Introduction
Chronic traumatic encephalopathy (CTE) is a neurodegenerative disorder associated with repetitive traumatic head injuries and characterized by the deposition of hyperphosphorylated tau aggregates in the brain [
5,
6]. This condition, originally observed in boxers “punch drunk” [
23], “dementia pugilistica” [
28], has since been described in players of contact sports [
13] and military personnel exposed to blast injuries [
30]. The clinical picture of CTE includes progressive behavioral and cognitive changes, including irritability, aggression, depression and memory loss, with onset years or decades after brain injury [
25], that can eventually progress to dementia [
11,
12].
The current clinical criteria of CTE lack specificity and the definitive diagnosis of this condition can only be established by neuropathologic examination
. A set of consensus neuropathological criteria for CTE were defined in 2016, which emphasize that tau-containing lesions in CTE differ from those of other tauopathies such as Alzheimer disease (AD), progressive supranuclear palsy (PSP) or corticobasal degeneration (CBD) [
24]. The pathognomonic lesions for CTE consist of tau aggregates in neurons, astrocytes and cell processes around small vessels in an irregular pattern in the depths of the cortical sulci [
24]. The presence of other neurodegenerative lesions such as TAR DNA binding protein 43 (TDP-43) inclusions and β-amyloid pathology (including plaques and amyloid angiopathy) is also a frequent concomitant finding in CTE [
24,
26]. Four progressive stages of CTE have been described according to the abundance and distribution of tau lesions [
26]. Tau aggregates in CTE contain all six isoforms with presence of both 3 (3R) and 4 (4R) repeats of the microtubule binding domain, similar to AD but distinct from most other tauopathies [
34]. Despite this similarity, it has recently been demonstrated by electron cryomicroscopy (cryo-EM) that tau filament conformation in CTE differs from that of tau filaments present in classic neurofibrillary tangles (NFTs) of AD [
9,
10].
There is great interest in developing novel biomarkers for CTE to estimate the prevalence of this disorder in at-risk populations, improve diagnostic accuracy, allow disease progression tracking, and assess treatment response. Several positron emission tomography (PET) tracers designed for detection of tau aggregates in the human living brain have been developed in the past few years. After a number of early failures, [
18F]-AV-1451 (alternatively called flortaucipir and previously [
18F]-T807) was reported [
41] as the first promising ligand for imaging tau in AD. Increased in vivo [
18F]-AV-1451 uptake has been observed in AD patients compared to cognitively normal controls (CTL) in cortical regions known to contain NFTs [
1,
3,
4,
14,
17,
32,
35,
39]. The usefulness of [
18F]-AV-1451 as a biomarker in other tauopathies such as frontotemporal lobar degeneration (FTLD)-tau including Pick’s disease (PiD), PSP, and CBD, however, is more controversial. Some authors reported increased in vivo [
18F]-AV-1451 retention in patients clinically diagnosed with non-Alzheimer (non-AD) tauopathies in regions that are expected to contain tau lesions while others noticed in vivo binding patterns nearly indistinguishable from those in normal controls [
1,
3,
4]. Several groups, including our own have demonstrated, using autoradiography approaches in postmortem brain tissue samples, that [
18F]-AV-1451 has a significantly higher affinity for tau aggregates in the form of NFTs in AD compared to tau aggregates in non-AD tauopathies [
19‐
21,
33]. Importantly, [
18F]-AV-1451 also exhibits strong
off-target binding to neuromelanin (in pigmented brainstem regions) and melanin (in leptomeninges). The former of these affinities explains the nearly universal elevated in vivo retention observed in the substantia nigra of elderly individuals regardless of their pathological diagnosis [
21]. There is additional
off-target binding in areas of intraparenchymal hemorrhage, although to a lesser degree [
21]. The underlying pathology of this tracer’s in vivo uptake frequently detected in other brain regions that do not typically contain tau aggregates in AD, such as basal ganglia, is still not yet well understood.
Only a few studies using [
18F]-AV-1451 PET in clinically diagnosed CTE subjects have been published to date [
8,
29,
36]. Results from those early reports have suggested that this tau tracer may serve as an in vivo surrogate marker for tau-containing aggregates in this condition. To date, no [
18F]-AV-1451 imaging-postmortem correlation studies in pathologically confirmed CTE cases have been published. The aim of our study was to investigate [
18F]-AV-1451 binding patterns in pathologically confirmed CTE tissue using phosphor screen and high-resolution autoradiography and correlate those findings with quantitative tau measurements as reported by immunohistochemistry, Western blotting, and tau seeding activity in the same samples. Our results show that [
18F]-AV-1451 exhibits relatively low binding affinity for tau aggregates in CTE suggesting that this tracer may have limited utility for the in vivo selective and reliable detection of tau aggregates which serve as the neuropathologic hallmark of this condition.
