Machine learning-driven multifunctional peptide engineering for sustained ocular drug delivery.
Henry T HsuehRenee Ti ChouUsha RaiWathsala LiyanageYoo Chun KimMatthew B AppellJahnavi PejavarKirby T LeoCharlotte DavisonPatricia KolodziejskiAnn MozzerHyeYoung KwonMaanasa SistaNicole M AndersAvelina HemingwaySri Vishnu Kiran RompicharlaMalia EdwardsIan PithaJustin HanesMichael P CummingsLaura M EnsignPublished in: Nature communications (2023)
Sustained drug delivery strategies have many potential benefits for treating a range of diseases, particularly chronic diseases that require treatment for years. For many chronic ocular diseases, patient adherence to eye drop dosing regimens and the need for frequent intraocular injections are significant barriers to effective disease management. Here, we utilize peptide engineering to impart melanin binding properties to peptide-drug conjugates to act as a sustained-release depot in the eye. We develop a super learning-based methodology to engineer multifunctional peptides that efficiently enter cells, bind to melanin, and have low cytotoxicity. When the lead multifunctional peptide (HR97) is conjugated to brimonidine, an intraocular pressure lowering drug that is prescribed for three times per day topical dosing, intraocular pressure reduction is observed for up to 18 days after a single intracameral injection in rabbits. Further, the cumulative intraocular pressure lowering effect increases ~17-fold compared to free brimonidine injection. Engineered multifunctional peptide-drug conjugates are a promising approach for providing sustained therapeutic delivery in the eye and beyond.
Keyphrases
- drug delivery
- cancer therapy
- machine learning
- drug release
- induced apoptosis
- ultrasound guided
- type diabetes
- adverse drug
- drug induced
- climate change
- metal organic framework
- artificial intelligence
- case report
- signaling pathway
- insulin resistance
- adipose tissue
- binding protein
- amino acid
- oxidative stress
- cataract surgery
- replacement therapy