchased grain.[4]Case clustering may operate where all the risk factors occur, but the majority of cases appear in isolation.[4]

Life Cycle

Life cycle diagram of Sarcocystis neurona. Created by the Agricultural Research Service, the research agency of the United States Department of Agriculture, July 2005. Sourced from the USDA Agricultural Research Service page on EPM/Sarcocystis neurona, located via WikiMedia Commons.

Infective sporocysts are passed in the faeces of the definitive host and must be ingested by the horse for infection to occur. See here for further details of the life cycle of Sarcocystis neurona.

Pathogenesis

Immune clearance of S.neurona must be, in the large part, very effective, since less than 1% of horses exposed to the protozoan suffer from EPM.[11] Factors which promote disease development include parasite dose[18]and, most probably virulence of the protozoal strain. Stress induced by pregnancy, travel, training and showing (25 in Furr) may have an immunosuppressive effect that encourages infection. Indeed, it has been shown that stress affects the severity of clinical signs seen in natural infections.[19]

The 'Trojan horse' hypothesis suggests that S.neurona meroziotes traverse the blood brain barrier encrypted within leucocytes that have phagocytosed the parasite in the periphery. Once inside the CNS, eggression and infection of other cells results in encephalitis.[20] Other theories include haematogenous spread or direct passage of parasites via the cytoplasm of endothelial cells into the CNS. However, despite extensive histological lesions, few organisms are typically visible in the neural tissues of affected horses. This implies that cytokines may have a considerable role in producing pathological changes.[21] Although the protozoan may induce some degree of immunosuppression in the host[22][23], it is likely that the immune-privilege of the CNS prevents parasite clearance from this site.[4] Placental transmission is considered highly unlikely.[4]

Both humoral and cell-mediated immune mechanisms are likely to be significant in the host defence against S.neurona. Antibodies are produced soon after infection and offer some degree of protection.[4] CD8 positive T-cells and their production of IFN-γ are likely to be pivotal in the removal of intracellular stages of the parasite.[4]

Signalment

Mostly Standardbreds and Thoroughbreds aged 1-6years.[1] Foal infection may be possible.[2]

Clinical Signs

The disease onset may be acute, peracute or chronic. An insidious onset ataxia is most typical and with such cases, the clinical examination may reveal a bright, alert horse, perhaps with some focal muscle atrophy.[4] In all cases, the clinical signs are referable to diffuse focal and multifocal lesions of the white and grey matter of the spinal cord and brain.[3] The three characteristic 'As' (ataxia, asymmetry, atrophy) suggest multifocal or diffuse disease, but are not pathognomonic for EPM.[4]

Lesion Location Clinical signs
Spinal cord
  • Ataxia, paresis or spasticity of one or more limbs, often asymmetrical, signs usually worse in hindlimbs, may see stumbling, falling, knuckling, toe dragging, circumduction, crossing over, tetraparesis - areflexia, hyporeflexia (LMN) or hyperreflexia (UMN) depending on site of lesion
  • Loss of reflexes or cutaneous anaesthesia
  • Apparent lameness, particularly atypical or slight gait asymmetry of hindlimbs (not alleviated by local anaesthesia)
  • Abnormal placing reactions
  • Focal muscle atrophy of individual muscle groups[1], especially gluteal muscles, often asymmetrical
  • Generalized muscle atrophy or loss of condition
  • Localized sensory deficits and 'strip sweating' of dermatomes
  • Sacrococcygeal involvement will produce signs that mimic polyneuritis equi
Peripheral nerves
  • Upward fixation of the patella
  • Exertional rhabdomyolysis
  • Back pain
  • Gait abnormality
Brainstem (cranial nerve signs)
  • Atrophy of temporalis and masseter muscles, loss of facial sensation (V)
  • Facial (VII) and vestibulocochlear (VIII) nerve deficits often seen together:
    • VIII - vestibular signs: nystagmus, head tilt, base-wide stance (peripheral or central vestibular disease)
    • VII - unilateral facial paralysis: muzzle deviation, ptosis, ear droop
  • Loss of tongue tone (XII)
  • Dysphagia (V, VII, IX, X, XII)
  • Dorsal displacement of the soft palate (IX, X)
  • Laryngeal hemiplegia (X)
  • Abnormal menace response (II, VII)
  • Headshaking[24]
  • Blindness with or without abnormal pupillary reflexes,[1]
Cerebrum, basal nuclei, cerebellum
  • Abnormal menace response
  • Circling
  • Seizures (may be the only clinical sign)[25]
  • Abnormal electroencephalogram (EEG)
  • Asymmetrical central blindness
  • Facial hypoalgesia
  • Cerebellar ataxia
  • Altered behavior
  • Depression
  • Narcolepsy-like syndrome

