A novel method of growing fungi is disclosed which uses an engineered artificial media and produces high density filamentous fungi biomats that can be harvested with a minimum of processing and from which fungal products such as antibiotics, proteins, and lipids can be isolated, the method resulting in lowered fungus cultivation costs for energy usage, oxygenation, water usage and waste stream production.

A novel method of growing fungi is disclosed which uses an engineered artificial media and produces high density filamentous fungi biomats that can be harvested with a minimum of processing and from which fungal products such as antibiotics, proteins, and lipids can be isolated, the method resulting in lowered fungus cultivation costs for energy usage, oxygenation, water usage and waste stream production.

A novel method of growing fungi is disclosed which uses an engineered artificial media and produces high density filamentous fungi biomats that can be harvested with a minimum of processing and from which fungal products such as antibiotics, proteins, and lipids can be isolated, the method resulting in lowered fungus cultivation costs for energy usage, oxygenation, water usage and waste stream production.

Set forth herein is a composition that includes a fungal pellet and animal cells, wherein the animal cells are in connection with the fungal pellet. The animal cells can be located on the exterior surface of the fungal pellet, the interior of the fungal pellet, or both. The fungal pellet can include intact fungal cells. The fungal pellet can be substantially inviable. In an example, the pellet can be heat-treated, chemically treated, or lyophilized. The animal cells can be mammalian cells, wherein the mammalian cells may be non-human mammalian cells.

The present invention relates generally to the field of degrading polyurethane (PU), for example PU layers in multi-layer packaging. For example, the present invention relates to a method of degrading polyurethane (PU) comprising the step of subjecting the PU to an enzyme cocktail comprising at least one lipase and at least one cutinase. The PU may be a PU-based layer in a multilayer packaging structure comprised in a packaging. Remarkably, the subject matter of the present invention allows the efficient selective degradation of PU containing layers in multi-layer packaging materials.

A novel method of growing fungi is disclosed which uses an engineered artificial media and produces high density filamentous fungi biomats that can be harvested with a minimum of processing and from which fungal products such as antibiotics, proteins, and lipids can be isolated, the method resulting in lowered fungus cultivation costs for energy usage, oxygenation, water usage and waste stream production.

Provided is a Saccharomyces cerevisiae strain deposited under Accession No. KCTC 14268BP; a cosmetic composition, a quasi-drug composition, or a food composition, each including any one or more selected from the group consisting of the strain, a culture thereof, and a fermentation product thereof; a method of improving the skin using the strain, the culture thereof, and the fermentation product thereof; and use of the strain, the culture thereof, and the fermentation product thereof, for the skin improvement.

The present invention provides a fungus of the genus Rhizopus having high productivity of an organic acid. The present invention also provides a mutant of the genus Rhizopus with reduced pyruvate decarboxylase activity.

The present application relates to a Rhizopus oligosporus CJCC02-20 strain deposited with Accession No. KCCM12893P and application thereof.

A novel method of growing fungi is disclosed which uses an engineered artificial media and produces high density filamentous fungi biomats that can be harvested with a minimum of processing and from which fungal products such as antibiotics, proteins, and lipids can be isolated, the method resulting in lowered fungus cultivation costs for energy usage, oxygenation, water usage and waste stream production.