Disclosed is a marker for observing an effect of a compound or a drug on cells in real time. The marker is: 1) an amino acid sequence shown in SEQ No. 1 and/or SEQ No. 2; or 2) an amino acid sequence having a function for observing an effect of a compound or a drug on cells in real time and having at least more than 80%, preferably more than 85%, more preferably 90%, further preferably 95%, and most preferably 99% homology with the amino acid sequence shown in SEQ No. 1 and/or SEQ No. 2. Also disclosed is a method and a kit for observing an effect of a compound or a drug on cells in real time and use thereof.

A method of creating a reperfusion injury can include: providing a cell culture device having an internal chamber with at least one port coupled to a perfusion modulating system capable of modulating perfusion in the internal chamber, wherein the internal chamber includes a cell culture; perfusing a fluid through the internal chamber with the perfusion modulating system, wherein the perfusion modulating system includes at least one pump; reducing fluid flow through the internal chamber; reperfusing fluid flow through the internal chamber; and creating a reperfusion injury in the cell culture by the reperfusion of the fluid flow through the internal chamber. The cell culture includes at least one type of tissue cell. The cell culture can include a tissue construct formed of hydrogel and/or extracellular matrix.

Disclosed is a method for detecting chemotaxis of neutrophil, including: mixing a blood sample and an equal volume of glucose, mixing, and standing; taking a supernatant of the blood sample after standing into a centrifuge tube, and centrifuging; adding 1× calcium and magnesium ion-free HBSS into a centrifuged blood sample to re-suspend cell aggregates at bottom; uniformly blowing and dispersing a re-suspended bottom cell aggregates, and slowly adding a polysucrose solution from the bottom of the centrifuge tube to perform density gradient centrifuging treatment; dividing a density gradient centrifuged solution into three layers, pipetting a clear liquid at an upper layer and a PBMC layer at a middle layer to obtain cell aggregates at a bottom layer; lysing erythrocytes in the cell aggregates, then successively adding 2× calcium and magnesium ion-free HBSS and 1× calcium and magnesium ion-free HBSS, mixing, and centrifuging again to obtain neutrophils.

The present invention describes an integrated apparatus that enables identification of invasive tumor cells directly from a specimen. The methods using the apparatus can be used to prognose or predict the survivability of the cancer in a subject and the risk of recurrence of the cancer in the subject after treatment. The methods disclosed herein can be used to determine which chemotherapeutic or other therapies most strongly inhibit the tumor cells invasiveness as a form of personalized therapy.

Provided are cortical interneurons and other neuronal cells and in vitro methods for producing such cortical interneurons and other neuronal cells by the directed differentiation of stem cells and neuronal progenitor cells. The present disclosure relates to novel methods of in vitro differentiation of stem cells and neural progenitor cells to produce several type neuronal cells and their precursor cells, including cortical interneurons, hypothalamic neurons and pre-optic cholinergic neurons. The present disclosure describes the derivation of these cells via inhibiting SMAD and Wnt signaling pathways and activating SHH signaling pathway. The present disclosure relates to the novel discovery that the timing and duration of SHH activation can be harnessed to direct controlled differentiation of neural progenitor cells into either cortical interneurons, hypothalamic neurons or pre-optic cholinergic neurons. The present disclosure also relates to compositions of cortical interneurons, hypothalamic neurons or pre-optic cholinergic neurons, and their precursors, that are highly enriched and can be used in variety of application. These cells can be used therapeutically to treat neurodegenerative and neuropsychiatric disorders, and can be used for disease modeling and drug screening.

Disclosed herein are methods for the generation of highly accurate oligonucleic acid libraries encoding for predetermined variants of a nucleic acid sequence. The degree of variation may be complete, resulting in a saturated variant library, or less than complete, resulting in a selective library of variants. The variant oligonucleic acid libraries described herein may designed for further processing by transcription or translation. The variant oligonucleic acid libraries described herein may be designed to generate variant RNA, DNA and/or protein populations. Further provided herein are method for identifying variant species with increased or decreased activities, with applications in regulating biological functions and the design of therapeutics for treatment or reduction of disease.

The present invention provides methods for determining bone growth velocity comprising: (a) measuring an amount of a collagen X marker in a sample obtained from a subject in need thereof; and (b) comparing the amount of collagen X marker measured in step (a) with a collagen X marker standard curve, wherein the amount of collagen X marker is measured using at least two reagents. In an embodiment, there is at least one capture reagent and at least one detection reagent. In a preferred embodiment for measuring CXM, the capture reagent is the aptamer SOMA1 and the detection reagent is the monoclonal antibody mAb X34. The present invention further provides methods for treating diseases, disorders or conditions comprising receiving an identification of an amount of CXM in a sample, wherein the amount of CXM has been identified using a combination of SOMA1 and mAb X34 as CXM-binding reagents, and administering a treatment in light of the amount of CXM in the sample.

A device includes an input chamber, an attractant chamber, a migration channel arranged in fluid communication between an outlet of the input chamber and inlet of the attractant chamber, a baffle arranged in fluid communication between the outlet of the input chamber and the migration channel or within the migration channel, and an exit channel in fluid communication with the migration channel at a point beyond the baffle and before the migration channel enters the inlet of the attractant chamber. The baffle is configured to inhibit movement of a first type of cell through the baffle to a greater extent than the baffle inhibits movement of a second type of cell through the baffle.

A method and system for deriving particle characteristics is described. The method comprises imaging the movement of at least one free-floating particle in a liquid environment at at least one moment in time, determining for at least one moment in time a movement parameter based on the imaged movement of the free-floating particles in the liquid environment, and deriving from the movement parameter a characteristic of the at least one particle.

In order to determine, in a cancer test using nematodes, whether or not the nematodes used in the cancer test are adequate, the present invention is characterized in that after a plate on which a urine from a subject and the nematode are set is placed, a cancer test apparatus performs imaging for quality assay of the nematode during the initial two minutes; an analysis apparatus determines a quality of the nematode using the imaging result; after taxis of the nematode is completed, the cancer test apparatus performs imaging for cancer test assay by the nematode; and the analysis apparatus determines the presence or absence of a cancer in the subject using the imaging result.