A cell retention device includes a structured support with a plurality of circumferentially distributed ribs to retain the active filtering surface of a flexible, porous membrane filter medium. The filter medium surrounds the support in contact with the peaks of the ribs, thereby forming axial voids between the rib peaks. This arrangement imparts sufficient structural support over small regions of the filter medium to facilitate its use in a circular (or other rounded) configuration while providing sufficient channel volume to support high throughput of fluid sparse of cells.

A cell retention device includes a structured support with a plurality of circumferentially distributed ribs to retain the active filtering surface of a flexible, porous membrane filter medium. The filter medium surrounds the support in contact with the peaks of the ribs, thereby forming axial voids between the rib peaks. This arrangement imparts sufficient structural support over small regions of the filter medium to facilitate its use in a circular (or other rounded) configuration while providing sufficient channel volume to support high throughput of fluid sparse of cells.

Methods and apparatus for use in a water treatment system to separate charged compositions from the water stream are provided. An electric filtration cell may include a fluid passageway, a filtration membrane, and a first and second electrode, configured to provide an oscillating electric field across the filtration membrane to separate charged compositions on a first side of the membrane. A water treatment system may be provided to separate charged compositions from a water stream. The water treatment system may include an electromagnetic field (EMF) device to generate an electromagnetic field within a passageway. The water treatment system may further include a filtration membrane and a first electrode and a second electrode, configured to provide an oscillating electric field across the filtration membrane to separate charged compositions. In one embodiment, the system is configured to separate struvite and/or vivianite on a first side of the membrane. In another embodiment, the system is configured to separate salt on a first side of the membrane.

Methods and apparatus for use in a water treatment system to separate charged compositions from the water stream are provided. An electric filtration cell may include a fluid passageway, a filtration membrane, and a first and second electrode, configured to provide an oscillating electric field across the filtration membrane to separate charged compositions on a first side of the membrane. A water treatment system may be provided to separate charged compositions from a water stream. The water treatment system may include an electromagnetic field (EMF) device to generate an electromagnetic field within a passageway. The water treatment system may further include a filtration membrane and a first electrode and a second electrode, configured to provide an oscillating electric field across the filtration membrane to separate charged compositions. In one embodiment, the system is configured to separate struvite and/or vivianite on a first side of the membrane. In another embodiment, the system is configured to separate salt on a first side of the membrane.

The invention relates to a heating device for a rack of a diagnose robot comprising: -a polygonal, oval or cylindrical ring (221) defining a polygonal, oval or cylindrical closed wall, having a bottom opening (222) and a top opening (223) -wherein the bottom opening matches the size and form of a filter membrane and/or supporting body (2, 3) of a carrier (1) of a filtration assembly; and -one or more heating elements (224) selected from -a heating element which is integrated into the ring, -a heating element which is arranged on the outer and/or inner surface of the wall defining the ring, and -a heating element arranged in or on a lid, wherein the lid matches the size and form of the opening of the ring.

Disclosed are selectively-permeable membranes and components configured for selective permeation of a specified gas, such as oxygen, therethrough, methods for making the same and methods for using the same, for example, to implement fuel cells and electrochemical cells.

Disclosed are selectively-permeable membranes and components configured for selective permeation of a specified gas, such as oxygen, therethrough, methods for making the same and methods for using the same, for example, to implement fuel cells and electrochemical cells.

A gas permeable, liquid impermeable membrane for use with gas sensors consists of a film forming polymer which incorporates nanoparticles selected to improve one or more of the following: permeability to gases, to selectively regulate permeability of selected gases through the membrane, to inhibit microbial growth on the membrane. A capsule shaped container consists of wall material biocompatible with a mammal GI tract and adapted to protect the electronic and sensor devices in the capsule, which contains gas composition sensors, pressure and temperature sensors, a microcontroller, a power source and a wireless transmission device. The microprocessor receives data signals from the sensors and converts the signals into gas composition and concentration data and temperature and pressure data for transmission to an external computing device. The capsule wall incorporates gas permeable nano-composite membranes with embedded catalytic and nano void producing nanoparticles, enhancing the operation, selectivity and sensitivity of the gas sensors.

An isolation device for adipose-derived stromal vascular fraction is provided. More particularly the embodiments relates to novel systems, devices, methods and kits for adipose tissue collection and stromal vascular fractions isolation from collected adipose. The devices and systems are used in the field of healthcare/regenerative medicine.

The invention relates to a gas in/outlet-adapter system for a container/rack assembly for a diagnostic robot comprising: —a receptacle (15) comprising a gas-inlet wherein the receptacle (15) is attached to a container (12), —a nozzle (16) comprising a gas-outlet wherein the nozzle (16) is attached to a rack to supply the container (12) via the receptacle (15) with a gas at a defined pressure level, wherein the receptacle (12) —provides one opening (24) —which provides for a fluidic contact to the interior of the container (12) —and a second opening (25) —which provides for a gas leak-proof connection to the nozzle (16) on the rack when the receptacle (15) is placed over the nozzle (16), and wherein the nozzle (16) —provides one opening (26) —which provides for a fluidic contact to a tubing system of the rack—and a second opening (27) —which provides for a fluidic contact to the nozzle (16) when the receptacle (15) is placed to cover the nozzle (15).