Alzheimer's Disease

disease · SciDEX wiki

Introduction

Alzheimer’S Disease is a progressive neurodegenerative disorder characterized by the gradual loss of neuronal function 1The Epidemiology of Alzheimer's Disease Modifiable Risk Factors and Prevention.2021 · J Prev Alzheimers Dis · DOI 10.14283/jpad.2021.15 · PMID 34101789Open reference. This page provides comprehensive information about the disease, including its pathophysiology, clinical presentation, diagnosis, and current therapeutic approaches 2Comprehensive Review on Alzheimer's Disease: Causes and Treatment.2020 · Molecules · DOI 10.3390/molecules25245789 · PMID 33302541Open reference.

Overview

Alzheimer’s disease (AD) is the most common cause of dementia, characterized by progressive cognitive decline, memory loss, and behavioral changes 3Cholinesterase inhibitors and memantine for the treatment of Alzheimer and non-Alzheimer dementias.2021 · Ideggyogy Sz · DOI 10.18071/isz.74.0379 · PMID 34856086Open reference. It is a neurodegenerative disorder that primarily affects older adults, with prevalence doubling every 5 years after age 65. Approximately 6.5 million Americans aged 65 and older live with AD, making it a major public health challenge worldwide.

Pathology

The Hippocampal Neurogenesis pathway is impaired in AD, contributing to memory deficits. Adult hippocampal neurogenesis declines with age and is further reduced in Alzheimer’s Disease due to amyloid toxicity, neuroinflammation, and reduced neurotrophic support.

Cerebral Amyloid Angiopathy pathway involvement is common in AD, with Aβ deposition in cerebral blood vessels contributing to hemorrhagic strokes and impaired vascular clearance of amyloid.

The Wnt/β-Catenin Signaling pathway plays a critical role in synaptic plasticity and neuroprotection; its dysregulation contributes to amyloidogenesis and tau pathology.

Histone Modification pathways are altered in AD, with global histone acetylation changes affecting gene expression patterns related to memory and neuronal survival.

Key Hallmarks

  • Amyloid-beta plaques: Extracellular deposits of Aβ peptides (Aβ40, Aβ42)

  • Neurofibrillary tangles: Intracellular tau protein aggregates (paired helical filaments)

  • Neuronal loss: Progressive death of synapses and neurons, particularly in hippocampus and cortex

  • Neuroinflammation: chronic activation of microglia and astrocytes; the NF-κB Signaling pathway regulates this response

  • Synaptic dysfunction: Early loss of synaptic markers and function

MAPT Mutations and Tauopathy

The MAPT V337M mutation provides insight into tau pathophysiology. Multi-omic analysis of iPSC-derived neurons with this mutation revealed perturbations in axonogenesis pathways and unexpected decreases in tau phosphorylation compared to wild-type neurons, highlighting the complex relationship between tau mutations and downstream molecular changes.

Amyloid Cascade Hypothesis

The amyloid cascade hypothesis proposes that Aβ accumulation is the primary driver of AD pathogenesis:

  1. Amyloid precursor protein (APP) processing produces Aβ peptides via β- and γ-secretases

  2. Aβ oligomerization and plaque formation (soluble oligomers are more toxic than plaques)

  3. Synaptic dysfunction and neuronal toxicity through multiple mechanisms

  4. Neurofibrillary tangle formation secondary to neuronal stress

  5. Progressive neurodegeneration and cognitive decline

flowchart TD
    subgraph Genetics ["Genetic and Environmental Triggers"]
        G1["APP Mutations<br/>(Chromosome 21)"]
        G2["PSEN1/PSEN2<br/>Mutations"]
        G3["APOE epsilon4<br/>Risk Allele"]
        G4["Aging, Head Trauma,<br/>Cardiovascular Risk"]
    end

    subgraph Amyloid ["Amyloid Pathway"]
        APP["APP Processing<br/>(beta- and gamma-secretase)"]
        AB["Abeta42 Production<br/>and Accumulation"]
        OL["Soluble Abeta<br/>Oligomers"]
        PL["Amyloid Plaques"]
    end

