Data‐driven analysis of 10,361 amyloid‐PET scans from the IDEAS study reveals two primary axes of variation

Background The variability in the regional distribution of Aβ‐PET signal and its relation to clinical features is debated. We used data‐driven approaches to uncover heterogeneity in cortical Aβ‐PET signal from a large representative sample collected through the IDEAS study. Methods We analysed cross...

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Veröffentlicht in:	Alzheimer's & dementia 2024-12, Vol.20 (S2), p.n/a
Hauptverfasser:	Giorgio, Joseph, Mundada, Nidhi S, Blazhenets, Ganna, Mejía‐Perez, Jhony Alejandro, Schonhaut, Daniel R., Carrillo, Maria C., Hanna, Lucy, Gatsonis, Constantine, March, Andrew, Apgar, Charles, Siegel, Barry A., Hillner, Bruce E, Whitmer, Rachel A., Jagust, William J., Rabinovici, Gil D., Joie, Renaud La
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creator	Giorgio, Joseph Mundada, Nidhi S Blazhenets, Ganna Mejía‐Perez, Jhony Alejandro Schonhaut, Daniel R. Carrillo, Maria C. Hanna, Lucy Gatsonis, Constantine March, Andrew Apgar, Charles Siegel, Barry A. Hillner, Bruce E Whitmer, Rachel A. Jagust, William J. Rabinovici, Gil D. Joie, Renaud La
description	Background The variability in the regional distribution of Aβ‐PET signal and its relation to clinical features is debated. We used data‐driven approaches to uncover heterogeneity in cortical Aβ‐PET signal from a large representative sample collected through the IDEAS study. Methods We analysed cross‐sectional Aβ‐PET collected from 10,361 patients with MCI or mild dementia scanned in 295 PET facilities using one of the 3 FDA‐approved tracers. Central image processing resulted in template‐space SUVR images (reference: whole cerebellum) and centiloid (CL) values. Spatial independent component analysis was used to decompose SUVR volumes into 40 independent components. After excluding noise components, participants’ scores were extracted for each of the remaining 11 grey matter (GM) components describing cortical and subcortical binding. K‐means clustering was used on these GM component scores to assign each participant to different Aβ‐PET clusters based on GM binding (Figure 1). Results Three informative clusters of PET binding were estimated. Cluster 1: Aβ‐(n=4729, CL mean=2±23) with low GM binding, and two Aβ+ clusters; Cluster 2(n=2484, CL mean=76±34) and Cluster 3(n=3148, CL mean=86±32). Subtracting average SUVR of Clusters 2 and 3 showed they differed along a posterior‐anterior gradient with Cluster 2 showing an occipital predominant pattern. Principal component analysis conducted on the GM scores confirmed two dominant axes of variation separated the clusters, a Aβ‐ to Aβ+ axis and, an anterior‐posterior axis (Figure 2). Statistically significant but weak differences were observed between the two Aβ+ Clusters (2 vs. 3); Visual Read (positive: 95% vs. 92%); Clinical Stage (dementia: 47% vs. 41%); Age (76.9±6.4 vs. 75.9±6.2), however, most clinical variables showed no differences (Figure 3a). 48 ADNI participants with Aβ‐PET and post‐mortem neuropathology data (11 Female, Age mean=79.7±7.4, PET‐Death mean=2.3±1.7years; Aβ‐CL mean=71.2±55.5; APOE4(0/1/2)=22/21/5; Diagnosis(CN/MCI/AD)=6/8/32) were applied to the model fit on IDEAS data. Qualitatively, no differences in neuropathology were observed between the two Aβ+ Clusters (Figure 3b). Conclusion Data driven classification of Aβ‐PET reveals two primary axes reflecting Aβ load and anterior‐posterior binding, with the later not clearly related to clinical or pathological variation. Future work will apply new data to this model and investigate if this spatial variation in Aβ‐PET is related to longitudinal ch
doi_str_mv	10.1002/alz.091027
