The present invention relates to the preparation and use in recipients of CAR-T cell-derived effector cells which are modified to limit their proliferation within the recipient. This is accomplished through the introduction of adducts into the nucleic acids of CAR-T cell-derived effector cells following expansion in vitro to provide expanded and activated CAR-T cell-derived effector cells that retain immunologic function, including the expression of one ore more cytokines.

The disclosure relates to the fabrication of a three dimensional [3-D] cell culture membrane comprising one or more functionalized surfaces adapted to provide cell culture conditions suitable for the analysis of proliferation, differentiation or function of cells, typically eukaryotic or prokaryotic cells.

A cytometer includes an avalanche photodiode, a switching power supply, a filter, and voltage adjustment circuitry. The switching power supply includes a feedback loop. The filter is electrically connected between the switching power supply and the avalanche photodiode. The voltage adjustment circuitry adjusts a voltage on the feedback loop based at least in part on a voltage measured between the filter and the avalanche photodiode.

The present invention relates to a device and a method for inducing pluripotent cells using energy and, more specifically, has an effect of inducing new type pluripotent cells having pluripotent characteristics by applying energy such as ultrasonic waves, lasers or heat treatment to differentiated cells.

To provide a technique for selecting a target cell producing a target substance that specifically binds to a desired cell membrane protein more rapidly and efficiently. A substrate 1 having a plurality of microwells 2 is provided. A first cell 3 expressing a target cell membrane protein on its surface is allowed to adhere to each of the microwells 2. One or two second cells 5 as a candidate of a target cell are introduced into each microwell 2, and are allowed to coexist with the first cell 3 in the microwell 2, and target substance 6 secreted by the second cell 5 is brought into contact with the first cell 3. A microwell 2 including the first cell 3 to which the target substance 6 binds is identified. The second cell 5 as the target cell is recovered from the identified microwell 2. One example of the target substance 6 is an antibody. Visualization may be performed by adding a label substance 7.

Methods for laser-assisted repositioning of a micro-object and for culturing an attachment-dependent biological cell within a microfluidic device are described herein. Laser illumination is used to controllably create a bubble which repositions the micro-object. Further, methods of culturing an attachment-dependent biological cell are described, where the methods may include laser-assisted repositioning.

Disclosed are methods, devices, and techniques useful for enhancing function of an organ or cellular graft through photoceutical manipulation. In one embodiment a hematopoietic graft is treated with one or more wavelengths of low level laser irradiation at a sufficient energy to enhance homing and engraftment. In another embodiment the recipient long bones are treated with one or more wavelengths of low level laser irradiation at a sufficient energy to enhance chemoattraction and growth factor secretion on recipient stromal cells. Application of the invention includes areas of cellular transplants such as islet and hepatic cell grafts.

A method of coating a surface with nanoparticles for biological analysis of cells that includes the steps of cleaning the surface with an oxidizing acid, treating the surface with an organosilane, coating the surface with nanoparticles, and then growing cells on the surface coated with the nanoparticles. The surface may be a glass surface, a silica-based surface, a plastic-based surface or a polymer-based surface. The nanoparticles may be gold-based nanomaterials.

To provide a technique for selecting a target cell producing a target substance that specifically binds to a desired cell membrane protein more rapidly and efficiently. A substrate 1 having a plurality of microwells 2 is provided. A first cell 3 expressing a target cell membrane protein on its surface is allowed to adhere to each of the microwells 2. One or two second cells 5 as a candidate of a target cell are introduced into each microwell 2, and are allowed to coexist with the first cell 3 in the microwell 2, and target substance 6 secreted by the second cell 5 is brought into contact with the first cell 3. A microwell 2 including the first cell 3 to which the target substance 6 binds is identified. The second cell 5 as the target cell is recovered from the identified microwell 2. One example of the target substance 6 is an antibody. Visualization may be performed by adding a label substance 7.

A method of manufacturing a transparent microbial energy device includes disposing a first transparent electrode, disposing a first hydrogel layer including an algal cell on the first transparent electrode, disposing a Nafion layer on the first hydrogel layer, disposing a second hydrogel layer including potassium ferricyanide on the Nafion layer, and disposing a second transparent electrode on the second hydrogel layer.