PoLambRimetry:羔羊大脑多光谱极坐标图集。

IF 3 3区 医学 Q2 BIOCHEMICAL RESEARCH METHODS Journal of Biomedical Optics Pub Date : 2024-09-17 DOI:10.1117/1.jbo.29.9.096002
Verónica Mieites,Giulio Anichini,Ji Qi,Kevin O'Neill,Olga M Conde,Daniel S Elson
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引用次数: 0

摘要

意义穆勒矩阵成像(MMI)是偏振成像的一种综合形式,可用于评估结构变化。我们的目标是利用多光谱 MMI 对大脑结构进行详尽的偏振分析,为未来的研究提供参考数据集,并加深临床医生和研究人员对大脑解剖学的理解。方法利用多光谱宽视场 MMI 系统测量六块新鲜羊羔大脑标本。通过计算多种分解方法(正向极性、对称和微分)和极化不变量(极化纯度指数和各向异性系数),获得了样本的完整极化描述。根据灰质(GM)和白质(WM)等主要大脑结构,共确定了 16 个标签。结果 随着波长的增加,去极化和延迟均增加,表明组织对深层的穿透力增强。此外,利用多个波长,我们可以跟踪脑组织内延迟光轴的动态变化,从而深入了解皮层表面下 WM 的形态变化。使用多光谱数据进行分类的结果优于使用单波长数据获得的所有结果,测试数据集的准确率超过 95%。
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PoLambRimetry: a multispectral polarimetric atlas of lamb brain.
Significance Mueller matrix imaging (MMI) is a comprehensive form of polarization imaging useful for assessing structural changes. However, there is limited literature on the polarimetric properties of brain specimens, especially with multispectral analysis. Aim We aim to employ multispectral MMI for an exhaustive polarimetric analysis of brain structures, providing a reference dataset for future studies and enhancing the understanding of brain anatomy for clinicians and researchers. Approach A multispectral wide-field MMI system was used to measure six fresh lamb brain specimens. Multiple decomposition methods (forward polar, symmetric, and differential) and polarization invariants (indices of polarimetric purity and anisotropy coefficients) have been calculated to obtain a complete polarimetric description of the samples. A total of 16 labels based on major brain structures, including grey matter (GM) and white matter (WM), were identified. K -nearest neighbors classification was used to distinguish between GM and WM and validate the feasibility of MMI for WM identification. Results As the wavelength increases, both depolarization and retardance increase, suggesting enhanced tissue penetration into deeper layers. Moreover, utilizing multiple wavelengths allowed us to track dynamic shifts in the optical axis of retardance within the brain tissue, providing insights into morphological changes in WM beneath the cortical surface. The use of multispectral data for classification outperformed all results obtained with single-wavelength data and provided over 95% accuracy for the test dataset. Conclusions The consistency of these observations highlights the potential of multispectral wide-field MMI as a non-invasive and effective technique for investigating the brain's architecture.
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来源期刊
CiteScore
6.40
自引率
5.70%
发文量
263
审稿时长
2 months
期刊介绍: The Journal of Biomedical Optics publishes peer-reviewed papers on the use of modern optical technology for improved health care and biomedical research.
期刊最新文献
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