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We used data‐driven approaches to uncover heterogeneity in cortical Aβ‐PET signal from a large representative sample collected through the IDEAS study. Methods We analysed cross‐sectional Aβ‐PET collected from 10,361 patients with MCI or mild dementia scanned in 295 PET facilities using one of the 3 FDA‐approved tracers. Central image processing resulted in template‐space SUVR images (reference: whole cerebellum) and centiloid (CL) values. Spatial independent component analysis was used to decompose SUVR volumes into 40 independent components. After excluding noise components, participants’ scores were extracted for each of the remaining 11 grey matter (GM) components describing cortical and subcortical binding. K‐means clustering was used on these GM component scores to assign each participant to different Aβ‐PET clusters based on GM binding (Figure 1). Results Three informative clusters of PET binding were estimated. Cluster 1: Aβ‐(n=4729, CL mean=2±23) with low GM binding, and two Aβ+ clusters; Cluster 2(n=2484, CL mean=76±34) and Cluster 3(n=3148, CL mean=86±32). Subtracting average SUVR of Clusters 2 and 3 showed they differed along a posterior‐anterior gradient with Cluster 2 showing an occipital predominant pattern. Principal component analysis conducted on the GM scores confirmed two dominant axes of variation separated the clusters, a Aβ‐ to Aβ+ axis and, an anterior‐posterior axis (Figure 2). Statistically significant but weak differences were observed between the two Aβ+ Clusters (2 vs. 3); Visual Read (positive: 95% vs. 92%); Clinical Stage (dementia: 47% vs. 41%); Age (76.9±6.4 vs. 75.9±6.2), however, most clinical variables showed no differences (Figure 3a). 48 ADNI participants with Aβ‐PET and post‐mortem neuropathology data (11 Female, Age mean=79.7±7.4, PET‐Death mean=2.3±1.7years; Aβ‐CL mean=71.2±55.5; APOE4(0/1/2)=22/21/5; Diagnosis(CN/MCI/AD)=6/8/32) were applied to the model fit on IDEAS data. Qualitatively, no differences in neuropathology were observed between the two Aβ+ Clusters (Figure 3b). Conclusion Data driven classification of Aβ‐PET reveals two primary axes reflecting Aβ load and anterior‐posterior binding, with the later not clearly related to clinical or pathological variation. Future work will apply new data to this model and investigate if this spatial variation in Aβ‐PET is related to longitudinal changes in pathology.</description><identifier>ISSN: 1552-5260</identifier><identifier>EISSN: 1552-5279</identifier><identifier>DOI: 10.1002/alz.091027</identifier><language>eng</language><publisher>Hoboken: John Wiley and Sons Inc</publisher><subject>Biomarkers</subject><ispartof>Alzheimer's & dementia, 2024-12, Vol.20 (S2), p.n/a</ispartof><rights>2024 The Alzheimer's Association. published by Wiley Periodicals LLC on behalf of Alzheimer's Association.</rights><lds50>peer_reviewed</lds50><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktopdf>$$Uhttps://www.ncbi.nlm.nih.gov/pmc/articles/PMC11714768/pdf/$$EPDF$$P50$$Gpubmedcentral$$Hfree_for_read</linktopdf><linktohtml>$$Uhttps://www.ncbi.nlm.nih.gov/pmc/articles/PMC11714768/$$EHTML$$P50$$Gpubmedcentral$$Hfree_for_read</linktohtml><link.rule.ids>230,314,723,776,780,881,1411,11541,27901,27902,45550,45551,46027,46451,53766,53768</link.rule.ids></links><search><creatorcontrib>Giorgio, Joseph</creatorcontrib><creatorcontrib>Mundada, Nidhi S</creatorcontrib><creatorcontrib>Blazhenets, Ganna</creatorcontrib><creatorcontrib>Mejía‐Perez, Jhony Alejandro</creatorcontrib><creatorcontrib>Schonhaut, Daniel R.</creatorcontrib><creatorcontrib>Carrillo, Maria C.</creatorcontrib><creatorcontrib>Hanna, Lucy</creatorcontrib><creatorcontrib>Gatsonis, Constantine</creatorcontrib><creatorcontrib>March, Andrew</creatorcontrib><creatorcontrib>Apgar, Charles</creatorcontrib><creatorcontrib>Siegel, Barry A.</creatorcontrib><creatorcontrib>Hillner, Bruce E</creatorcontrib><creatorcontrib>Whitmer, Rachel A.</creatorcontrib><creatorcontrib>Jagust, William J.</creatorcontrib><creatorcontrib>Rabinovici, Gil D.</creatorcontrib><creatorcontrib>Joie, Renaud La</creatorcontrib><title>Data‐driven analysis of 10,361 amyloid‐PET scans from the IDEAS study reveals two primary axes of variation</title><title>Alzheimer's & dementia</title><description>Background The variability in the regional distribution of Aβ‐PET signal and its relation to clinical features is debated. We used data‐driven approaches to uncover heterogeneity in cortical Aβ‐PET signal from a large representative sample collected through the IDEAS study. Methods We analysed cross‐sectional Aβ‐PET collected from 10,361 patients with MCI or mild dementia scanned in 295 PET facilities using one of the 3 FDA‐approved tracers. Central image processing resulted in template‐space SUVR images (reference: whole cerebellum) and centiloid (CL) values. Spatial independent component analysis was used to decompose SUVR volumes into 40 