This study investigates the magnetotropic and radiotropic (radio frequency–induced) behavior of Ganoderma lucidum with the aim of directing hyphal growth to enhance the mechanical properties of mycelial mats. As mycelium-based biomaterials gain traction as sustainable alternatives to leather and synthetic composites, their scalability and utility remain constrained by intrinsic mechanical limitations such as low tensile strength and poor fiber cohesion. Current approaches to improve material performance often rely on post-processing or substrate optimization, neither of which resolve issues of microstructural misalignment. Here, we propose a fundamentally different strategy: the use of static magnetic fields and controlled radio frequency exposure to actively steer hyphal orientation during the growth phase. By inducing directional growth responses through biophysical stimuli—specifically magnetotropism and radiotropism—we hypothesize that mycelial networks can be grown with greater alignment and density, leading to mechanically superior bio-leathers.

Our experimental design isolates and characterizes directional hyphal responses under magnetic field strengths ranging from 0.2 to 1.4 T, and under radio frequency exposure within the MHz range. Directionality, branching complexity, and hyphal cohesion are quantitatively assessed through fluorescence microscopy and image analysis. Preliminary results suggest that G. lucidum exhibits field-responsive growth, with implications for scalable, energy-efficient fabrication of hierarchically structured fungal materials. This foundational study lays the groundwork for integrating magnetotropic and radiotropic guidance into biofabrication workflows, offering a low-impact method to produce structurally enhanced, biodegradable mycelium textiles. By elucidating the process–structure–property relationships underlying field-directed hyphal alignment, this work provides critical insights into the engineering of next-generation bioenabled materials.