    subgraph Downstream ["Downstream Cascades"]
        T["Tau Hyperphosphorylation<br/>-> Neurofibrillary Tangles"]
        N["Neuroinflammation<br/>(Microglia, Astrocytes)"]
        S["Synaptic Dysfunction<br/>and Loss"]
        M["Mitochondrial<br/>Dysfunction and ROS"]
    end

    subgraph Clinical ["Clinical Progression"]
        PRE["Preclinical<br/>(biomarker +, no symptoms)"]
        MCI["MCI due to AD<br/>(mild cognitive changes)"]
        MILD["Mild AD<br/>(functional impairment)"]
        MOD["Moderate -> Severe AD<br/>(progressive decline)"]
    end

    G1 --> APP
    G2 --> APP
    G3 --> AB
    G4 --> AB
    APP --> AB
    AB --> OL
    AB --> PL
    OL --> S
    OL --> T
    OL --> N
    OL --> M
    T --> S
    N --> M
    M --> S
    S --> PRE
    PRE --> MCI
    MCI --> MILD
    MILD --> MOD

    click G1 "/genes/app" "APP Gene"
    click G2 "/genes/psen1" "PSEN1"
    click G3 "/genes/apoe" "APOE"
    click APP "/mechanisms/app-processing" "APP Processing"
    click AB "/mechanisms/amyloid-aggregation" "Amyloid Aggregation"
    click PL "/mechanisms/amyloid-plaques" "Amyloid Plaques"
    click T "/mechanisms/tau-pathology" "Tau Pathology"
    click N "/mechanisms/neuroinflammation-ad" "Neuroinflammation in AD"
    click S "/mechanisms/synaptic-loss-ad" "Synaptic Loss in AD"
    click M "/mechanisms/mitochondrial-dysfunction" "Mitochondrial Dysfunction"

    style Genetics fill:#0a1929,stroke:#333,color:#e0e0e0
    style Amyloid fill:#3e2200,stroke:#333,color:#e0e0e0
    style Downstream fill:#3b1114,stroke:#333,color:#e0e0e0
    style Clinical fill:#0e2e10,stroke:#333,color:#e0e0e0

Figure: Amyloid cascade hypothesis — from genetic and environmental triggers through Abeta accumulation and downstream cascades to clinical disease progression.

Key AD Biomarkers

Biomarker Sample Change in AD Earliest Detection Clinical Use
Aβ42/40 ratio CSF ↓ Decreased 15–20 years before symptoms AT(N) classification
p-tau181 CSF / Plasma ↑ Increased 10–15 years before symptoms Tau pathology staging
p-tau217 Plasma ↑ Increased 10–15 years before symptoms Screening (high accuracy)
Total tau CSF ↑ Increased 5–10 years before symptoms Neurodegeneration marker
NfL CSF / Plasma ↑ Increased 5–10 years before symptoms Neurodegeneration severity
GFAP Plasma ↑ Increased 10+ years before symptoms Astrocyte reactivity
Amyloid PET Brain imaging Positive 15–20 years before symptoms Amyloid plaque burden
Tau PET Brain imaging Positive 5–10 years before symptoms Tangle distribution (Braak)

Tau Pathology

  • Hyperphosphorylated tau (p-tau) forms neurofibrillary tangles

  • Tau spreads along neural circuits in a predictable pattern

  • Braak staging: I-VI based on tangle distribution

  • Tau PET imaging allows visualization of tangle burden

Other Pathological Features

  • Cerebral amyloid angiopathy (CAA): Aβ in blood vessel walls; S1P Signaling pathway regulates oligodendrocyte function and white matter integrity

  • Granulovacuolar degeneration

  • Senile plaques with neuritic cores

  • Oxidative stress and mitochondrial dysfunction

Genetics

Causal Mutations (Early-Onset AD)

  • APP (Chromosome 21): Swedish mutation (KM670/671NL), London mutation (V717I)

  • PSEN1 (Chromosome 14): Over 200 mutations identified, most common cause of familial AD

  • PSEN2 (Chromosome 1): Less common than PSEN1, later onset

Risk Genes (Late-Onset AD)

