Abstract: 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.

Abstract: A panel of mycological polymer consisting entirely of fungal mycelium as described in U.S. patent application Ser. No. 16/190,585 is post-processed to impart desired characteristics thereto, such as, texture, flavor and nutritional profile for use as a foodstuff or a tissue scaffold. Alternatively, the growth conditions of the growth media may be tailored to obtain a desired density, morphology, and/or composition of the undifferentiated fungal material with or without the use of post-processes.

Abstract: A method of producing a mycological composite material comprises inoculating a substrate of fibrous material with an inoculum of mycelial tissue; rolling the inoculated substrate into a roll; and thereafter incubating the rolled inoculated substrate for a time sufficient for the mycelial tissue to grow hyphae that enmesh with the substrate to form a cohesive unified filamentous network with the rolled inoculated substrate being characterized in being flexible. The rolled inoculated substrate may be subsequently processed by subjecting lengths of the roll to heat and pressure in molds to form rigid products.

Abstract: The product is made, in part, of a network of interconnected mycelia cells forming a mass. In one embodiment, the mass includes one or more embedded elements, such as a panel. In another embodiment, the mass is formed over a three-dimensional lattice. The mycelia cells form hyphae that bond directly to panels made of cellulosic materials.

Abstract: The mycelial foam contains macroscopic void spaces that are formed by filler elements, such as agar beads, that are incorporated in the mycelial matrix during growth of the matrix and are removed from the matrix after growth in a non-destructive manner, such as by heating. The foam may be made of pure mycelium or may be a composite biomaterial.

Abstract: The process for producing mycelium biomaterial provides two phases of incubation. In a first phase of fungal expansion, the fungal inoculum is allowed to expand and dominate the substrate. In a second phase, nutrient is added to the inoculated mixture to allow the fungal inoculum to bond the discrete particles into a self-supporting biocomposite. The process allows for the processing of grown materials in separate vessels with the second vessel providing the final shape of the biomaterial.

Abstract: The process for producing mycelium biomaterial provides fresh oxygen to the growing mycelium biomaterial while removing waste heat and waste carbon dioxide by forced aeration through large volumes of material. In a first phase of fungal expansion, humidified air at a programmed temperature is passed upwardly and through a fungal inoculated substrate of discrete particles to allow the fungal inoculum to expand and dominate the substrate. Nutrient is added to the inoculated mixture and a second phase of fungal expansion is performed wherein humidified air at a programmed temperature is passed upwardly and through the nutrient enriched fungal inoculated substrate to allow the fungal inoculum to bond the discrete particles into a self-supporting biocomposite. The process and apparatus of the invention allows for the processing of grown materials bound by mycelium at depths of greater than 6? and particularly in the range of from 24? to 28?.

Abstract: The process of making a mineralized mycelium scaffolding requires obtaining a scaffold of fungal biopolymer having a network of interconnected mycelia cells, functionalizing the biopolymer to create precursor sites and thereafter mineralizing the scaffold with one of silicates, apatites and carbonates. The mineralized mycelium scaffolding may be used for medical applications in place of mineralized collagen membranes and collagen/hydroxyapatite composite scaffolds.

Abstract: The process of making a biocomposite material utilize a bacterial species and a fungal species in an agricultural feedstock composed of a substrate of non-nutrient discrete particles and a nutrient material wherein the bacterial species imparts mechanical properties to the biocomposite material and the fungal species binds the biocomposite material. Both bacterium and fungus can be genetically engineered to produce desired properties within the microbial communities.

Abstract: A method of fermenting mycelium composite materials wherein layers of fermentable material are stacked in alteration with ventilation layers with air being passed through the ventilation layers to remove heat and gas generated in the layers of fermentable material during fermentation thereof. The obtained composite materials may be formed into cohesive flat boards, such as are used in the manufacture of insulation or furniture.

