ABSTRACT
Purpose/Objectives: Nature efficiently self-organizes cells and tissues into complex fractal forms. Whether fractal patterning contributes functionally to maturation, and how cells sense and interpret such shape cues, is not well understood. Methodology: Using kidney podocytes as a model system, bioinspired templating of glomerular histology was leveraged to design controlled fractal 21/2 -D surfaces for cell culture. Results: Microcurvature was associated with charge density gradients in space, found to direct extracellular matrix protein organization resulting in hierarchical assembly of cell structures and fractally-branching podocyte morphology in vitro, that was delineated clearly in vitro with a novel highresolution fluorescent assaying technique. Shape stimulation was uniquely associated with development of mature-like foot processes and organized ECM. In applications of drug testing, coronavirus infection, and a cells-as-sensors approach to patient serum diagnostics, fractally stimulated cells were more responsive than flat cultures. Conclusion/Significance: Fractal frameworks may thus provide a functional role in podocyte maturation and could serve to advance other bioengineered systems.
ABSTRACT
Nature efficiently self-organizes cells and tissues into complex fractal forms. Whether fractal patterning contributes functionally to maturation, and how cells sense and interpret such shape cues, is not well understood. Using kidney podocytes as a model system, bioinspired templating of glomerular histology was leveraged to design controlled fractal 21/2 -D surfaces for cell culture. Microcurvature was associated with charge density gradients in space, found to direct extracellular matrix protein organization resulting in hierarchical assembly of cell structures and fractally-branching podocyte morphology in vitro, outlined with a novel fluorescent assaying technique. Shape simulation was uniquely associated with mature-like foot processes on an organized ECM. In applications of drug testing, coronavirus infection, and a cells-as-sensors approach to patient serum diagnostics, fractally stimulated cells were more responsive than flat cultures. Fractal frameworks may thus provide a functional role in podocyte maturation and could serve to advance other bioengineered systems.