Mucoadhesive Hydrogel Nanoparticles as Smart Biomedical Drug Delivery System

Hydrogels are widely used materials which have many medical applications. Their ability to absorb aqueous solutions and biological fluids gives them innovative characterizations resulting in increased compatibility with biological activity. In this sense, they are used extensively for encapsulation of several targets such as biomolecules, viruses, bacteria, and mammalian cells. Indeed, many methods have been published which are used in hydrogel formulation and biomedical encapsulations involving several cross-linkers. This system is still rich with the potential of undiscovered features. The physicochemical properties of polymers, distinguished by their interactions with biological systems into mucoadhesive, gastro-adhesive, and stimuli responsive polymers. Hydrogel systems may be assembled as tablets, patches, gels, ointments, and films. Their potential to be co-formulated as nanoparticles extends the limits of their assembly and application. In this review, mucoadhesive nanoparticles and their importance for biomedical applications are highlighted with a focus on mechanisms of overcoming mucosal resistance

Evaluation of liposomal hydrocolloidal NPs loaded by tea tree oil as antifungal agent in vitro and in vivo investigations: Preclinical studies

Fungi have a great ability and a wide variety of mechanisms to endure the toxicity of current antifungal agents. Researchers are working to find new therapeutic agents to combat the resistance ability of fungi. Almost all commercial antifungal agents have a wide variety of side effects on human health. This study aims to introduce tea tree oil nanoparticles as antifungal delivery termed TNSAD, which contains hybrid tea tree oil attached chitosan in a liposomal formulation, and assess its antifungal activity using in vitro and in vivo infection models. Tea tree oil was first coated by chitosan, then inserted inside liposomal bilayers, and finally functionalized by a layer of chitosan, forming the TNSAD. The antifungal activity was evaluated against four different invasive, opportunistic, and zoonotic fungal pathogens (Aspergillus flavus, Aspergillus fumigatus, Microsporum gypsum, and Fusarium oxysporum). The cytotoxicity of TNSAD was then tested against the HEp-2 cell line. Finally, the antifungal activity against Aspergillus fumigatus and Microsporum gypsum was assessed in vivo in a rat model. The in vitro results confirm the potency of TNSAD against fungi and its safety at a concentration of ≤ 5 mg/ml. In vivo results revealed that fungal cells were destroyed within the tissue when used systematically. we have described here a natural remarkable design that represents a potential antifungal agent and provided evidence for its efficiency and safety, which makes it a promising antifungal agent for the treatment of systemic and topical fungal infections