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      Both the optical and normal functions of the cornea depend on the integrity of the lacrimal system. The PTF maintains an optically uniform corneal surface by smoothing out minor irregularities, removing foreign matter from the cornea and conjunctiva, lubricating the conjunctiva and cornea, providing nutrients to the avascular cornea, and controlling the local bacterial flora. The PTF also undergoes constant evaporation and formation of transient “dry spots.” Hence, the rate of tear evaporation appears to be directly related to the rate of blinking, since the rate of blinking is faster than the development of these dry spots. Actual tear flow rates are difficult to measure in most species; however, in the horse, the tear flow rate has been estimated to be 34 μl/min with a tear volume of 234 μl, which indicates a turnover of the tear volume in approximately 7 minutes. By comparison, tear turnover and tear evaporation rates in humans are ~1 ± 0.4 and 0.14 ± 0.07 μl/min, respectively.

Schematic illustration of the tear film is a complex multilayered fluid phase.

      The middle aqueous layer (∼7 μm) is the thickest (>60% of the total tear film thickness) and performs the primary nutritional functions of the tear film. This layer is composed of ~98% water and ~2% solids, comprising predominantly proteins. The aqueous layer contains inorganic salts, glucose, urea, proteins, glycoproteins, and soluble mucins. The lacrimal gland, gland of the NM, harderian gland, and accessory lacrimal glands in the conjunctiva all contribute to its formation. Destruction or excision of the canine lacrimal gland or NM gland results in a variable reduction in aqueous tear production, and indicates that approximately two‐thirds of the aqueous tear production is produced by the lacrimal gland, approximately one‐third by the gland of the third eyelid, and a very minor amount by the accessory lacrimal glands in the conjunctiva. The aqueous portion is evaluated clinically primarily through use of the Schirmer tear test (STT) I; the phenol red thread test can be used in very small animals.

      The deep, or mucin, layer (∼1 μm) is composed of tear mucins produced by the apocrine conjunctival goblet cells, as well as an underlying glycocalyx that is associated with the corneal and conjunctival microvilli. The distribution of goblet cells varies among species, but the fornix is rich in goblet cells in dogs, cats, and horses, whereas the highest density in chinchillas and guinea pigs is in the palpebral conjunctiva. All species have lower concentrations of goblet cells in the bulbar conjunctiva. Mucin is produced by goblet cells in response to mechanical, immune, histamine, antigenic, or (direct or indirect) neural stimulation. The glycocalyx comprises polysaccharides that are produced by the stratified squamous epithelial cells of the cornea and conjunctiva and project from the surface microvilli of those cells. Mucins play a critical role in lubricating the corneal surface, thus making its hydrophobic surface more hydrophilic (to permit spreading), and in stabilizing the PTF. The mucin layer as well as the integrity of the outermost layer of corneal epithelium is necessary for retention of the tear film on the cornea.

      Tears are a clear and slightly alkaline solution, with a mean pH of 8.3, 8.1, and 7.8 in cattle, dogs, and horses, respectively. In humans, horses, cattle, and rabbits, tear electrolyte concentration is similar to that in plasma, except for potassium, which is three to six times more abundant in tears, thus indicating an active transport mechanism. Tear film osmolarity/osmolality is influenced by the rate of tear secretion, evaporation, and composition. It is similar in cats (329 mOsm/l), dogs (356 mOsm/l), and rabbits (376 mmol/kg), whereas humans (283 mmol/kg) and horses (284 mmol/kg) have a lower osmolarity.

      The lacrimal nerve, a branch of the trigeminal nerve, is primarily sensory but also provides the lacrimal gland with its parasympathetic (release acetylcholine and vasoactive intestinal peptide neurotransmitters) and sympathetic (release norepinephrine and neuropeptide Y neurotransmitters) innervation. Both adrenergic and cholinergic distribution patterns around the acini and blood vessels of the canine lacrimal gland are similar; however, the cholinergic fibers appear to be greater in number than the adrenergic fibers.

      Lacrimation is stimulated by painful irritants, eye diseases, mechanical or olfactory stimuli of the nasal mucous membranes, and sinus diseases. Tear production as assessed with the external ocular surfaces anesthetized and the lower conjunctival

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