An apparatus is used for growing plants or tissues under aseptic conditions. The apparatus includes a lid and a base compartment. A linking mechanism is provided for connecting the lid and the base compartment. The linking mechanism is provided with a locking mechanism, which is movable from a locked position to an un-locked position and vice-versa. In the locked position, the locking mechanism holds the lid in an abutting closed relation with respect to the base compartment. In the un-locked position, the linking mechanism is provided with means for automatically lifting the lid to an elevated-suspended position with respect to the base compartment thereby providing an access route to reach the base compartment and perform desired operations.

The present disclosure discloses a biological reaction device and a culture method for adventitious roots of panax ginseng C. A. MEY. The biological reaction device includes a tank body, wherein the top of the tank body is provided with a cover body which can be opened and closed, and a bottom of the tank body is provided with at least two air inlet devices. The method includes washing and disinfecting mature ginseng, cutting the disinfected ginseng into slices, inoculating the ginseng slices into an induction medium to induce ginseng adventitious roots, re-inoculating the ginseng adventitious roots into an induction medium for subculture and propagation, then inoculating the obtained ginseng adventitious roots into a shake flask containing a liquid medium for dark culture, and then inoculating the obtained ginseng adventitious roots into a biological reaction device containing a liquid medium for culture to obtain ginseng adventitious roots.

The present invention relates to a culturing apparatus for culturing potato tissue, the culturing apparatus including a culture table including a plurality of vertical frame parts erected to be spaced apart from each other and a horizontal frame part connecting the vertical frame parts, a shelf part which slidably moves on the horizontal frame part, on which a culture container which accommodates a plantlet cultured in a medium is seated and which includes a plurality of hole parts on a bottom surface thereof, a light emitting diode (LED) light source unit that is installed in the culture table and irradiates the culture container with a light beam, a condensation measurement unit that is installed in the shelf part and measures condensation generated in the culture container by irradiating the culture container with infrared rays, and a cooling unit that is installed in the culture table, is electrically connected to the condensation measurement unit, and circulates cooling water passing through the LED light source unit according to condensation information measured by the condensation measurement unit, and thus controls a temperature of the LED light source unit.

An apparatus, system and method for removing and treating contaminated materials on a bottom of a body of water and introducing growth packets to revitalize the treated bottom of the body of water. The structure may comprise a vessel with an open face. The vessel may be lowered down to the bottom of the body of water with the face facing down. As a result, the vessel and the bottom form an isolated space. The structure may comprise at least one agitating device(s) for stirring up the materials inside the vessel so as to form a mixture containing the sediment materials which in turn contain the contaminants. Multiple at least one pipe(s) may be coupled to the vessel for transporting the mixture out of the vessel for processing (filtering, treating with chemicals, etc.) so as to neutralize or eliminate the contaminants in the mixture. Then, the treated mixture can be returned to the inside of the vessel via the at least one pipe(s).

The present invention provides methods for transforming monocot plants via a simple and rapid protocol, to obtain regenerated plants capable of being planted to soil in as little as 4-8 weeks. Associated cell culture media and growth conditions are also provided, as well as plants and plant parts obtained by the method. Further, a method for screening recalcitrant plant genotypes for transformability by the methods of the present invention is also provided. Further, a system for expanding priority development window for producing transgenic plants by the methods of the present invention is also provided.

The invention provides methods for identifying regenerated transformed plants and differentiated transformed plant parts, obtained without subjecting plant cells to selective conditions prior to regenerating the cells to obtain differentiated tissues. In particular embodiments, the plant cells are corn plant cells. Methods for growing and handling plants, including identifying plants that demonstrate specific traits of interest are also provided.

The present invention discloses and claims methods and devices for the rapid mechanical isolation of monocot plant tissues suitable for transformation or tissue culture. The invention includes mechanical devices for substantially isolating target plant tissues for use as transformable explants, and propagation of transgenic plants and plant tissues.

Methods and systems are provided for singulating, orienting, and delivering oriented objects (e.g., embryos) to a desired location (e.g., a plate containing a selected medium).

Examples of an automated micropropagation system for plant tissue culture is provided. The system comprises a culture vessel that comprises a number of detachable culture items that are designed with a plurality of culture cells sized to accept a single plantlet. Such culture vessel is fed into the system to an automated gripper and cutter assembly that is configured to grip the plantlets, cut them and transfer them into a new culture vessel.

A container for effecting at least one non-lethal change in inherent properties of a non-human biological system, such as a plant or a fungus, under the influence of zero gravity, comprising a carrier plate configured to receive two capacitor plates of a plate capacitor, wherein the plates are situated parallel to one another and in each case perpendicularly on the carrier plate, at least one sample container arranged horizontally on the carrier plate, adjacent to each of the two capacitor plates and configured to receive the biological system, and an electromagnet arranged substantially half way between the capacitor plates and, when seen from the carrier plate, arranged horizontally above the at least one sample container. Additionally, a European modular cultivation system for use in the International Space Station comprises a centrifuge, wherein the container is received in the centrifuge.