Encapsulation of single hMSCs in polyelectrolyte shells

The main objective of this Thesis was to encapsulate single viable cells within polyelectrolyte films using the Layer-by-Layer (LbL) technique. Most of the experiments used human mesenchymal stem cells (MSCs) whose characteristics (capacity of selfrenewal and potential to differentiate into several types of cells) make them particularly interesting to be used in biomedical applications. Also, most of the experiments used alginate (ALG) as the anionic polyelectrolyte and chitosan (CHI) or poly(allylamine hydrochloride) (PAH) as the cationic polyelectrolyte. Hyaluronic acid (HA) was also tested as an anionic polyelectrolyte. At the beginning of the work, the experimental conditions necessary to obtain the encapsulation of individual cells were studied and established. Through fluorescence microscopy visualization by staining the cell nucleus and using polyelectrolytes conjugated to fluorescent dyes, it was possible to prove the obtainment of capsules containing one single cell inside. Capsules aggregation was an observed problem which, despite the efforts to design an experimental process to avoid this situation (namely, by playing with cell concentration and different means of re-suspending and stirring the cells), was not completely overcome. In a second part of the project, single cells were encapsulated within polyelectrolyte layers made of CHI/ALG, PAH/ALG and PAH/HA and their viability was evaluated through the resazurin reduction assay and the Live/Dead assay. In these experiments, during the LbL process, polyelectrolyte solutions were used at a concentration of 1mg/mL based on literature. In general, the viability of the encapsulated cells was shown to be very low/absent. Then, as a consequence of the lack of viability of cells encapsulated within polyelectrolyte layers, the LbL technique was applied in cells growing adherent to the surface of cell culture plates. The cells were cultured like in a sandwich, between the surface of the cell culture dish and the polyelectrolyte layers. Also here, the polyelectrolyte solutions were used at a concentration of 1mg/mL during the LbL process. Surprisingly, cell viability was also absent in these systems. A systematic study (dose-effect study) was performed to evaluate the effect of the concentration of the individual polyelectrolytes (ALG, CHI and PAH were studied) in cell viability. Experiments were performed using cells growing adherent to the surface of cell culture plates. The results pointed out that a very high (cytotoxic) concentration of polyelectrolytes had been in use. Also, in general, PAH was much more cytotoxic than CHI, whereas ALG was the less cytotoxic polyelectrolyte. Finally, using alginate and chitosan solutions with adequate concentrations (low concentrations: 50ng/mL and 1μg/mL), the encapsulation of single viable cells was again attempted. Once again, the encapsulated cells were not shown to be viable. In conclusion, the viability of the encapsulated cells is not only dependent on the cytotoxic characteristics (or combined cytotoxic characteristics) of the polyelectrolytes but it seems that, when detached from the culture plates, the cells become too fragile and lose their viability very easily.

Susceptibility of mosquito vectors to Dirofilaria immitis on Madeira Island, Portugal

Dirofilaria immitis (Leidy, 1856), an agent of heartworm disease, is an important parasite from both the veterinary standpoint and as a model to study human filariasis. It is a mosquito-borne filarial nematode which inhabits the right ventricle and pulmonary arteries of dogs. D. immitis is an important disease agent on Madeira Island with about 30% of dogs testing positive for this worm. Nevertheless, the vectors of this parasite in Madeira have never been studied, nor has the interaction between pathogen and vector, or the environmental variables that might influence heartworm transmission. Innate susceptibility to infection is only one component of vector competence, and field isolation of naturally infected mosquitoes has shown the capability of D. immitis to exploit a great diversity of vector species under natural conditions. The purpose of this work was to determine which mosquitoes are vectors of heartworm disease, the relation between population density and environment, and the association between immune response of the vector to the filarial parasite. Seasonal abundance of Culex theileri and Culex pipiens molestus was studied. Correlation and canonical correspondence analysis were performed using abundance data of these two species with selected weather variables, including mean temperature, relative humidity and accumulated precipitation. The most important factor determining Cx. theileri abundance was accumulated precipitation, while Cx. pipiens molestus abundance did not have any relationship with weather variables. Field studies were performed to verify whether Cx. theileri Theobald functions as a natural vector of D. immitis on Madeira Island, Portugal. Cx. theileri tested positive for D. immitis for the first time. The same study was made regarding Cx. p. molestus. Two abnormal L2 stage filarial worms were found in Malpighian tubules in field caught Cx. p. molestus. In the laboratory, two strains of Cx. p. molestus were studied for their susceptibility to D. immitis. None presented infective-stage larvae. Finally, because Cx. p. molestus is an autogenous mosquito, we evaluated the reproductive costs when this mosquito mounts an immune response against D. immitis in the absence of a blood meal. This mosquito showed an active immune response when inoculated intrathoracically with microfilariae (mf) of the heartworm. The ovaries from mosquitoes undergoing melanotic encapsulation developed more eggs than those which could not melanize the mf. This fact is contradictory with some previous studies of reproductive costs in Armigeres subalbatus and Ochlerotatus trivittatus, and it was the first time that an autogenous mosquito was used to study this subject.