Transcranial Photoacoustic Tomography De-Aberrated Using Boundary Elements

IEEE transactions on medical imaging Pub Date : 2025-01-06 DOI:10.1109/TMI.2025.3526000

Karteekeya Sastry;Yousuf Aborahama;Yilin Luo;Yang Zhang;Manxiu Cui;Rui Cao;Geng Ku;Lihong V. Wang

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Abstract

Photoacoustic tomography holds tremendous potential for neuroimaging due to its functional magnetic resonance imaging (fMRI)-like functional contrast and greater specificity, richer contrast, portability, open platform, faster imaging, magnet-free and quieter operation, and lower cost. However, accounting for the skull-induced acoustic distortion remains a long-standing challenge due to the problem size. This is aggravated in functional imaging, where high accuracy is needed to detect minuscule functional changes. Here, we develop an acoustic solver based on the boundary-element method (BEM) to model the skull and de-aberrate the images. BEM uses boundary meshes and compression for superior computational efficiency compared to volumetric discretization-based methods. We demonstrate BEM’s higher accuracy and favorable scalability relative to the widely used pseudo-spectral time-domain method (PSTD). In imaging through an ex-vivo adult human skull, BEM outperforms PSTD in several metrics. Our work establishes BEM as a valuable and naturally suited technique in photoacoustic tomography and lays the foundation for BEM-based de-aberration methods.

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经颅光声断层成像使用边界元素去像差

光声断层扫描具有功能磁共振成像（fMRI）般的功能对比和更大的特异性、更丰富的对比度、便携性、开放式平台、更快的成像、无磁和更安静的操作以及更低的成本，因此在神经成像方面具有巨大的潜力。然而，由于问题的大小，对头骨引起的声学畸变的解释仍然是一个长期的挑战。这在功能成像中更为严重，因为检测微小的功能变化需要高精度。在这里，我们开发了一个基于边界元方法（BEM）的声学求解器来建模颅骨和去像差图像。与基于体积离散化的方法相比，边界元法使用边界网格和压缩来提高计算效率。与广泛使用的伪谱时域方法（PSTD）相比，BEM具有更高的精度和良好的可扩展性。通过离体成人颅骨成像，BEM在几个指标上优于PSTD。我们的工作确立了边界元法作为一种有价值且自然适用于光声层析成像的技术，并为基于边界元法的去像差方法奠定了基础。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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IEEE transactions on medical imaging

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