Nanoparticles (NPs) assumed an important role in the area of drug delivery. Despite the number of studies including NPs are growing over the last years, their side effects on the immune system are often ignored or omitted. One of the most studied polymers in the nano based drug delivery system field is chitosan (Chit). In the scientific literature, although the physicochemical properties [molecular weight (MW) or deacetylation degree (DDA)] of the chitosan, endotoxin contamination and appropriate testing controls are rarely reported, they can strongly influence immunotoxicity results. The present work aimed to study the immunotoxicity of NPs produced with different DDA and MW Chit polymers and to benchmark it against the polymer itself. Chit NPs were prepared based on the ionic gelation of Chit with sodium tripolyphosphate (TPP). This method allowed the production of two different NPs: Chit 80% NPs (80% DDA) and Chit 93% NPs (93% DDA). In general, we found greater reduction in cell viability induced by Chit NPs than the respective Chit polymers when tested in vitro using human peripheral blood monocytes (PBMCs) or RAW 264.7 cell line. In addition, Chit 80% NPs were more cytotoxic for PBMCs, increased reactive oxygen species (ROS) production (above 156 µg/mL) in the RAW 264.7 cell line and interfered with the intrinsic pathway of coagulation (at 1 mg/mL) when compared to Chit 93% NPs. On the other hand, only Chit 93% NPs induced platelet aggregation (at 2 mg/mL). Although Chit NPs and Chit polymers did not stimulate the nitric oxide (NO) production in RAW 264.7 cells, they induced a decrease in lipopolysaccharide (LPS)-induced NO production at all tested concentrations. None of Chit NPs and polymers caused hemolysis, nor induced PBMCs to secrete TNF-α and IL-6 cytokines. From the obtained results we concluded that the DDA of the Chit polymer and the size of Chit NPs influence the in vitro immunotoxicity results. As the NPs are more cytotoxic than the corresponding polymers, one should be careful in the extrapolation of trends from the polymer to the NPs, and in the comparisons among delivery systems prepared with different DDA chitosans.
Poly-ε-caprolactone
(PCL) is a biodegradable polyester that
has FDA and CE approval as a medical device. Nonetheless, the lack
of toxicity exhibited by the polymer cannot be extrapolated to its
nanomaterial conformation. Despite PCL-based NPs being widely studied
in the biomedical field for their advantages as controlled drug delivery
systems, little data describe PCL NPs’ toxicity, particularly
immunotoxicity. This work assessed different PCL-based delivery systems
intended for protein delivery regarding their immunotoxicity and hemocompatibility.
Two different molecular weight PCL polymers were used, as well as
blends with chitosan and glucan. Results showed that the presence
of NaOH during the production of PCL2 NPs and PCL2/glucan NPs induced PCL alkali hydrolysis, generating more reactive
groups (carboxyl and hydroxyl) that contributed to an increased toxicity
of the NPs (higher reduction in peripheral blood mononuclear cell
viability and lower hemocompatibility). PCL2/glucan NPs
showed an anti-inflammatory activity characterized by the inhibition
of LPS stimulated nitric oxide (NO) and TNF-α. In conclusion,
generalizations among different PCL NP delivery systems must be avoided,
and immunotoxicity assessments should be performed in the early stage
of product development to increase the clinical success of the nanomedicine.
Beta-glucans are a group of polysaccharides with intrinsic immunostimulatory properties which makes the design of new particulate vaccine adjuvants based on β-glucans very promising. The size of the particles and the antigen loading method, encapsulated into particles or adsorbed on its surface, will influence the toxicological and adjuvanticity properties of the particulate adjuvant. Herein we describe the production of glucan nanoparticles (NPs) with three different sizes, approximately 150 nm, 350 nm, and microparticles as shells (GPs) with approximately 3 μm. The association of the antigen to the particulate adjuvant is described using model protein antigens. The method can be easily adapted for real protein antigens.
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