  • APOE: ε4 allele increases risk (3-4x for heterozygotes, 10-15x for homozygotes); ε2 is protective; see APOE4

  • HSP90AB1: Heat shock protein 90 beta, involved in protein folding and tau metabolism

  • CERS2: Ceramide synthase 2, involved in sphingolipid metabolism and neuronal survival

  • DDX55: DEAD-box helicase 55, RNA helicase involved in RNA processing and stress response

  • BMF: Bcl-2 modifying factor, pro-apoptotic BH3-only protein involved in neuronal apoptosisive

  • TREM2: R47H variant increases risk ~3x (microglial function)

  • CLU: Clusterin variant modestly increases risk

  • PICALM: Involved in endocytosis

  • BIN1: Bridging integrator 1, tau pathology

  • LILRB2/LILRB5: Immunoglobulin-like transcript receptor variants associated with AD risk in East Asian populations (PMID 41700061)

  • APOE lipid metabolism: Genetic variants affecting lipid metabolism interact with APOE to modify AD risk

Protective Variants

  • APP A673T: Reduces amyloid processing, protects against cognitive decline

  • APOE ε2: Associated with longevity and reduced AD risk

Cellular Models and Genetic Risk

Cellular models derived from patient stem cells and genetic studies have advanced understanding of Alzheimer’s Disease pathogenesis:

  • Down Syndrome Neurons: Individuals with trisomy 21 develop Alzheimer-like neuropathology by age 40-60 due to APP overexpression from the extra chromosome. iPSC-derived neurons from Down syndrome patients provide insight into amyloid-driven neurodegeneration.

  • Calretinin Neurons (Alzheimer’s Disease): These interneurons are relatively preserved in early AD but show dysfunction as disease progresses, providing a model for studying inhibitory neuron vulnerability.

Risk Factors

Non-Modifiable

  • Age (greatest risk factor - doubles every 5 years after 65)

  • Family history (2-4x increased risk with first-degree relative)

  • Genetic predisposition (APOE ε4, mentioned above)

  • Female sex (higher prevalence, possibly due to longevity); Estrogen Signaling may provide neuroprotective effects

  • Down syndrome (trisomy 21 - extra APP copy)

Potentially Modifiable

  • Cardiovascular health (hypertension, diabetes, hypercholesterolemia)

  • Physical activity (regular exercise reduces risk 28-45%)

  • Cognitive reserve (education, mental stimulation)

  • Social engagement (maintains brain connectivity)

  • Sleep quality (glymphatic clearance of Aβ); GDNF Signaling supports neuronal survival

  • Traumatic brain injury (repetitive concussions increase risk)

  • Smoking (increases risk 1.5-2x)

  • Moderate alcohol consumption (may be protective)

  • Diet (Mediterranean or MIND diet)

  • Plasmalogen deficiency: Emerging research links reduced plasmalogen levels (membrane phospholipids) to increased AD risk; APOE4 carriers show particularly pronounced plasmalogen deficiency (PMID 41768790)

Clinical Features

Disease Progression

Alzheimer’s disease typically progresses through several distinct stages, from preclinical to severe dementia:

timeline
    title Alzheimer's Disease Progression Timeline
    section Preclinical Stage
        No obvious symptoms : 10-20 years
        Biomarker changes begin : Abeta accumulation
        Brain atrophy starts : Hippocampal shrinkage
    section Mild Cognitive Impairment (MCI)
        Memory lapses : Word-finding difficulties
        Mood changes : Anxiety, depression
        Mild functional impairment : Managing finances
    section Mild Dementia
        Memory loss : Recent events difficult to recall
        Personality changes : Apathy, irritability
        Need assistance : Complex tasks difficult
    section Moderate Dementia
        Significant confusion : Disorientation to time/place
        Behavioral symptoms : Wandering, agitation
        Help with daily activities : Dressing, bathing
    section Severe Dementia
        Loss of communication : Verbal abilities decline
        Total care needed : Feeding, mobility
        Terminal stage : Death from complications

Cognitive Symptoms

  • Memory loss (especially episodic memory - recent events)

  • Word-finding difficulties (anomia)

  • Disorientation to time and place

  • Impaired judgment and decision-making

  • Executive dysfunction (planning, organization)

