In certain example embodiments, the invention provides a method of generating an ex vivo cell-based system comprising dissociating an original tissue sample obtained from a subject into a single cell population; determining an in vivo phenotype of the tissue sample by conducting single-cell RNA analysis on a first portion of the single cells; establishing an ex vivo cell-based system from a second portion of the single cells; and culturing the ex vivo cell-based system in a medium or conditions selected to maintain the in vivo phenotype. In some embodiments, the original tissue sample is a tumor tissue sample, such as a pancreatic ductal adenocarcinoma (PDAC) tumor sample.

Provided are methods of treating a disease or condition characterized by a deficiency of or a defect in an iron transporter using a small molecule. For example, the method may increase transepithelial iron transport, or it may increase iron release. Additionally, the small molecule may be hinokitiol, or it may be selected from the group consisting of amphotericin B, calcimycin, nonactin, deferiprone, purpurogallin, and maltol. Also provided is a method of identifying a compound capable of treating a disease or condition characterized by a deficiency of or a defect in an iron transporter.

The invention provides methods and systems for drug screening by segregating single cells into droplets simultaneously and providing candidate compound to the single cells to measure cellular response. Methods of the present invention combine template particles with a plurality of single cells in a tube, generate in the tube monodispersed droplets simultaneously that encapsulate a single one of the template particles and single one of the single cells, provide to the single cells one or more candidate compounds, and measure a cellular response to the one or more candidate compounds.

Methods of altering viral latency, sensitizing EBV+ tumors, or modulating viral immunogenicity, are provided.

An object of the present invention is to provide a new method for evaluating and/or screening an excellent healthcare material or pharmaceutical product based on a new concept. The present invention to solve the above object is a method for evaluating and/or screening a control agent for tissue morphology and/or tissue function, the method including: applying a test substance to a tissue or cell capable of expressing a mechanical stress signaling molecule; and evaluating expression, activity, or intracellular localization of the mechanical stress signaling molecule in the tissue or cell.

The invention enables efficient, rapid, and sensitive enumeration of living cells by detecting microscopic colonies derived from in situ cell division using large area imaging. Microbial enumeration tests based on the invention address an important problem in clinical and industrial microbiology—the long time needed for detection in traditional tests—while retaining key advantages of the traditional methods based on microbial culture. Embodiments of the invention include non-destructive aseptic methods for detecting cellular microcolonies without labeling reagents. These methods allow for the generation of pure cultures which can be used for microbial identification and determination of antimicrobial resistance.

The present invention relates to systems and methods for the arrangement of droplets in pre-determined locations. Many applications require the collection of time-resolved data. Examples include the screening of cells based on their growth characteristics or the observation of enzymatic reactions. The present invention provides a tool and related techniques which addresses this need, and which can be used in many other situations. The invention provides, in one aspect, a tool that allows for stable storage and indexing of individual droplets. The invention can interface not only with microfluidic/microscale equipment, but with macroscopic equipment to allow for the easy injection of liquids and extraction of sample droplets, etc.

The present invention relates to an in vitro method for identifying a skin wound in an individual as being a non-healing skin wound or healing skin wound, in vitro methods for monitoring the healing of a skin wound in an individual, methods for screening for compounds suitable for modulating skin wound healing, as well as kits related thereto.

Disclosed herein is are methods and apparatuses for synthesizing deposited films of compounds (e.g., organic compounds such as a pharmaceutical active ingredient or a new chemical entity) on or in a variety of substrates, where such deposited compounds the desired stability under storage conditions, ease of handling, and yet enhanced dissolution properties when used in various assays. The disclosure further relates to methods of coating substrates, such as medical or diagnostic devices, with deposited films of organic compounds, as well as film-coated substrates.

A well for electrically stimulating at least one cell. The well includes a bottom portion and comprises an adaptive electrode arrangement for introducing an electric field into the well. The adaptive electrode arrangement includes a pair of electrodes disposed within the well. Each electrode of the pair of electrodes has a distal end and is independently and axially displaceable relative to the other electrode and the bottom portion of the well. The distal end of each electrode of the pair of electrodes is in contact with the bottom portion of the well, ensuring a uniform and constant electric field is applied within the well.