Impact of the aggregation state of amphotericin B on its biopharmaceutical properties. Design of micro- and nanocarriers for oral delivery

Abstract

This thesis is part of the development and evaluation of nanomedicines potentially able to overcome unfavorable biopharmaceutical properties of amphotericin B (AmB), a highly effective molecule used for the treatment of systemic fungal infections and leishmaniasis, but difficult to formulate efficiently, whatever the route of delivery. It is believed that this hydrophobic molecule suffers from severe limitations due to its pronounced tendency to aggregate under physiological conditions. The first part of the thesis was driven on the hypothesis that the degree of aggregation of AmB could have a strong impact on some of its pharmacokinetics properties. For this purpose albumin has been used to produce controlled complexes between albumin and AmB in order to control AmB aggregation states. The morphological characteristics of the resulting colloidal objects have been carefully characterized by UV-Vis spectroscopy and circular dichroism. Furthermore, the impact of aggregation state on both the intestinal permeability and a possibly expected recognition of the aggregates by the immunological system were investigated. The second part of this work was focused on the development of micro- and nanocarriers intended to overcome the absorption barrier raised against AmB after oral delivery. For this purpose, AmB was loaded into micro- and nanoemulsions to evaluate a possible permeability enhancement effect through the intestinal membrane, which was evaluated in ratas using the Ussing chamber model. No detectable permeation was seen in any of the experimental conditions. However, the electrophysiological data showed tissue viability losses due to the strong toxicity of AmB, that were dependent on the aggregation state of AmB when in contact with the tissue. It was also concluded from detailed permeation experiments in healthy tissues that paracellular and transcellular routes were likely to be only marginal pathways when oral absorption are observed in vivo, as reported in the literature. The likeness of other possible absorption pathways, including Peyer's patches capture and lymphatic pathway implication for aggregated particles has been discussed. Finally, another particulate system intended for colonic delivery and based on xylan, a natural and enzymatically degradable biopolymer, has been investigated. Xylan is a polysaccharide present in grains, cereals and angiosperm plants that is specifically degraded on colon region, by the microbiota. An original process consisting in a water-in-water emulsion of xylan in presence of PEG followed by a crosslinking phase using trisodium trimetaphosphate has been developed, making possible the production of xylan-based biocompatible micro- and nanospheres ranging from 380 nm to 4.5 μm, depending on the parameters in the process. This eco-friendly process is free of harmful solvents and has potential application for the delivery of AmB at the colonic level.