  • Visuospatial difficulties (getting lost)

  • Agnosia (failure to recognize objects)

Behavioral and Psychological Symptoms

  • Apathy (most common)

  • Depression and anxiety

  • Agitation and aggression

  • Sleep disturbances (sundowning)

  • Psychosis (delusions, hallucinations)

  • Disinhibition

  • Eating disturbances

Stages

  • Preclinical: Biomarker changes, no symptoms

  • MCI due to AD: Mild cognitive changes, preserved daily function

  • Mild AD: Difficulty with complex tasks, mood changes

  • Moderate AD: Needs assistance, behavioral changes

  • Severe AD: Loss of verbal ability, mobility decline

Diagnosis

Clinical Assessment

  • Comprehensive neuropsychological testing

  • Mini-Mental State Examination (MMSE): 30-point scale

  • Clinical Dementia Rating (CDR): 0-3 scale

  • Montreal Cognitive Assessment (MoCA): Sensitive to MCI

Biomarkers

Cerebrospinal Fluid (CSF)

  • Reduced Aβ42 (reflects plaque formation)

  • Elevated total tau (t-tau)

  • Elevated phosphorylated tau (p-tau)

  • Neurofilament light chain (NfL) - neuronal damage

Blood Biomarkers

  • Neurofilament light chain (NfL)

  • Phosphorylated tau (p-tau181, p-tau217)

  • Glial fibrillary acidic protein (GFAP)

  • Aβ42/40 ratio

Neuroimaging

  • MRI: Hippocampal atrophy, cortical thinning

  • PET amyloid: Florbetapir, florbetaben

  • PET tau: Flortaucipir

  • FDG-PET: Hypometabolism in posterior cingulate

Neuropathology

  • Braak stage for tau

  • Thal phase for amyloid

  • CERAD plaque score

  • ABC score for AD neuropathologic change

Treatment

Approved Medications

Cholinesterase Inhibitors

  • Donepezil (Aricept): Mild to moderate AD

  • Rivastigmine (Exelon): Mild to moderate AD

  • Galantamine (Razadyne): Mild to moderate AD

NMDA Receptor Antagonist

  • Memantine (Namenda): Moderate to severe AD

Disease-Modifying Therapies

  • Aducanumab (Aduhelm): Anti-Aβ monoclonal antibody, removes amyloid plaques

  • Lecanemab (Leqembi): Anti-Aβ protofibrils, slower cognitive decline

  • Donanemab (Kisunla): Anti-Aβ plaque, removes tau pathology

Anti-Tau Therapeutics

Anti-tau therapeutics represent the next generation of disease-modifying treatments for Alzheimer’s disease, targeting the tau pathology that closely correlates with cognitive decline. Key approaches include monoclonal antibodies, antisense oligonucleotides, and small-molecule inhibitors.

Anti-Tau Antibodies (Passive Immunotherapy)

Drug Company Target Status
E2814 (Etalanetug) Eisai MTBR (p-tau396/404) Phase III
Bepranemab UCB aa 235-250 Phase II
JNJ-63733657 Janssen p-tau217 Phase II
Posdinemab Bristol Myers Squibb Mid-domain Phase II
Semorinemab Roche N-terminus Phase II
PRX005 Prothena MTBR Phase I
Gosuranemab Biogen N-terminal Discontinued (Phase II)
Tilavonemab AbbVie N-terminal Discontinued (Phase II)
Zagotenemab Eli Lilly MC1 epitope Discontinued (Phase II)

Tau Gene Therapy (ASOs)

Drug Company Mechanism Status
BIIB080 (MAPTRx) Biogen/Ionis MAPT mRNA knockdown Phase II
NIO752 Roche MAPT mRNA knockdown Phase I

Tau Small-Molecule Inhibitors

Drug Company Mechanism Status
LY3372689 (Oglemilide) Eli Lilly OGA inhibitor Phase II
ASN90 Asceneuron OGA inhibitor Phase II
LMTM (TRx0237) TauRx Aggregation inhibitor Phase III

Tau Vaccines (Active Immunization)

