The macromolecular MR spectrum does not change with healthy aging

Hui, Steve C.N.; Gong, Tao; Zöllner, Helge J.; Song, Yulu; Murali‐Manohar, Saipavitra; Oeltzschner, Georg; Mikkelsen, Mark E.; Tapper, Sofie; Chen, Yufan; Saleh, Muhammad G.; Porges, Eric C.; Chen, Weibo; Wang, Guangbin; Edden, Richard A.E.

doi:10.1002/mrm.29093

Cited by 24 publications

(77 citation statements)

References 40 publications

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“…Metabolites included in the model are as follows: ascorbate, Asp; creatine, Cr; negative creatine methylene, CrCH2; gamma-aminobutyric acid, GABA; glycerophosphocholine, GPC; glutathione, GSH; glutamine, Gln; glutamate, Glu; myo-inositol, mI; lactate, Lac; N-acetylaspartate, NAA; N-acetylaspartylglutamate, NAAG; phosphocholine, PCh; phosphocreatine, PCr; phosphoethanolamine, PE; scyllo-inositol, sI; and taurine, Tau. Osprey analysis procedures match those previously described in, with the exception that experimentally derived in vivo macromolecular (MM) basis spectra derived from a previous study (Hui et al, 2022b) are incorporated into the basis set instead of 8 parameterized Gaussian basis functions. To create the MM basis function, individual-subject 'clean' MM spectra (separate for PCC and CSO) were modeled with a flexible spline (0.1 ppm knot spacing) across the full spectral range.…”

Section: Discussionmentioning

confidence: 99%

“…Exclusion criteria included contraindications for MRI and a history of neurological and psychiatric illness. Metabolite-nulled data from the same cohort of subjects was recently published (Hui et al, 2022a) to investigate the age trajectory of macromolecular signals in the spectrum. Since this analysis revealed no significant age- or sex-related changes to the macromolecular spectrum, a cohort-mean macromolecule spectrum was incorporated into the modeling (see Analysis ).…”

Section: Methodsmentioning

confidence: 99%

“…To create the MM basis function, individual-subject ‘clean’ MM spectra (separate for PCC and CSO) were modeled with a flexible spline (0.1 ppm knot spacing) across the full spectral range. The mean of these splines was taken across all subjects (since no significant MM-age relationships were observed before (Hui et al, 2022b) to generate the cohort-mean MM basis function. Water reference spectra were modeled with a simulated water basis function in the frequency domain with a 6-parameter model (amplitude, zero- and first-order phase, Gaussian and Lorentzian line-broadening, and frequency shift).…”

Section: Methodsmentioning

confidence: 99%

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Neurometabolic timecourse of healthy aging

Gong

Hui

Zöllner

et al. 2022

Preprint

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Purpose: The neurometabolic timecourse of healthy aging is not well-established, in part due to diversity of quantification methodology. In this study, a large structured cross-sectional cohort of male and female subjects throughout adulthood was recruited to investigate neurometabolic changes as a function of age, using consensus-recommended magnetic resonance spectroscopy quantification methods. Methods: 102 healthy volunteers, with approximately equal numbers of male and female participants in each decade of age from the 20s, 30s, 40s, 50s, and 60s, were recruited with IRB approval. MR spectroscopic data were acquired on a 3T MRI scanner. Metabolite spectra were acquired using PRESS localization (TE = 30 ms; 96 transients) in the centrum semiovale (CSO) and posterior cingulate cortex (PCC). Water-suppressed spectra were modeled using the Osprey algorithm, employing a basis set of 18 simulated metabolite basis functions and a cohort-mean measured macromolecular spectrum. Pearson correlations were conducted to assess relationships between metabolite concentrations and age for each voxel; paired t-tests were run to determine whether metabolite concentrations differed between the PCC and CSO. Results: Two datasets were excluded (1 ethanol; 1 unacceptably large lipid signal). Statistically significant age-by-metabolite correlations were seen for tCr (R2=0.36; p<0.001), tCho (R2=0.11; p<0.001), sI (R2=0.11; p=0.004), and mI (R2=0.10; p<0.001) in the CSO, and tCr (R2=0.15; p<0.001), tCho (R2=0.11; p<0.001), and GABA (R2=0.11; p=0.003) in the PCC. No significant correlations were seen between tNAA, NAA, GSH, Glx or Glu and age in either region (all p>0.25). Levels of sI were significantly higher in the PCC in female subjects (p<0.001) than in male subjects. There was a significant positive correlation between linewidth and age. Conclusion: The results indicated age correlations for tCho, tCr, sI, and mI in CSO and for tCr, tCho and GABA in PCC, while no age-related changes were found for NAA, tNAA, GSH, Glu or Glx. Our results provide a normative foundation for future work investigating the neurometabolic time course of healthy aging using MRS.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Neurometabolic timecourse of healthy aging

