Protein-like polymers illuminate the path to macular degeneration treatment
In the latest stride toward combating neovascular age-related macular degeneration (nAMD), a team led by SQI member Nathan Gianneschi has unveiled a novel approach that could transform patients' lives worldwide.
Their research, published in Science Advances, introduces Thrombospondin-1 mimetic protein-like polymers (TSP1 PLPs) as a potential game-changer in the fight against this leading cause of blindness.
nAMD is the primary cause of blindness in developed nations, leaving millions grappling with deteriorating eyesight and a diminished quality of life. While effective for many, current treatments fall short for a significant portion of patients, highlighting the urgent need for alternative therapies.
“Some years ago, we were made aware of the fact that some patients do not respond to current therapeutics in conversations with Professors Jeremy Lavine and Greg Schwartz in ophthalmology at the Northwestern Feinberg School of Medicine,” Gianneschi said. “We formed a multidisciplinary team to tackle the problem by mimicking a protein with our polymer technology, hypothesized to play a key role in the necessary pathway.”
Gianneschi is the Jacob and Rosaline Cohn Professor of Chemistry, Materials Science and Engineering, and Biomedical Engineering at Northwestern University. He is also a member of the International Institute for Nanotechnology at Northwestern.
A ray of hope
Gianneschi and his colleagues have invented proteomimetic polymers, synthetic compounds engineered to mimic the behavior of natural proteins, as a potential solution. Their study centers around Thrombospondin-1 (TSP1), a protein known for inhibiting angiogenesis and forming new blood vessels. In nAMD, abnormal angiogenesis contributes to vision loss. By designing TSP1 PLPs, the researchers aimed to harness the power of this natural anti-angiogenic agent in a groundbreaking manner.
Their nano-size scale sets TSP1 PLPs apart, making them incredibly efficient at targeting specific cellular processes — much like an antibody, but manmade. By binding with CD36, a key player in angiogenesis regulation, these proteomimetic polymers interfere with the abnormal blood vessel formation characteristic of nAMD. Their diminutive size enables them to navigate the intricate ocular environment.
“Our polymers act to engage the key receptor in a multivalent manner,” Gianneschi said. “This is similar to how we grab things with our entire hand instead of with one finger. It means we can hold on tight. The PLPs do this, but at cellular receptors at the back of the eye.”
Moreover, these nano marvels demonstrate remarkable selectivity, stability, and longevity within the eye, ensuring a sustained therapeutic effect. Their nanoscale dimensions enhance their biological interactions and pave the way for minimally invasive delivery methods, promising improved patient comfort and outcomes.
Note: This article was first published by the McCormick School of Engineering.