In nature, materials with complex architectures are formed through hierarchical self-assembly. Therefore, the study and design of hierarchically assembling materials is important in producing materials that mimic biological structures and is a key challenge in biomaterials science and engineering. In articular cartilage, hierarchical assembly of extracellular matrix (ECM) components provides...
Cancer progression is a complex process, leading to metastatic spread of primary tumor cells that colonize distant vital organs and mortality if not stopped. Since clinical strategies to stem this progression are still being developed, it is of great importance to detect this end stage metastatic spread as early as...
End-stage renal disease, or kidney failure, can result from acute kidney injury or sustained kidney damage in the form of chronic kidney disease. As the prevalence of end-stage renal disease continues to rise, the gold-standard treatment—kidney transplantation—is increasingly restricted by the shortage of transplantable donor kidneys. Bioengineered kidney tissues may...
Biomaterials have immense potential for studying fundamental biological processes and developing therapies to help regenerate or replace the structure and function of injured tissues. In order to accomplish this, they need to be designed to mimic the structure and function of Nature’s most important material, the extracellular matrix (ECM) surrounding...
Built from non-covalent interactions, supramolecular biomaterials are highly dynamic and tunable, and recent work has shown that they are uniquely capable of mimicking functional biological structures. In this work, supramolecular biomaterials built from self-assembling peptide amphiphiles (PA) were investigated with the goal of precisely tuning their cohesive interactions to optimize...