independent components. After excluding noise components, participants’ scores were extracted for each of the remaining 11 grey matter (GM) components describing cortical and subcortical binding. K‐means clustering was used on these GM component scores to assign each participant to different Aβ‐PET clusters based on GM binding (Figure 1). Results Three informative clusters of PET binding were estimated. Cluster 1: Aβ‐(n=4729, CL mean=2±23) with low GM binding, and two Aβ+ clusters; Cluster 2(n=2484, CL mean=76±34) and Cluster 3(n=3148, CL mean=86±32). Subtracting average SUVR of Clusters 2 and 3 showed they differed along a posterior‐anterior gradient with Cluster 2 showing an occipital predominant pattern. Principal component analysis conducted on the GM scores confirmed two dominant axes of variation separated the clusters, a Aβ‐ to Aβ+ axis and, an anterior‐posterior axis (Figure 2). Statistically significant but weak differences were observed between the two Aβ+ Clusters (2 vs. 3); Visual Read (positive: 95% vs. 92%); Clinical Stage (dementia: 47% vs. 41%); Age (76.9±6.4 vs. 75.9±6.2), however, most clinical variables showed no differences (Figure 3a). 48 ADNI participants with Aβ‐PET and post‐mortem neuropathology data (11 Female, Age mean=79.7±7.4, PET‐Death mean=2.3±1.7years; Aβ‐CL mean=71.2±55.5; APOE4(0/1/2)=22/21/5; Diagnosis(CN/MCI/AD)=6/8/32) were applied to the model fit on IDEAS data. Qualitatively, no differences in neuropathology were observed between the two Aβ+ Clusters (Figure 3b). Conclusion Data driven classification of Aβ‐PET reveals two primary axes reflecting Aβ load and anterior‐posterior binding, with the later not clearly related to clinical or pathological variation. Future work will apply new data to this model and investigate if this spatial variation in Aβ‐PET is related to longitudinal changes in pathology.</description><subject>Biomarkers</subject><issn>1552-5260</issn><issn>1552-5279</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2024</creationdate><recordtype>article</recordtype><sourceid>24P</sourceid><recordid>eNp9kMFKw0AQhoMoWKsXn2DPYutOk-wmJylt1UJBwXrxskw3u3YlyZbdNDWefASf0Scx2lLw4mmGmW8-hj8IzoH2gdLBFebvfZoCHfCDoANxPOjFA54e7ntGj4MT718pjWgCcSewY6zw6-Mzc6ZWJcES88YbT6wmQC9DBgSLJrcma5mHyZx4iaUn2tmCVEtFpuPJ8JH4ap01xKlaYe5JtbFk5UyBriH4pn5dNTqDlbHlaXCkW0id7Wo3eLqZzEd3vdn97XQ0nPUksJT3lMxYRDO-gBClihKtQIaQJSxViAmGOpaLNAkV42mEqBlozeMwSdoRl5RB2A2ut97VelGoTKqycpiL3V_CohF_N6VZihdbCwAOEWdJa7jYGqSz3jul98dAxU_Yog1bbMNuYdjCG5Or5h9SDGfPu5tvRleFIA</recordid><startdate>202412</startdate><enddate>202412</enddate><creator>Giorgio, Joseph</creator><creator>Mundada, Nidhi S</creator><creator>Blazhenets, Ganna</creator><creator>Mejía‐Perez, Jhony Alejandro</creator><creator>Schonhaut, Daniel R.</creator><creator>Carrillo, Maria C.</creator><creator>Hanna, Lucy</creator><creator>Gatsonis, Constantine</creator><creator>March, Andrew</creator><creator>Apgar, Charles</creator><creator>Siegel, Barry A.</creator><creator>Hillner, Bruce E</creator><creator>Whitmer, Rachel A.</creator><creator>Jagust, William J.</creator><creator>Rabinovici, Gil D.</creator><creator>Joie, Renaud La</creator><general>John Wiley and Sons Inc</general><scope>24P</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>5PM</scope></search><sort><creationdate>202412</creationdate><title>Data‐driven analysis of 10,361 amyloid‐PET scans from the IDEAS study reveals two primary axes of variation</title><author>Giorgio, Joseph ; Mundada, Nidhi S ; Blazhenets, Ganna ; Mejía‐Perez, Jhony Alejandro ; Schonhaut, Daniel R. ; Carrillo, Maria C. ; Hanna, Lucy ; Gatsonis, Constantine ; March, Andrew ; Apgar, Charles ; Siegel, Barry A. ; Hillner, Bruce E ; Whitmer, Rachel A. ; Jagust, William J. ; Rabinovici, Gil D. ; Joie, Renaud La</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c1697-ecd640d7b13ace48fe1c31d869eaa8a3f5cb983e6794aaf61ff7538883e7c0613</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2024</creationdate><topic>Biomarkers</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Giorgio, Joseph</creatorcontrib><creatorcontrib>Mundada, Nidhi S</creatorcontrib><creatorcontrib>Blazhenets, Ganna</creatorcontrib><creatorcontrib>Mejía‐Perez, Jhony Alejandro</creatorcontrib><creatorcontrib>Schonhaut, Daniel R.</creatorcontrib><creatorcontrib>Carrillo, Maria C.