Drug Company Target Status
AADvac1 Axon Neuroscience Phosphorylated tau Phase II
ACI-35 AC Immune p-tau396/404 Phase Ib/IIa

Key Insights

  • MTBR-targeting antibodies showing promise: E2814, Bepranemab, and PRX005 target the microtubule-binding region where tau forms pathological aggregates

  • N-terminal antibodies failed: Gosuranemab, Tilavonemab, and Zagotenemab failed in Phase II trials, suggesting N-terminal tau is not an optimal target

  • ASO approach validated: BIIB080 demonstrated 50-60% CSF tau reduction in Phase I/II

  • OGA inhibitors emerging: LY3372689 and ASN90 represent novel small-molecule approaches targeting tau O-GlcNAcylation

See Anti-Tau Therapeutics for detailed rankings and clinical trial data.

Symptomatic Treatments

  • Behavioral interventions

  • Sleep hygiene

  • Caregiver support

  • Occupational therapy

Investigational Therapies

  • Anti-tau antibodies

  • BACE inhibitors (failed due to side effects)

  • Immunotherapies targeting different Aβ epitopes

  • Gene therapy approaches

  • Neuroprotective agents

Brain-Computer Interface (BCI) Therapy

Brain-computer interfaces represent an emerging therapeutic approach for Alzheimer’s disease, focusing on cognitive enhancement, memory restoration, and monitoring disease progression.

Current Applications

  • Memory Prosthetic BCI: Experimental systems designed to restore memory function

  • EEG-Based Cognitive Monitoring: Non-invasive EEG systems for cognitive monitoring

  • Neurofeedback Training: BCI therapy for cognitive training

Clinical Evidence

  • Preliminary studies show non-invasive BCI training can improve cognitive function in MCI and early AD

  • Memory prosthetic research demonstrates proof-of-concept for hippocampal stimulation

  • Closed-loop neuromodulation systems being developed for dynamic response to neural activity

Emerging Technologies

  • Neuralink: Invasive BCI in clinical trials

  • fNIRS-BCI: Functional near-infrared spectroscopy for cognitive assessment

  • Kernel Flow: Non-invasive neuroimaging for cognitive studies

  • Closed-Loop Neuromodulation: Adaptive stimulation systems

Company Pipeline

For a comprehensive list of companies developing AD therapeutics, see AD Pipeline Companies. Key companies include:

  • Biogen: Leqembi (approved), Aducanumab

  • Eli Lilly: Donanemab (Kisunla), Remternetug

  • Eisai: Leqembi (partnered with Biogen)

  • Roche: Gantenerumab, Crenezumab

  • AC Immune: Tau vaccines, ACI-35

  • Prothena: Tau antibodies, PRX003

  • Vaxxinity: UB-311 vaccine

  • Acumen Pharmaceuticals: AC-1934 (Tau oligomer inhibitor)

  • INmune Bio: XPro1595 (TNF-alpha inhibitor)

  • Annovis Bio: Buntanetap

  • Athira Pharma: ATH-1017 (HGF/MET activator)

  • Alector: TREM2 agonists

  • Anavex Life Sciences: ANAVEX2-73

  • Ionis Pharmaceuticals: IONIS-MAPT (antisense tau)

  • Cassava Sciences: Simufilam

  • Pinteon: PNT001 (Tau antibody)

Clinical Trials

Anti-Amyloid Immunotherapies (Phase 3)

Anti-Tau Therapies (Phase 2/3)

TREM2 & Neuroinflammation Targeting

Neuroprotection & Disease Modification (Phase 2/3)

Challenges in AD Clinical Trials

Challenges

  • Late-stage intervention may be too late

  • Biomarker enrollment criteria

  • Heterogeneity of AD

  • Comorbidities in elderly populations

  • Need for combination therapy approaches

Research Directions

Emerging Concepts

  • Amyloid-tau interaction hypothesis

  • Synaptic plasticity dysfunction

  • Microglial biology (TREM2, DAM)

  • Network dysfunction

  • Resilience and cognitive reserve

Biomarker Development

  • Blood-based diagnostics

  • Digital biomarkers

  • Multi-modal biomarker panels

  • Precision medicine approaches

Prevention Trials

  • DIAN-TU: Familial AD prevention

  • A4: Preclinical AD prevention

  • FINGER: Lifestyle intervention

Prognosis

  • Average survival: 4-8 years after diagnosis (up to 20 years)

  • Progression rate varies

  • Leading cause of death: 6th in US

  • Quality of life impact for patients and caregivers

See Also

Background

The study of Alzheimer’S Disease has evolved significantly over the past decades. Research in this area has revealed important insights into the underlying mechanisms of neurodegeneration and continues to drive therapeutic development.