Material and methods
Brain tissue samples
Five cases from the Boston University (BU) Alzheimer’s Disease Research Center (ADRC) Brain Bank with a neuropathological diagnosis of CTE were selected for this study. Tissue collection and use were approved by the local Institutional Board. The neuropathological processing followed the procedures previously established by the BU ADRC Brain Bank [
38]. Paraffin-embedded sections were stained with Luxol fast blue, hematoxylin and eosin, Bielschowsky silver, AT8, amyloid-β (Aβ), α-synuclein, ubiquitin, TDP-43, SMI-31 and SMI-34 using methods described previously [
25]. Diagnostic evaluation was performed in accordance with published guidelines for neurodegenerative diseases [
2,
16,
27]. Neuropathological diagnoses were made by a BU ADRC Brain Bank neuropathologist without any knowledge of the subject’s clinical histories and was confirmed by two other neuropathologists.
Frozen brain tissue blocks containing hippocampus (HPC), superior temporal cortex (TC), superior frontal cortex (FC), inferior parietal cortex (PC) and occipital cortex including calcarine cortex (OC) were analyzed. Demographical and neuropathological information for each case is shown in Table
1. Cases were classified according to the recently described CTE staging [
26] into stages I-IV. The tissue blocks were sectioned in a freezing cryostat (Thermo-Shandon SME Cryostat) into 10-μm-thick slices and used for immunohistochemistry (IHC) and phosphor screen and nuclear emulsion autoradiography. Fresh frozen homogenates prepared from the same tissue blocks were used to quantify tau contents by Western Blot and to measure tau seeding activity by sensitive in vitro seeding assays. Fresh frozen homogenates containing the same regions of interest (ROIs) from 15 additional cases (including 9 pathologically-confirmed AD cases and 6 control cases free of pathology) from the Massachusetts ADRC where also included in the Western Blot and tau seeding assays for comparison.
Table 1 Demographic and neuropathologic characteristics
1 | CTE (CTE stage III) | 46 | M | III | none | LP |
2 | CTE (CTE stage IV) | 65 | M | II | A | LP |
3 | CTE (CTE stage III) | 56 | M | II | none | LP |
4 | CTE (CTE stage II-III) | 25 | M | 0 | none | LP |
5 | CTE (CTE stage III) | 58 | M | III | none | LP |
6 | AD | 87 | F | V | Frequent | IP |
7 | AD | 71 | M | V | Moderate | IP |
8 | AD | 96 | F | V | Frequent | HP |
9 | AD | 82 | F | V | Moderate | HP |
10 | AD | 79 | M | V | Frequent | HP |
11 | AD | 66 | M | V | Moderate | HP |
12 | AD | 69 | F | VI | Frequent | HP |
13 | AD | 66 | F | VI | Frequent | HP |
14 | AD | 66 | F | VI | Frequent | HP |
15 | CTL | 76 | F | I | Sparse | LP |
16 | CTL | 97 | F | I | Sparse | LP |
17 | CTL | 81 | M | I | none | LP |
18 | CTL | 59 | F | I-II | Moderate | LP |
19 | CTL | 91 | M | II | none | LP |
20 | CTL | 101 | F | II | Moderate | LP |
[18F]-AV-1451 phosphor screen and high resolution autoradiography
10-μm-thick frozen tissue sections containing the ROIs were used to perform [
18F]-AV-1451 phosphor screen and high resolution autoradiography experiments following our previously published protocols [
21]. In brief, sections were fixed in 100% methanol at room temperature (RT) for 20 min and transferred to a bath containing high specific activity [
18F]-AV-1451 in 10 mM PBS with a radioactivity concentration of approximately 20 μCi/ml. Adjacent sections were placed in an identical bath except that unlabeled AV-1451 was added to yield 1 μM chemical concentration, a blocking condition sufficient to saturate essentially all specific binding sites of tau [
21]. After incubation for 60 min, sections were removed from radioactivity solutions and washed to remove unbound radiotracer. Wash solutions and incubation times were: 10 mM PBS for 1 min, 70% ethanol/30% PBS for 2 min, 30% ethanol/70% PBS for 1 min, and lastly 100% 10 mM PBS for 1 min. Sections were then air dried before transferring to a storage phosphor screen (MultiSensitive Phosphor Screen, PerkinElmer Life and Analytic Sciences, Shelton, CT) that had been photobleached immediately prior by exposure on a white light box for a minimum of 15 min. Sections and phosphor screen were enclosed in aluminum film cassette and set in a dark area. Under dim lighting conditions, the cassette was opened and the slides removed from the exposed screen, which was mounted to the carousel of imaging system (Cyclone Plus Storage Phophor Scanner, PerkinElmer Life and Analytic Sciences). Scanning of screens was controlled by the manufacturer’s OptiQuant software package using the highest available resolution of 600 dpi (approximately 42 μm sampling interval). Digital images were saved in uncompressed form at full resolution and pixel depth. Images from adjacent brain slices incubated in the unblocked (high specific activity [
18F]-AV-1451 only) and blocking [
18F]-AV-1451 plus 1 μM unlabeled AV-1451) conditions were compared to determine total and non-specific binding of [
18F]-AV-1451 in the tissue. All experiments were run in triplicate on adjacent tissue sections.
