NF-κB Pathway and Its Inhibitors: A Promising Frontier in the Management of Alzheimer’s Disease

The nuclear factor kappa B (NF-κB) pathway has emerged as a pivotal player in the pathogenesis of various diseases, including neurodegenerative illnesses like Alzheimer’s disease (AD). The involvement of the NF-κB pathway in immune system responses, inflammation, oxidative stress, and neuronal survival highlights its significance in AD progression. We discuss the advantages of NF-κB pathway inhibition, including the potential to mitigate neuroinflammation, modulate amyloid beta (Aβ) production, and promote neuronal survival. However, we also acknowledge the limitations and challenges associated with this approach. Balancing the fine line between dampening inflammation and preserving physiological immune responses is critical to avoid unintended consequences. This review combines current knowledge on the NF-κB pathway’s intricate involvement in AD pathogenesis, emphasizing its potential as a therapeutic target. By evaluating both advantages and limitations, we provide a holistic view of the feasibility and challenges of NF-κB pathway modulation in AD treatment. As the quest for effective AD therapies continues, an in-depth understanding of the NF-κB pathway’s multifaceted roles will guide the development of targeted interventions with the potential to improve AD management.


Introduction
Alzheimer's disease (AD), a neurodegenerative disease, is the most common type of dementia, responsible for up to 75% of all cases [1].It manifests as a clinical syndrome presenting symptoms like impairment of memory, language, and other cognitive functions, and behavioral changes that severely affect the activities of daily living.The worldwide prevalence of dementia is thought to be around 3.9%, which is estimated to escalate with the growing size of the population aged 65 years and older.The fundamental histopathological feature of AD has been considered to be aggregates of amyloid beta (Aβ) plaques in the cortical and limbic regions of the brain [2].Despite offering a comprehensive framework for understanding AD pathogenesis, certain observations do not seamlessly align with the most straightforward rendition of the hypothesis, leading to its existing lack of intricate explanations [3][4][5].It is noteworthy that, intriguingly, no treatment closely tied to the proposed amyloid hypothesis has achieved success thus far.Thus, ineffective attempts to manage the progressive symptoms have compelled new insights into pathogenesis.
treatment closely tied to the proposed amyloid hypothesis has achieved success thus far.Thus, ineffective attempts to manage the progressive symptoms have compelled new insights into pathogenesis.Post-translational modifications (PTMs) are pivotal in AD as they influence the aggregation of pathogenic proteins implicated in the disease [6].Aberrant PTMs, such as the hyperphosphorylation of tau protein and Aβ, glycation, nitration, and ubiquitination, contribute to the misfolding and aggregation of these proteins.The phosphorylation of tau disrupts its normal function, leading to neurofibrillary tangles (NFTs).Aβ, through PTMs like glycation and nitration, adopts toxic conformations, forming amyloid plaques.Ubiquitination may impair the clearance of misfolded proteins.These PTMs disrupt protein homeostasis, impair cellular functions, and trigger neuroinflammation.The interplay between PTMs and nuclear factor kappa B (NF-κB)-driven inflammation thus contributes to protein aggregation, neurodegeneration, and AD progression.
The NF-κB family is a group of transcription factors that play a pivotal role in regulating various biological processes, including immune responses, inflammation, cell survival, and cellular differentiation [7].The family encompasses five members.NF-κB1 regulates immune responses and inflammation (Figure 1).Upon proteolytic processing, NF-κB1 generates the active p50 subunit.Similarly, NF-κB2 undergoes proteolytic processing to produce the active p52 subunit, which is involved in immune responses and lymphoid organ development.The p65 subunit aids in functional NF-κB dimer formation and is pivotal in regulating inflammation, immune responses, and cellular survival.The transcription factor, RelB, contributes to NF-κB dimer assembly and is particularly associated with immune responses, especially in lymphoid organ development.The c-Rel subunit modulates immune responses and gene expression related to inflammation and lymphoid organ development.These NF-κB family members form homo-or heterodimers, dictating target gene specificity and ensuing biological impacts [8].