Historical context and key discoveries in this field have shaped our current understanding and will continue to guide future research directions.

See Also (1)

Open Questions in Alzheimer’s Disease Research

Despite significant advances in understanding Alzheimer’s Disease (AD) pathogenesis, several fundamental questions remain unresolved. These knowledge gaps represent active areas of investigation and opportunity for future research.

Disease Initiation and Biomolecular Mechanisms

  • What is the precise sequence of events in preclinical AD?: While amyloid-beta accumulation is thought to initiate the disease process, the exact sequence of cellular events leading from normal aging to clinically manifest dementia remains incompletely characterized. Understanding the temporal relationship between amyloid, tau, synaptic loss, and neurodegeneration is critical for timing therapeutic interventions.

  • Why do some individuals with amyloid plaques never develop dementia?: Population studies reveal a significant subset of individuals with neuropathological AD hallmarks who maintain normal cognitive function. The biological mechanisms underlying this resilience—termed cognitive reserve—require further investigation to inform protective strategies.

  • What drives the selective vulnerability of specific neuronal populations?: Certain brain regions (hippocampus, entorhinal cortex, basal forebrain) show early and severe neurodegeneration in AD, while others are relatively preserved. The molecular basis for this selective vulnerability is not fully understood.

Diagnostic and Prognostic Biomarkers

  • Can blood biomarkers reliably detect preclinical AD?: While plasma p-tau217 and other blood-based biomarkers show promise, standardization across platforms and validation in diverse populations remains incomplete. The field needs accessible, inexpensive biomarkers for population screening.

  • What biomarker combinations best predict progression?: Individual biomarkers provide limited prognostic information. Developing composite biomarker panels that accurately predict conversion from mild cognitive impairment to AD dementia would improve clinical trial design and patient counseling.

Therapeutic Challenges

  • Why do amyloid-targeting therapies show limited clinical benefit?: Despite successful amyloid clearance, clinical trials have shown modest effects on cognitive decline. This suggests that amyloid reduction alone may be insufficient, or that treatment is initiated too late in the disease process. Understanding the relationship between amyloid removal and downstream tau pathology is crucial.

  • How can we effectively target tau pathology?: Tau aggregation correlates more strongly with cognitive decline than amyloid, yet tau-targeted therapies have proven challenging. Developing effective tau-modifying treatments requires better understanding of tau propagation mechanisms and optimal treatment windows.

  • What is the role of neuroinflammation in AD progression?: Microglial activation is a hallmark of AD, but whether it represents a protective or deleterious response remains contested. Clarifying the causal role of neuroinflammation could open new therapeutic avenues.

Emerging Therapeutics and Precision Medicine (2025-2026)

  • What are the real-world outcomes of amyloid-targeting antibodies?: Lecanemab and donanemab have received regulatory approval, but real-world effectiveness data across diverse populations remains limited. Understanding long-term outcomes, optimal treatment duration, and combination strategies is critical for clinical implementation.

  • Can combination therapy approaches improve outcomes over monotherapy?: Given the modest effects of amyloid clearance alone, combining anti-amyloid with anti-tau, anti-inflammatory, or synaptic protective approaches may yield greater clinical benefit. What are the optimal sequencing and combinatorial strategies?

  • How can biomarker-defined subtypes guide personalized treatment?: Emerging data suggests different therapeutic responses based on biomarker profiles (e.g., tau burden, APOE status). How should treatment selection be personalized based on molecular subtype?

  • What is the therapeutic potential of TREM2 modulators?: TREM2 variants strongly influence AD risk, and TREM2-activating antibodies are in development. What is the optimal timing and patient selection for TREM2-targeted therapy?

