New Design Rules for Cartilage Drug Delivery
BioE Associate Professor Ambika Bajpayee’s lab established new design principles for joint drug delivery in an article titled “Spatial charge-hydrophobicity configuration modulates cationic peptide transport in cartilage,” recently published in Biophysical Journal. The study reveals that peptide carriers with evenly distributed charges and minimal hydrophobicity achieve the deepest and most durable penetration into cartilage, providing a vital framework for treating conditions like osteoarthritis.
Abstract:
Charge-based delivery systems offer a promising approach for targeting dense, negatively charged tissues such as cartilage, which presents a significant transport barrier due to its high fixed charge density from aggrecan glycosaminoglycans. Cationic nanocarriers, including peptide-based systems, can overcome these barriers by leveraging electrostatic interactions to enhance intratissue penetration. However, the effectiveness of these carriers depends not only on their net positive charge, which drives Donnan partitioning, but also on the precise spatial arrangement of cationic and hydrophobic residues, which influences transport, binding, and retention. In this study, we investigated the impact of spatial charge distribution and hydrophobicity on the intracartilage transport and retention of arginine-rich cationic peptide carriers with a net charge of +14, optimized for effective cartilage targeting. Using both experimental methods and molecular modeling, we examined the transport properties of cationic peptide carriers with varied charge and hydrophobic cluster arrangements in healthy and degenerated cartilage with different fixed charge densities. Our findings reveal that peptides with a higher degree of clustered cationic or hydrophobic residues exhibit greater intracartilage diffusivity due to weaker binding interactions with aggrecan glycosaminoglycans and a more flexible structural conformation that incurs an entropic penalty. However, although hydrophobic residues can enhance intratissue retention, particularly in degenerated tissues, they also promote competitive binding within synovial fluid, emphasizing the need for hydrophilic designs. Overall, our results indicate that evenly distributed cationic residues and minimal hydrophobicity yield the most effective carriers for deep, long-term tissue penetration, providing a framework for the rational design of tissue-targeting cationic peptide carriers. The design principles established in this work can be broadly applied to the rational development of cationic carriers for targeted drug delivery in a wide range of negatively charged tissues.