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 gate apparatus includes: an exit gate door; a first biometrics information acquisition unit that acquires, from a user who moves toward the exit gate door in a closed state, first target biometrics information to be compared with registered biometrics information registered in advance; a second biometrics information acquisition unit that acquires second target biometrics information to be compared with the registered biometrics information from the use who stops in front of the exit gate door when there is no matching in a comparison between the first target biometrics information and the registered biometrics information or the comparison is unable to be performed; and a door control unit that opens the closed exit gate door in accordance with a result of a comparison between the first target biometrics information or the second target biometrics information and the registered biometrics information.

An aquaponics and greenhouse system, includes a solar greenhouse insulated on north, east and west sides and with glazing on a south side at an angle to maximize winter sunlight, and housing a fish tank, grow beds, and a hard filter. The grow beds and hard filter include geyser pumps in the fish tank powered by air pumps that pump water from the fish tank to the grow bed or hard filter and aerate fish tank water. The hard filter includes algae layer with an air stone powered by an air pump underneath to aerate the algae. Grow beds on the north side have a barrier layer over media, and with a mushroom bulk substrate layer disposed thereover. The air intake of the air pump of the hard filter or the air stone extract CO2 from the mushroom bulk substrate and pump the extracted CO2 to the algae layer.

A method of growing an extra-particle aerial mycelium employs electrostatically charged mist to control mist deposition uniformity in a growth environment, and on a growth matrix (or growing extra-particle aerial mycelium on a growth matrix) comprising nutritive substrate and a fungus in a growth environment with a predetermined environment of humidity, temperature, carbon dioxide, and oxygen. Control of mist deposition by electrostatically charging mist allows for control of the morphology and uniformity of the extra-particle aerial mycelium produced, independent of airflow uniformity, growth environment size, and structural obstacles that may be present within a growth environment. Control of mist deposition by electrostatically charging mist also offers the potential for targeted mist application where it might be needed most for fungal organism growth.

A mushroom compost leveling apparatus includes a panel with a bottom edge where the panel is vertically suspended in a mushroom compost receptacle leaving a gap between the bottom edge and the floor of the receptacle. The panel reciprocates from side to side as mushroom compost is conveyed under the panel. Optionally, the panel includes vanes extending outwardly from a first face surface, and a rake outwardly and downwardly extending from the panel at or near the bottom edge. Optionally, a pair of wheels are mounted for rotation either to the first face of the panel or to a rail of a frame to be isolated from the panel, and the wheels each include paddles that push compost toward the side edges of the mushroom compost receptacle as the wheels are rotated. Optionally, the leveling apparatus is removably attached to sleeves depending over sidewalls of the compost receptacle, and a roller assembly is removably attached to such sleeves downstream of the leveling apparatus.

A mushroom compost leveling apparatus includes a panel with a bottom edge where the panel is vertically suspended in a mushroom compost receptacle leaving a gap between the bottom edge and the floor of the receptacle. The panel reciprocates from side to side as mushroom compost is conveyed under the panel. Optionally, the panel includes vanes extending outwardly from a first face surface, and a rake outwardly and downwardly extending from the panel at or near the bottom edge. Optionally, a pair of wheels are mounted for rotation either to the first face of the panel or to a rail of a frame to be isolated from the panel, and the wheels each include paddles that push compost toward the side edges of the mushroom compost receptacle as the wheels are rotated. Optionally, the leveling apparatus is removably attached to sleeves depending over sidewalls of the compost receptacle, and a roller assembly is removably attached to such sleeves downstream of the leveling apparatus.

A fungal growth structure comprising a nutritive vehicle, a porous material, an administrable space. fungal tissue comprising fungal hyphae having a growth pattern, the fungal tissue connecting said nutritive vehicle to said porous material to said administrable space, wherein the fungal tissue within said space defines at least one successive fungal material layer; and a chemically or physically altered separated portion of fungal material, the separated portion separated from said fungal tissue.

A fungal growth structure comprising a nutritive vehicle, a porous material, an administrable space. fungal tissue comprising fungal hyphae having a growth pattern, the fungal tissue connecting said nutritive vehicle to said porous material to said administrable space, wherein the fungal tissue within said space defines at least one successive fungal material layer; and a chemically or physically altered separated portion of fungal material, the separated portion separated from said fungal tissue.

A gate apparatus includes: an exit gate door; a first biometrics information acquisition unit that acquires, from a user who moves toward the exit gate door in a closed state, first target biometrics information to be compared with registered biometrics information registered in advance; a second biometrics information acquisition unit that acquires second target biometrics information to be compared with the registered biometrics information from the use who stops in front of the exit gate door when there is no matching in a comparison between the first target biometrics information and the registered biometrics information or the comparison is unable to be performed; and a door control unit that opens the closed exit gate door in accordance with a result of a comparison between the first target biometrics information or the second target biometrics information and the registered biometrics information.

A method of forming fungal materials and fungal objects from those fungal materials, the method comprising the steps of growing a first fungal tissue in contact with a nutritive vehicle; supplying a porous material in contact with said first fungal tissue; directing growth of said fungal tissue through said porous material such that a portion of said fungal tissue comprises a first fungal material having first fungal hyphae; optionally incorporating composite material; directing a change in the composition or growth pattern of at least some of said first fungal hyphae; separating at least a portion of the first fungal material from said nutritive vehicle; obtaining a second fungal material having second fungal hyphae; and forming a fungal object by encouraging fused growth between said first fungal material and said second fungal material and optionally incorporating composite material.