Alzheimer’s Diseases (AD) is a neurodegenerative disorder characterized by progressive neuronal loss leading to cognitive decline. Although there is yet to be a cure nor a way to reverse the neuronal damage, there are current treatments to amend some of the cognitive symptoms associated with AD. Acetylcholinesterase inhibitors (AChEi) are the primary agents of choice and have had profound implications throughout the past decades. AChEi such as donepezil, rivastigmine, and galantamine mediates and increases cholinergic activities in the central nervous system (CNS), and have been shown to improve and preserve cognition in AD patients. Beyond the current drugs on the market, investigational discoveries continue to explore the potential of safer and more efficacious AChEi agents for the treatment of AD. There have been quite a few challenges, given the high failure rates. Yet, these very trials and studies have been a fundamental step towards better understanding the treatments of AD and have provided some insight on the potential to surpass what is currently available.
Currently, there is neither a cure for Alzheimer’s disease (AD) nor a way to stop the progressive death of neuronal cells associated with this devastating aliment. To date, there are only medications that temporarily slow its progression, and do not interfere with its pathogenesis. One of the hallmarks of AD is the presence of amyloid-beta plaques derived from the metabolism of the amyloid precursor protein, via the cleavage by beta followed by gamma secretase. Homotaurine, a naturally occurring small molecule found in some seaweeds, and curcumin, a phenolic antioxidant found in Curcuma longa, have been extensively studied as potential compounds to prevent/reverse plaque formation. In this study, libraries of chalcones and extended chalcones based on curcumin, as well as aminopropylsulfonamides inspired by homotaurine, were synthesized. Using fluorescence spectroscopic analysis with Thioflavin T, the anti-aggregation effect on Aβ42 was determined. A select number of newly synthesized chalcones and extended chalcone analogs were revealed to be potential anti-amyloidogenic agents. These were further evaluated with regard to their neurotoxicity/neuroprotection. The extended chalcone analogs that displayed the most anti-aggregation effect on Aβ42 were further analyzed in an MTT assay. Although none of the compounds alone displayed any neurotoxicity, none were able to provide neuroprotection against Aβ42.
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