The invention provides a series of steps that prepare nucleic acids (RNA and/or DNA) isolated from extracellular vesicles for sequencing. This enables a wide diversity of RNAs and/or DNAs, to be efficiently detected. These can then be used to identify various attributes such as gene expression, alternative splicing, and the detection of both somatic and germline mutations including single nucleotide variants (SNV) and structural variations (insertions/deletions, fusions, inversions).

The present disclosure provides compositions, methods and kits for internal controls of microvesicle isolations. The compositions, methods and kits can comprise enveloped viruses, including, but not limited to, inactive mouse hepatitis virus (MHV).

The present disclosure provides compositions, methods and kits for internal controls of microvesicle isolations. The compositions, methods and kits can comprise enveloped viruses, including, but not limited to, inactive mouse hepatitis virus (MHV).

Disclosed is a microfluidic chip, including a chip upper cover, a chip lower layer, a membrane, a sealing gasket and a sealing ring. The microfluidic chip is provided with a sample storage zone, a droplet formation zone, a droplet storage zone, a droplet detection zone and a waste liquid storage zone. The sample storage zone, the droplet formation zone, the droplet storage zone, the droplet detection zone and the waste liquid storage zone communicate by means of a micropore or a micro-channel. The droplet formation zone is used to transform the sample phase into tens of thousands to millions of droplets, the droplets undergo the PCR reaction in the droplet storage zone, the droplet detection zone is used to perform optical detection on the droplets after PCR reaction, and the waste liquid storage zone is used to collect and store the detected droplets and continuous phase.

Disclosed is a microfluidic chip, including a chip upper cover, a chip lower layer, a membrane, a sealing gasket and a sealing ring. The microfluidic chip is provided with a sample storage zone, a droplet formation zone, a droplet storage zone, a droplet detection zone and a waste liquid storage zone. The sample storage zone, the droplet formation zone, the droplet storage zone, the droplet detection zone and the waste liquid storage zone communicate by means of a micropore or a micro-channel. The droplet formation zone is used to transform the sample phase into tens of thousands to millions of droplets, the droplets undergo the PCR reaction in the droplet storage zone, the droplet detection zone is used to perform optical detection on the droplets after PCR reaction, and the waste liquid storage zone is used to collect and store the detected droplets and continuous phase.

The invention relates to a non-invasive, simple, inexpensive, quick method to assess embryo competence in vitro by detecting nucleic acid-containing extracellular vesicles in the culture medium of the embryo. The culture medium may be fixed before being stained with propidium iodide and analysed by flow cytometry.

The invention relates to a non-invasive, simple, inexpensive, quick method to assess embryo competence in vitro by detecting nucleic acid-containing extracellular vesicles in the culture medium of the embryo. The culture medium may be fixed before being stained with propidium iodide and analysed by flow cytometry.

The present disclosure provides methods for high throughput barcoding nucleic acids and/or protein inside the cells. The in-cell single cell capture method uses an individual cell itself as a compartment and delivers a plurality of unique identifiers, e.g. barcodes into the cell and captures the nucleic acid and/or protein targets within the cell directly. It significantly simplifies single cell analysis experimental setup and eliminates the need of external compartment generation. It provides a high throughput single cell expression profiling and cellular protein quantitation method. Targeted sequencing with in-cell capture will be able to significantly increase sensitivity and specificity for low frequent mutation detection, such as, somatic mutation in very early stage of cancer and truly enables early cancer detection.

The present disclosure provides methods for high throughput barcoding nucleic acids and/or protein inside the cells. The in-cell single cell capture method uses an individual cell itself as a compartment and delivers a plurality of unique identifiers, e.g. barcodes into the cell and captures the nucleic acid and/or protein targets within the cell directly. It significantly simplifies single cell analysis experimental setup and eliminates the need of external compartment generation. It provides a high throughput single cell expression profiling and cellular protein quantitation method. Targeted sequencing with in-cell capture will be able to significantly increase sensitivity and specificity for low frequent mutation detection, such as, somatic mutation in very early stage of cancer and truly enables early cancer detection.

The disclosure is related to compositions comprising a cell and a spherical nucleic acid (SNA) comprising a nanoparticle, an oligonucleotide on the surface of the nanoparticle, and an antigen; and to methods for production of such compositions and their applications, including but not limited to adoptive cell therapy.