The present study seeks to define a stable mixing ratio using powder Polyvinyl Alcohol (PVOH) based polymeric additives to control the loss of filtrate, defoamer, and dispersant, characterizing the influence of each addition on hydration kinetics, mechanical and physical properties, and rheology of the mix. The behavior of cement pastes under curing conditions that simulate the wellbore situation up to 6100 m depth was also evaluated, following API recommendations. Moreover, the behavior of the material under in situ states, using confining pressures to perform the compression tests, was characterized. Finally, the inclusion of Polyvinyl Alcohol (PVA) microfibers is proposed to improve the mechanical performance of cement pastes, evaluating different types of loading and defining the impacts of the fiber addition on the viscosity and thixotropy of the mixtures. It was found that the use of PVOH as a fluid loss additive does not influence hydration kinetics for concentrations up to 0.4% by weight of cement, but as the amount of PVOH is increased in the mixture, the hydration process of the cement paste may be modified because of the PVOH absorptive mechanism. Moreover, new hydration products phases appear with increasing curing temperature and pressure: dellaite, hydroxyellestadite, and alpha-C2SH. The last phase (alpha-C2SH) is related to the loss of strength capacity of the samples cured at 149°C, simulating a 6100 m depth wellbore. For the triaxial tests, the confining pressure gave the samples a behavior markedly different from the uniaxial case, implying a considerable improvement in the plasticity of the stress-strain behavior. Although some frictional reinforcement is observed due to shear stresses in the cracks surface, the most important effect of confinement is to withstand ductile deformation, even in the case of PVA fiber-reinforced cement paste. Finally, the study has shown that PVA fibers impart a slight viscosifying effect on the cement slurry, a prolonged plastic phase with apparently no loss of load-carrying capacity in triaxial tests, and an improved ability to absorb energy when evaluating tensile and shear loads.