A system for determining components of matter removed from a body includes a container for receiving the matter, a device for weighing the container and the matter therein, an instrument for obtaining information relating to determine the components of the matter based in part on a weight of the matter determined by said device and the information relating to the at least one aspect of the matter obtained by said instrument. A display includes a screen for displaying information relating to the matter provided by said processer. The information may include a height and/or a color of the matter among other aspects. An insert containing an absorbent material may be utilized to separate fat cells from a fluid when liposuction is used to remove the matter. The insert may be porous allowing fluid to enter the absorption.

The illustrative embodiments described herein are directed to an apparatus, system, and method for storing liquid from a tissue site. The apparatus may include a drape having an aperture, and a fluid pouch coupled to the drape such that the fluid pouch is in fluid communication with the aperture. In one embodiment, the fluid pouch is operable to transfer reduced pressure to the aperture such that the liquid from the tissue site is drawn into the fluid pouch. The fluid pouch may have a cavity that stores the liquid that is drawn from the tissue site. In another embodiment, the fluid pouch may include at least one baffle. The fluid pouch may also include a fluid channel at least partially defined by the at least one baffle. The fluid channel may be operable to store liquid from the tissue site when reduced pressure is applied through the fluid channel.

Embodiments of a reduced pressure system and methods for operating the system are disclosed. In some embodiments, the system can include one or more processors responsible for various functions associated with various levels of responsiveness, such as interfacing with a user, controlling a vacuum pump, providing network connectivity, etc. The system can present GUI screens for controlling and monitoring its operation. The system can be configured to determine and monitor flow of fluid in the system by utilizing one or more of the following: monitoring the speed of a pump motor, monitoring flow of fluid in a portion of a fluid flow path by using a calibrated fluid flow restrictor, and monitoring one or more characteristics of the pressure pulses. The system can be configured to provide external connectivity for accomplishing various activities, such as location tracking of the system, compliance monitoring, tracking of operational data, remote selection and adjustment of therapy settings, etc.

Embodiments of negative pressure wound therapy systems and methods for operating the systems are disclosed. In some embodiments, a system includes a negative pressure source, a wound dressing configured to be positioned over a wound, and optionally a canister configured to store fluid aspirated from the wound. The negative pressure source, wound dressing, and canister (when present) can be fluidically connected to facilitate delivery of negative pressure to the wound. The system can be configured to automatically detect whether the canister is positioned in the fluid flow path between the negative pressure source and the dressing while negative pressure source provides negative pressure to the wound dressing. Operation of the system can be adjusted based on whether presence of the canister has been detected. For example, a value of an operational parameter can be set to indicate that the canister is present.

A waste collection unit including a waste container, and vacuum source to collect medical waste into the waste container. The vacuum source is disposed within a sound attenuating enclosure that defines an enclosure inlet for receiving cooling air and an enclosure outlet for discharging warmed cooling air. The sound attenuating enclosure is at least partially formed of a sound-absorbing material and may define a pocket for receiving a first end of the vacuum source. The first end of the vacuum source may engage a seat of the sound attenuating enclosure to provide a cooling air barrier. The seat may define a bottom portion of the pocket. Internal geometries of the sound attenuating enclosure may be shaped to define another air path that does not pass through the vacuum source. A plenum may be attached to the sound attenuating enclosure and define a plenum chamber to collect the warmed cooling air.

The infant nasal suction apparatus is disclosed for clearing the nasal passages of small babies and toddlers. The invention provides stress-free mucus extraction and allows the child to breathe easily and freely. The nasal suction apparatus is comprised of the suction housing, which includes the motor, battery, suction level adjustment controls, and an on/off switch. A collection container is removably connected to the suction housing, and a fluid conduit is connected to the container and adapted for placement in a nostril. The infant nasal suction apparatus is arranged for the removal of excess fluid and mucus from an infant nasal passageway and is controlled by the provided speed adjustment controller.

A medical waste management system including a boom secured to a fixed structure of a medical facility. A waste container defines a waste volume sized to collect liquid waste material received through a suction line under the influence of a vacuum provided by a vacuum pump. The system may include a service head coupled to the boom and including the waste container. A vacuum port is in fluid communication with the waste volume, and discharge and/or cleaning ports also in communication with the waste volume may be provided. The vacuum pump may be integrated with the medical facility, and the system may include an offload pump Integrated with the medical facility and in communication with the discharge port. The waste container may be supported on a mobile cart configured to be removably coupled with the boom. The system may further include a liquid measuring system coupled to the waste container.

Examples relate to fluid collection systems and methods of use of the system. The fluid collection system may include a fluid collection device configured to receive fluid discharged from a user, a fluid collection container in fluid communication with the fluid collection device configured to collect the fluid and a suction device in fluid communication with the fluid collection device and the fluid collection container. The suction device is compressible and configured to draw fluid from the fluid collection device into the fluid collection container solely responsive to mechanical actuation of the suction device.

Provided is a treatment method of being able to improve the obstruction of a biological lumen caused by stenosis of the biological lumen and the stagnation of a secretion. The treatment method includes a disposition step of disposing a dilation portion that can be dilated and deflated, and a collection portion, which is capable of removing a secretion S secreted from a biological lumen from a living body, in a stenosed site occurring in the biological lumen; a dilation step of widening the stenosed site after the disposition step by dilating the dilation portion in the stenosed site after the disposition step; and a removal step of removing the secretion from the living body by a removal portion.

A canister for collection and storage of fluids under vacuum, comprising a spherical container having a first hemispherical component and a second hemispherical component. The first and second components are connected at a canister beltline consisting of multiple flanges, to provide an air-tight and liquid tight seal.