PMMA-co-EHA cements for osteoprotheses

The main purpose of this thesis was to produce new formulations of PMMA-co- EHA and study its feasibility as being an alternative to traditional PMMA bone cements. Thus, were originally produced several co-polymers of PMMA-co-EHA and its mechanical properties and in vitro behaviour were evaluated. The copolymers were obtained by radical polymerization and several formulations were produced by partial replacement of MMA (up to about 50%) for EHA. Overall, the results suggest that the partial replacement of MMA by EHA decreased the modulus of the materials and, consequently, increased its flexibility. Then, PMMA commercial beads were added to PMMA-co-EHA formulations (to get bone cement) and the general properties of the resulting bone cements were evaluated. In general, the results revealed that the partial replacement of MMA by EHA led to beneficial changes in curing parameters (there was a reduction of the peak temperature and an increase of curing/setting time), in the in vitro behaviour (the water capacity increased) and in the mechanical properties (the bending strength increased) of new cements. The in vitro cellular response of new formulations of PMMA-co-EHA was compared with that of traditional PMMA bone cement. To this end, we tested the cell adhesion and proliferation of osteoblast-like MG63 cells and human cells from bone marrow. The results revealed that both types of cells were able to attach and proliferate in both formulations. The only exception was observed for the formulation prepared with the highest percentage of EHA, where a few cells that adhere failed to proliferate. Moreover, it was found that increasing the amount of EHA in cement led to an increasing inhibition of cell growth, especially during the first week of culture. This was related to increased water uptake capacity by the new formulations and consequent release of some of its toxic components. Finally, PMMA commercial beads were partially replaced by HA particles and the influence of this substitution on the curing parameters, the mechanical properties and in vitro behaviour of the resulting composites was also evaluated. Incorporation of HA into the bone cements induced a number of significant changes in its final properties: 1) decrease the peak temperature; 2) increase of curing time, 3) increasing the value of elastic modulus accompanied by decrease of the strength/tension. This last finding was related to poor interfacial adhesion between the various components of the bone cements and a heterogeneous distribution (possible agglomeration) of HA particles.

Trends in deep-water shark fisheries in the Azores

Deep-sea resources have been increasingly exploited, and due to that, several ecosystems and species have been considerably affected. Deep-water sharks populations have been of the most disturbed by practices of unselected fisheries, bycatch and discard, mainly due to their low commercial value. Those practices make deep-water sharks very vulnerable to overfishing given their life-history traits, increasing their extinction risk. With the prohibition of the direct fishery, and implementation of quotas and TACs (Total Allowable Catches) regarding the deep-sea shark landings, the official landings have dramatically decreased after the 1990s. However, the IUU (Illegal, unreported and unregulated) catch has exponentially increased. With the analysis of catch per unit effort (CPUE), the depths, and the mean weight of the individuals over the years for each one of the nine most caught species in the Azores, we produced a descriptive analysis of the effect of fisheries in those species. The results show that some of these species have been suffering from a great fishing pressure, and their populations will be greatly affected in the near future if drastic measures are not taken when it comes to managing their long term sustainability.