To rule out the possibility that the ethanol washing steps used in the above autoradiography protocol may have removed some weaker tracer binding, parallel experiments in comparable tissue samples incubated with [18F]-AV-1451 with a radioactivity concentration of approximately 1 μCi/ml and avoiding the use of ethanol in the washing conditions were also conducted. All assays were done in triplicate on adjacent tissue sections.
To obtain autoradiographic information at cellular resolution level, frozen cryostat sections, adjacent to those used for phosphor screen autoradiography, were coated with liquid photographic emulsion, then immunostained using appropriate primary antibodies - anti-tau PHF1 (1:100, mouse, kind gift of Dr. Peter Davies), anti Aβ (1:50, rabbit, IgG Affinify Purify, IBL) or anti TDP-43 (1:100, rabbit, Protein Tech) – and counterstained with H&E following our previously published protocol [
20].
Tau burden quantification by immunohistochemistry
10-μm-thick frozen tissue sections containing the five ROIs and adjacent to those used in autoradiography experiments were stained with PHF-1 antibody (1:100, mouse, kind gift of Dr. Peter Davies) and analyzed with an upright Olympus BX51 microscope (Olympus, Denmark) using the CAST software (Visiopharm, 2004, Denmark). Each ROI was drawn in the corresponding slide at 1.25x magnification, and then a systematic random sampling was applied using the software’s optical disector probe at 10x magnification (meander sampling 20%). A threshold of optical density was obtained in each microphotograph using ImageJ (National Institute of Health). Manual editing in each field eliminated artifacts. Tau pathology burden, defined as total percentage (%) of area covered by PHF-1 immunostaining, was calculated in each ROI.
Measurements of soluble tau in synaptoneurosomal fractions by Western blot
Synaptoneurosomal fractions from the five ROIs were obtained from the same tissue blocks used in immunohistochemistry and autoradiography experiments to measure soluble tau content by Western blot, following our previously published protocol [
20]. Human tau (Dako, A0024) and PHF-1 (kind gift of Dr. Peter Davies) antibodies were used to assess levels of total tau and hyperphosphorilated-tau, respectively. Briefly, tissue samples were homogenized in Buffer A (25 mM HEPES 7.5, 120 mM NaCl, 5 mM KCL, 1 mM MgCl2, 2 mM CaCl2, 1 mM DTT) supplemented with Phosphatase Inhibitor Cocktail tablets (Roche, 04906845001) and Protease Inhibitor Cocktail tablets (Roche, 11,697,498,001). The homogenate was filtered through 2 Millipore Nylon 80 μm filters after the addition of 0.6 mL Buffer A and 200 μL of homogenate was separated. Two hundred microliter of distilled H
2O and 70 μL of 10% SDS were added to the homogenate and passed through a 27½ G needle 3 times. The remaining homogenate was filtered again through PALL Acrodisc Syringe 5 μm Filters after the addition of 1 mL Buffer A, and centrifuged at 1000 g for 10 min at 4 °C. The supernatant was then separated and ultracentrifuged at 100,000 g for 45 min, and the pellet was resuspended in 200 μL Buffer B (50 mM Tris, 1.5% SDS, 1 mM DTT). The resuspended pellet and the separated homogenate were then boiled for 5 min, centrifuged for 15 min, and the supernatants were collected as synaptoneurosome (SNS) and total fractions, respectively.
