A process and an apparatus continuously treat seeds with ultrasonic transmission. The process includes mixing seeds with a flowable medium to create a flowable slurry of seeds; continuously moving the flowable slurry of seeds for a length of a flow pipe through a helical path within the flow pipe; and as the flowable slurry flows through the helical path within the for the length of the flow pipe, subjecting the seeds to ultrasonic transmission created by ultrasonic transducers arranged along the length of the flow pipe. The seeds in the flowable slurry are subjected to the ultrasonic transmission having such waveforms and being transmitted in a manner so as not to damage the seeds and to produce ultrasonically-treated seeds that have regulated germination characteristics, such that plants resulting from the ultrasonically-treated seeds when the seeds are planted have affected growth characteristics. The apparatus effects this process.

A system for sorting seeds based on their resistance to a stress is disclosed. Batches of purified seeds sorted using the system are also disclosed.

A system for sorting seeds based on their resistance to a stress is disclosed. Batches of purified seeds sorted using the system are also disclosed.

Method for sorting corn kernels of a batch of corn kernels, the method comprising the steps of: laying the corn kernel on a support surface, the corn kernel having a resting surface in contact with the support surface, and an upper surface opposite the resting surface, acquiring at least one orientation image of the corn kernel with an orientation imaging system, the orientation imaging system having a modality adapted to enable structural features of the corn kernel to be measured, determining an orientation of the corn kernel with respect to the support surface based on the structural features of the corn kernel measured on the orientation image, sorting the corn kernel as a function of the orientation.

Method for sorting corn kernels of a batch of corn kernels, the method comprising the steps of: laying the corn kernel on a support surface, the corn kernel having a resting surface in contact with the support surface, and an upper surface opposite the resting surface, acquiring at least one orientation image of the corn kernel with an orientation imaging system, the orientation imaging system having a modality adapted to enable structural features of the corn kernel to be measured, determining an orientation of the corn kernel with respect to the support surface based on the structural features of the corn kernel measured on the orientation image, sorting the corn kernel as a function of the orientation.

The present invention provides a method for improving salt tolerance of a plant so as to enable the plant to be cultivated under a high salt concentration condition. The present invention discloses a method for improving salt tolerance of a plant, including suppressing or inhibiting a function of PERK13 (Proline-rich extensin-like receptor kinase 13) in a plant; the method for improving salt tolerance of a plant, wherein an antagonist of PERK13 is brought into contact with a root of the plant; the method for improving salt tolerance of a plant, wherein the antagonist is one or more species of microorganisms or a secretion therefrom; and the method for improving salt tolerance of a plant, wherein the suppression of the function of the PERK13 is carried out by suppressing expression of PERK13 gene, or the inhibition of the function of the PERK13 is carried out by inhibiting expression of PERK13 gene.

The present invention provides a method for improving salt tolerance of a plant so as to enable the plant to be cultivated under a high salt concentration condition. The present invention discloses a method for improving salt tolerance of a plant, including suppressing or inhibiting a function of PERK13 (Proline-rich extensin-like receptor kinase 13) in a plant; the method for improving salt tolerance of a plant, wherein an antagonist of PERK13 is brought into contact with a root of the plant; the method for improving salt tolerance of a plant, wherein the antagonist is one or more species of microorganisms or a secretion therefrom; and the method for improving salt tolerance of a plant, wherein the suppression of the function of the PERK13 is carried out by suppressing expression of PERK13 gene, or the inhibition of the function of the PERK13 is carried out by inhibiting expression of PERK13 gene.

A liquid treating conveyor system that can apply a metered liquid treatment to a metered stream of seed within the conveyor, with either the rate of the seed or treatment fluid regulated. The conveyor has a curved structure. A belt conformed to the curved structure carries a bed of seed through the conveyor. A liquid dispenser distributes a treatment across the seed bed. The liquid may enter the liquid dispenser at low pressure for low shear applications. Liquid dispensers may be spaced apart along a portion of the conveyor. Gas outlet ports and mixing baffles may be disposed within the conveyor. A liquid channel may be disposed within a mixing baffle to direct flow of treatment from the liquid port to an outlet port in contact with the seed bed.

An automated method for sampling seeds generally includes removing material from a seed at an automated sampling station and then, after removing the material from the seed, detecting, by at least one sensor, movement of the seed out of the automated sampling station. The automated method may also include, after removing the material from the seed, transferring the seed from the automated sampling station to a seed container and transferring the material removed from the seed from the automated sampling station to a sample container.

An automated method for sampling seeds generally includes removing material from a seed at an automated sampling station and then, after removing the material from the seed, detecting, by at least one sensor, movement of the seed out of the automated sampling station. The automated method may also include, after removing the material from the seed, transferring the seed from the automated sampling station to a seed container and transferring the material removed from the seed from the automated sampling station to a sample container.