Gong

Hui

Zöllner

et al. 2022

Preprint

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Section: Introductionmentioning

confidence: 99%

“…Interestingly, it has not been investigated whether including subject-specific measured MMs (mMM) in the LCM has advantages over cohort-mean mMMs, possibly because prohibitively long acquisition times have disincentivized such a study, and current MRS analysis software does not provide easily accessible workflows to do so. A recent large-scale lifespan cohort 9,10 now provides sufficient publicly available data to compare the two strategies. This dataset further allows investigation of other important issues of MM modeling in short-TE spectra to be investigated: Parameterized vs. measured MM: Only a few low-n studies have systematically compared metabolite estimation between parameterized MM (pMM) and mMM modeling, or studied updated MM parameterizations 11–13 . Other studies focused on individual differences between measured MM spectra, but did not investigate the impact on the metabolite estimation 9,14 . LCM algorithms apply modeling parameters to the basis functions, including a single Gaussian linebroadening parameter to account for B 0 inhomogeneities in the MRS volume 7,15,16 .…”

Section: Introductionmentioning

confidence: 99%

Cohort-mean measured macromolecules lead to more robust linear-combination modeling than parameterized and subject-specific ones

Zöllner

Davies-Jenkins

Murali‐Manohar

et al. 2022

Preprint

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Expert consensus recommends linear-combination modeling (LCM) of proton MR spectra with sequence-specific simulated metabolite basis function and experimentally derived macromolecular (MM) basis functions. Measured MM basis functions have been derived from metabolite-nulled spectra averaged across a small cohort. The use of subject-specific instead of cohort-averaged measured MM basis functions has not been studied. Furthermore, measured MM basis functions are not widely available to non-expert users, who commonly rely on parameterized MM signals internally simulated by LCM software. To investigate the impact of the choice of MM modeling, this study, therefore, compares metabolite level estimates between different MM modeling strategies (cohort-mean measured; subject-specific measured; parameterized) in a lifespan cohort and characterizes its impact on metabolite-age associations. 102 conventional (TE = 30 ms) and metabolite-nulled (TI = 650 ms) PRESS datasets, acquired from the medial parietal lobe in a lifespan cohort (20-70 years of age), were analyzed in Osprey. Short-TE spectra were modeled in Osprey using six different strategies to consider the macromolecular baseline. Fully tissue- and relaxation-corrected metabolite levels were compared between MM strategies. Model performance was evaluated by model residuals, the Akaike information criterion (AIC), and the impact on metabolite-age associations. The choice of MM strategy had a significant impact on metabolite level estimates. The estimates agreed relatively well between different MM strategies (r > 0.6) and had no major impact on the variance. The lowest relative model residuals and AIC values were found for the cohort-mean measured MM. Metabolite-age associations were consistently found for two major singlet signals (tCr, tCho) for all MM strategies, but varied substantially for highly J-coupled metabolites. A variance partition analysis indicated that up to 44% of the total variance was related to the choice of MM strategy. Additionally, the variance partition analysis reproduced the metabolite-age association for tCr and tCho found in the simpler correlation analysis. In summary, the inclusion of a single high-SNR MM basis function (cohort-mean) leads to more robust metabolite estimation (lower model residuals and AIC values) compared to MM strategies with more degrees of freedom (Gaussian parametrization) or subject-specific MM information. Integration of multiple LCM analyses into a single statistical model potentially improves the robustness in the detection of underlying effects (e.g. metabolite vs age), reduces algorithm-based bias, and estimates algorithm-related variance.

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sLASER and PRESS perform similarly at revealing metabolite‐age correlations at 3 T

Hui,

Zöllner,

Gong

et al. 2023

Magnetic Resonance in Med

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PurposeTo compare the respective ability of PRESS and sLASER to reveal biological relationships, using age as a validation covariate at 3 T.MethodsMRS data were acquired from 102 healthy volunteers using PRESS and sLASER in centrum semiovale and posterior cingulate cortex (PCC). Acquisition parameters included TR/TE = 2000/30 ms, 96 transients, and 2048 datapoints sampled at 2 kHz.Spectra were analyzed using Osprey. SNR, FWHM linewidth of total creatine, and metabolite concentrations were extracted. A linear model was used to compare SNR and linewidth. Paired t‐tests were used to assess differences in metabolite measurements between PRESS and sLASER. Correlations were used to evaluate the relationship between PRESS and sLASER metabolite estimates, as well as the strength of each metabolite‐age relationship. Coefficients of variation were calculated to assess inter‐subject variability in each metabolite measurement.ResultsSNR and linewidth were significantly higher (p < 0.01) for sLASER than PRESS in PCC. Paired t‐tests showed significant differences between PRESS and sLASER in most metabolite measurements. PRESS‐sLASER measurements were significantly correlated (p < 0.05) for most metabolites. Metabolite‐age relationships were consistently identified using both methods. Similar coefficients of variation were observed for most metabolites.ConclusionThe study results suggest strong agreement between PRESS and sLASER in identifying relationships between brain metabolites and age in centrum semiovale and PCC data acquired at 3 T. sLASER is technically desirable due to the reduced chemical shift displacement artifact; however, PRESS performed similarly in homogeneous brain regions at clinical field strength.

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The macromolecular MR spectrum does not change with healthy aging

Cited by 24 publications

References 40 publications

Neurometabolic timecourse of healthy aging

Neurometabolic timecourse of healthy aging

Cohort-mean measured macromolecules lead to more robust linear-combination modeling than parameterized and subject-specific ones

sLASER and PRESS perform similarly at revealing metabolite‐age correlations at 3 T

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