SNS fractions from each ROI were electrophoresed in MES SDS Running Buffer (Novex, NP0002) using 4–12% Bis-Tris Novex gels (Invitrogen, #MAN0003679). Protein was then transferred onto nitrocellulose membranes and blocked for an hour at room temperature using Odyssey Blocking Buffer (LiCor, 927–40,000). Membranes were probed with human tau (Dako, A0024) and PHF-1 (kind gift of Dr. Peter Davies) antibodies to detect content of total tau and phospho-tau, respectively. GAPDH (Millipore, AB2302) was used as loading control for protein normalization. LiCor secondary antibodies (IR Dye 680RD Donkey anti-chicken 926–68,075, IR Dye 800 CW Donkey anti-rabbit 926–32,213, IR Dye 800CW Donkey anti-mouse 926–32,212) were then used to visualize bands with the Odyssey Infrared Imaging System (V3.0). ImageStudio was used to quantify the bands of interest by drawing equal size rectangles around individual bands of interest. Background subtraction was applied by taking the median of the area three pixels to the left and right of each band of interest and subtracting that value from the measured signal.
Tau seeding assays
PBS fractions obtained from fresh frozen total homogenates from the five ROIs were used to perform tau seeding activity assays. Equivalent samples from AD (
n = 9) and control cases free of tau pathology (
n = 6) were also analyzed for comparison. In vitro tau seeding activity was measured as previously described elsewhere [
15]. In short, HEK293 cells stably expressing TauRD
P301S fused with cyan fluorescent protein (CFP) and TauRD
P301S-yellow fluorescent protein (YFP) (Tau RD P301S FRET Biosensor (ATCC CRL
R-3275™)) were plated at 40,000 cells per well in poly-D-lysine coated black clear-bottom 96-well plates (Corning). The following day, cells were transduced with a total of 50 μl of 2 μg/well PBS-soluble frozen brain lysate (3,000
g) plus 7% lipofectamine 2000 transfection reagent (#11668–019, Invitrogen) in Opti-MEM (#11058–021, Life technologies), after the lysate and lipofectamine complex had incubated at room temperature for 20 min. The cells were left to incubate at 37 °C with the lysate-lipofectamine complex for 41 h. Cells were then removed from the plate using Trypsin-EDTA and transferred to a 96-well U-bottom plate (Corning) with chilled DMEM 10% FBS media. Cells were pelleted at 1,800
g using a plate spinner, fixed with 2% paraformaldehyde (PFA, #15714-S, Electron Microscopy Sciences) in the dark for 10 min at 4 °C, and pelleted again. Cells were resuspended in cold PBS and immediately run on the MACSQuant VYB flow cytometer (Miltenyi). CFP and FRET were measured on the flow cytometer by exciting the HEK293 cells with a 405 nm laser and then reading fluorescence at 405/50 nm and 525/50 nm filters, respectively. Using the MACSQuantify flow cytometry software (Miltenyi), the integrated FRET density (IFD) was calculated by multiplying the % number of FRET-positive tau aggregates by the mean fluorescence intensity of FRET-positive tau aggregates. This value was then normalized by the value for the cells that were treated only with the lipofectamine (without brain lysate), serving as a non-treated FRET-negative population. Each sample was run in triplicate. Representative images of the tau aggregates were captured using the ZOE Fluorescent Cell Imager (BioRad) in the GFP excitation and emission filters.
Statistical analysis
Correlation analyses between PHF-tau burden quantification by immunohistochemistry, measurements of soluble tau contents as reported by Western blot, and IFD as reported by tau seeding assays were conducted using a Spearman correlation test. For non-parametric analyses, Kruskal-Wallis test was used to compare IFD in control, CTE and AD samples. Significance was set at p < 0.05. All statistical analysis and graphs were generated using GraphPad Prism v6.0 software (GraphPad Software Inc., La Jolla, CA).
