A core advantage of nanomedicine is that appropriately designed nanoparticles can be targeted to deliver drugs to a very specific subset of cells in the body. An elegant example of specificity targets immune cells called neutrophils that are actively involved in damaging vascular inflammation while sparing neutrophils in circulation that are needed for other functions. A hat tip to Science Daily for reprinting this University of Illinois at Chicago news release written by Sharon Parmet “Nanoparticles target anti-inflammatory drugs where needed“:
Researchers at the University of Illinois at Chicago have developed a system for precisely delivering anti-inflammatory drugs to immune cells gone out of control, while sparing their well-behaved counterparts. Their findings were published online Feb. 23 in Nature Nanotechnology [abstract].
The system uses nanoparticles made of tiny bits of protein designed to bind to unique receptors found only on neutrophils, a type of immune cell engaged in detrimental acute and chronic inflammatory responses.
In a normal immune response, neutrophils circulating in the blood respond to signals given off by injured or damaged blood vessels and begin to accumulate at the injury, where they engulf bacteria or debris from injured tissue that might cause infection. In chronic inflammation, neutrophils can pile up at the site of injury, sticking to the blood vessel walls and to each other and contributing to tissue damage.
Adhesion of neutrophils to blood vessel walls is a major factor in acute lung injury, where it can impair the exchange of gases between the lungs and blood, leading to severe breathing problems. If untreated, the disease has a 50 percent mortality rate in intensive care units.
Corticosteroids and non-steroidal anti-inflammatory drugs used to treat inflammatory diseases are “blunt instruments that affect the whole body and carry some significant side effects,” says Asrar B. Malik, the Schweppe Family Distinguished Professor and head of pharmacology in the UIC College of Medicine, who is lead author of the paper.
Neutrophils that are stuck to blood vessels or clumped together have unique receptors on their surface that circulating neutrophils lack. Malik and his colleagues designed a nanoparticle to take advantage by embedding it with an anti-inflammatory drug. The nanoparticles bind to the receptors, and the neutrophils internalize the nanoparticle. Once inside, the anti-inflammatory drug works to “unzip” the neutrophil and allow it to re-enter the bloodstream.
“The nanoparticle is very much like a Trojan horse,” Malik said. “It binds to a receptor found only on these activated, sticky neutrophils, and the cell automatically engulfs whatever binds there. Because circulating neutrophils lack these receptors, the system is incredibly precise and targets only those immune cells that are actively contributing to inflammatory disease.”
Malik, along with research assistant professor Zhenjia Wang and assistant professor Jaehyung Cho, used intra-vital microscopy to follow nanoparticles in real-time in mice with induced vascular inflammation. The nanoparticles were labeled with a fluorescent dye, and could be seen binding to and entering neutrophils clustered together on the inner walls of capillaries, but not binding to freely circulating neutrophils. If the researchers attached a drug called piceatannol, which interferes with cell-cell adhesion, to the nanoparticles, they observed that clusters of neutrophils that took up the particles detached from each other and from the blood vessel wall. The cells were in effect neutralized and could no longer contribute to inflammation at the site of an injury.
The findings, Malik said, “show that nanoparticles can be used to deliver drugs in a highly targeted, specific fashion to activated immune cells and could be designed to treat a broad range of inflammatory diseases.”
Nanomedicine will advance hand-in-hand with biotechnology. As more is learned about proteins that are specifically displayed on cell surfaces in conjunction with disease, there will be more opportunities to design nanoparticles to target diseased cells.
—James Lewis, PhD