The present application provides a prognostic marker for lung cancer, a prognostic typing model for lung cancer, and applications thereof. The marker includes imprinted genes Dcn, Peg10, Snrpn/Snurf, and Trappc9. The four imprinted genes Dcn, Peg10, Snrpn/Snurf, and Trappc9 used in the present application have a significant correlation with lung cancer prognosis. Imprinted gene Dcn is the most sensitive and most specific marker for lung cancer prognosis and can serve an indicative purpose earlier than clinicopathologic features. The product of a total expressed quantity of each of the four imprinted genes and an expressed quantity of the imprinted gene with a copy number variation contributes to creating the prognostic typing model for lung cancer, thereby enabling the prediction of the five-year survival rates of individual lung cancer patients and the provision of accurate, useful prognosis information to lung cancer patients.

The present application provides a prognostic marker for lung cancer, a prognostic typing model for lung cancer, and applications thereof. The marker includes imprinted genes Dcn, Peg10, Snrpn/Snurf, and Trappc9. The four imprinted genes Dcn, Peg10, Snrpn/Snurf, and Trappc9 used in the present application have a significant correlation with lung cancer prognosis. Imprinted gene Dcn is the most sensitive and most specific marker for lung cancer prognosis and can serve an indicative purpose earlier than clinicopathologic features. The product of a total expressed quantity of each of the four imprinted genes and an expressed quantity of the imprinted gene with a copy number variation contributes to creating the prognostic typing model for lung cancer, thereby enabling the prediction of the five-year survival rates of individual lung cancer patients and the provision of accurate, useful prognosis information to lung cancer patients.

Methods and systems for mRNA analysis and quantification of mRNA expression in cells are provided. An example method includes introducing a first capture probe and a second capture probe into the cells, the first capture probe and the second capture probe each configured to be complementary to a respective section of target mRNA within the cells, wherein binding of the first and second capture probes to the respective sections of the target mRNA results in tagging of the cells and causes the first and second capture probes to form clusters with each other. The first capture probe and the second capture probe are each bound to magnetic nanoparticles (MNPs) that, when trapped within the tagged cells, cause the tagged cells to be susceptible to magnetic forces. The method and system further include introducing the cells into a device configured to magnetically capture tagged cells.

Methods and systems for mRNA analysis and quantification of mRNA expression in cells are provided. An example method includes introducing a first capture probe and a second capture probe into the cells, the first capture probe and the second capture probe each configured to be complementary to a respective section of target mRNA within the cells, wherein binding of the first and second capture probes to the respective sections of the target mRNA results in tagging of the cells and causes the first and second capture probes to form clusters with each other. The first capture probe and the second capture probe are each bound to magnetic nanoparticles (MNPs) that, when trapped within the tagged cells, cause the tagged cells to be susceptible to magnetic forces. The method and system further include introducing the cells into a device configured to magnetically capture tagged cells.

The present invention relates to a tumor marker, a methylation detection reagent, a kit and use thereof. By detecting the methylation level of SDC2, COL4A1/COL4A2 and ITGA4 genes, colorectal cancer specimens can be well distinguished from fecal specimens, and the detection sensitivity and specificity for the colorectal cancer can be 90% or above.

The present invention relates to a tumor marker, a methylation detection reagent, a kit and use thereof. By detecting the methylation level of SDC2, COL4A1/COL4A2 and ITGA4 genes, colorectal cancer specimens can be well distinguished from fecal specimens, and the detection sensitivity and specificity for the colorectal cancer can be 90% or above.

Disclosed herein is a method of quantifying a mutant allele burden of a target gene in a subject. The method includes providing a first plasmid that includes a mutant allele sequence and an internal control sequence, and a second plasmid that includes a wild-type allele sequence and the internal control sequence, and subjecting DNA of the subject to quantitative polymerase chain reaction to measure a mutant allele expression level of the target gene, so as to determine the mutant allele burden of the target gene in the subject based on a standard curve of the mutant allele burden of the target gene created by serial dilution of the first and second plasmids.

Disclosed herein is a method of quantifying a mutant allele burden of a target gene in a subject. The method includes providing a first plasmid that includes a mutant allele sequence and an internal control sequence, and a second plasmid that includes a wild-type allele sequence and the internal control sequence, and subjecting DNA of the subject to quantitative polymerase chain reaction to measure a mutant allele expression level of the target gene, so as to determine the mutant allele burden of the target gene in the subject based on a standard curve of the mutant allele burden of the target gene created by serial dilution of the first and second plasmids.

A method for determining a patient's susceptibility of contracting a nosocomial infection that includes obtaining a biological sample from the patient and extracting biological material from the biological sample; preparing a specific reagent of an expression product of at least one target gene selected from S100A9 and S100A8 target genes; and determining the expression of at least one of the target genes S100A9 and S100A8, where overexpression relative to a specified threshold value indicates susceptibility of contracting a nosocomial infection.

Provided are vesicles derived from bacteria of the genus Deinococcus and a use thereof. The vesicles significantly decreased in a clinical sample obtained from a patient with cancer, an inflammatory disease, and dementia, compared with a normal individual, and when the vesicles isolated from the strain were administered, the secretion of inflammation mediators caused by pathogenic vesicles such as E. coli-derived vesicles was considerably inhibited, and vesicles derived from bacteria of the genus Deinococcus significantly inhibit cranial nerve cell damage caused by stress hormones, and therefore, the vesicles derived from bacteria of the genus Deinococcus according to the presently claimed subject matter may be effectively used to develop a method of diagnosing cancer, an inflammatory disease, and/or dementia, and a composition for preventing, alleviating, or treating cancer, an inflammatory disease, and/or a cranial nerve disease.