The invention relates to an anti-blocking seawater desalination device based on graphene filtering, comprising heating device, solar heat-collecting device, fresh water condensation heat-exchange device and thermal-expansion and cold-shrinkage control valve mechanism; the heating device can fully heat and distill seawater, the sprayed seawater is distilled by graphene heat-conduction layers to improve the distillation efficiency and avoiding blocking; the distilled water vapor enters into fresh water condensation heat-exchange device to exchange heat with seawater, increasing the seawater temperature, making full use of the heat in water vapor, and increasing water vapor condensation speed; the distilled concentrated seawater enters into the thermal-expansion and cold-shrinkage control valve mechanism, the flow of seawater entering into the heating device is controlled by the concentrated seawater temperature, when the temperature is too high, the flow of the seawater entering into the heating device increases, and when the temperature is too low, the flow decreases.

Provided is a red blood cell filtering apparatus comprising: a filtering film having multiple through holes; and a shell having a first opening on an upper portion of one lateral part of the shell, and a second opening on a lower portion of the other lateral part of the shell; the filtering film is accommodated in the shell. Also provided is a red blood cell filtering system comprising the red blood cell filtering apparatus, a first blood collector and a second blood collector; wherein the first blood collector has a first connecting opening, and the first connecting opening is connected with the first opening through the first connecting apparatus; the second blood collector has a second connecting opening, and the second connecting opening is connected with the second opening through the second connecting apparatus.

The present disclosure provides a cell separation apparatus for a bioreactor. The cell separation apparatus may be disposed outside the bioreactor and in fluid connection with the bioreactor, the cell separation apparatus may be in a shape of a box body, the cell separation apparatus may include a liquid buffer device including a first liquid cavity disposed in the box body; a filter device including a filter channel and a filter membrane disposed in the box body, the filter membrane may be disposed above the filter channel; and a first liquid channel may be configured in the box body to facilitate a fluid communication between the first liquid cavity and the filter channel. A power system for filtering and microfluidic channels are integrated in the cell separation apparatus that is of a box shape, thereby reducing the volume and production cost thereof.

A membrane filter apparatus for splitting a feed into filtrate and retentate is provided. The apparatus comprises a body chamber, a feed inlet disposed on the body chamber, a retentate outlet located in the body chamber, a feed distribution tube connected to the feed inlet, and a filter assembly having a filter. The feed distribution tube has a length sufficient to cause the feed to enter the body chamber at a feed distance from the filter assembly of no greater than 50% of a total length of the body chamber. The feed flows across the filter in a direction parallel to a surface of the filter assembly. The filtrate passes through the filter assembly and the retentate flows through the body chamber in a direction antiparallel to the feed flow through the feed distribution tube and out through the retentate outlet.

The present disclosure provides a cell separation apparatus for a bioreactor. The cell separation apparatus may be disposed outside the bioreactor and in fluid connection with the bioreactor, the cell separation apparatus may be in a shape of a box body, the cell separation apparatus may include a liquid buffer device including a first liquid cavity disposed in the box body; a filter device including a filter channel and a filter membrane disposed in the box body, the filter membrane may be disposed above the filter channel; and a first liquid channel may be configured in the box body to facilitate a fluid communication between the first liquid cavity and the filter channel. A power system for filtering and microfluidic channels are integrated in the cell separation apparatus that is of a box shape, thereby reducing the volume and production cost thereof.

Track-etched membranes for filtration are provided. Filtration methods utilizing such membranes and cell culture methods are also provided.

A vent assembly (100) has a vent body (110) defining a first end (104) and a second end (106), a central axis extending from the first end to the second end, and an inner surface defining a cavity. A first retainer extends across the cavity towards the first end of the vent body, and a second retainer (140) extends across the cavity towards the second end of the vent body. The first retainer defines a first retainer opening extending to a first radial distance from the central axis, and the second retainer defines a second retainer opening extending to a second radial distance from the central axis, where the second radial distance is greater than the first radial distance. Coalescing filter media is disposed in the cavity between the first retainer and the second retainer. The coalescing filter media, the cavity, the first retainer, and the second retainer cumulatively define an airflow pathway.

Methods and devices for producing a population of liposomes are provided. Aspects of the methods include applying a centrifugal force to a suspension of liposomes in a manner sufficient to pass the liposomes through a porous membrane to produce a population of liposomes. Aspects of the invention further include devices, systems and kits useful for performing the methods.

Disclosed is a permeable membrane support having an attachable and detachable permeable membrane, the permeable membrane support comprising: a lower support; an upper support partially accommodated into the lower support; and a permeable membrane disposed between the lower support and the upper support. When the upper support and the lower support are engaged with each other in a snap-fit manner, the permeable membrane is sandwiched between a bottom opening of a cylindrical lower member of the upper support and a top face of a bottom support portion of the lower support.

Disclosed is a device for extracting a filtrate from a liquid sample that includes one or more filtration membranes and, in physical contact with a portion of the downstream surface(s) of the filtration membrane(s), a soluble matrix possessing a capillary drawing force sufficient to draw filtrate through the at least one filtration membrane and into the soluble matrix, causing the soluble matrix to at least partially dissolve or disintegrate in the filtrate, whereby the filtrate is released. Various configurations, including device configurations having two filtration membranes with a soluble matrix in between or having a tubular filtration membrane at least partially surrounding or surrounded by a soluble matrix are described.