Researchers in Prof. Hemamala Karunadasa's laboratory have developed inexpensive, robust, high capacity hybrid materials for reversible or irreversible capture of halogens (chlorine, bromine, and iodine gas).
Researchers at Stanford have developed methods for preparing photo-, and chemical-, cross-linkable three-dimensional matrices for the controlled delivery of bioactive molecules for therapeutic applications.
Stanford researchers have invented a novel concept to prevent or minimize scar formation during injury by controlling the mechanical environment through molecular targeting of mechanotransduction sensors including focal adhesion kinase (FAK).
Stanford researchers have developed a method that can tune the ratio between reversible (RE) and irreversible (IRE) electroporation through waveform adjustments.
Hydrogel-based tissue engineering scaffolds are widely used for culturing cells in three dimensions (3D) due to their tissue-like water content, tunable biochemical and physical properties, and ease of cell encapsulation and distribution in 3D.
Researchers in Dr. Fan Yang's lab have developed 3D tissue engineering scaffolds with dynamic, temporally and spatially controllable macropore formation.