AVS 68 Session BP-SuA: Biomaterials Plenary Session: Programmable Biologic Materials (ALL-INVITED SESSION)
Session Abstract Book
(237KB, Nov 18, 2022)
Time Period SuA Sessions
|
Abstract Timeline
| Topic BP Sessions
| Time Periods
| Topics
| AVS 68 Schedule
Start | Invited? | Item |
---|---|---|
4:20 PM | Invited |
BP-SuA-5 Enhancing the Programmability of Engineered Extracellular Matrices with Sequence Specific Peptoids
Adrianne M. Rosales (The University of Texas at Austin) Hydrogel substrates have garnered intense interest as engineered extracellular matrices due to their tailorable mechanics and degradability. These substrates can be composed of naturally derived materials (e.g., collagen) or synthetic materials (e.g., poly(ethylene glycol). Synthetic materials are attractive due to their known chemical compositions and scalability, but the challenge with their use lies in the lack of complexity as compared to biological systems, especially with regard to sequence-specific bioactivity. Hence, our work aims to enhance the programmability of synthetic hydrogel biomaterials by using precise polymer architectures, specifically with a class of materials called peptoids. Here, we describe our efforts to control two key properties of hydrogel substrates with peptoid functionality: 1) bulk mechanics and 2) enzymatic degradability. Tailoring these features is essential for regulating the interface of hydrogel substrates with adhered cells for efficacious cell manufacturing and tissue engineering platforms. Drawing inspiration from semiflexible biopolymers, we achieved control over the mechanics of hydrogel substrates by controlling chain structure with peptoid cross-linker sequence. Specifically, helical peptoids increased the shear moduli of hydrogels due to increased chain stiffness as compared to non-helical peptoids, while keeping all other hydrogel parameters fixed. This strategy decoupled bulk mechanics of the substrate from the network connectivity, allowing for investigation of mechanical effects on adhered mesenchymal stromal cell (MSC) behavior. We found that MSCs adhered on soft substrates secreted higher levels of indoleamine 2,3-dioxygenase (IDO), an immunomodulatory enzyme necessary for enhanced cell performance. Furthermore, we examined the ability of peptoids to tune hydrogel degradability via proteolysis. We substituted peptoids into key sites of proteolytically degradable substrates, enabling a tailored material response to matrix metalloproteinases secreted by cells. Overall, our results suggest that sequence control of synthetic peptoids may provide effective strategies for expanding the functionality of biomaterial scaffolds for tissue engineering and regenerative medicine, particularly with respect to mechanics and degradation in complex biological environments.
View Supplemental Document (pdf)
|
5:00 PM | Invited |
BP-SuA-7 New Biomaterials and Bio-inspired Materials from Polyelectrolyte Complexation
Matthew Tirrell (University of Chicago); Yun Fang (The University of Chicago) Nature exploits all available covalent and non-covalent interactions for unparalleled spatiotemporal control over hierarchical length scales of macromolecular and supramolecular structure. The complex interplay of electrostatic and other non-covalent interactions of charged macromolecules still poses many open questions that will require broad collaboration among the life and physical sciences, as well as input from the engineering disciplines to drive toward new solid-state structures and useful materials. Scientific questions related to the physics of electrostatic self-assembly and to its role in biology will be discussed. Recent advances in understanding and biomedical applications of polyelectrolyte complex micelles will be presented. |
5:40 PM |
BP-SuA-9 BID Flash Poster Session: Oral Presentations
5:40. BI-TuP-2 - Hannah Omeoka 5:43: BI-TuP-8 - Juhi Jaiswal 5:46: BI-TuP-12 - Ainslie Allen 5:49: BI-TuP-6 Shahidul Alam Mohammad |