Advancing Amyloid Aggregation Research: A Focus on Innovative Therapies, Molecular Modeling and Nano-Delivery Systems in Alzheimer's Disease.

Introduction: Alzheimer's disease (AD), the most common form of dementia, is a major global health issue. Its complex pathology, including amyloid-beta (Aβ) aggregation, leads to neuronal damage and cognitive decline. Since Aβ plays a major role in AD, therapies targeting its production, aggregation, and clearance are being actively explored. This review discusses recent advances in gene therapy, enzyme inhibitors, molecular modeling, and nano-delivery systems aimed at modifying AD progression, highlighting their potential and challenges.

Methods: This review compiles findings on BACE1 and γ-secretase inhibitors, gene therapies that modify amyloid metabolism, and combination therapies. Studies have been selected based on their focus on Aβ regulation and their impact on disease progression, cognitive function, and breakthroughs in diagnostics, molecular modeling, and drug delivery for neurodegenerative conditions.

Results: BACE1 inhibitors, such as verubecestat, and γ-secretase inhibitors, shows potential, however, they face significant challenges related to BBB penetration and adverse effects. Gene therapies using AAV vectors and CRISPR/Cas9 technologies are promising, particularly for individuals genetically predisposed to these diseases. Combination therapies targeting amyloid, tau, and neuro-inflammation have emerged as effective approaches. Advancements in PET, SPECT, MRI, small molecule probes, molecular modeling, and nano-particle-based drug delivery are improving diagnostic and treatment options.

Discussion: The findings emphasize the multifactorial complexity of amyloid disorders and the limitations of mono-therapies. While certain agents demonstrated efficacy in early disease stages, most treatments have failed in advanced phases due to poor central nervous system (CNS) bioavailability, adverse effects, or insufficient target engagement. Novel delivery systems, combination therapies, and computational design approaches offer enhanced translational potential. However, challenges such as immune responses, delivery efficiency, and off-target effects continue to pose significant barriers.

Conclusion: Aβ-targeted therapies, including enzyme inhibitors and gene therapies, hold promise, though challenges such as BBB penetration and toxicity still remain. Combination therapies, along with advancements in diagnostics and drug delivery technology, are essential for finding effective treatments for Alzheimer's, Parkinson's, and other neurodegenerative diseases. Future research should prioritize overcoming the persistent barriers to BBB penetration, enhancing therapeutic selectivity, and refining drug delivery systems to enable more precise, targeted interventions, to ultimately reduce the progression of disease at the molecular level.