The present disclosure relates to a method for establishing an oral ulcer animal model with Yin-deficiency and fire-excess syndrome based on sleep deprivation, comprising the following steps of: burning buccal mucosa of a rat with phenol to cause a white injury, and obtaining the oral ulcer animal model after 24-48 h; placing the animal model in a sleep deprivation device for 2-7 days; wherein the device is composed of a mouse box in which a plurality of platforms with a diameter of 4-8 cm are arranged at an interval of 10-20 cm from each other; and water is filled among the platforms, and the platforms are about 0.1-2 cm higher than a water surface. The present disclosure overcomes the defects of single evaluation index, short model duration, and unconformity of etiology and clinic existed in the prior art.

An estimation method performed by a computer includes: executing a first identifying process that includes identifying a candidate for a limb having a problem by evaluating left and right balance at the time of movement based on measurement data of a motion sensor attached to an animal moving on four limbs, and executing a second identifying process that includes identifying the limb having a problem among the limbs which are considered as the candidates for a limb having a problem based on a detection result of a nutation movement by detecting the nutation movement from the measurement data.

An estimation method performed by a computer includes: executing a first identifying process that includes identifying a candidate for a limb having a problem by evaluating left and right balance at the time of movement based on measurement data of a motion sensor attached to an animal moving on four limbs, and executing a second identifying process that includes identifying the limb having a problem among the limbs which are considered as the candidates for a limb having a problem based on a detection result of a nutation movement by detecting the nutation movement from the measurement data.

Compositions of peritoneal dialysis solutions and metabolizing enzymes, and their uses to treat disorders associated with elevated levels of metabolites are disclosed. Animal models of hyperoxalemia are also disclosed.

Compositions of peritoneal dialysis solutions and metabolizing enzymes, and their uses to treat disorders associated with elevated levels of metabolites are disclosed. Animal models of hyperoxalemia are also disclosed.

The current invent relates to the construction and application of a three-line breeding system in the Peruvian scallop×bay scallop hybrids. The said three-line consists of a male sterile line, a maintainer line and a restorer line. A combination of male sterile line and maintainer line is obtained by continuously backcrossing the male sterile individuals selected from F.sub.1 inter-specific hybrid families with sperm of the selfing family of the sperm-providing bay scallops until the progenies are all male sterile. The restorer line is obtained by continuously backcrossing selected individuals from the male sterile line with sperm of the selfing family of a bay scallop until the progenies are all hermaphroditic and exhibit excellent production traits. Commercial male sterile brood stocks are produced by backcrossing the male sterile line with the maintainer line and commercial hybrid spats are produced by backcrossing the male sterile line and the restorer line.

The invention concerns a gallinacean embryo in which cancer cells have been grafted within the embryo tissue, characterised in that the embryo is at a developmental stage between the HH10 and HH25 stages at the time of the grafting, wherein said cancer cells are not neuroblastoma cells and said cells form tumors inside the embryo.

A device for rapid non-destructive genetic material collection can include a multi-reservoir array (202) and a movement mechanism. The multi-reservoir array (202) can include multiple reservoirs (204). A plurality of the multiple reservoirs (204) can include an abrasive surface (210) capable of retaining a source of genetic material in a liquid carrier. The abrasive surface (210) has a roughness. The movement mechanism can be operable to move the multi-reservoir array (202) in an oscillating motion sufficient to create relative movement between the abrasive surface (210) and the source of the genetic material in order to remove a portion of genetic material from the source of the genetic material without destroying the source of the genetic material or the portion of the genetic material that is removed.

A device for rapid non-destructive genetic material collection can include a multi-reservoir array (202) and a movement mechanism. The multi-reservoir array (202) can include multiple reservoirs (204). A plurality of the multiple reservoirs (204) can include an abrasive surface (210) capable of retaining a source of genetic material in a liquid carrier. The abrasive surface (210) has a roughness. The movement mechanism can be operable to move the multi-reservoir array (202) in an oscillating motion sufficient to create relative movement between the abrasive surface (210) and the source of the genetic material in order to remove a portion of genetic material from the source of the genetic material without destroying the source of the genetic material or the portion of the genetic material that is removed.

Provided in the present invention is a chicken whole-genome SNP chip and application thereof. There are a total of 50,000 SNP loci on the chip: including 19,600 SNP loci for white-feather broilers, yellow-feather and partridge chickens having a MAF value greater than 0.05 and uniformly distributed across the genome which were derived from the data of the whole-genome resequencing of main indigenous chicken breeds in China and introduced chicken breeds; 14,000 SNP loci associated with economic traits, and 16,400 SNP loci for making up for the genomic regions that are not covered by the first two types of probes. The 50,000 SNP loci on the chicken whole-genome SNP chip of the present invention have DNA sequences represented by SEQ ID NOs. 1 to 50,000. The SNP loci on the chip are uniformly distributed across the whole genome, and associated with traits such as feed efficiency, meat production rate, lipid metabolism, meat quality, general resistance to diseases, reproduction and the like, and the chip has moderate through-put and low cost, and could be used universally for chicken breeds at indigenous and abroad.