Within neuroinflammation, NF-κB occupies a central role in coordinating the expression of genes that contribute to both protective and detrimental aspects of the inflammatory response in the nervous system.Primarily sequestered in an inactive state within the cytoplasm, NF-κB is bound to inhibitory proteins named IκBs.Upon activation, typically induced by a spectrum of stimuli encompassing pro-inflammatory cytokines, pathogens, or cellular stressors, these IκBs undergo phosphorylation and consequent degradation, facilitating the translocation of NF-κB to the nucleus.This nuclear migration empowers NF-κB to engage specific DNA sequences, thereby orchestrating the modulation of an extensive array of target genes.NF-κB signaling also influences the integrity of the blood-brain barrier (BBB), governing the passage of molecules between the bloodstream and the brain milieu.The activation of NF-κB in the endothelial cells of the BBB provokes heightened permeability, allowing immune cells and molecules to enter the brain [9].
Further, NF-κB activation in microglia triggers their transition from resting to activated states, releasing pro-inflammatory cytokines, chemokines, and reactive oxygen species (ROS).NF-κB is pivotal for initiating protective immune responses against pathogens and facilitating tissue repair.However, prolonged NF-κB activation within neurons can result in neurotoxicity, contributing to oxidative stress, excitotoxicity, and inflammation, all of which undermine neuronal well-being.NF-κB also influences the balance between neuronal survival and apoptosis.In some cases, NF-κB activation can promote the expression of antiapoptotic genes, supporting neuronal survival [10].However, chronic NF-κB activation can lead to a pro-apoptotic response in other situations.
This review summarizes the role of the NF-κB pathway as a potential target in treating AD, along with the prospects and challenges of its modulation as a therapeutic strategy.Also, the manuscript discusses the interplay between inflammation and neurodegeneration.

Role of NF-κB Pathway Inhibitors in AD Treatment
The NF-κB pathway plays a significant role in neuroinflammation and other processes implicated in AD pathogenesis.Consequently, it has been considered a potential therapeutic target for the management of AD [11].However, targeting the NF-κB pathway is complex due to its multifaceted role in promoting and regulating inflammation and immune responses.NF-κB pathway inhibitors offer the means to modulate this intricate signaling network and counteract neuroinflammation.By inhibiting NF-κB activation, these inhibitors can dampen the excessive release of pro-inflammatory molecules, thereby reducing the harmful impact of inflammation on neurons [12].They hold the potential to alleviate neuronal damage and promote their survival in the face of AD-associated challenges.
Furthermore, NF-κB inhibitors may influence key pathological hallmarks of AD: Aβ plaques and tau tangles.NF-κB activation regulates enzymes involved in Aβ production and clearance [13].Inhibiting this pathway could potentially modify Aβ metabolism, impacting the deposition and accumulation of Aβ plaques.Similarly, NF-κB activation has been linked to tau hyperphosphorylation and tangle formation.Inhibitors might intervene in these processes, attenuating tau pathology and promoting neuronal stability.However, it is essential to tread cautiously in inhibiting NF-κB, as this pathway also plays crucial roles in immune responses and cell survival [14].A complete blockade could compromise the immune system's ability to defend against pathogens and maintain tissue integrity.Striking the right balance between dampening neuroinflammation and preserving necessary immune functions is critical.The direct inhibition of NF-κB activation is a strategy under investigation for its therapeutic potential in various diseases, including AD [15].Directly inhibiting NF-κB activation modulates the aberrant inflammatory response, potentially slowing disease progression.Researchers are exploring small molecules and compounds that directly target components of the NF-κB signaling pathway.These agents can interfere with the activation steps that lead to NF-κB translocation into the nucleus, where it regulates gene expression.
Advancements in NF-κB pathway inhibitor research are multifaceted.Scientists are striving to develop selective inhibitors that target specific pathway components, minimizing off-target effects.A study conducted by Elzayat and colleagues investigates mesenchymal stem cells (MSCs) and acitretin for AD treatment, focusing on the NF-kB pathway and miRNA regulation.Using a rat model, miR-146a, miR-155, necrotic, growth, and inflammatory genes were analyzed.Results showed that MSCs and acitretin restored normal levels, indicating potential therapeutic benefits.MiR-146a and miR-155 are proposed as AD biomarkers.This study underscores MSCs and acitretin's capacity to modulate miRNAs and related genes in the NF-kB pathway, offering insights for future AD interventions [16].
