Feasibility of laser optoacoustic tomography to detect turbid tissues with different optical properties was experimentally investigated using real biological tissues. The following abilities of this technique were quantitatively studied: maximal depth of optoacoustic signal detection, acoustic attenuation of laser-induced pressure waves, and limit of resolution. Two types of biological tissues were used for the experiments: chicken breast muscle as a tissue with low absorption coefficient and bovine liver as a tissue with higher absorption coefficient. Tissue samples were irradiated by Q-switched Nd:YAG-laser pulses to satisfy stress-confined irradiation conditions. Laser-induced pressure waves generated in the liver samples were detected by a wide-band acoustic transducer. Pressure wave amplitude, duration, and propagation time were analyzed after the experiments. The results and theoretical calculations have demonstrated that laser-induced optoacoustic signals from biological tissues with higher absorption coefficient are measurable at depth 5 times higher than penetration depth of radiation. Low acoustic attenuation (0.006 cm -1) for laser-induced pressure waves was detected. Feasibility of the proposed imaging to detect 3 mm 3 liver sample (tumor model) placed inside 80 mm-muscle tissue is demonstrated.