Discussion
We have examined the postmortem regional- and substrate-specific binding patterns of tau PET tracer [
18F]-AV-1541 in multiple ROIs from five autopsy-confirmed CTE cases. Our observations are derived from [
18F]-AV-1451 sensitive autoradiography, quantification of tau burden on immunostained sections, biochemical analysis of soluble tau content by Western blot and in vitro tau seeding activity assays. In agreement with our previous observations, high resolution autoradiography experiments revealed strong binding of [
18F]-AV-1451 to NFTs in AD [
20,
21], but negligible binding to tau aggregates in CTE brains. A strong [
18F]-AV-1451 binding to incidental leptomeningeal melanocytes present in two of the five CTE cases further confirmed tracer
off-target binding to this biological substrate [
20,
21]. These observations, along with the lack of correlation between [
18F]-AV-1541 autoradiographic regional binding at postmortem and the topographical distribution of tau aggregates or multiple other tau measures in these cases of CTE, suggest that [
18F]-AV-1451 may not have sufficient sensitivity to reliable detect and quantify tau pathology in CTE by in vivo neuroimaging particularly when confounding AD lesions are present in the context of aging.
As in other neurodegenerative conditions, the development of novel fluid and neuroimaging biomarkers potentially capable of facilitating an accurate diagnosis of CTE and of monitoring disease progression has become a priority in this research field [
37,
42]. While tau PET tracer [
18F]-AV-1451 has recently shown great promise as a surrogate biomarker for tau-containing lesions in AD through its binding to NFTs with PHF conformation, the potential utility of this ligand in assessing the burden of the distinct tau-containing lesions of CTE remains uncertain. To date, only very limited data from human in vivo [
18F]-AV-1451 PET imaging studies in patients with clinically suspected CTE have been published and they all, unfortunately, lack neuropathological confirmation of the diagnosis. Mitsis et al. reported a 71-year old retired NFL football player who had experienced multiple concussions and presented with progressive cognitive impairment in his 60s. [
18F]-Florbetapir PET was negative, excluding significant concomitant amyloid deposition, while [
18F]-AV-1451 PET showed increased uptake localized in globus pallidus, putamen, hippocampus and the substantia nigra [
29]. However, we and others have described a nearly identical pattern of in vivo retention in elderly controls [
17], that seems heavily influenced by the non-specific retention of this tracer in basal ganglia and its
off-target to neuromelanin-containing neurons in the substantia nigra [
21]. Dickstein et al. reported another 39-year old retired NFL football player with a history of multiple concussions who experienced cognitive decline, irritability and emotional lability in his 30s. [
18F]-Florbetapir PET was negative and [
18F]-AV-1451 showed increased retention in midbrain, globus pallidus and hippocampus, and also at gray-white matter junctions in multiple cortical areas, mirroring the described postmortem distribution of CTE tau lesions [
7]. It should be noted though that, in the absence of a validated threshold for defining signal with [
18F]-AV-1451, the authors relied on the value commonly used for the amyloid PET tracer florbetapir and thus, these results must be interpreted with caution [
18]. Very recently, another study by Stern et al. has reported a significantly higher [
18F]-AV-1451 in vivo retention at the group level in three brains regions (bilateral superior frontal, bilateral medial temporal, and left parietal) in a cohort of 26 former National Football League (NFL) players with cognitive and neuropsychiatric symptoms compared to 31 asymptomatic men with no history of traumatic brain injury [
36]. It remains unclear whether such differences were also present at individual level. Of note, the average in vivo retention values observed in the group of NFL players in that study were quite modest (SUVR values 1.09–1.12), with the exception of the medial temporal lobe (1.23); most fell within the range of in vivo retention values reported in normal elderly controls in multiple other studies [
31]. Intriguingly, no association between [
18F]-AV-1451 in vivo retention and scores on cognitive and neuropsychiatric tests could be demonstrated. The potential presence of age-related tau-containing lesions in the medial temporal lobe and tracer
off-target binding to old hemorrhages, which are quite common after brain trauma, are potential confounders when interpreting these results.
All of the 5 CTE cases studied here demonstrated immunohistochemically confirmed abundant tau aggregates in a distribution consistent with the consensus diagnostic criteria. Importantly, we carefully selected the CTE cases included in this study ruling out the presence of substantial concomitant AD pathology as a confounder in our autoradiography experiments given the known strong affinity of [
18F]-AV-1451 to classic AD tau tangles. Our phosphor-screen autoradiography experiments, showed negligible binding of [
18F]-AV-1451 in brain regions with a high burden of tau lesions apart from
off-target binding to leptomeningeal melanocytes present in two of the five cases. In contrast, tangle-containing sections from AD brains, included here as positive control, exhibited strong [
18F]-AV-1451 binding signal as previously reported by us and others [
19–22, 33, 41]. In agreement with these findings, high resolution nuclear emulsion autoradiography experiments showed high concentrations of silver grains colocalizing with NFTs in AD brains and incidental extracutaneous leptomeningeal melanocytes but no detectable silver grain accumulation colocalizing with CTE tau aggregates.