Melatonin, a hormone the pineal gland produces, has been recognized for its role in regulating sleep-wake cycles and its potential anti-inflammatory properties.While melatonin's direct impact on the NF-κB pathway is limited, it has been suggested that melatonin can indirectly modulate NF-κB activation through various mechanisms.Oxidative stress can activate NF-κB, leading to the expression of pro-inflammatory genes.Melatonin's antioxidant properties indirectly inhibit NF-κB activation by reducing the triggering oxidative signals [17].Melatonin can influence molecules downstream of the NF-κB pathway.For instance, it has been reported to downregulate COX-2 (Cyclooxygenase-2) expression, an inflammation enzyme that NF-κB often regulates.Melatonin's neuroprotective effects may indirectly impact NF-κB activation.By preserving neuronal health and reducing neuroinflammation, melatonin can contribute to an environment where NF-κB activation is less pronounced.Merlo et al. demonstrated the counteracting effects of melatonin on the pro-inflammatory properties of lipopolysaccharides in in vitro models [18].Another study investigated a phosphodiesterase 5 inhibitor (PDE5I) with dual antagonistic action on IKKB and TNFR1 to inhibit NF-kB and neuroinflammation.In silico docking with FDA-approved compounds identified avanafil with optimal IKKB and TNFR1 binding.Molecular dynamic studies confirmed avanafil's stability with these targets.In a mouse model of lipopolysaccharide (LPS)-induced neuroinflammation and cognitive decline, avanafil at 6 mg/kg improved cognitive performance, reduced Aβ levels, and lowered inflammatory markers and oxidative parameters [19].
Bay 11-7082 is a synthetic small molecule that has gained attention for its potential as an NF-κB pathway inhibitor.This compound has shown inhibitory effects on IκB kinase (IKK), allowing NF-κB to translocate into the nucleus and initiate the expression of target genes involved in inflammation and immune responses.By inhibiting IKK and IκB degradation, Bay 11-7082 effectively interferes with interleukin-6 (IL-6) secretion and the subsequent activation of NF-κB, leading to decreased pro-inflammatory gene expression [20].For Bay 11-7082 to effectively modulate NF-κB activity within the brain, it must cross the BBB.Developing strategies to enhance its delivery and distribution to the central nervous system while minimizing systemic effects is still a significant challenge [18].Additionally, a low dose of recombinant IL-2 (aldesleukin) is currently under clinical trial for its clinical application in AD (NCT05821153; NCT05468073).
The SN50 analog is a cell-permeable, synthetic peptide derived from the NF-κB nuclear localization sequence, and it holds potential in AD treatment due to its ability to inhibit NF-κB nuclear translocation.A study conducted by Lin and colleagues suggests that the inhibitory effect is not due to disrupting the binding activity of NF-κB complexes but rather its ability to enter the cell and compete with NF-κB complexes for the cellular machinery responsible for nuclear translocation [21,22].A study by Pogue and team reveals that upregulated miRNA-30b, associated with neuropathology in AD brain and LPS-stressed human neuronal-glial cells, targets neurofilament light (NF-L)-chain mRNA's 3 -UTR.This results in the post-transcriptional downregulation of NF-L expression, observed in AD and LPS-treated cells, leading to neuronal cytoskeleton atrophy and synaptic disruption.MiRNA-30b is highly expressed in Aβ-treated models, facilitating LPS entry into neurons.Elevated miRNA-30b induces neuro-injury, inflammation, synaptic impairment, and neuron loss.This gut-microbiota-derived LPS-NF-kB-miRNA-30b-NF-L pathway links GI tract microbes' LPS to AD's neuropathology and synaptic disruption, offering insights into neurodegeneration mechanisms [23].Optimizing dosages to achieve the desired therapeutic outcomes while avoiding potential side effects is an ongoing challenge.Table 1 enlists molecules being researched for their potential role in the NF-κB pathway in AD.In practical terms, combining NF-κB inhibition with other therapeutic approaches may yield enhanced results.Research conducted by Shehata et al. aimed to formulate nanostructured lipid carriers (NLCs) that co-encapsulate donepezil and astaxanthin (DPL/AST-NLCs) and assess their effectiveness in AD-like rat models following daily intranasal administration [41].AD is a complex disease with multiple underlying mechanisms, in-cluding Aβ aggregation, tau pathology, and synaptic dysfunction.Integrating NF-κB inhibitors with interventions targeting these aspects could offer a comprehensive treatment strategy, potentially addressing symptom relief and disease modification.
