A gas washout vent, and a patient interface with the gas washout vent, configured to allow patient-exhaled CO.sub.2 to flow to an exterior of the plenum chamber to minimise rebreathing of exhaled CO.sub.2 by the patient, the gas washout vent including at least one outlet orifice; a diffusing member at least partly covering the outlet orifice; and a blocking member having an air-impermeable material, the blocking member preventing gas exiting from the outlet orifice from flowing straight through the diffusing member.

An article of manufacture for a one-way CPAP/BiPAP mask is disclosed. The article includes a mask covering a mouth and nose of a user, an inlet for connecting to a CPAP/BiPAP machine, an exhalation port having an interlocking ring, and a removable filtering tube having an attachment end and an exhalation end. The removable filtering tube has an attachment port located at the attachment end and configured to connect to the interlocking ring of the exhalation port, a filtered exhalation opening located at the exhalation end, and a filter element located between the attachment port and the filtered exhalation opening, the filter permits air from within the mask leave the filtered exhalation opening while removing any pathogens present in the user's exhalations.

An article of manufacture for a one-way CPAP/BiPAP mask is disclosed. The article includes a mask covering a mouth and nose of a user, an inlet for connecting to a CPAP/BiPAP machine, an exhalation port having an interlocking ring, and a removable filtering tube having an attachment end and an exhalation end. The removable filtering tube has an attachment port located at the attachment end and configured to connect to the interlocking ring of the exhalation port, a filtered exhalation opening located at the exhalation end, and a filter element located between the attachment port and the filtered exhalation opening, the filter permits air from within the mask leave the filtered exhalation opening while removing any pathogens present in the user's exhalations.

A ventilation system having a mask, a blowing assembly, and a processor. The mask has a mask body and a pressure sensor operatively associated with the mask body and configured to measure pressure within the mask. The mask body defines an inlet opening and a plurality of leak openings. The blowing assembly is positioned in fluid communication with the inlet opening of the mask body and configured to direct air to the inlet opening of the mask body. The processor is positioned in operative communication with the blowing assembly and the pressure sensor of the mask. The processor is configured to selectively control the blowing assembly based upon at least the measured pressure within the mask.

A ventilation system having a mask, a blowing assembly, and a processor. The mask has a mask body and a pressure sensor operatively associated with the mask body and configured to measure pressure within the mask. The mask body defines an inlet opening and a plurality of leak openings. The blowing assembly is positioned in fluid communication with the inlet opening of the mask body and configured to direct air to the inlet opening of the mask body. The processor is positioned in operative communication with the blowing assembly and the pressure sensor of the mask. The processor is configured to selectively control the blowing assembly based upon at least the measured pressure within the mask.

A breathing mask includes a relatively rigid shell and an elastomeric sealing lip mounted to the relatively rigid shell. The elastomeric sealing lip has a contact zone configured to bear against the face of the person. The elastomeric sealing lip further includes a nose bridge region, a first nostril region and a second nostril region. The nose bridge region has a first zone of lower load-bearing capability. The first nostril region has a first zone of higher load-bearing capability. The second nostril region has a second zone of higher load-bearing capability. The first zone of lower load-bearing capability has a lower load-bearing capability than the first and second zones of higher load-bearing capability. In addition, the contact zone is configured to pivot about an articulation axis that extends through the first and second nostril regions.

A breathing mask includes a relatively rigid shell and an elastomeric sealing lip mounted to the relatively rigid shell. The elastomeric sealing lip has a contact zone configured to bear against the face of the person. The elastomeric sealing lip further includes a nose bridge region, a first nostril region and a second nostril region. The nose bridge region has a first zone of lower load-bearing capability. The first nostril region has a first zone of higher load-bearing capability. The second nostril region has a second zone of higher load-bearing capability. The first zone of lower load-bearing capability has a lower load-bearing capability than the first and second zones of higher load-bearing capability. In addition, the contact zone is configured to pivot about an articulation axis that extends through the first and second nostril regions.

A mask system for delivery of respiratory therapy to a patient includes a nares portion and a mouth portion and an inlet conduit connected to at least one of the nares portion and the mouth portion to deliver the pressurized, breathable gas. The mask system is adapted to selectively utilize the nares portion and/or the mouth portion in a first mode utilizing both the nares portion and the mouth portion, and in a second mode utilizing the nares portion and not utilizing the mouth portion.

A mask system for delivery of respiratory therapy to a patient includes a nares portion and a mouth portion and an inlet conduit connected to at least one of the nares portion and the mouth portion to deliver the pressurized, breathable gas. The mask system is adapted to selectively utilize the nares portion and/or the mouth portion in a first mode utilizing both the nares portion and the mouth portion, and in a second mode utilizing the nares portion and not utilizing the mouth portion.

A cell washing apparatus is provided to wash a cell-containing fluid. The apparatus is arranged to exchange one or more exchangeable entities from a cell-containing first fluid, and comprises, a first fluid conduit and a second fluid conduit, the second fluid conduit separated from the first fluid conduit by a semi-permeable membrane disposed therebetween; the first fluid conduit having a first fluid inlet and a first fluid outlet, the first fluid conduit arranged to transport the first fluid in a first direction between the first fluid inlet and the first fluid outlet; the second fluid conduit being arranged to house a second fluid; wherein the semi-permeable membrane comprises a plurality of pores arranged to permit transport of said one or more exchangeable entities from the first fluid to the second fluid; wherein the one or more exchangeable entities comprise free haemoglobin and/or blood plasma; and wherein the first fluid is whole blood isolated from a human body, or packed red blood cells. The cell washing apparatus of the present invention aims to solve the problem of harmful species that accumulate in a cell-containing fluid (such as, for example, transfusion blood) during storage and other applications, in which it is desired to transfer red blood cells to a clean suspending liquid.