Abstract: Encapsulated-cell therapy (ECT) is an attractive approach for continuously delivering freshly synthesized therapeutics to treat sight-threatening posterior eye diseases, circumventing repeated invasive intravitreal injections and improving local drug availability clinically. Composite collagen-alginate (CAC) scaffold in ECT contains an interpenetrating network that integrates the physical and biological merits of its constituents, including biocompatibility, mild gelling properties and availability. An injectable CAC system that supported the growth of HEK293 cells with sustainable glial-derived neurotrophic factor (GDNF) delivery has been developed. Continuous GDNF delivery was detected in culture and in healthy rat eyes for at least 14 days. The gels were well tolerated with no host tissue attachment and contained living cell colonies. Most importantly, gel implantation in dystrophic Royal College of Surgeons rat eyes for 28 days retained photoreceptors while those gels containing higher initial cell number yielded better photoreceptor rescue effect. This rescue effect is clinically relevant as photoreceptor death is a common pathology in many retinal diseases. Moreover, since cells including autologous cells can be genetically engineered to secrete various therapeutic agents, CAC gel offers a flexible system design and is a potential treatment option for other chronic neurodegenerative diseases.
Background: Retinal degeneration is a common feature of several retinal diseases, such as retinitis pigmentosa and age-related macular degeneration (AMD). In this respect, experimental models of photo-oxidative damage reproduce faithfully photoreceptor loss and many pathophysiological events involved in the activation of retinal cell degeneration. Therefore, such models represent a useful tool to study the mechanisms related to cell death. Their advantage consists in the possibility of modulating the severity of damage according to the needs of the experimenter. Indeed, bright light exposure could be regulated in both time and intensity to trigger a burst of apoptosis in photoreceptors, allowing the study of degenerative mechanisms in a controlled fashion, compared to the progressive and slower rate of death in other genetic models of photoreceptor degeneration.
Methods: Here, an exemplificative protocol of bright light exposure in albino rat is described, as well as the main outcomes in retinal function, photoreceptor death, oxidative stress, and inflammation, which characterize this model and reproduce the main features of retinal degeneration diseases.
Discussion: Models of photo-oxidative damage represent a useful tool to study the mechanisms responsible for photoreceptor degeneration. In this respect, it is important to adapt the exposure paradigm to the experimental needs, and the wide range of variables and limitations influencing the final outcomes should be considered to achieve proper results.
Trial Registration: None.