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神经退行性变的不同定义产生了相似的淀粉样蛋白/神经退行性变生物标志物组研究结果。

Different definitions of neurodegeneration produce similar amyloid/neurodegeneration biomarker group findings.

作者信息

Jack Clifford R, Wiste Heather J, Weigand Stephen D, Knopman David S, Mielke Michelle M, Vemuri Prashanthi, Lowe Val, Senjem Matthew L, Gunter Jeffrey L, Reyes Denise, Machulda Mary M, Roberts Rosebud, Petersen Ronald C

机构信息

1 Department of Radiology, Mayo Clinic and Foundation, 200 First Street SW, Rochester, MN 55905, USA

2 Department of Health Sciences Research, Mayo Clinic and Foundation, 200 First Street SW, Rochester, MN 55905, USA.

出版信息

Brain. 2015 Dec;138(Pt 12):3747-59. doi: 10.1093/brain/awv283. Epub 2015 Sep 30.

DOI:10.1093/brain/awv283
PMID:26428666
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4655341/
Abstract

We recently demonstrated that the frequencies of biomarker groups defined by the presence or absence of both amyloidosis (A+) and neurodegeneration (N+) changed dramatically by age in cognitively non-impaired subjects. Our present objectives were to assess the consequences of defining neurodegeneration in five different ways on the frequency of subjects classified as N+, on the demographic associations with N+, and on amyloidosis and neurodegeneration (A/N) biomarker group frequencies by age. This was a largely cross-sectional observational study of 1331 cognitively non-impaired subjects aged 50-89 drawn from a population-based study of cognitive ageing. We assessed demographic associations with N+, and A/N biomarker group frequencies by age where A+ was defined by amyloid PET and N+ was defined in five different ways: (i) abnormal adjusted hippocampal volume alone; (ii) abnormal Alzheimer's disease signature cortical thickness alone; (iii) abnormal fluorodeoxyglucose positron emission tomography alone; (iv) abnormal adjusted hippocampal volume or abnormal fluorodeoxyglucose positron emission tomography; and (v) abnormal Alzheimer's disease signature cortical thickness or abnormal fluorodeoxyglucose positron emission tomography. For each N+ definition, participants were assigned to one of four biomarker groups; A-N-, A+N-, A-N+, or A+N+. The three continuous individual neurodegeneration measures were moderately correlated (rs = 0.42 to 0.54) but when classified as normal or abnormal had only weak agreement (κ = 0.20 to 0.29). The adjusted hippocampal volume alone definition classified the fewest subjects as N+ while the Alzheimer's disease signature cortical thickness or abnormal fluorodeoxyglucose positron emission tomography definition classified the most as N+. Across all N+ definitions, N+ subjects tended to be older, more often male and APOE4 carriers, and performed less well on functional status and learning and memory than N- subjects. For all definitions of neurodegeneration, (i) the frequency of A-N- was 100% at age 50 and declined monotonically thereafter; (ii) the frequency of A+N- increased from age 50 to a maximum in the mid-70s and declined thereafter; and3 (iii) the frequency of A-N+ (suspected non-Alzheimer's pathophysiology) and of A+N+ increased monotonically beginning in the mid-50s and mid-60s, respectively. Overall, different neurodegeneration measures provide similar but not completely redundant information. Despite quantitative differences, the overall qualitative pattern of the A-N-, A+N-, A-N+, and A+N+ biomarker group frequency curves by age were similar across the five different definitions of neurodegeneration. We conclude that grouping subjects by amyloidosis and neurodegeneration status (normal/abnormal) is robust to different imaging definitions of neurodegeneration and thus is a useful way for investigators throughout the field to communicate in a common classification framework.

摘要

我们最近证明,在认知功能未受损的受试者中,由淀粉样变性(A+)和神经退行性变(N+)的存在与否所定义的生物标志物组的频率随年龄发生了显著变化。我们目前的目标是评估以五种不同方式定义神经退行性变对被归类为N+的受试者频率、与N+相关的人口统计学关联以及按年龄划分的淀粉样变性和神经退行性变(A/N)生物标志物组频率的影响。这是一项主要为横断面的观察性研究,研究对象为1331名年龄在50 - 89岁、认知功能未受损的受试者,这些受试者来自一项基于人群的认知衰老研究。我们评估了与N+相关的人口统计学关联以及按年龄划分的A/N生物标志物组频率,其中A+由淀粉样蛋白PET定义,N+以五种不同方式定义:(i)仅调整后的海马体积异常;(ii)仅阿尔茨海默病特征性皮质厚度异常;(iii)仅氟脱氧葡萄糖正电子发射断层扫描异常;(iv)调整后的海马体积异常或氟脱氧葡萄糖正电子发射断层扫描异常;以及(v)阿尔茨海默病特征性皮质厚度异常或氟脱氧葡萄糖正电子发射断层扫描异常。对于每个N+定义,参与者被分配到四个生物标志物组之一;A - N -、A + N -、A - N +或A + N +。三种连续的个体神经退行性变测量指标之间存在中度相关性(rs = 0.42至0.54),但在分类为正常或异常时仅有较弱的一致性(κ = 0.20至0.29)。仅调整后的海马体积定义将最少的受试者归类为N+,而阿尔茨海默病特征性皮质厚度或氟脱氧葡萄糖正电子发射断层扫描异常定义将最多的受试者归类为N+。在所有N+定义中,N+受试者往往年龄更大,男性和APOE4携带者更为常见,并且在功能状态以及学习和记忆方面的表现比N - 受试者更差。对于神经退行性变的所有定义,(i)A - N - 的频率在50岁时为100%,此后单调下降;(ii)A + N - 的频率从50岁增加到70年代中期达到最大值,此后下降;以及(iii)A - N +(疑似非阿尔茨海默病病理生理学)和A + N +的频率分别从50年代中期和60年代中期开始单调增加。总体而言,不同的神经退行性变测量方法提供了相似但并非完全冗余的信息。尽管存在数量差异,但在神经退行性变的五种不同定义中,按年龄划分的A - N -、A + N -、A - N +和A + N +生物标志物组频率曲线的总体定性模式相似。我们得出结论,根据淀粉样变性和神经退行性变状态(正常/异常)对受试者进行分组对于神经退行性变的不同影像学定义具有稳健性,因此是该领域研究人员在通用分类框架中进行交流的一种有用方式。

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