This thesis work is related to photoacoustic imaging techniques which are new multiwave modalities in medical imaging that combine both high resolution of ultrasounds and contrast of optical methods. Weprecisely studied the inverse problem that consists of determining the optical coefficients of biologicaltissues from measurement of acoustic waves generated by the photoacoustic effect. The photoacoustic inverse problem proceeds in two steps.We first retrieve the initial pressure from the measurement of the pressure wave on a part of the boundary of the sample. The first inversion takes then the form of a linear inverse source problem and provides internal data for the optical waves that are more sensitive to the contrast of the absorption and diffusion coefficients. In a second step we recover the optical coefficients from the acquired internal data.The aim of this work is to study the two inversions in different contexts. In the first part, we develop a model that takes into account the variations of the acoustic speed in the medium. Indeed, most of the inversion methods suppose that the acoustic speed is constant, and this assumption can lead to errors in the reconstruction of the optical coefficients. The second part of this work is the derivation of stability estimates for the photoacoustic inverse problem in a layered medium. We prove that the reconstruction is getting worse with depth. This is one of the main drawbacks of the photacoustic method, the imaging depth is limited to a few centimeters. The last part is about photoacoustic generation with plasmonic nanoparticles. They enhance the photoacoustic signal around them, so that we can investigate the tissue more deeply. We derive the mathematical model of the photoacoustic generation by heating nanoparticles, and we solve the photoacoustic inverse problem in this context.