A method of forming an edible meat substitute product includes growing fungal cells in a growth media such that the fungal cells produce a mycelium mass having a protein content of greater than 40 wt % of a dry mass of the mycelium mass. The method includes separating the mycelium mass from the growth media. The method includes disposing the mycelium mass on a base of a mold. The method includes applying a uniaxial pressure to the mycelium mass via a follower to produce a compacted mycelium mass having a moisture content in a range of 65 vol % to 85 vol % and having a shape corresponding to a shape of the mold. A plurality of fibers of the compacted mycelium mass are aligned in a direction orthogonal to the direction of the applied uniaxial pressure.

An edible meat substitute product includes a fibrous mycelium mass in a range of 10 wt % to 100 wt %. The fibrous mycelium mass has a protein content greater than 40 wt % of a dry mass of the fibrous mycelium mass. The edible meat substitute product includes a water content in a range of 0 w % to 90 wt %.

An edible meat substitute product includes a fibrous mycelium mass in a range of 10 wt % to 100 wt %. The fibrous mycelium mass has a protein content greater than 40 wt % of a dry mass of the fibrous mycelium mass. The edible meat substitute product includes a water content in a range of 0 w % to 90 wt %.

A monokaryotic mycelium sheet producing system for creating a sheet of monokaryotic mycelial material. The mycelium sheet producing system includes a culture unit, a spore stock unit, a plating unit, a section unit, a sub-plating unit, an expanding unit and a colonization unit. The culture unit prepares a monokaryon culture. The spore stock unit grows a plurality of fruit bodies in sterile laboratory conditions to create a spore stock. The plating unit performs a peroxide-based spore rescue and a plating process. The section unit is adaptable to section robust hyphae. The sub-plating unit sub-plates and expands the robust hyphae onto a spawn grain master. The expanding unit subsequently expands the spawn grain master into appropriate production of spawn volume. The colonization unit is adaptable to perform a subsequent colonization of mycelium substrate thereby creating a substantially defect free sheet of mycelium.

A monokaryotic mycelium sheet producing system for creating a sheet of monokaryotic mycelial material. The mycelium sheet producing system includes a culture unit, a spore stock unit, a plating unit, a section unit, a sub-plating unit, an expanding unit and a colonization unit. The culture unit prepares a monokaryon culture. The spore stock unit grows a plurality of fruit bodies in sterile laboratory conditions to create a spore stock. The plating unit performs a peroxide-based spore rescue and a plating process. The section unit is adaptable to section robust hyphae. The sub-plating unit sub-plates and expands the robust hyphae onto a spawn grain master. The expanding unit subsequently expands the spawn grain master into appropriate production of spawn volume. The colonization unit is adaptable to perform a subsequent colonization of mycelium substrate thereby creating a substantially defect free sheet of mycelium.

The present disclosure relates to the field of ecological restoration of a coal gangue hill, and in particular, to a solid waste-based porous material, a method for preparing the solid waste-based porous material, and a method of ecological restoration of the coal gangue hill by applying the solid waste-based porous material. A coal-based solid waste restoration material and mycorrhizal solid bacterial agent are mixed to restore the coal gangue hill, the coal-based solid waste restoration material is prepared by mixing coal-based solid waste porous materials, low-rank coal, and waste organic matter and adding a microbial quickly decomposition agent for aerobic fermentation and standing.

The present disclosure relates to the field of ecological restoration of a coal gangue hill, and in particular, to a solid waste-based porous material, a method for preparing the solid waste-based porous material, and a method of ecological restoration of the coal gangue hill by applying the solid waste-based porous material. A coal-based solid waste restoration material and mycorrhizal solid bacterial agent are mixed to restore the coal gangue hill, the coal-based solid waste restoration material is prepared by mixing coal-based solid waste porous materials, low-rank coal, and waste organic matter and adding a microbial quickly decomposition agent for aerobic fermentation and standing.

Disclosed is a landscaped surface applicable to all types of vehicles, which includes a frame with a settling base that rests on a detachable supporting element or directly on the roof of the vehicle, inside which there are separator partitions and a root development base made of flexible and light hydrophilic material, with a reticular structure that retains a volume of water of between 10 and 30 times the weight thereof, expelling the excess via drainage openings arranged in the lower area of its vertical face of the frame. There is a layer of covering vegetation on the root development base and a mesh secured to a fastening flap in the high part of the frame.

A device and a method for breeding blueberry-specific mycorrhizal fungi. The device includes a container, where a bottom of the container is laid with perlite to form a perlite layer; an absorbent cotton is arranged on the perlite layer; a hole for planting is provided in the absorbent cotton and blueberry tissue culture seedlings or moss seedlings are placed in the hole; and a spore transfer solution is provided around the blueberry tissue culture seedlings or moss seedlings. When used as a bacterial fertilizer for inoculation in the field, the pieces of absorbent cotton are buried directly around the blueberry roots; while used for research, one of the pieces of the absorbent cotton is washed with sterile water and filtered with a filter paper to obtain mycorrhizal fungi spores.

A device and a method for breeding blueberry-specific mycorrhizal fungi. The device includes a container, where a bottom of the container is laid with perlite to form a perlite layer; an absorbent cotton is arranged on the perlite layer; a hole for planting is provided in the absorbent cotton and blueberry tissue culture seedlings or moss seedlings are placed in the hole; and a spore transfer solution is provided around the blueberry tissue culture seedlings or moss seedlings. When used as a bacterial fertilizer for inoculation in the field, the pieces of absorbent cotton are buried directly around the blueberry roots; while used for research, one of the pieces of the absorbent cotton is washed with sterile water and filtered with a filter paper to obtain mycorrhizal fungi spores.