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Chest drainage
Chest drains are surgical drains placed within the pleural space to facilitate removal of unwanted substances (air, blood, fluid, etc.) in order to preserve respiratory functions and hemodynamic stability. Some chest drains may utilize a flutter valve to prevent retrograde flow, but those that do not have physical valves employ a water trap seal design, often aided by continuous suction from a wall suction or a portable vacuum pump.
The active maintenance of an intrapleural negative pressure via chest drains builds the basis of chest drain management, as an intrapleural pressure lower than the surrounding atmosphere allows easier lung expansion and thus better alveolar ventilation and gas exchange.
The so-called "central vacuum" was the first sub-atmospheric pressure device available. Sub-atmospheric pressure of around 100 cm of water column was historically generated at a central location in the hospital. This "central vacuum" was available throughout the entire hospital, as it was proved via a tubing system. It was referred to as "wall suction".[citation needed]
Reduction valves that reduce the negative pressure to a therapeutically reasonable range were commercially available later. Due to this, multi-chamber suction – the use of three-chamber systems – was developed. In the 1960s, the first pumps (Emerson-Pump) were available. These and other systems launched later generated a fixed "negative pressure". These pumps couldn't compensate for an inadequate position of the collection chamber of a siphon. Since 2008, an electronically driven and regulated system is available, generating a "negative pressure" on demand.
External suction (previously referred to as active suction) is used to create a sub-atmospheric pressure at the tip of a catheter. As the atmospheric pressure is lower compared to the intrapleural pressure, the lack of external suction (which was previously referred to as passive suction) is used to drain air and fluids. Traditional drainage systems are not able to suction sub-atmospheric pressure in the pleural space. These systems only allow for a regulation of pressure via the system itself but cannot regulate sub-atmospheric pressure in the pleural space.[citation needed]
Two different principles are used in chest drainage management: The Heber-Drain principle and the Bülau-Drain principle. The "Heber-Drain" is based on the Heber principle, which uses hydrostatic pressure to transfer fluid from the chest to a collection canister. It produces permanent passive suction. As the Heber drain is a classical gravity drain, the canister must be placed below chest level to be active. The difference in height between the floor and the patient bed determines the resultant sub-atmospheric pressure. With a difference, for example, of 70 cm in height, a pressure of minus 70 cm of water is created. A water seal component is always combined with a Heber-Drain.
The "Bülau-Drain" is based on the Bülau principle and creates a permanent passive suction within a closed system that is based on the Heber-Drain principle. The pulmonologist Gotthard Bülau (1835-1900) used this system in 1875 for the first time for the treatment of pleural empyema.[citation needed]
This type of drainage is mainly used in cardiac surgery. Mediastinal drains are placed behind the sternum and/or next to the heart. The main indication in these cases is the monitoring of post-operative bleeding. Whether these drains are used with active suction or not depends on factors such as personal preference and experience of the physician, individual patient-related factors etc...[citation needed]
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Chest drainage AI simulator
(@Chest drainage_simulator)
Chest drainage
Chest drains are surgical drains placed within the pleural space to facilitate removal of unwanted substances (air, blood, fluid, etc.) in order to preserve respiratory functions and hemodynamic stability. Some chest drains may utilize a flutter valve to prevent retrograde flow, but those that do not have physical valves employ a water trap seal design, often aided by continuous suction from a wall suction or a portable vacuum pump.
The active maintenance of an intrapleural negative pressure via chest drains builds the basis of chest drain management, as an intrapleural pressure lower than the surrounding atmosphere allows easier lung expansion and thus better alveolar ventilation and gas exchange.
The so-called "central vacuum" was the first sub-atmospheric pressure device available. Sub-atmospheric pressure of around 100 cm of water column was historically generated at a central location in the hospital. This "central vacuum" was available throughout the entire hospital, as it was proved via a tubing system. It was referred to as "wall suction".[citation needed]
Reduction valves that reduce the negative pressure to a therapeutically reasonable range were commercially available later. Due to this, multi-chamber suction – the use of three-chamber systems – was developed. In the 1960s, the first pumps (Emerson-Pump) were available. These and other systems launched later generated a fixed "negative pressure". These pumps couldn't compensate for an inadequate position of the collection chamber of a siphon. Since 2008, an electronically driven and regulated system is available, generating a "negative pressure" on demand.
External suction (previously referred to as active suction) is used to create a sub-atmospheric pressure at the tip of a catheter. As the atmospheric pressure is lower compared to the intrapleural pressure, the lack of external suction (which was previously referred to as passive suction) is used to drain air and fluids. Traditional drainage systems are not able to suction sub-atmospheric pressure in the pleural space. These systems only allow for a regulation of pressure via the system itself but cannot regulate sub-atmospheric pressure in the pleural space.[citation needed]
Two different principles are used in chest drainage management: The Heber-Drain principle and the Bülau-Drain principle. The "Heber-Drain" is based on the Heber principle, which uses hydrostatic pressure to transfer fluid from the chest to a collection canister. It produces permanent passive suction. As the Heber drain is a classical gravity drain, the canister must be placed below chest level to be active. The difference in height between the floor and the patient bed determines the resultant sub-atmospheric pressure. With a difference, for example, of 70 cm in height, a pressure of minus 70 cm of water is created. A water seal component is always combined with a Heber-Drain.
The "Bülau-Drain" is based on the Bülau principle and creates a permanent passive suction within a closed system that is based on the Heber-Drain principle. The pulmonologist Gotthard Bülau (1835-1900) used this system in 1875 for the first time for the treatment of pleural empyema.[citation needed]
This type of drainage is mainly used in cardiac surgery. Mediastinal drains are placed behind the sternum and/or next to the heart. The main indication in these cases is the monitoring of post-operative bleeding. Whether these drains are used with active suction or not depends on factors such as personal preference and experience of the physician, individual patient-related factors etc...[citation needed]