The possibility that the use of ethanol in the washing steps included in our traditional autoradiography protocol may have removed some weaker tracer binding was carefully ruled out by performing experiments which avoided the use of ethanol or other solvents in the washing conditions. Those parallel autoradiography studies yielded identical results.
The pathological tau burden in the CTE cases, quantified on immunostained sections containing multiple ROIs, significantly correlated with the levels of soluble p-tau monomers and oligomers, as assessed by Western blotting, and with tau seeding activity in the same ROIs. These measures of pathologic tau aggregates, however, were substantially lower than those found in a series of 9 AD cases that were used here for comparison. Intriguingly, a previous study by Woerman et al. reported increased tau seeding activity in CTE when compared to AD brains [
40]. We believe that the discrepancies between that and the present study may be related to differences in sampling, given the highly focal nature of CTE [
40], and/or the potential presence of concomitant AD pathology, a common finding in this condition [
26], in older individuals with CTE. As noted above, our studies specifically excluded coincident neuropathologic processes, including the presence of substantial AD pathology, as a potential confounder through careful case selection.
Our results suggest that [
18F]-AV-1451 differs in its affinity for the tau aggregate-containing lesions of CTE and AD, despite both being comprised of 3 and 4 repeat isoforms of tau. Importantly, recent studies based on cryo-EM have elegantly demonstrated the existence of distinct conformers of assembled tau in different tauopathies [
9,
10]. That work has demonstrated that, despite the presence of both 3 and 4 repeat isoforms, the tau filament structures in CTE are distinct from those of AD, as well as from the 3 repeat isoform containing tau aggregates of Pick disease. Even though similarly to AD, all six tau isoforms assemble into filaments in CTE, a conformation of the β-helix region creates a hydrophobic cavity that is absent in tau filaments in AD. Moreover, filaments in CTE have distinct protofilament interfaces to those of AD [
10] The distinct conformations of tau filaments in different tauopathies may not only explain the phenotypic and neuropathologic diversity of these disorders but also underlie the differential affinity of PET ligands, like [
18F]-AV-1451, for tau aggregates in AD and non-AD tauopathies. This may, in part, reflect the process by which this compound was identified as potential tau imaging agents screening using cortical homogenates from AD brain tissue rich in NFT as the binding target. A potential limitation of the current study is the lack of females in the CTE group.
Competing interests
Marta Marquié received research funding from NIH grant AG005134 and AG036694. Marta Marquié currently works at Fundació ACE Institut Català de Neurociències Aplicades – Universitat Internacional de Catalunya in Barcelona, Spain.
Cinthya Agüero received research funding from NIH grant AG036694 and AG061206.
Ana C. Amaral received research funding from NIH grant AG036694 and AG061206. Alberto Villarejo-Galende received research funding from the Instituto de Salud Carlos III (BA17/00035).
Prianca Ramanan received research funding from NIH grant AG036694 and AG061206. Michael Siao Tick Chong received research funding from NIH grant AG036694.
Eline Verwer received research funding from the Society of Nuclear Medicine and Molecular Imaging Education and Research Foundation.
Sally Ji Who Kim received research funding from NIH grant T32 EB013180.
Keith A. Johnson received research funding from NIH grants R01 EB014894, R21 AG038994, R01 AG026484, R01 AG034556, P50 AG00513421, U19 AG10483, P01 AG036694, R13 AG042201174210, R01 AG027435 and R01 AG037497 and the Alzheimer’s Association grant ZEN-10-174210 K.
Ann C. McKee received research funding from NIH grants R01 AG062348, RO1 AG057902, P30-AG13846, U01 NS086659, and the Nick and Lynn Buoniconti Foundation, Andlinger Foundation, National Football League and WWE.
Matthew P. Frosch received research funding from NIH grants AG005134 and AG061206. Teresa Gómez-Isla received research funding from NIH grants AG005134, AG036694 and AG061206. Teresa Gómez-Isla participated as speaker in an Eli Lilly and Company sponsored educational symposium and serves in an Eli Lilly Data Monitoring Committee. Eli Lilly and Company currently owns Avid, the company that created AV-1451.
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.