A system comprising a respirator, a biochip, and an atomizer for studying respiratory pathogens. The respirator of the system is configured to create breathe-mimicking air movement, the biochip comprises an airway lumen in fluid communication with the respirator, and the atomizer is in fluid communication with the airway lumen of the biochip, according to various embodiments. The atomizer may be configured to generate droplets of a respiratory pathogen (e.g., from liquid inoculum). In various embodiments, the breath-mimicking air movement comprises air volume as a function of time, wherein the respirator is configured to generate breathing cycles.

A bioreactor for growing micro-organisms in a reaction mixture including a reaction medium and micro-organisms. The bioreactor includes a first reaction chamber, a second reaction chamber and means for connecting the first reaction chamber to the second reaction chamber. The first reaction chamber has first volume for containing first number of micro-organisms, a first input for providing reaction mixture thereto, and a first output for removing excess gases therefrom. The second reaction chamber, arranged downstream from first reaction chamber, has a second volume for containing a second number of micro-organisms, a second input for providing gases thereto, and a second output for removing reaction mixture therefrom. The means for connecting is the sole input for allowing the reaction mixture to flow from the first reaction chamber to the second reaction chamber and for gases to flow from the second reaction chamber to the first reaction chamber.

The present invention relates to a laboratory device, wherein the laboratory device has an outer housing which defines an interior of the device, wherein the laboratory device is designed to assume an operating state at which a pressure in the interior of the device is lower than an ambient pressure in the environment of the laboratory device. The present invention also relates to the use of the laboratory device in a clean room.

The present disclosure provides systems and methods for recycling gas in a reactor. An example of gas-recycling system comprises: a housing, a gas conduit, and a powered propeller. The housing encloses a gas space and a liquid space, wherein the gas space is configured to collect gas within a reactor. The powered propeller comprises a shaft having an upper end and a lower end; and a plurality of radial blades connected to the lower end of the shaft. Upon rotation of the powered propeller, the powered propeller is configured to: generate a suction to cause the collected gas to flow from the gas space to the liquid space through the conduit; cause fluid of the reactor to flow in a direction from the upper end of the shaft to the lower end of the shaft; and mix the liquid and the collected gas proximate the powered propeller.

Microorganisms present within a plurality of microorganism clusters immobilized in a porous support material may collectively define a supported bio-catalyst. When the microorganisms are effective to convert methane into one or more oxidized carbon compounds (e.g., methanotrophic bacteria), the supported bio-catalysts may be utilized to remove methane from methane-containing gas streams, such as those obtained from mining ventilation. Methods for processing a methane-containing gas stream may comprise interacting the gas stream with the supported bio-catalyst in substantial absence of a liquid phase, and obtaining a methane-depleted gas stream downstream from the supported bio-catalyst. Systems for processing a methane-containing gas stream may comprise the supported bio-catalysts housed in one or more vessels fluidly coupled to a source of methane-containing gas stream. A gas concentration in the methane-containing gas stream and/or the methane-depleted gas stream may be used to determine a current state or anticipated remaining lifetime of the supported bio-catalyst.

An object of the present invention is to provide a novel approach capable of conveniently and efficiently removing air that has entered a cell culture bag at the time of addition of a culture medium. The present invention provides a system for culturing cells or cell aggregates using a cell culture bag, the cell culture bag having a lower face comprising a plurality of recesses, the culturing system comprising a mechanism which removes air in the cell culture bag through the cell culture bag by applying a pressure before cell addition to the cell culture bag supplemented with a culture medium.

A method for filtering a gas includes delivering a gas into a compartment of a gas filter assembly; applying a partial vacuum to the gas filter assembly so that the partial vacuum assists in drawing the gas through a porous filter body of the gas filter assembly that is at least partially disposed within the compartment of the gas filter assembly; and regulating the application of the partial vacuum based on a pressure reading of the gas upstream or downstream of the gas filter assembly.

Reactors, systems and processes for the production of biomass by culturing microorganisms in aqueous liquid culture medium circulating inner loop reactor which utilize nonvertical pressure reduction zones are described. Recovery and processing of the culture microorganisms to obtain products, such as proteins or hydrocarbons is described.

Algae harvesting and cultivating systems and methods for producing high concentrations of algae product with minimal energy. In an embodiment, a dead-end filtration system and method includes at least one tank and a plurality hollow fiber membranes positioned in the at least one tank. An algae medium is pulled through the hollow fiber membranes such that a retentate and a permeate are produced.

A Petri dish (100) base (300) and lid (200) each having a substantially circular, substantially flat region from which sidewalls extend perpendicular to the flat region (312) forming a corner (326), (230). The base may have a base stacking ring (325) extending from the base (300) at the corner (326), and an internal channel (330) around the inside of the base (300) at the corner (326). The base (300) may have a uniform cross-sectional thickness (350) and may also have vents (322) in the base stacking ring (325). The lid (200) may have a uniform cross-sectional thickness (250). The lid (200) may have a lid stacking ring (225) at the corner (230), which forms a groove (240) in the interior (212) of the lid (200) at the corner (230). The lid may also have ribs (295) and vents (222) to enable multiple dishes to be stacked without forming a vacuum.