  • How do we address tau pathology beyond antibody approaches?: Small molecule tau aggregation inhibitors, antisense oligonucleotides, and gene therapy approaches are in development. Which modality offers the best balance of brain penetration, efficacy, and safety?

Prevention and Risk Modification

  • Which lifestyle interventions provide meaningful risk reduction?: Epidemiological studies suggest that cognitive reserve, physical activity, and cardiovascular health modifiers may reduce AD risk. However, the magnitude of effect and mechanisms underlying these associations require validation in rigorous clinical trials.

  • How should AD risk be communicated and acted upon?: Developing effective strategies for risk communication and behavioral modification could enable primary prevention approaches before neurodegenerative processes become established.

  • Combination Biomarker Panels for Alzheimer’s Disease## Recent Research

2025-2026 Findings

  • Alpha-7 Nicotinic Acetylcholine Receptor Neuroprotection: Research has demonstrated that sinomenine attenuates AD pathology through alpha7 nAChR-mediated neuroprotection, inhibiting oxidative stress and Abeta-induced neuronal damage. This adds to the growing evidence for alpha7 nAChR as a therapeutic target in AD.

  • Novel Blood-Based Proteomic Signatures: Durcan R et al. (2025) evaluated multiplex proteomic methods for detecting Alzheimer’s, Lewy body, and frontotemporal dementia biomarkers. This approach offers less invasive diagnostic options compared to cerebrospinal fluid analysis

    .

  • Metal Ions in Neurodegeneration: Chen L et al. (2025) reviewed the involvement of iron, manganese, copper, and zinc in AD pathogenesis, highlighting potential therapeutic targets for metal homeostasis modulation

    .

  • Mendelian Randomization Study: Belbasis L et al. (2025) identified novel protein associations with AD using genetic data, providing insights into disease mechanisms and potential biomarkers

    .

  • Global Neurodegeneration Proteomics Consortium: Imam F et al. (2025) conducted large-scale biomarker and drug target discovery across neurodegenerative diseases through collaborative proteomics

    .

: Durcan R et al. Multiplex proteomic methods in neurodegenerative dementias. Alzheimer’s & Dementia. 2025;21(3):e70116. https://pubmed.ncbi.nlm.nih.gov/40145305/

: Chen L et al. Metal ions in neurodegenerative diseases. Signal Transduction and Targeted Therapy. 2025;10(1):31. https://pubmed.ncbi.nlm.nih.gov/39894843/

: Belbasis L et al. Mendelian randomization identifies proteins related to neurodegenerative diseases. Brain. 2025;148(7):2412-2428. https://pubmed.ncbi.nlm.nih.gov/40037332/

: Imam F et al. Global Neurodegeneration Proteomics Consortium. Nature Medicine. 2025;31(8):2556-2566. https://pubmed.ncbi.nlm.nih.gov/40665048/

  • Ginsenosides Neuroprotective Effects: Jiang M et al. (2025) reviewed the neuroprotective effects of ginsenosides Rg1, Rb1 and rare ginsenosides as promising candidate agents for both Parkinson’s disease and Alzheimer’s disease, providing insights into network pharmacology and potential therapeutic applications

    .

  • Vitamin D and Neurodegeneration: Savran Z et al. (2025) reviewed the role of vitamin D in the etiopathogenesis of neurodegenerative diseases including multiple sclerosis, Parkinson’s disease, Alzheimer’s disease, and amyotrophic lateral sclerosis, highlighting its potential as a modifiable risk factor

    .

  • Diabetes and Neurodegeneration: Szablewski L (2025) reviewed the associations between diabetes mellitus as a major risk factor for cognitive decline, dementia, Parkinson’s disease, and Alzheimer’s disease, highlighting the importance of metabolic health in neurodegeneration

    .

