A methane fermentation system which can efficiently generate methane gas is provided. The methane fermentation system decomposes an organic waste with an anaerobic microorganism to cause methane fermentation so as to generate the methane gas. The methane fermentation system includes a wet bead mill which finely pulverizes the organic waste. The methane fermentation system also includes a methane fermentation chamber in which the organic waste finely pulverized in the wet bead mill is decomposed with the anaerobic microorganism to cause the methane fermentation so as to generate the methane gas.

A device configured for lysing a sample includes a holding element configured to hold an energy-transmitting element such that the holding element lies around the held part of the energy-transmitting element and envelops the held part of the energy-transmitting element and/or that the holding element lies against the held part of the energy-transmitting element. The holding element is further configured to cause lysis with the energy-transmitting element when the holding element is immersed into the sample to be subjected to lysis or comes into contact with the sample to be subjected to lysis. A method includes inserting the energy-transmitting element into the holding element. A system configured for lysing a sample by way of ultrasound includes the device and the energy transmitting element.

Processes for grinding corn, ground corn products, and processes for making ethanol from the ground corn products. In some examples, a process for making ethanol can include introducing a plurality of corn pieces into a mill. The process can also include milling the corn pieces in the mill to produce a ground corn product. Greater than 25 wt % of the ground corn product can have a particle size of greater than 105 μm, as measured according to AOAC 965.22-1966. Greater than 80 wt % of the ground corn product can have a particle size of 425 μm or less, as measured according to AOAC 965.22-1966. The process can also include processing the ground corn product to produce a fermentation mash that can include ethanol and separating at least a portion of the ethanol from the fermentation mash to produce a stillage.

A fat cutter and an integrated machine for preparation of in vitro fine-particle fat are provided. The fat cutter includes a fat inlet channel, a fat outlet channel, at least one set of blades disposed between an outlet of the fat inlet channel and an inlet of the fat outlet channel, and a housing that seals a space in which the outlet of the fat inlet channel, the inlet of the fat outlet channel, and the blades are located. A fat inlet of the fat inlet channel is connected to a large-diameter liposuction tube by a liposuction channel, and a fat outlet of the fat outlet channel is connected to a high-negative pressure device. The outlet of the fat inlet channel and the inlet of the fat outlet channel are oppositely provided, and a gap therebetween matches the thickness of the blades.

There is provided a cell mass dissociator including a serpentine flow path which is a flow path through which a cell mass flows.

A system to process a waste food includes a housing; at least one drum enclosed in the housing where the waste food is mixed up and digested by microorganisms or dehydrated; and at least one cleaner incorporated in or on the machine to permit a jet of water to be turned on and off to clean the drum.

A device for mechanical fragmentation of tissues facilitates preparation of the composition of isolated cells from a tissue sample, the preparation including mechanical fragmentation of the tissue, the device including a motorized support and a container, the motorized support including a motor having a rotor secured to a coupling member, the container internally including a rotary shaft with radial arms sweeping the inside of the container as the shaft rotates, the motorized support and the container including a complementary securing unit that allow the container to be immobilized on the motorized support, the coupling member and the rotary shaft being configured in such a way as to allow axial rotation of the rotary shaft when the rotor of the motor is turning. The radial arms are of two types: rigid vane-type arms, and flexible filamentary-type arms, notably made of nylon or of metal. A corresponding method is also disclosed.

A tool for fixating and handling membrane-shaped tissue for research or clinical use includes a platform having a base plate with at least one positioning element for positioning a spanning element on the platform, at least one round shaped spanning element adapted for being positioned on the platform using the positioning element, at least one flexible element for positioning over the round shaped spanning element for spanning the membrane shaped tissue, and at least one handling means for handling the flexible element during positioning of the flexible element over the round shaped spanning element, and for handling the combination of the round shaped spanning element and the flexible element, when the membrane is spanned over the round shaped spanning element.

Methods and devices are disclosed for processing stromal precursor cells (i.e., cells which can differentiate into connective tissue cells, such as in muscles, ligaments, or tendons) which can be obtained from fatty tissue extracts obtained via liposuction. Normal processing of a liposuction extract involves centrifugation, to concentrate the stromal cells into a semi-concentrated form called “spun fat”. That “spun fat” can then be treated by mechanical processing (such as pressure-driven extrusion through 0.5 mm holes) under conditions which can gently pry the stromal cells away from extra-cellular collagen fibers and other debris in the “spun fat”. The extruded mixture is then centrifuged again, to separate a highly-enriched population of stromal cells which is suited for injection back into the patient (along with platelet cells, if desired, to further promote tissue repair or regeneration).

A tray for processing platelet rich fibrin includes a base having at least one alignment structure, a screen attachment having at least one alignment structure for engagement with the base, and a lid having at least one alignment structure for engagement with the base and the screen attachment. The screen attachment includes a screen offset between the top and bottom surface of the screen. When the screen attachment is placed on the base with the top surface facing upward, the lid is configured to compress a fibrin clot placed on the screen to a first thickness, and when the screen attachment is placed on the base with the bottom surface facing upward the lid is configured to compress a fibrin clot placed on the screen to a second thickness different from the first thickness.