REVIEW PAPER: Animals as Models of Age-Related Macular Degeneration

Abstract: Age-related macular degeneration (AMD) is a degenerative condition that begins in Bruch's membrane and progresses to involve the retinal pigment epithelium and ultimately the overlying photoreceptors. The only required etiologic factor is age, and AMD is regarded as the leading cause of blindness in individuals older than 65 years. AMD results from variable contributions of age, environment, and genetic predisposition. Many loci are linked to AMD; in the majority of cases, the disease is associated with polymo… Show more

“…This idea is supported by data showing that the double-transgenic Cfh −/− , C3 −/− retinal phenotype is similar to the phenotype observed in C3 −/− or Cfh −/− mice (60). In contrast, the Cfh +/− ∼HFC mice we have characterized here display a robust AMD-like ocular phenotype, with substantial sub-RPE deposit formation, multinucleate RPE and atrophy, photoreceptor cell loss, and visual function decline (61, 62). It should be noted that nearly 10% of sub-RPE deposits were greater than 4 μm in height, which represents the largest deposits detected in any AMD mouse model within our laboratory; comparisons to other studies is difficult due to the lack of systematic quantification and the use of younger mice (38, 58, 60, 63–71).…”

“…Thus, our data show that sub-RPE deposit formation occurs with the combination of diet and CFH deficiency before RPE/photoreceptor dysfunction. Furthermore, it is important to note that the cornerstones of the Cfh +/− ∼HFC model are predominant factors established within the human disease: advanced age, genetic alteration of CFH, complement dysregulation, and cholesterol/lipid metabolism perturbation (15, 61, 62). …”

Regulation of age-related macular degeneration-like pathology by complement factor H

“…This idea is supported by data showing that the double-transgenic Cfh −/− , C3 −/− retinal phenotype is similar to the phenotype observed in C3 −/− or Cfh −/− mice (60). In contrast, the Cfh +/− ∼HFC mice we have characterized here display a robust AMD-like ocular phenotype, with substantial sub-RPE deposit formation, multinucleate RPE and atrophy, photoreceptor cell loss, and visual function decline (61, 62). It should be noted that nearly 10% of sub-RPE deposits were greater than 4 μm in height, which represents the largest deposits detected in any AMD mouse model within our laboratory; comparisons to other studies is difficult due to the lack of systematic quantification and the use of younger mice (38, 58, 60, 63–71).…”

“…Thus, our data show that sub-RPE deposit formation occurs with the combination of diet and CFH deficiency before RPE/photoreceptor dysfunction. Furthermore, it is important to note that the cornerstones of the Cfh +/− ∼HFC model are predominant factors established within the human disease: advanced age, genetic alteration of CFH, complement dysregulation, and cholesterol/lipid metabolism perturbation (15, 61, 62). …”

Regulation of age-related macular degeneration-like pathology by complement factor H

“…Despite evidence converging on the role of energy deregulation, surprisingly little is known about the energy signals that may govern AMD. Few suitable animal models replicate all aspects of AMD, but several transgenic mice present some characteristic signs of the disease (Table 1) (Ambati et al, 2003; Baba et al, 2010; Cao et al, 2010; Cashman et al, 2011; Chen et al, 2007; Combadière et al, 2007; Hahn et al, 2004; Heckenlively et al, 2003; Imamura et al, 2006; Jo et al, 2011; Luhmann et al, 2009; Lyzogubov et al, 2011; Malek et al, 2005; Markovets et al, 2011; Shen et al, 2006; Takada et al, 1994; Tuo et al, 2007; Zeiss, 2010; Zhao et al, 2011b). …”

Retinal energy demands control vascular supply of the retina in development and disease: The role of neuronal lipid and glucose metabolism

“…[1][2][3][4] Rodent models provide cost-effective ways to investigate the pathogenesis and therapeutic strategies in visual impairing diseases, such as macular degeneration, diabetic retinopathy, and glaucoma. [5][6][7] Histological examination is commonly used to visualize subtle structural and functional changes in retinal tissue during disease progressions and treatments. 8 However, histological examinations are limited to terminal studies.…”

Investigating the influence of chromatic aberration and optical illumination bandwidth on fundus imaging in rats