Abstract
Different pathophysiologic mechanisms are involved in the initiation, development, and outcome of dry eye disease (DED). Animal models have proven valuable and efficient in establishing ocular surface microenvironments that mimic humans, thus enabling better understanding of the pathogenesis. Several dry eye animal models, including lacrimal secretion insufficiency, evaporation, neuronal dysfunction, and environmental stress models, are related to different etiological factors. Other models may be categorized as having a multifactorial DED. In addition, there are variations in the methodological classification, including surgical lacrimal gland removal, drug-induced models, irradiation impairment, autoimmune antibody-induced models, and transgenic animals. The aforementioned models may manifest varying degrees of severity or specific pathophysiological mechanisms that contribute to the complexity of DED. This review aimed to summarize various dry eye animal models and evaluate their respective characteristics to improve our understanding of the underlying mechanism and identify therapeutic prospects for clinical purposes.
Highlights
Dry eye disease (DED) is one of the most common ocular surface disorders affecting millions of people worldwide [1,2,3]
Researchers have used several dry eye animal models in translational research, each focusing on different pathophysiological mechanisms of dry eye disease (DED)
Lacrimal gland excision is the easiest and most practical method, and it is widely used in dry eye research
Summary
Dry eye disease (DED) is one of the most common ocular surface disorders affecting millions of people worldwide [1,2,3]. The tear film is the most important component of the ocular surface in maintaining microenvironment stability and providing lubrication to the cornea, maintaining its refractive function [7,8,9]. Factors that affect the production or quality of tear film may lead to DED; these include but are not limited to lacrimal gland impairment, inflammation, infection, systemic autoimmune conditions, and environmental stress [10,11,12,13,14]. Animal models of DED are essential to better investigate the mechanisms underlying this multifactorial condition, explore potential therapeutic targets, and identify factors that can accurately predict prognosis.
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