In-Depth Study of Cyclodextrin Complexation with Carotenoids toward the Formation of Enhanced Delivery Systems

A hyaluronic acid-modified cyclodextrin self-assembly system for the delivery of β-carotene in the treatment of dry eye disease

Dry eye disease (DED) is a multifactorial ocular disease, the core mechanism of which is the tear film instability caused by ocular oxidative stress damage and inflammation. Although various pharmaceutical agents are available for DED treatment, their effectiveness is often limited by the eyes' unique biological barriers, and the long-term use of steroid hormones can lead to several adverse effects. This study reported a nano-supramolecular delivery system consisting of a polycyclodextrin (PCD), hyaluronic acid (HA) and the natural compound β-carotene (BC) for the DED treatment. Our findings indicate that the HA/PCD@BC eye drops effectively distribute on the ocular surface, retain BC, and significantly enhance the corneal penetration of BC. The excellent biocompatibility of HA/PCD@BC was demonstrated through viability testing on different cell lines, the Draize eye test, as well as the hematoxylin-eosin staining (H&E) sections of cornea and conjunctiva. Both in vitro oxidative stress assays and in vivo DED model evaluations demonstrated that the HA/PCD@BC delivery system significantly reduced abnormal oxidative stress levels on the ocular surface, inhibited the secretion of inflammatory factors, and increased the secretion of tear film stabilizing mucin. These effects collectively improved pathological changes in eye tissues and minimized damage to the ocular surface. It is of particular importance to note that HA/PCD@BC eye drops showed superior efficacy in comparison to cyclosporine A (CsA), an FDA-approved first-line drug. To sum up, the HA/PCD@BC nanodelivery system provides a natural, safe and effective therapeutic strategy for the treatment of DED and various ocular diseases.

Drug Carriers: A Review on the Most Used Mathematical Models for Drug Release

Carriers are protective transporters of drugs to target cells, facilitating therapy under each points of view, such as fast healing, reducing infective phenomena, and curing illnesses while avoiding side effects. Over the last 60 years, several scientists have studied drug carrier properties, trying to adapt them to the release environment. Drug/Carrier interaction phenomena have been deeply studied, and the release kinetics have been modeled according to the occurring phenomena involved in the system. It is not easy to define models’ advantages and disadvantages, since each of them may fit in a specific situation, considering material interactions, diffusion and erosion phenomena, and, no less important, the behavior of receiving medium. This work represents a critical review on main mathematical models concerning their dependency on physical, chemical, empirical, or semi-empirical variables. A quantitative representation of release profiles has been shown for the most representative models. A final critical comment on the applicability of these models has been presented at the end. A mathematical approach to this topic may help students and researchers approach the wide panorama of models that exist in literature and have been optimized over time. This models list could be of practical inspiration for the development of researchers’ own new models or for the application of proper modifications, with the introduction of new variable dependency.