The present invention relates to a living fatty material from which immunity is removed, and a method for manufacturing the same, and more specifically, to a living fat tissue from which immunity is removed and to a method for manufacturing the same, comprising the steps of collecting fat tissues; irradiating the fat tissues with 20 to 500 kGy of gamma (γ) rays; and applying centrifugal separation of the fat tissues irradiated with gamma rays.

The present invention provides a cell treatment apparatus capable of treating cells in a cell culture vessel. The cell treatment apparatus 100 according to the present invention includes a first region 1, a second region 3, and a third region 5. The first region 1 and the second region 3 are placed in succession. The first region 1 is a cell treatment chamber for treating cells. The cell treatment chamber can be closed from the outside of the cell treatment chamber and includes a culture vessel placement portion for placing a cell culture vessel. The second region 3 includes: a laser irradiation device capable of irradiating the cell culture vessel placed in the culture vessel placement portion with a laser; and a spot diameter adjustment device that adjusts a spot diameter formed in a portion to be irradiated with the laser in an object to be irradiated. The third region 5 includes a control device that controls at least one device in the cell treatment apparatus 100 and a power supply device 52 that supplies electric power to at least one device in the cell treatment apparatus 100. The culture vessel placement portion is placed to be adjacent to the second region 3 in the cell treatment chamber. An adjacent portion to the second region 3 in the culture vessel placement portion is translucent.

The present invention provides a cell treatment apparatus capable of treating cells in a cell culture vessel. The cell treatment apparatus 100 according to the present invention includes a first region 1, a second region 3, and a third region 5. The first region 1 and the second region 3 are placed in succession. The first region 1 is a cell treatment chamber for treating cells. The cell treatment chamber can be closed from the outside of the cell treatment chamber and includes a culture vessel placement portion for placing a cell culture vessel. The second region 3 includes: a laser irradiation device capable of irradiating the cell culture vessel placed in the culture vessel placement portion with a laser; and a spot diameter adjustment device that adjusts a spot diameter formed in a portion to be irradiated with the laser in an object to be irradiated. The third region 5 includes a control device that controls at least one device in the cell treatment apparatus 100 and a power supply device 52 that supplies electric power to at least one device in the cell treatment apparatus 100. The culture vessel placement portion is placed to be adjacent to the second region 3 in the cell treatment chamber. An adjacent portion to the second region 3 in the culture vessel placement portion is translucent.

A cell treatment apparatus capable of treating cells in a cell culture vessel. The cell treatment apparatus (100) according to the present invention includes a first region (1), a second region (3), and a third region (5). The first region (1) and the second region (3) are placed in succession. The first region (1) is a cell treatment chamber for treating cells. The cell treatment chamber can be closed from the outside of the cell treatment chamber and includes a culture vessel placement portion for placing a cell culture vessel. The second region (3) includes a laser irradiation device capable of irradiating the cell culture vessel placed in the culture vessel placement portion with a laser. The third region (5) includes a control device that controls at least one device in the cell treatment apparatus (100) and a power supply device (52) that supplies electric power to at least one device in the cell treatment apparatus (100). The culture vessel placement portion is placed to be adjacent to the second region (3) in the cell treatment chamber. An adjacent portion to the second region (3) in the culture vessel placement portion is translucent.

The present invention relates to a recombinant bacterium wherein said bacterium comprises an optogenetic interaction switch to control cellular functions, in particular wherein said bacterium is a recombinant gram-negative bacterium comprising a type III secretion system, wherein the activity of said type III secretion system is light-dependent, and to methods for controlling cellular functions in a bacterium using such an optogenetic interaction switch.

The present invention relates to a recombinant bacterium wherein said bacterium comprises an optogenetic interaction switch to control cellular functions, in particular wherein said bacterium is a recombinant gram-negative bacterium comprising a type III secretion system, wherein the activity of said type III secretion system is light-dependent, and to methods for controlling cellular functions in a bacterium using such an optogenetic interaction switch.

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.

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.

Aspects of the present disclosure describe systems, methods, and structures for acoustic wave-based separation of particulates in a fluidic flow. Illustrative systems, methods, and structures according to aspects of the present disclosure may advantageously provide for the continuous, label-free, non-invasive separation of the particulates that include—among other types—difficult-to-separate biological particulates and in particular those in blood including circulating tumor cells and micro-blood-borne particles and other subgroups of extracellular vesicles including nanoscale exosomes.

Devices for high throughput cell electroporation include a trapping component that at least partially defines an upper boundary of a microfluidic chamber. A cell trap array is patterned on the underside of the trapping component, and a channeling component is positioned beneath the trapping component. The channeling component includes a vertically oriented nanochannel array. The trapping component and the channeling component are positioned such that a given nanochannels is positioned beneath a cell trap. During use, fluid flow holds trapped cells in secure contact with the nanochannels beneath the cell trap. The device further includes upper and lower electrode layers for generating an electric field to electroporate trapped cells via the nanochannel array. A reservoir positioned beneath the channeling component can be filled transfection reagent solution. During electroporation, the transfection reagent solution travels through the nanochannel array during to transfect the trapped cells.