Abstract
Photoacoustic (PA) imaging is an emerging imaging technique for many clinical applications. One of the challenges posed by clinical translation is that imaging systems often rely on a finite-aperture transducer rather than a full tomography system. This results in imaging artifacts arising from an underdetermined reconstruction of the initial pressure distribution (IPD). Furthermore, clinical applications often require deep imaging, resulting in a low-signal-to-noise ratio for the acquired signal because of strong light attenuation in tissue. Conventional approaches to reconstruct the IPD, such as back projection and time-reversal, do not adequately suppress the artifacts and noise. We propose a sparsity-based optimization approach that improves the reconstruction of IPD in PA imaging with a linear array ultrasound transducer. In simulation studies, the forward model matrix was measured from k-Wave simulations, and the approach was applied to reconstruct simulated point objects and the Shepp-Logan phantom. The results were compared with the conventional back projection, time-reversal approach, frequency-domain reconstruction, and the iterative least-squares approaches. In experimental studies, the forward model of our imaging system is directly measured by scanning a graphite point source through the imaging field of view. Experimental images of graphite inclusions in tissue-mimicking phantoms are reconstructed and compared with the back projection and iterative least-squares approaches. Overall these results show that our proposed optimization approach can leverage the sparsity of the PA images to improve the reconstruction of the IPD and outperform the existing popular reconstruction approaches.
Highlights
Photoacoustic (PA) imaging is an emerging biomedical imaging technique that combines optical contrast with ultrasound acquisition and image reconstruction to achieve good resolution and high-contrast deep tissue imaging.[1,2,3] In PA imaging, the acoustic signal is generated from tissue optical absorption following irradiation of the tissue by a short laser pulse
In the acoustic inversion problem, which is the focus of this paper, factors such as acoustic diffraction, spatial variance, artifacts, and weak acoustic signal will all deteriorate the reconstructed initial pressure distribution (IPD).[5,6]
Artifacts in PA imaging commonly come from the finite aperture effects of the ultrasound transducer
Summary
Photoacoustic (PA) imaging is an emerging biomedical imaging technique that combines optical contrast with ultrasound acquisition and image reconstruction to achieve good resolution and high-contrast deep tissue imaging.[1,2,3] In PA imaging, the acoustic signal is generated from tissue optical absorption following irradiation of the tissue by a short laser pulse. A full-wave iterative image reconstruction was developed based on TV regularization in PAT system with acoustically inhomogeneous media.[22] The forward and back-projection operators in this algorithm are based on the k-space pseudospectral method to compute numerical solutions to PA wave equation in the time domain with a circular ultrasound transducer geometry for data collection in the experiments. This algorithm is still an analytical approach utilizing the numerical solutions to PA wave equation to build the forward and backward model in a circular detection geometry instead of using a linear array ultrasound transducer. In this paper, we propose a sparsity-based-photoacoustic image reconstruction (SPAIR) to optimize the IPD image using the two-step iterative shrinkage/thresholding (TwIST) algorithm[25] and a linear array transducer system (rather than tomography systems) with direct measurement of the spatial- and element-variant impulse response to construct the mathematical forward model matrix
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