Microfluidic technology has become increasingly important in many scientific fields, such as regenerative medicine, microelectronics, and environmental science. However, conventional microfabrication techniques face limitations in scale and in the construction of complex networks. These hurdles are compounded when it comes to building more intricate 3D microfluidic networks. Microfluidic technology has become increasingly important in many scientific fields, such as regenerative medicine, microelectronics, and environmental science. However, conventional microfabrication techniques face limitations in scale and in the construction of complex networks. These hurdles are compounded when it comes to building more intricate 3D microfluidic networks. Plants & Animals Biotechnology Phys.org – latest science and technology news stories
Building roots in glass, a bio-inspired approach to creating 3D microvascular networks using plants and fungi