Lesions of the brainstem, cerebrum or cerebellum are less frequently recognized than those of the spinal cord. Horses with severe EPM may be unable to stand or swallow and, if left untreated, progress to recumbency within 14 days to 6 months.[1] This deterioration may occur smoothly or spasmodically,[26] but is likely to result in death. It has been suggested that rapidly progressive presentations reflect brainstem lesions.[4]

Diagnosis

It is difficult to obtain a definitive antemortem diagnosis of EPM. Certain criteria must be met before such a diagnosis is assigned (Furr):

  • The relevant clinical signs must be attributable to one or more lesions of the CNS (IVIS 4)
  • Immunodiognostic tests must confirm exposure to the parasite
  • Other differentials with similar presentations should be ruled out wherever possible
  • The horse should be resident in or have travelled within the Americas (EPM3)

The primary step in the diagnostic procedure should be to carry out thorough clinical and neurological examinations (IVIS 4).

Immunodiagnostic tests

All of these tests aim to confirm exposure to the pathogens of EPM by detecting the presence of antibodies to these agents(FUrr). None of these tests is considered a gold standard and they are only supportive. Currently, a definitive diagnosis can only be obtained at postmortem.(IVIS 4)

  • Immunoblot analysis (Western blot) of serum and CSF: senstivity around 90%, specificity 48-89%.(EPM4) Cultured merozoites are used to detect antibodies versus S.neurona-specific proteins. The CSF test has over 90% specificity and sensitivity(86 in Furr). The blood brain barrier is not prevent the passage of antibodies, thus the CSF concentration of a specific antibody will be directly related to its serum concnetration (87 in Furr). This permeability is likely responsible for many of the weakly false-positive CSF immunoblot tests. Blood contamination during CSF collection or bleeding within the CNS due to trauma or infection might also cause false positives. The CSF titre will be greatly increased during CNS infection as there will be local production of the antibody. One of the difficulties in interpreting immunoblot results is that many horses develop antibodies against S.neurona in the absence of neurological disease.(EPM4) For this reason, testing CSF may be preferable to serum despite the impact that minor blood contamination may have on CSF results.(IVIS 4)False negative results may arise if horses fail to respond to the specific proteins recognised by the immunoblot. Such cases are rare, so a negative immunoblot result tends to exclude the diagnosis of EPM.(Merck) Cases that originally test negative should be re-tesed 14-21 days later. In most instances, owing to a substantial incubation period, detectable levels of IgG are present prior to the emergence of clinical signs.(Furr)
  • Whole organism indirect fluorescent antibody test (IFAT): sensitivity around 90%, specificity 97-100%.(EPM4) Serum titres of more than 1:100 and CSF titres of more than 1:5 indicate an active infection. The IFAT is considered to have slightly improved diagnostic efficiency than the immunoblot test(92 in furr) but is unable to distinguish between S.neurona and other related nonpathogenic organsims such as S.fayeri(94 in Furr). This can lead to false positive results. Compared with the immunblot test, CSF blood contamination has an insignificant effect on the IFAT.(11 in IVIS 4) An IFAT for N.hughesi is also available from the Universty of California.(Furr)
  • ELISA for antibodies to the snSAG-1 protein: based on an immunodominant surface antigen of S.neurona (SAG-1).(IVIS 4) Serum titres more than 1:100 suggest an active infection. False negatives are possible as not all S.neurona isolates produce the specific protein.(58 in Furr). SAG-5 is an alternative surface antigen of S.neurona strains, which is mutually exclusive to SAG-1.(15 in IVIS 4) Therefore, the ELISA may only be of use where strains of S.neurona expressing SAG-1 predominate.(IVIS 4)

