A method using a system adapted for continuous growth and harvesting of fungal fruiting bodies. The system includes a growth chamber, one or more mycelium feed assemblies, a nutrient reservoir with liquid media, one or more environmental controls to control an environment within the growth chamber and of the liquid media within the nutrient reservoir. One or more mycelium feed assemblies are arranged within the growth chamber. Each of the one or more mycelium feed assemblies includes a nutrient supply member and a mycelium colony which grows around the nutrient supply member, that continuously supplies liquid media to the mycelium colony. The method includes starting one or more mycelium colonies on the nutrient supply member, establishing that a mature colony has formed, and then maintaining the mature mycelium colony by continuous delivery of liquid medium to the mycelium colony, thus allowing for contiguous generation and harvesting of fungal fruiting bodies.

A method using a system adapted for continuous growth and harvesting of fungal fruiting bodies. The system includes a growth chamber, one or more mycelium feed assemblies, a nutrient reservoir with liquid media, one or more environmental controls to control an environment within the growth chamber and of the liquid media within the nutrient reservoir. One or more mycelium feed assemblies are arranged within the growth chamber. Each of the one or more mycelium feed assemblies includes a nutrient supply member and a mycelium colony which grows around the nutrient supply member, that continuously supplies liquid media to the mycelium colony. The method includes starting one or more mycelium colonies on the nutrient supply member, establishing that a mature colony has formed, and then maintaining the mature mycelium colony by continuous delivery of liquid medium to the mycelium colony, thus allowing for contiguous generation and harvesting of fungal fruiting bodies.

The method grows a mycelial mass over a three-dimensional lattice such that a dense network of oriented hyphae is formed on the lattice. Growth along the lattice results in mycelium composite with highly organized hyphae strands and allows the design and production of composites with greater strength in chosen directions due to the organized nature of the supporting mycelia structure.

The method grows a mycelial mass over a three-dimensional lattice such that a dense network of oriented hyphae is formed on the lattice. Growth along the lattice results in mycelium composite with highly organized hyphae strands and allows the design and production of composites with greater strength in chosen directions due to the organized nature of the supporting mycelia structure.

A mycelium growth bed for growing a solid substrate-bound mycelium through which the mycelium composite is easily and readily removed. This is achieved through the use of a perforation layer embedded between the mycelium substrate and the mycelium composite so as to create a uniform structural weakness and thereby enhancing harvesting abilities of the ex-substrate mycelium via a greatly reduced and uniform tear strength. The perforation layer, through which the mycelium grows, allows for the gated and controlled extrusion of a matrix of colonial cells that may be easily and uniformly delaminated from the underlying mycelium substrate.

A mycelium growth bed for growing a solid substrate-bound mycelium through which the mycelium composite is easily and readily removed. This is achieved through the use of a perforation layer embedded between the mycelium substrate and the mycelium composite so as to create a uniform structural weakness and thereby enhancing harvesting abilities of the ex-substrate mycelium via a greatly reduced and uniform tear strength. The perforation layer, through which the mycelium grows, allows for the gated and controlled extrusion of a matrix of colonial cells that may be easily and uniformly delaminated from the underlying mycelium substrate.

This application relates generally to aerial mycelium and methods of making aerial mycelium suitable for use as a food or textile product or ingredient. The aerial mycelium can be grown using a growth matrix provided into a growth environment and introducing aqueous mist into the growth environment. The aqueous mist has a mist deposition rate and a mean mist deposition rate to allow for aerial mycelial growth from the growth matrix.

A mycelium growth bed for growing a solid substrate-bound mycelium through which the mycelium composite is easily and readily removed. This is achieved through the use of a perforation layer embedded between the mycelium substrate and the mycelium composite so as to create a uniform structural weakness and thereby enhancing harvesting abilities of the ex-substrate mycelium via a greatly reduced and uniform tear strength. The perforation layer, through which the mycelium grows, allows for the gated and controlled extrusion of a matrix of colonial cells that may be easily and uniformly delaminated from the underlying mycelium substrate.

A mycelium growth bed for growing a solid substrate-bound mycelium through which the mycelium composite is easily and readily removed. This is achieved through the use of a perforation layer embedded between the mycelium substrate and the mycelium composite so as to create a uniform structural weakness and thereby enhancing harvesting abilities of the ex-substrate mycelium via a greatly reduced and uniform tear strength. The perforation layer, through which the mycelium grows, allows for the gated and controlled extrusion of a matrix of colonial cells that may be easily and uniformly delaminated from the underlying mycelium substrate.

An Antrodia cinnamomea cultivation method sequentially comprises the following steps: step 1, obtaining a nutrient solution by mixing ingredients thereof, wherein ingredients of the nutrient solution comprises Cinnamomum kanehirae extracts, carbon sources and nitrogen sources, the nutrient solution is placed in a porous carrier, the porous carrier has a peripheral surface and multiple micropores recessed into the peripheral surface, the nutrient solution is able to infiltrate into the micropores to form a nutrient layer on the peripheral surface and inner peripheries of the micropores; step 2, performing a membrane treatment on the porous carrier to form a membrane on the nutrient layer; step 3, sterilizing the porous carrier; and step 4, growing Antrodia cinnamomea strains on the membrane on the porous carrier, and then placing the porous carrier in a sealed environment for cultivation at constant temperature and humidity.