To translate NF-κB inhibition into clinical practice, robust clinical trials are imperative.These trials should involve diverse patient populations, incorporate appropriate outcome measures, and assess long-term safety.Furthermore, identifying reliable biomarkers that reflect NF-κB activity and its downstream effects will aid in monitoring treatment efficacy and patient response.

Factors Affecting NF-κB Inhibitors-Based AD Treatments
Inhibiting NF-κB in the context of AD presents a formidable scientific challenge due to the intricate and multifaceted nature of the disease and the pivotal role of NF-κB in immune responses and inflammation.NF-κB serves a dual role, exhibiting both pro-inflammatory and anti-inflammatory functions.It plays a crucial part in the innate immune response, essential for pathogen clearance and tissue homeostasis.For instance, NF-κB activation in microglial cells can release pro-inflammatory cytokines, such as TNF-α and IL-1β, contributing to neuroinflammation in AD [42].However, NF-κB also has anti-inflammatory functions by promoting the expression of anti-inflammatory cytokines like IL-10.Thus, the complete inhibition of NF-κB may risk suppressing these protective anti-inflammatory responses, vital for maintaining brain homeostasis [43].
Consequently, attempting to completely inhibit NF-κB raises concerns regarding impaired immune responses, necessitating a delicate balance between mitigating its detrimental effects in AD and preserving its protective capabilities.One instance highlighting this challenge is that a non-specific inhibition of NF-κB could disturb this control mechanism, resulting in unregulated NF-κB activation and consequently harming neurons [44].Furthermore, NF-κB is rigorously controlled through various mechanisms, including inhibitory proteins (IκBs) and post-translational modifications, making precise and specific inhibition challenging.NF-κB operates within diverse cell types in the central nervous system, including neurons and glial cells, with its effects contingent upon cell type, rendering it problematic to target NF-κB without unintentional consequences in various cell populations.In astrocytes, NF-κB can have protective effects by regulating the release of neurotrophic factors.These beneficial effects might be compromised if NF-κB is inhibited without cell type specificity [45].
Additionally, AD is a progressive ailment encompassing distinct stages, and the contribution of NF-κB may evolve throughout the disease course, necessitating the consideration of temporal factors for therapeutic intervention.Furthermore, the limited capacity of numerous potential NF-κB inhibitors to penetrate the blood-brain barrier (BBB) effectively poses a significant challenge, as inhibitors must adequately reach neural tissues to modulate NF-κB activity.The potential for off-target effects, impacting alternate signaling pathways or cellular functions, further complicates NF-κB inhibition.Moreover, AD's heterogeneity, characterized by diverse underlying mechanisms and pathological manifestations, results in NF-κB potentially exerting differential impacts on disease progression among individuals, augmenting the complexity of targeted inhibition.Furthermore, the intricate web of interactions between NF-κB and other signaling pathways, including those associated with amyloid-beta and tau pathology, further complicates the potential outcomes of NF-κB inhibition.Inhibiting NF-κB, for example, may disrupt its interaction with the vital Notch signaling pathway, with potential consequences for neuronal development and function, thereby impacting neuronal health [46].Lastly, the inhibition of NF-κB may trigger adaptive or compensatory cellular responses, potentially leading to the activation of alternative pro-inflammatory pathways, posing additional challenges in achieving effective and durable therapeutic outcomes [47].

Insights and Challenges to Targeting the NF-κB Pathway
In the context of AD, the inhibition of NF-κB holds substantial promise as a therapeutic target.As a central regulator of neuroinflammation, NF-κB inhibition can mitigate the excessive inflammatory responses witnessed in AD brains, potentially alleviating the harmful consequences of chronic inflammation on neuronal health.By influencing Aβ metabolism and accumulation, the engagement of NF-κB establishes the possibility of utilizing its inhibition to regulate Aβ production and clearance [48].This modulation could potentially mitigate Aβ buildup and delay the development of plaques.The intricate role of NF-κB in neuronal survival is noteworthy; it can induce the expression of anti-apoptotic genes, thereby offering potential neuroprotective effects upon inhibition [49].Notably, targeting NF-κB addresses symptomatic manifestations and certain fundamental mechanisms underpinning AD pathogenesis, suggesting a capacity to modify disease progression.Integrating NF-κB inhibitors with other therapeutic strategies aimed at various aspects of AD pathology holds promise for comprehensive treatment effects.The wealth of research on NF-κB inhibitors in diverse disease contexts provides a valuable foundation for AD treatment development.Leveraging this existing knowledge accelerates the translational potential of NF-κB inhibition as a viable strategy for AD.The well-established role of NF-κB in AD pathogenesis solidifies its standing as a rational and scientifically grounded therapeutic target, bolstering the credibility of NF-κB inhibition as a plausible avenue for effective AD treatment.