Other tests

  • CSF analysis: to rule out other conditions as stated below. Most horses with EPM have normal CSF (Furr). Rarely, increased totoal protein or white blood cell count is seen in severe cases(Furr). PCR can be used to detect S.neurona DNA in CSF. (EPM8)
  • Diclazuril: a positive response to treatment with diclazuril would firmly support a diagnosis of EPM, since the drug has no antimicrobial activity.(EPM 1)
  • Blood gene expression biomarkers: may be sensitive and specific indicators of early and active disease[27]


Differential Diagnoses

The protozoan can migrate to any region of the CNS[2], thus the differential list comprises almost all diseases of this system.

Differential Differentiating signs Tests to rule out
Cervical vertebral malformation (CVM, cervical compressive myelopathy, cervical vertebral instability, cervical stenotic myelopathy, cervical spondylomyelopathy, Wobbler's syndrome). Symmetrical gait deficits, worse in pelvic limbs[28] with spasticity and dysmetria, good retention of strength, no muscle wasting.[4] NB: can be concurrent with EPM.[29] Plain lateral radiography of C1 to T1[29], myelography. [30]
West Nile encephalitis Systemically ill, pyrexia. Difficult to differentiate if horse is afebrile and has no excessive muscle fasciculations.[31] Leukogram, CSF analysis, IgM capture ELISA, plaque reduction neutralization test (PRNT),[30]absence of mosquito vectors.[32]
WEE Systemically ill, pyrexia, abnormal motor function.[31] Leukogram, ELISA, titres, virus isolation.[30]
EEE Systemically ill, pyrexia, abnormal motor function[31], rapidly progressive.[30] Leukogram, CSF analysis, ELISA, titres, virus isolation.[30]
VEE Systemically ill, pyrexia. Leukogram, IgM ELISA[33]
Equine herpesvirus-1 myeloencephalopathy Sudden onset and early stabilization of neurological signs, multiple horses affected, recent fever, respiratory disease, abortion.[34] Dysuria not often seen in EPM.[4] CSF analysis, buffy coat, nasal swab PCR.[32][30]
Rabies Rapid progression[35], behavioural alterations, depression, seizure, coma.[31] Post-mortem fluorescent antibody testing of brain required for definitive diagnosis.[35]
Polyneuritis equi (previously cauda equina neuritis) Cranial nerve deficits are peripheral with no change in attitude.[36] Western blot analysis of CSF.[37]
Equine degenerative myeloencephalopathy Symmetrical signs.[38] May get increased CSF creatinine kinase (CK)[39] and reduced serum Vitamin E concentrations but these are unreliable for ante mortem diagnosis.[38]
Verminous encephalomyelitis Acute onset. CSF analysis.[40]
Bacterial meningoencephalitis Stiff neck.[1]
CNS abscessation due to 'bastard strangles'[4] History of Streptococcus equi subsp. equi infection.[41] CSF analysis (severe, suppurative inflammation), culture of CSF.[41]
Spinal trauma[1] History (usually acute onset neurological signs), usually solitary lesion localised by neurological exam.[42] Radiography, myelography, CT, MRI, nuclear scintigraphy, ultrasound, CSF analysis, nerve conduction velocities, EMG, transcranial magnetic stimulation.[43]
Occipito-atlanto-axial malformation (OAAM) Deficits develop before 6mths in Arabian horse.[44] Radiography.[30]
Spinal tumor Signs can usually be localized to one region of the CNS. CT, MRI. Definitive diagnosis requires cytology, biopsy, histopathology or CSF analysis.[45]
Sorghum cystitis/ataxia[1] Posterior ataxia or paresis, cystitis, history of grazing Sorghum species[46] Demonstration of cystitis or pyelonephritis by laboratory methods, but not specific.[46]

NB: EPM has been seen concurrently with equine motor neuron disease in a mule[47]

