缅北强奸 researchers develop nanoparticle to detect early-stage Alzheimer's
Research led by Professor Shirley Wu at the University of Toronto鈥檚 Leslie Dan Faculty of Pharmacy has resulted in the development of a new nanoparticle that has potential to help diagnose and intervene in Alzheimer鈥檚 disease at an early stage.
The study, late last year, describes how the new nanoparticle enables MRI to image early changes in the brain before symptoms of the disease occur.
鈥淭he pre-symptomatic stage of Alzheimer鈥檚 disease, when you don鈥檛 see any cognitive or functional changes, starts 15 to 20 years before a patient has symptoms, and it鈥檚 extremely important to detect and treat the disease at this stage, before it progresses,鈥 says Taksim Ahmed, a PhD candidate in the Wu lab and one of the study authors. 鈥淥ur new technology has that potential.鈥
Alzheimer鈥檚 disease is often diagnosed at a late stage when it is irreversible. It is largely diagnosed through the patient鈥檚 symptoms, but when imaging techniques such as MRI or PET/CT scans are used, they have significant limitations. The contrast agents used for these techniques are not able to cross the blood-brain barrier, a protective structure that prevents most molecules from entering the brain. In addition, the imaging techniques currently show changes and damage to the brain that occur at later stages of the disease.
Members of Shirley Wu鈥檚 lab 鈥 which also includes Chunsheng He and Azhar Abbasi 鈥 in collaboration with Jeff Henderson, an associate professor at the Leslie Dan Faculty of Pharmacy, and Professor Paul Fraser, an Alzheimer鈥檚 expert in the Temerty Faculty of Medicine, developed a biocompatible nanoparticle that solves several of the problems faced by current imaging techniques. Combining the Wu team鈥檚 expertise in pharmaceutical nanotechnology with the Henderson lab鈥檚 expertise in brain structure and neurology led to the development of a powerful new early detection and intervention tool.
The nanoparticle is designed to fit into a receptor found on cells in the blood-brain barrier, allowing it to cross this highly selective layer of cells and enter the brain. Once in the brain, the particle targets and accumulates in areas with high concentrations of reactive oxygen species 鈥 unstable oxygen molecules that are generated by neuroinflammation and found at the earliest stages of Alzheimer鈥檚 disease.
When the particle reaches these inflammatory areas of the brain, it initiates a chemical reaction that produces manganese ions that generate the contrast required for MRI.
鈥淭his kind of technique could be very useful for screening in families with genes that put them at high risk of the disease, rather than waiting until they have symptoms,鈥 says Wu.
The team also found evidence that the chemical reaction removes the damaging proinflammatory species. 鈥淎s a result, this is a theranostic system,鈥 Wu says. 鈥淚t serves a dual function of diagnosis and therapy.鈥
When they tested the nanoparticles in an animal model of Alzheimer鈥檚 disease, MRI was able to detect inflammation-associated biomarkers in the brain at the earliest pre-symptomatic stage of disease.
鈥淢ost of the clinically used MRI contrast agents are based on the heavy metal gadolinium, but the FDA recently came up with the new safety warning for these contrast agents. Our technology uses manganese, a naturally occurring essential mineral found in the human body, to enhance the MRI signal鈥 says Abbasi.
鈥淲e believe that the successful development of this system will overcome the safety concerns related to the conventional gadolinium-based agents.鈥 Abbasi adds that while many research articles are published on nanomedicine every year, only a few nanoparticles products have made it to the clinic.
鈥淚 think one of the main obstacles is nanoparticle manufacturing and scale-up,鈥 says Abbasi. 鈥淭o synthesize these nanoparticles, we鈥檙e using techniques in Dr. Wu鈥檚 lab that are well-established in the pharmaceutical industry.
鈥淚t will help us to move this technology faster from bench to bedside.鈥
Many drugs intended to treat brain and central nervous system diseases are not effective because they aren鈥檛 able to cross the blood-brain barrier. Because the new nanoparticle does, it has the potential to act as a platform that could be loaded with different drugs to treat a variety of brain and central nervous system conditions.
鈥淔inding the best way to deliver therapeutics into the brain has been a longstanding problem in the field,鈥 says He. 鈥淲e have used the body鈥檚 own physiology to cross the blood-brain barrier, which is a unique feature of this nanoplatform and could help with loading it with different therapeutic agents.鈥
Since the study was published late last year, it has remained one of the journal鈥檚 most shared articles on social media. The team is currently working on scaling up production of the nanoparticle to allow them to continue their preclinical work and they hope to eventually test the system in the clinic.
鈥淲hat we have done with these nanoparticles is completely different from what people have been doing,鈥 says Ahmed. 鈥淭here has been a lot of focus on finding a cure for later stage Alzheimer鈥檚 disease, but if we can detect it at the beginning, there would be a huge benefit.鈥
The study received support from the Weston Brain Institute.