Figure 12.5 This horse was also suffering from S. neurona encephalitis partly involving left and right motor nuclei of the trigeminal nerves in the pontomedullary region. It had normal movement of the facial muscles, lips, and tongue but could not close the jaw (A). Drinking was achieved by lapping like a dog (B).
Figure 12.6 Asymmetric temporalis (and masseter and pterygoid) muscle atrophy (A) can be associated with severe dental problems as seen in this teenaged Thoroughbred with a deep supraorbital fossa on the right side (yellow arrow) compared with that on the left side (white arrow). Long fibers of chewed forage were present in the feces (B) associated with the oral dysphagia displayed by the horse. All signs were resolved with appropriate dental care.
References
1 1 Pearson EG, Snyder SP and Saulez MN. Masseter myodegeneration as a cause of trismus or dysphagia in adult horses. Vet Rec 2005; 156(20): 642–646.
2 2 Conwell R. Hyperlipaemia in a pregnant mare with suspected masseter myodegeneration. Vet Rec 2010; 166(4): 116–117.
3 3 Step DL, Divers TJ, Cooper B, et al. Severe masseter myonecrosis in a horse. J Am Vet Med Assoc 1991; 198(1): 117–119.
4 4 Aharonson‐Raz K, Milgram J, Chai O and Sutton GA. Fibrosis of the masseter leading to trismus and dysphagia in a mare. Vet Rec 2009; 164(19): 597–608.
5 5 Schweizer G, Ehrensperger F, Torgerson PR and Braun U. Clinical findings and treatment of 94 cattle presumptively diagnosed with listeriosis. Vet Rec 2006; 158(17): 588–592.
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7 7 Rebhun WC and deLahunta A. Diagnosis and treatment of bovine listeriosis. J Am Vet Med Assoc 1982; 180(4): 395–408.
8 8 Barlow RM and McGorum B. Ovine listerial encephalitis: analysis, hypothesis and synthesis. Vet Rec 1985; 116(9): 233–236.
9 9 Divers TJ and Peek SF. Rebhun's Diseases of Dairy Cattle. Saunders Elsevier, Philadelphia, PA. 2008.
10 10 Rebhun WC. Diseases of the bovine orbit and globe. J Am Vet Med Assoc 1979; 175(2): 171–175.
13 Decreased and Increased facial sensation
Many animals, mentally obtunded because of marked systemic illness and particularly severe brain disease, are slow to respond to noxious stimuli anywhere on the body, including the face. The problem of decreased facial sensation is identified when the degree of hypalgesia detected is greater than that to be expected by any accompanying somnolent or moribund state or is demonstrably asymmetric.
In defining this problem, care must be taken to distinguish facial hyporeflexia from facial hypalgesia—and these signs can occur together. The facial reflex (CN V sensory → CN VII motor) can be poorly functional with lesions involving the sensory trigeminal nerve, ganglion or nucleus, or the facial motor nucleus or nerve. With lesions involving the sensory branches of the trigeminal nerve, these facial reflexes will not function. Degrees of facial hypalgesia or analgesia also occur and the animal does not pull its head away from the noxious facial stimulus, for example in a cow that had an ocular squamous cell carcinoma invading the trigeminal nerve resulting in facial analgesia.1
Sensation from at least the rostral third of the tongue of horses is mediated via fibers in the mandibular nerve and that has been inadvertently sectioned during surgical debulking of intermandibular tumors, resulting in analgesia and areflexia from the ipsilateral rostral circa 10 cm of the tongue. Expansile retrobulbar tumors including lymphosarcoma, melanoma, squamous cell carcinoma, and parotid adenocarcinoma have caused facial hypalgesia, usually with other overt evidence of face and eye lesions.2,3 Partial facial analgesia resulting from trauma to single branches of CN Vs is not common and is usually associated with trauma to the face, nasal region, and sinuses. Because distal portions of sensory trigeminal nerves are distributed with branches from autonomic nerves, processes such as perineuritis that affect distal nerves may result in signs of autonomic denervation. For example, trigeminal innervation of the nasal membranes includes parasympathetic branches of CN VII, thus resulting in rhinitis sicca when these nerves are damaged (Figure 13.1). A similar involvement of oculomotor branches to the eyeball that are confluent with the ophthalmic branch of CN V may also result in poor pupillary constrictor function (Figure 13.2).
Figure 13.1 Facial analgesia is evident in the bright and alert horse shown here, by the needle holders clamped on the distal face (arrow). There was a cranial—believed immune‐associated—polyneuritis particularly involving the trigeminal nerves, with bilateral facial and rostral nasal analgesia. The presence of severe rhinitis sicca as also shown was unusual. In the right clinical setting, this sign is regarded as almost pathognomonic for equine dysautonomia, but this horse had no other signs of enteric or autonomic nervous dysfunction. As is the case often with polyneuritis equi, the trigeminal neuritis was accompanied by a prominent perineuritis. Also, the neuritis involved not just proximal cranial nerves but spread along the distal branches. It was believed that the more distal perineuritis involving the maxillary nerve also involved the autonomic fibers innervating the nasal membranes, mimicking the rhinitis sicca seen with grass sickness.
Figure 13.2 This case of polyneuritis involved the trigeminal nerves, and quite distinctly the ophthalmic branch on the left side was clinically affected. The latter resulted in conjunctival and corneal hypalgesia demonstrated here in the left eye (OS). Likely because of perineuritis, and the fact that branches of the ophthalmic nerve are confluent with the oculomotor fibers and the ciliary ganglion, a degree of pupillary dilation was also present in the left eye (OS) compared with the right (OD) (yellow bars).
Medullary (and cranial cervical spinal cord) diseases such as equine protozoal myeloencephalitis and listeriosis in ruminants are the more common central causes of decreased facial sensation due to involvement of the sensory tract and/or nucleus of the trigeminal nerve in the caudal medulla oblongata and cranial cervical spinal cord (Figure 13.3).
Central pathways for sensory perception from the face pass from the trigeminal sensory nucleus to the contralateral thalamus, contralateral internal capsule, and somesthetic, sensory cerebral cortex, mostly in