Sarcocystis neurona stages and lesions. (A). Cross section of spinal cord of horse with focal areas of discoloration (arrows) indicative of necrosis. Unstained. (B). Section of spinal cord of a horse with severe EPM. Necrosis, and a heavily infected neuron (arrows), all dots (arrows) are merozoites. H and E stain . (C). Higher magnification of a dendrite with numerous merozoites (arrows). One extracellular merozoite (arrowhead) and a young schizont (double arrowhead). (D). Section of brain of an experimentally-infected mouse stained with anti-S. neurona antibodies. Note numerous merozoites (arrows). (E). Immature schizonts in cell culture. A schizont with multilobed nucleus (arrow) and a schizont with differentiating merozoites (arrowheads). Giemsa stain. (F). Mature sarcocysts with hairlike villar protrusions (double arrowheads) on the sarcocyst wall. H and E stain. (G). Mature live sarcocyst with numerous septa (arrows) and hairlike protrusions on the sarcocyst wall (double arrowheads). Unstained. (H). An oocyst with two sporocysts each with banana-shaped sporozoites. Unstained. Created by the Agricultural Research Service, the research agency of the United States Department of Agriculture, July 2005. Sourced from the USDA Agricultural Research Service page on EPM/Sarcocystis neurona, located via WikiMedia Commons.

Pathology

Widespread lesions of the CNS are typically observed in horses.[4]

Gross exam

Lesions may be up to several centimetres across.[4] They range from mild discolouration to multifocal areas of haemorrhage and/or malacia[26] of the brain, spinal cord and less commonly, peripheral nerves.[4]

Histopathology

Microscopically, both grey and white matter may be affected with focal to diffuse areas of nonsuppurative inflammation, necrosis and neuronal destruction. Perivascular infiltrates comprise lymphocytes, macrophages, plasma cells, giant cells, eosinophils and gitter cells.[4] In around 25% of cases, schizonts or merozoites may be found in the neuronal cytoplasm.[26] Less frequently, protozoa parasitize intravascular and tissue neutrophils and eosinophils, capillary endothelial cells and myelinated axons[4][26]. Free merozoites may be seen in necrotic regions. If organisms are absent, the diagnosis relies on recognition of the inflammatory changes described above.[26]

Treatment

Antiprotozoals

The Food and Drug Administration (FDA) has approved four treatments for use in horses with EPM, but not all of these are commercially available:[32]

  • Sulfadiazine and pyrimethamine combination, ('Rebalance™', Antiprotozoal Oral Suspension, IVX Animal Health): administered PO daily for a minimum of 90 days. Due to availability and ease of administration, some use an off-label regimen of trimethoprimsulfa tablets with pyrimethamine tablets. Pyrimethamine must be given at least 1 hr before or after hay is fed.(Merck) Mode of action: trimethoprim, sulfadiazine, and pyrimethamine all inhibit enzymes of folic acid synthesis. Efficacy: 61.5% improvement by one clinical grade.[48]Potential adverse effects: bone marrow suppression (mild anaemia, leucopenia, neutropenia, thrombocytopenia), fever, anorexia, depression, acute worsening of ataxiam altered reproductive performance in stallions[49], congenital defects[50]and abortion. Folic acid deficiency may also cause gastrointestinal disturbances such as glossitis.[51]Blood dyscrazias are typically self-limiting and resolve on withdrawal of treatment.[4] Feeding high quantities of green forage should reduce the risk of anaemia after prolonged treatment.(MErck)
  • Ponazuril (Marquis®, Bayer Animal Health): PO daily for 28 days, use in pregnant animals is off-label. Mode of action: ponazuril is a triazinetrione that targets the “apicoplast” organelle and inhibits the respiratory chain. Efficacy: well absorbed PO, achieves steady state therapeutic concentration in CSF within 3 days[52]clinical response within 10 days, 60% improvement by at least one clinical grade, 8% relapse within 90 days of stopping treatment.[53] Potential adverse effects: none in a multi-centre field study[32], no systemic toxicity even at high doses.[54]However, the manufacturer reports signs that may have been related to treatment including blisters on nose and mouth, skin rash or hives, loose stools, mild colic, and a seizure.[32]
  • Diclazuril: PO, daily for 28 days, approved by FDA for use as top-dress tablet but not commercially available Mode of action: chemically similar to ponazuril but mechanism of action unknown. Efficacy: one study reported clinical improvement in 58% of cases.[48] Potential adverse effects: none found in one efficacy study.[4] Reported problems in a multi-centre field study included worsening neurologic status and laminitis but these were not proven to be related to treatment.[32]
  • Nitazoxanide, NTZ ('Navigator®', Idexx Pharmaceuticals): no longer commercially available in the US. Mode of action: a member of the 5-nitrothiazole class of antiparasitics that inhibits the pyruvate:ferredoxin oxidoreductase (PFOR) enzyme dependent electron transfer reaction essential for anaerobic energy metabolism.[32] Efficacy: 60% success rate in an FDA-regulated study.[48] Potential adverse effects: adverse effects and death at high doses[48], fever, anorexia, diarrhoea, lethargy, depression and laminitis recorded at lower doses. Toxic signs usally resolve upon cessation of treatment.[4] Caution: 'administration of nitazoxanide can disrupt the normal microbial flora of the gastrointestinal tract leading to enterocolitis. Deaths due to enterocolitis have been observed while administering the recommended dose in field studies.[32]


