Maximum entropy based non-negative optoacoustic tomographic image reconstruction

Optoacoustic (photoacoustic) tomography reconstructs maps of the initial pressure rise induced by the absorption of light pulses in tissue. In practice, due to inaccurate assumptions in the forward model employed, noise and other experimental factors, the images often contain errors, occasionally manifested as negative values. We present optoacoustic tomography based on an entropy maximization algorithm that uses logarithmic regularization as a potent method for imparting non-negative image reconstruction. We experimentally investigate the performance achieved by the entropy maximization scheme on phantoms and in vivo samples. The findings demonstrate that the proposed scheme reconstructs physically relevant image values devoid of unwanted negative contrast, thus improving quantitative imaging performance.