The present disclosure relates to a structure capable of simultaneously purifying and detecting a nucleic acid by directly applying a sample, and more particularly, to a structure capable of performing sample preparation, loop-mediated isothermal amplification, detection and analysis steps on a single chip by applying lab-on-paper technology, and capable of finally determining whether the disease or bacterial is infected by moving the sample in a lateral flow method and immediately being connected to genetic big data related to disease and bacterial infection.

The present disclosure relates to a structure capable of simultaneously purifying and detecting a nucleic acid by directly applying a sample, and more particularly, to a structure capable of performing sample preparation, loop-mediated isothermal amplification, detection and analysis steps on a single chip by applying lab-on-paper technology, and capable of finally determining whether the disease or bacterial is infected by moving the sample in a lateral flow method and immediately being connected to genetic big data related to disease and bacterial infection.

Aspects of the present disclosure relate generally to methods, compositions, and kits for in situ whole cell barcoding. Aspects of the present disclosure also include a computer readable-medium and a processor to carry out the steps of the method described herein. In some embodiments, the disclosure relates to whole cell barcoding performed in situ.

Aspects of the present disclosure relate generally to methods, compositions, and kits for in situ whole cell barcoding. Aspects of the present disclosure also include a computer readable-medium and a processor to carry out the steps of the method described herein. In some embodiments, the disclosure relates to whole cell barcoding performed in situ.

Aspects of the present disclosure relate generally to methods, compositions, and kits for in situ whole cell barcoding. Aspects of the present disclosure also include a computer readable-medium and a processor to carry out the steps of the method described herein. In some embodiments, the disclosure relates to whole cell barcoding performed in situ.

Provided herein are automated apparatus for the identification of microorganisms in various samples. The disclosure solves existing challenges encountered in identifying and distinguishing various types of microorganisms, including viruses and bacteria in a timely, efficient, and automated manner by sequencing.

Provided herein are automated apparatus for the identification of microorganisms in various samples. The disclosure solves existing challenges encountered in identifying and distinguishing various types of microorganisms, including viruses and bacteria in a timely, efficient, and automated manner by sequencing.

Provided herein are automated apparatus for the identification of microorganisms in various samples. The disclosure solves existing challenges encountered in identifying and distinguishing various types of microorganisms, including viruses and bacteria in a timely, efficient, and automated manner by sequencing.

A gene detection method, a gene detection kit, and a gene detection device, including the following steps: providing a plurality of separation cavities on a kit, using a plunger to separate adjacent separation cavities, and respectively providing a lysate solution, a washing solution and a reaction solution in the separation cavities; when detecting a sample, pushing each plunger to align a plunger hole of the plunger with the separation cavity, thereby making the separation cavities interconnected; then, controlling magnetic beads in the kit to drive the sample to be tested to pass through the separation cavities in sequence by an electromagnetic control method, carrying out a lysing, a washing and a reaction in sequence; and finally, performing a optical detection on a gene in the reaction solution from outside.

A gene detection method, a gene detection kit, and a gene detection device, including the following steps: providing a plurality of separation cavities on a kit, using a plunger to separate adjacent separation cavities, and respectively providing a lysate solution, a washing solution and a reaction solution in the separation cavities; when detecting a sample, pushing each plunger to align a plunger hole of the plunger with the separation cavity, thereby making the separation cavities interconnected; then, controlling magnetic beads in the kit to drive the sample to be tested to pass through the separation cavities in sequence by an electromagnetic control method, carrying out a lysing, a washing and a reaction in sequence; and finally, performing a optical detection on a gene in the reaction solution from outside.