Prolonged, off-license treatment is often instigated after 1 month, based on repeated clinical examination. Even successfully treated cases may remain immunoblot positive for long periods, thus aiming for seronegativity is unrealistic.[4] A lack of response to treatment suggests that the diagnosis should be re-assessed. Another month's worth of the same treatment is recommended for partial responders, switching to a different chemical class if this fails.[4] The efficacy of currently approved antiprotozoals against N.hughesi is unknown.(Furr)

Ancillary medication

  • NSAIDs: DMSO IV as 10% solution, thought to reduce CSF pressure and improve clinical status. Recommended for severe cases of EPM or to avoid worsening inflammation that may be induced by parasite kill.[4] Caution: DMSO may cause intravascular haemolysis.[1]
  • Corticosteroids: a short course of dexamethasone may be beneficial whilst waiting for antiprotozoals to take effect. However, use is controversial because cell-mediated immunity is required to control parasites[1] and stress is a proposed risk factor for EPM.[4]
  • Immunomodulators: Levamisole influences T-cell mediated immunity and enhances phagocytosis. Parapox ovis virus (PPOV) immunomodulator (Zylexis, Pfizer Animal Health, Kalamazoo, Mich). This vaccine has been shown to upregulate the secretion of cytokines including IFN-γ in several species.[55]IFN-γ is thought to be essential for the clearance of S neurona, thus PPOV may be useful in EPM.[4]
  • Multiple vitamin B supplement.[1]

Supportive management

Box rest with deep bedding and good footing or turn out in a flat, grassy field. Ensure all obstacles are removed and avoid turning out ataxic animals with dominant herd mates. Recumbent horses will require dedicated support and a sling if available.[4]

Prognosis

Depends on duration and severity of neurological signs[3] but clinical resolution is more likely if the condition is diagnosed and treated early.[2] With standard therapy, involving 6-8months of ponazuzril or pyrimethamine-sulfadiazine (V), there is a recovery rate of around 25% and an improvement in 60-75% of cases.[48] A good prognosis might be expected if there is an improvement in clinical signs within two weeks of commencing anti-protozoal and anti-inflammatory treatment (V). The prognosis will be guarded to poor[1] for a horse with severe irreversible neuronal damage or one that has not been diagnosed or treated appropriately (V).

Prevention

Prophylaxis

A killed vaccine, developed using S.neurona merozoites, was conditionally licensed for use in horses.[56] The vaccine proved to be ineffective in the prevention of EPM and has since been removed from the market.[4] There is evidence to suggest that the antiprotozoal, ponazuril, may be useful prophylactically to reduce the incidence and severity of clinical signs.[57] Implementing such a regime prior to and during stressful events may be beneficial, although the cost is likely to be prohibitive.[4]Protocols involving intermittent administration of ponazuril may also show promise in the prevention of EPM.[58]

References

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