The exploration of NF-κB as a therapeutic target in AD holds significant promise, but several challenges must be addressed for successful clinical applications.Subsequent research should emphasize formulating strategies for the selective modulation of NF-κB activity within distinct cell types, encompassing neurons, microglia, and astrocytes [50].This precise targeting holds the potential to avert undesired effects while achieving therapeutic objectives.Precisely regulating the extent of NF-κB inhibition stands as a critical imperative.Total abrogation might compromise NF-κB's advantageous contributions to immune responses and cellular survival [51].There is a need to devise methodologies that establish an equilibrium between attenuating neuroinflammation and safeguarding fundamental cellular functions.Given the intricate nature of AD, amalgamating therapies focused on NF-κB with complementary interventions could yield enhanced outcomes [52].
Integrating NF-κB inhibition with strategies addressing amyloid-beta accumulation, tau pathology, or synaptic dysfunction could yield a holistic therapeutic approach.Acknowledging the heterogeneous nature of AD patients and the diverse mechanisms underlying the ailment, prospective treatments could necessitate customization based on individual molecular profiles and disease progression [53,54].Pioneering the development of dependable biomarkers reflecting NF-κB activity and downstream ramifications within the brain could facilitate gauging treatment efficacy and patient responsiveness to NF-κB-targeted interventions.Overcoming the considerable challenge of designing therapeutic agents capable of crossing the BBB to access the central nervous system requires concentrated research on enhancing drug delivery methodologies.Safeguarding the long-term safety of NF-κB-targeted therapies holds paramount importance.Prolonged NF-κB inhibition may engender off-target ramifications, potentially influencing immune responses and broader physiological processes [55].A comprehensive evaluation of safety implications is imperative.Methodical and meticulously designed clinical trials are necessary to systematically assess the effectiveness and safety of NF-κB-targeted therapies.Such trials should incorporate diverse patient cohorts, employ pertinent outcome measures, and delineate well-defined endpoints.The disparate impacts of distinct NF-κB inhibitors on neuroprotection, inflammation, and immune responses necessitate further exploration.A comprehensive investigation is warranted to discern the potential of these inhibitors in addressing specific facets of AD pathogenesis.Beyond alleviating symptomatic manifestations, the trajectory of NF-κB-targeted therapies should encompass the development of interventions capable of arresting or decelerating the inherent progression of the disease, thereby confronting the fundamental causes of AD [42].

Future Directions
The prospects of NF-κB as an AD therapeutic target lie in refining its modulation to culminate in optimal therapeutic consequences.The convergence of advancements in precision medicine, biomarker elucidation, drug delivery modalities, and an enriched comprehension of NF-κB's intricate roles in AD pathogenesis is poised to catalyze the successful transition of this strategy from preclinical research to efficacious clinical treatments.
The future direction of targeting NF-κB inhibition through phytochemicals represents a promising and innovative avenue for AD treatment [56].This approach capitalizes on the potential of natural compounds derived from plants to modulate NF-κB activity, offering a novel way forward in AD management.Several key directions and strategies can shape the progression of NF-κB inhibition using phytochemicals as a target for AD.Future research should prioritize the identification of phytochemicals with robust NF-κBinhibitory properties.Screening and evaluating various plant-derived compounds can uncover novel candidates that effectively modulate NF-κB signaling pathways.Curcumin has demonstrated potent anti-inflammatory properties by inhibiting NF-κB activation.It may also impact amyloid-beta aggregation and tau phosphorylation, key factors in AD pathogenesis [57].Epigallocatechin gallate (EGCG) is a bioactive polyphenol found abundantly in green tea, and it has gained attention for its potential benefits in AD management.EGCG has been shown to suppress the activation of NF-κB, a key regulator of inflammation.By inhibiting NF-κB, EGCG can mitigate the production of pro-inflammatory cytokines, chemokines, and other molecules involved in neuroinflammation, a prominent feature of AD [58].Salvia miltiorrhiza is a traditional Chinese herbal medicine that has garnered attention for its potential benefits in AD management.The primary active compounds (Tanshinones and salvianolic acids) in S. miltiorrhiza have been investigated for their multifaceted effects, including their potential interaction with NF-κB.S. miltiorrhiza has been explored for its potential to influence Aβ metabolism.By modulating NF-κB, S. miltiorrhiza's compounds might impact Aβ production, clearance, and aggregation, key factors in AD pathogenesis.S. miltiorrhiza compounds have shown promise in reducing tau hyperphosphorylation, a key feature of neurofibrillary tangles in AD [59].