Abstract: The process aseptically inoculates a liquid media with a vegetative Xylaria fungal species to form a culture; statically incubates the culture in a vessel for a time sufficient to begin initiation of fruit body development and asexual sporulation and halts incubation at maximum conidia production prior to the beginning of sexual sporulation. Thereafter, the entire culture contents of the incubation vessel are macerated to homogenize the fungal biomass and conidia therein and form an inoculum.

Abstract: A growth medium formed as an inoculum including a preselected fungus and a nutrient material capable of being digested by the fungus is placed in or on a tool formed of a material capable of being at least partially consumed by the fungus. The tool may define a cavity of predetermined shape for the growth medium or the tool may form a scaffolding on which the growth medium grows into the final product taking on the shape of the tool.

Abstract: A growth medium formed as an inoculum including a preselected fungus and a nutrient material capable of being digested by the fungus is placed in or on a tool formed of a material capable of being at least partially consumed by the fungus. The tool may define a cavity of predetermined shape for the growth medium or the tool may form a scaffolding on which the growth medium grows into the final product taking on the shape of the tool.

Abstract: A self-supporting composite body comprising a substrate of discrete particles and a network of interconnected mycelia cells extending through and around the discrete particles and bonding the discrete particles together is characterized in being stiff and in having a density of greater than 18 pounds per cubic foot (pcf). The method of making the composite body includes compressing a mass of biocomposite material comprised of discrete particles and a network of interconnected mycelia cells in the presence of moisture into a compressed body having a density in excess of 18 pcf. Compression may take place batch wise in a press or continuously between a pair of movable endless conveyors.

Abstract: The method of making a composite biomaterial employs a binding organism (a filamentous fungi that produce mycelium) based on the material physical properties required for the composite biomaterial and a modulating organism (bacteria, fungus or yeast) based on a desired effect of the modulating organism on the binding organism. The modulating organism is selected based on the desired effect on the binding organism.

Abstract: In one embodiment, the process combines a fraction (up to 15%) of a lignocellulose substrate with supplemental nutritional material and hydrates the fraction to a moisture content of from 40% to 70% by weight. The hydrated substrate fraction is heat processed to remove ambient bioburden (yeast, mold, bacteria) and to maintain the hydrated substrate fraction in an aseptic condition. Thereafter, the hydrated substrate fraction is inoculated with a fungus and incubated to obtain a myceliated substrate which is then reduced into discrete particles. The remaining fraction of the substrate is combined with water and then combined with the discrete particles of myceliated substrate and incubated to obtain a second myceliated substrate which is then reduced into discrete particles. The second myceliated substrate is combined with supplemental nutritional material and incubated to obtain a third myceliated substrate composed of at least 10% mycelium.

Abstract: The process of growing a homogeneous polymer matrix comprising the steps of growing a viable mycelium in a liquid suspension; extracting mycelium from the liquid suspension; thereafter incubating the mycelium for a period of time sufficient to induce mycelium cohesion and to form a solid material; and thereafter drying the solid material to remove moisture and to inactivate the mycelium.

Abstract: The composite material is comprised of a substrate of discrete particles and a network of interconnected mycelia cells bonding the discrete particles together. The composite material forms a core to which one or more boards of veneer material are bonded to form a panel.

Abstract: A living hydrated mycelium composite containing at least one of a combination of mycelium and fibers, mycelium and particles, and mycelium, particles and fibers is processed with a nutrient material to promote mycelia tissue growth; thereafter dehydrated to a moisture content of less than 50% by weight to deactivate the further growth of mycelia tissue; and then stored. The stored dehydrated mycelium composite is further processed by rehydrating to reactivate the mycelium and to initiate growth of at least one fruiting body.

Abstract: A self-supporting composite material is made with a shape conforming to the shape of an enclosure within which the composite material is incubated and molded. In on embodiment, a lid with at least one extrusion is placed over the enclosure to form a void in the final product corresponding to the extrusion. In another embodiment, a tool with extruded features is pressed into a face of the product in the enclosure to mold features into the finished product.