: Jiang M et al. Ginsenosides Rg1, Rb1 and rare ginsenosides: Promising candidate agents for Parkinson’s disease and Alzheimer’s disease. Pharmacol Res. 2025 Feb;212:107578. https://pubmed.ncbi.nlm.nih.gov/39756554/

: Savran Z et al. Vitamin D and Neurodegenerative Diseases. Curr Nutr Rep. 2025 Jun;14(1):77. https://pubmed.ncbi.nlm.nih.gov/40464816/

: Szablewski L. Associations Between Diabetes Mellitus and Neurodegenerative Diseases. Int J Mol Sci. 2025 Jan;26(2):542. https://pubmed.ncbi.nlm.nih.gov/39859258/

Additional Recent Findings (March 2026)

Emerging Research (Late March 2026)

: Sadleir KR et al. Neuronal overexpression of Nrf2 reduces dystrophic neurites in 5XFAD Alzheimer’s disease model mice. bioRxiv. 2026. doi:10.64898/2026.03.16.711596

: Lemon NL et al. Mitochondrial Carbonic Anhydrase-VB inhibition rescues brain endothelial stress and memory in Alzheimer’s disease models. bioRxiv. 2026. doi:10.64898/2026.03.16.711716

: Barbour AJ et al. Seizures drive tau propagation in a tauopathy mouse model. bioRxiv. 2026. doi:10.64898/2026.03.14.711088

: Ruff DA et al. Loss of neuronal population organization links pathology to behavior in a model of Alzheimer’s disease. bioRxiv. 2026. doi:10.64898/2026.03.18.712735

Digital Therapeutics and Emerging Treatments

Digital therapeutics represent an emerging frontier in Alzheimer’s and Parkinson’s disease management. A comprehensive 2026 review examined current trends and future perspectives for digital interventions in neurodegeneration, including cognitive training apps, wearable monitoring devices, and AI-powered diagnostic tools

.

: Jeong YJ et al. Digital Therapeutics for Alzheimer’s and Parkinson’s Diseases. JAD (2026)

Biomarker Advances (2026)

A comprehensive 2026 review analyzed current and potential biomarkers for Alzheimer’s disease, Parkinson’s disease, and ALS. Key findings include:

Recent Research (March 2026)

Recent advances in Alzheimer’s disease research include:

Immune Dysfunction

Microglia and TREM2

Therapeutic Approaches

Common Mechanisms

Recent Research Findings (2026)

Recent publications have advanced our understanding of Alzheimer’s disease mechanisms and therapeutic approaches:

Biomarkers and Early Detection

The European Federation of Clinical Chemistry and Laboratory Medicine (EFLM) has published guidance on harmonizing Alzheimer’s disease biomarker practices, addressing variability in fluid biomarker measurements across laboratories

.

Sleep and Dementia Risk

The COSMIC collaboration study found that disturbing dreams (nightmares) are associated with increased dementia incidence in adults aged 60-89, suggesting sleep disturbances as a potential early marker of neurodegeneration

.

Exercise and Tau Pathology

Research has demonstrated that physical exercise provides cognitive benefits through the adiponectin-PP2A pathway, which protects against chronic stress-induced tau hyperphosphorylation in the hippocampus. This mechanism provides molecular justification for exercise interventions in AD prevention

.

Vascular Contributions to Pathology

Chronic cerebral hypoperfusion has been shown to exacerbate amyloid and tau pathology by impairing glymphatic transport through AQP4- and VEGF-mediated pathways, highlighting the importance of vascular health in AD progression

.

Advanced Imaging Tracers

New PET tracer methods using [(125)I]IPPI and [(125)I]IBETA autoradiography have been validated for detecting tau protein and amyloid plaques in postmortem human brains of Down Syndrome and Alzheimer’s disease patients[^19].

References

  1. The Epidemiology of Alzheimer's Disease Modifiable Risk Factors and Prevention. 2021 · J Prev Alzheimers Dis · DOI 10.14283/jpad.2021.15 · PMID 34101789
  2. Comprehensive Review on Alzheimer's Disease: Causes and Treatment. 2020 · Molecules · DOI 10.3390/molecules25245789 · PMID 33302541
  3. Cholinesterase inhibitors and memantine for the treatment of Alzheimer and non-Alzheimer dementias. 2021 · Ideggyogy Sz · DOI 10.18071/isz.74.0379 · PMID 34856086

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