Comparison of baseline correction algorithms for in vivo ¹H-MRS.

IF 2.7 4区医学 Q2 BIOPHYSICS

NMR in Biomedicine Pub Date : 2024-11-01 Epub Date: 2024-07-02 DOI:10.1002/nbm.5203

Diego Pasmiño, Johannes Slotboom, Brigitte Schweisthal, Pamela Guevara, Waldo Valenzuela, Esteban J Pino

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引用次数: 0

Abstract

Proton MRS is used clinically to collect localized, quantitative metabolic data from living tissues. However, the presence of baselines in the spectra complicates accurate MRS data quantification. The occurrence of baselines is not specific to short-echo-time MRS data. In short-echo-time MRS, the baseline consists typically of a dominating macromolecular (MM) part, and can, depending on B₀ shimming, poor voxel placement, and/or localization sequences, also contain broad water and lipid resonance components, indicated by broad components (BCs). In long-echo-time MRS, the MM part is usually much smaller, but BCs may still be present. The sum of MM and BCs is denoted by the baseline. Many algorithms have been proposed over the years to tackle these artefacts. A first approach is to identify the baseline itself in a preprocessing step, and a second approach is to model the baseline in the quantification of the MRS data themselves. This paper gives an overview of baseline handling algorithms and also proposes a new algorithm for baseline correction. A subset of suitable baseline removal algorithms were tested on in vivo MRSI data (semi-LASER at T_E = 40 ms) and compared with the new algorithm. The baselines in all datasets were removed using the different methods and subsequently fitted using spectrIm-QMRS with a TDFDFit fitting model that contained only a metabolite basis set and lacked a baseline model. The same spectra were also fitted using a spectrIm-QMRS model that explicitly models the metabolites and the baseline of the spectrum. The quantification results of the latter quantification were regarded as ground truth. The fit quality number (FQN) was used to assess baseline removal effectiveness, and correlations between metabolite peak areas and ground truth models were also examined. The results show a competitive performance of our new proposed algorithm, underscoring its automatic approach and efficiency. Nevertheless, none of the tested baseline correction methods achieved FQNs as good as the ground truth model. All separately applied baseline correction methods introduce a bias in the observed metabolite peak areas. We conclude that all baseline correction methods tested, when applied as a separate preprocessing step, yield poorer FQNs and biased quantification results. While they may enhance visual display, they are not advisable for use before spectral fitting.

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体内 1H-MRS 基线校正算法的比较。

质子 MRS 在临床上用于收集活体组织的局部定量代谢数据。然而，光谱中基线的存在使 MRS 数据的精确量化变得复杂。基线的出现并非短回波时间 MRS 数据所特有。在短回波时间 MRS 中，基线通常由主要的大分子 (MM) 部分组成，根据 B0 偏移、体素位置不佳和/或定位序列的不同，基线还可能包含宽泛的水和脂质共振成分，即宽泛成分 (BC)。在长回波时间 MRS 中，MM 部分通常要小得多，但 BC 仍可能存在。MM 和 BC 的总和用基线表示。多年来，人们提出了许多算法来解决这些伪影问题。第一种方法是在预处理步骤中识别基线本身，第二种方法是在 MRS 数据本身的量化过程中建立基线模型。本文概述了基线处理算法，并提出了一种新的基线校正算法。在活体 MRSI 数据（TE = 40 ms 时的半 LASER）上测试了合适的基线去除算法子集，并与新算法进行了比较。所有数据集中的基线均使用不同的方法去除，然后使用仅包含代谢物基集而不包含基线模型的 TDFDFit 拟合模型用 spectrIm-QMRS 进行拟合。同样的光谱也使用明确建立代谢物和光谱基线模型的 spectrIm-QMRS 模型进行拟合。后者的量化结果被视为基本真实值。拟合质量数（FQN）用于评估基线去除效果，同时还检验了代谢物峰面积与地面实况模型之间的相关性。结果表明，我们提出的新算法具有很强的竞争力，突出了其自动方法和效率。然而，没有一种测试过的基线校正方法能获得与地面实况模型一样好的 FQN。所有单独应用的基线校正方法都会对观测到的代谢物峰面积产生偏差。我们的结论是，所有测试过的基线校正方法在作为单独的预处理步骤应用时，都会产生较差的 FQN 和有偏差的定量结果。虽然这些方法可以增强视觉显示效果，但不宜在光谱拟合前使用。

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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来源期刊

NMR in Biomedicine 医学-光谱学

CiteScore

6.00

自引率

10.30%

发文量

209

审稿时长

3-8 weeks

期刊介绍： NMR in Biomedicine is a journal devoted to the publication of original full-length papers, rapid communications and review articles describing the development of magnetic resonance spectroscopy or imaging methods or their use to investigate physiological, biochemical, biophysical or medical problems. Topics for submitted papers should be in one of the following general categories: (a) development of methods and instrumentation for MR of biological systems; (b) studies of normal or diseased organs, tissues or cells; (c) diagnosis or treatment of disease. Reports may cover work on patients or healthy human subjects, in vivo animal experiments, studies of isolated organs or cultured cells, analysis of tissue extracts, NMR theory, experimental techniques, or instrumentation.