</creatorcontrib><creatorcontrib>Hanna, Lucy</creatorcontrib><creatorcontrib>Gatsonis, Constantine</creatorcontrib><creatorcontrib>March, Andrew</creatorcontrib><creatorcontrib>Apgar, Charles</creatorcontrib><creatorcontrib>Siegel, Barry A.</creatorcontrib><creatorcontrib>Hillner, Bruce E</creatorcontrib><creatorcontrib>Whitmer, Rachel A.</creatorcontrib><creatorcontrib>Jagust, William J.</creatorcontrib><creatorcontrib>Rabinovici, Gil D.</creatorcontrib><creatorcontrib>Joie, Renaud La</creatorcontrib><collection>Wiley Online Library Open Access</collection><collection>CrossRef</collection><collection>PubMed Central (Full Participant titles)</collection><jtitle>Alzheimer's & dementia</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Giorgio, Joseph</au><au>Mundada, Nidhi S</au><au>Blazhenets, Ganna</au><au>Mejía‐Perez, Jhony Alejandro</au><au>Schonhaut, Daniel R.</au><au>Carrillo, Maria C.</au><au>Hanna, Lucy</au><au>Gatsonis, Constantine</au><au>March, Andrew</au><au>Apgar, Charles</au><au>Siegel, Barry A.</au><au>Hillner, Bruce E</au><au>Whitmer, Rachel A.</au><au>Jagust, William J.</au><au>Rabinovici, Gil D.</au><au>Joie, Renaud La</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Data‐driven analysis of 10,361 amyloid‐PET scans from the IDEAS study reveals two primary axes of variation</atitle><jtitle>Alzheimer's & dementia</jtitle><date>2024-12</date><risdate>2024</risdate><volume>20</volume><issue>S2</issue><epage>n/a</epage><issn>1552-5260</issn><eissn>1552-5279</eissn><abstract>Background The variability in the regional distribution of Aβ‐PET signal and its relation to clinical features is debated. We used data‐driven approaches to uncover heterogeneity in cortical Aβ‐PET signal from a large representative sample collected through the IDEAS study. Methods We analysed cross‐sectional Aβ‐PET collected from 10,361 patients with MCI or mild dementia scanned in 295 PET facilities using one of the 3 FDA‐approved tracers. Central image processing resulted in template‐space SUVR images (reference: whole cerebellum) and centiloid (CL) values. Spatial independent component analysis was used to decompose SUVR volumes into 40 independent components. After excluding noise components, participants’ scores were extracted for each of the remaining 11 grey matter (GM) components describing cortical and subcortical binding. K‐means clustering was used on these GM component scores to assign each participant to different Aβ‐PET clusters based on GM binding (Figure 1). Results Three informative clusters of PET binding were estimated. Cluster 1: Aβ‐(n=4729, CL mean=2±23) with low GM binding, and two Aβ+ clusters; Cluster 2(n=2484, CL mean=76±34) and Cluster 3(n=3148, CL mean=86±32). Subtracting average SUVR of Clusters 2 and 3 showed they differed along a posterior‐anterior gradient with Cluster 2 showing an occipital predominant pattern. Principal component analysis conducted on the GM scores confirmed two dominant axes of variation separated the clusters, a Aβ‐ to Aβ+ axis and, an anterior‐posterior axis (Figure 2). Statistically significant but weak differences were observed between the two Aβ+ Clusters (2 vs. 3); Visual Read (positive: 95% vs. 92%); Clinical Stage (dementia: 47% vs. 41%); Age (76.9±6.4 vs. 75.9±6.2), however, most clinical variables showed no differences (Figure 3a). 48 ADNI participants with Aβ‐PET and post‐mortem neuropathology data (11 Female, Age mean=79.7±7.4, PET‐Death mean=2.3±1.7years; Aβ‐CL mean=71.2±55.5; APOE4(0/1/2)=22/21/5; Diagnosis(CN/MCI/AD)=6/8/32) were applied to the model fit on IDEAS data. Qualitatively, no differences in neuropathology were observed between the two Aβ+ Clusters (Figure 3b). Conclusion Data driven classification of Aβ‐PET reveals two primary axes reflecting Aβ load and anterior‐posterior binding, with the later not clearly related to clinical or pathological variation. Future work will apply new data to this model and investigate if this spatial variation in Aβ‐PET is related to longitudinal changes in pathology.</abstract><cop>Hoboken</cop><pub>John Wiley and Sons Inc</pub><doi>10.1002/alz.091027</doi><tpages>5</tpages><oa>free_for_read</oa></addata></record>
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title	Data‐driven analysis of 10,361 amyloid‐PET scans from the IDEAS study reveals two primary axes of variation
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