A scalable and tunable thermoreversible polymer for 3D human pluripotent stem cell biomanufacturing.

Human pluripotent stem cells (hPSCs) are an exciting and promising source to enable cell replacement therapies for a variety of unmet medical needs. Though hPSCs can be successfully derived into numerous physiologically relevant cell types, effective translation to the clinic is limited by challenges in scalable production of high-quality cells, cellular immaturity following the differentiation process, and the use of animal-derived components in culture. To address these limitations, we have developed a fully defined, reproducible, and tunable thermoreversible polymer for high-quality, scalable 3D cell production. Our reproducible synthesis method enables precise control of gelation temperature (24°C-32°C), hydrogel stiffness (100-4000 Pa), and the prevention of any unintended covalent crosslinking. After material optimization, we demonstrated hPSC expansion, pluripotency maintenance, and differentiation into numerous lineages within the hydrogel. Overall, this 3D thermoreversible hydrogel platform has broad applications in scalable, high-quality cell production to overcome the biomanufacturing burden of stem cell therapy.

Advanced Materials to Enhance Central Nervous System Tissue Modeling and Cell Therapy.

The progressively deeper understanding of mechanisms underlying stem cell fate decisions has enabled parallel advances in basic biology-such as the generation of organoid models that can further one's basic understanding of human development and disease-and in clinical translation-including stem cell based therapies to treat human disease. Both of these applications rely on tight control of the stem cell microenvironment to properly modulate cell fate, and materials that can be engineered to interface with cells in a controlled and tunable manner have therefore emerged as valuable tools for guiding stem cell growth and differentiation. With a focus on the central nervous system (CNS), a broad range of material solutions that have been engineered to overcome various hurdles in constructing advanced organoid models and developing effective stem cell therapeutics is reviewed. Finally, regulatory aspects of combined material-cell approaches for CNS therapies are considered.

Engineering bioorthogonal protein-polymer hybrid hydrogel as a functional protein immobilization platform.

We demonstrate the synthesis of protein-polymer hybrid hydrogel that can be used as a platform for immobilizing functional proteins. Orthogonal chemistry was employed for cross-linking the hybrid network and conjugating proteins to the gel backbone, allowing for the convenient, one-pot formation of a functionalized hydrogel. The resulting hydrogel had tunable mechanical properties, was stable in solution, and biocompatible.

Dendritic amphiphiles strongly affect the biophysical properties of DPPC bilayer membranes.

Molecular dynamics (MD) simulations were used to gain insight on the molecular interactions in a model biological membrane comprised of a bilayer with DPPC (dipalmitoylphosphotidylcholine) and antimicrobial dendritic amphiphile molecules [RCONHC(CH(2)CH(2)COOH)(3), where R is the saturated hydrocarbon tail (R = n-C(n)H(2n+1)), to be abbreviated as 3CAmn]. This study analyzes different biophysical properties of the equilibrated mixed bilayers, at 300 and 325 K, to determine how the presence of the 3CAmn, in varying concentrations and tail lengths, affects the lipid bilayer. Lipid tail order parameter data, bilayer thickness trends, and qualitative lipid tail tilt observations suggest that a molar ratio of 0.2 3CAm19/DPPC is sufficient to induce a phase transition in the bilayer from gel to liquid crystalline at 300 K. These results also imply that the phase transition temperature of the mixed bilayer decreases upon incorporation of higher concentrations of 3CAm19. Hydrogen bonding takes place between the 3CAmn and DPPC at specific sites, as evidenced by the radial distribution function. Increased hydrogen bonding and the smaller headgroup size of the 3CAmn molecule result in a decrease in the total lateral area with higher concentrations of 3CAm19. Diffusion constants of 3CAmn varied with concentration and tail length; diffusion constants of DPPC and 3CAm19 increased with increasing 3CAm19 concentration at 300 K and shorter 3CAmn tails had higher diffusion constants at both temperatures. These computational studies provide a comprehensive understanding of the biophysical changes to model biological membranes by the association of 3CAmn.