Ashwagandha (Withania somnifera), an adaptogenic herb with a long history in traditional medicine, has gained attention for its potential benefits in AD management.The active compounds in ashwagandha, known as withanolides, have been studied for their diverse effects, including their potential interaction with NF-κB signaling.Ashwagandha has been suggested to enhance the expression of neurotrophic factors that support neuronal growth and plasticity.Its interaction with NF-κB may play a role in these effects.Using a Drosophila melanogaster AD model, a study explored Ashwagandha's impact on beta-amyloid toxicity and longevity.At 20 mg/mL, Ashwagandha rescued AD-related phenotypes and enhanced longevity in AD and wild-type Drosophila.These findings suggest Ashwagandha's potential as a potent AD treatment and cellular well-being enhancer [60].Turner et al. conducted a 52-week randomized, placebo-controlled study investigating resveratrol's effects on mild to moderate AD.Resveratrol, well tolerated and able to cross the BBB, showed altered biomarker trajectories.Notably, CSF Aβ40 and plasma Aβ40 levels decreased less in the resveratrol group compared to placebo after 52 weeks.It exhibits antioxidant activity, which can counteract oxidative-stress-induced NF-κB activation.While providing class II evidence for resveratrol's safety and influence on AD biomarkers, further research is necessary to understand these changes [61].While Ginkgo biloba is generally considered safe for short-term use, its efficacy in treating AD remains debatable [62].Clinical trials examining the effects of G. biloba in AD have yielded mixed results.While some studies have reported modest cognitive improvements and slowed decline, others have found no significant benefit compared to placebo.Table 2 lists the representative phytochemicals demonstrating promising bioactivity against AD encompassing the NF-κB signaling pathway.A comprehensive understanding of how specific phytochemicals modulate NF-κB activation is crucial.Research efforts should elucidate the molecular mechanisms underlying their effects, potentially leading to the development of targeted therapies with minimized off-target effects.In vitro [83] Wnt/β-catenin: Wingless-related integration site/β-catenin; IRE1/XBP1s: Inositol-requiring enzyme 1/X-box binding protein

Conclusions
NF-κB emerges as a pivotal influencer over both the onset and progression of AD.As elucidated, the dual nature of NF-κB becomes evident-a guardian of immune responses and cell survival, yet also a potential instigator of neuroinflammation and neuronal compromise.The multifaceted contributions of NF-κB in AD pathogenesis have stimulated investigations into harnessing its potential as a therapeutic target.Efforts to manipulate NF-κB, both in preclinical models and clinical contexts, present a compelling approach to mitigating the inflammatory milieu characteristic of AD.Yet, this endeavor is not devoid of challenges.The intricate balance between dampening neuroinflammation and preserving essential cellular functions underscores the delicate nature of NF-κB modulation.Its intricate interplay with other molecular players, such as β-secretase and amyloid-beta, demands a nuanced understanding to untangle the intricacies of AD pathogenesis.The evolving trajectory of NF-κB-targeted therapies hinges on precision-selectively addressing specific cell types, customizing interventions based on individual profiles, and optimizing drug delivery methodologies.The amalgamation of NF-κB-focused strategies with complementary approaches offers a comprehensive approach to tackling the multifaceted nature of AD.These considerations and the imperative of safety assessments and robust clinical trials aid in developing or improving AD treatments.Further studies are required to understand the potential of the NF-κB pathway and its inhibitors in managing AD.

Table 1 .
The list of representative molecules targeting the NF-κB pathway to treat and manage Alzheimer's disease.

Table 2 .
Phytochemicals targeting the NF-κB pathway as therapeutic agents for Alzheimer's disease.