초록 ▼

An anesthetic breathing apparatus and system, having a patient circle system for re-breathing exhaled gases by a patient, a volume reflector, a fresh gas delivery line, and a gas sensor unit arranged to measure a gas stream upstream a fresh gas connection and downstream said reflector unit. The gas

An anesthetic breathing apparatus and system, having a patient circle system for re-breathing exhaled gases by a patient, a volume reflector, a fresh gas delivery line, and a gas sensor unit arranged to measure a gas stream upstream a fresh gas connection and downstream said reflector unit. The gas sensor unit provides a signal for detection of a reflector driving gas (RDG) crossing over the volume reflector during inspiration based on at least one property of the gas stream measured by the gas sensor unit. Appropriate action may be taken based on this measurement, for instance in disclosed methods.

대표청구항 ▼

1. An anesthetic breathing apparatus comprising: a patient circle system adapted to interact with a patient to allow re-breathing by the patient of gases exhaled by the patient;a common expiration and inspiration line in fluid communication with said patient circle;a volume reflector unit located in

1. An anesthetic breathing apparatus comprising: a patient circle system adapted to interact with a patient to allow re-breathing by the patient of gases exhaled by the patient;a common expiration and inspiration line in fluid communication with said patient circle;a volume reflector unit located in said common expiration and inspiration line, said volume reflector unit having a proximal end and a distal end, said distal end being connected via a reflector connection to said patient circle system, and said volume reflector unit comprising a reflector volume that receives patient gases from the patient circle system during expiration and said volume reflector unit being configured to return said patient gases from the reflector volume into the patient circle system during a subsequent inspiration;a reflector driving gas line configured to push a reflector driving gas into said proximal end of said volume reflector unit and to push said patient gases out of said distal end of said volume reflector unit during said inspiration into said common expiration and inspiration line and into said circle system;a fresh gas delivery line connected to said patient circle system at a fresh gas connection, said fresh gas connection being located downstream of said reflector connection in said patient circle system;a gas sensor unit configured to measure at least one property of a gas stream upstream of said fresh gas connection and downstream of said volume reflector unit and to generate a gas sensor signal representing said at least one property; anda control unit configured to receive said gas sensor signal and to detect, based on said at least one property of said gas stream measured by said gas sensor unit, a reflector driving gas that crosses over said volume reflector during said inspiration. 2. An anesthetic breathing apparatus as claimed in claim 1 comprising a carbon dioxide absorber unit located in said patient circle system upstream of said fresh gas connection, said gas sensor unit being located upstream of said carbon dioxide absorber unit. 3. An anesthetic breathing apparatus as claimed in claim 1 wherein said gas sensor unit is located in said common expiration and inspiration line, and wherein said common expiration and inspiration line is coupled to said patient circle system at said reflector connection upstream of said fresh gas connection. 4. An anesthetic breathing apparatus as claimed in claim 1 wherein said gas sensor unit is selected from the group consisting of gas identification units, gas concentration units and gas flow sensors. 5. An anesthetic breathing apparatus as claimed in claim 1 wherein said gas sensor unit is configured to measure expiratory flow during an expiration phase of said patient. 6. An anesthetic breathing apparatus as claimed in claim 1 wherein said gas sensor unit is an ultrasonic sensor. 7. An anesthetic breathing apparatus as claimed in claim 6 wherein said ultrasonic sensor is configured to measure a time of flight in said gas stream to measure a flow of said gas stream, or is configured to detect a presence or absence of a gas based on a speed of ultrasound propagation in said gas stream. 8. An anesthetic breathing apparatus as claimed in claim 1 wherein said gas sensor unit is configured to detect a presence or absence of a predetermined gas component in said gas stream. 9. An anesthetic breathing apparatus as claimed in claim 8 wherein said predetermined gas component is said reflector driving gas. 10. An anesthetic breathing apparatus as claimed in claim 1 wherein said volume reflector unit comprises a fixed reflector volume of approximately one liter. 11. An anesthetic breathing apparatus as claimed in claim 1 comprising a carbon dioxide absorber unit located in said patient circle system upstream of said fresh gas connection, said gas sensor unit being located downstream of said carbon dioxide absorber unit. 12. An anesthetic breathing apparatus as claimed in claim 1 wherein said control unit is configured to set an operational mode, among a plurality of available operational modes of said anesthetic breathing apparatus, dependent on said at least one property of said gas stream measured by said gas sensor unit. 13. An anesthetic breathing apparatus as claimed in claim 12 wherein said control unit is configured to set an operational mode comprising controlled admixture of said reflector driving gas into said patient circle system. 14. An anesthetic breathing apparatus as claimed in claim 12 wherein said control unit is configured to set an operational mode comprising delivery of a fresh gas composition via said fresh gas connection dependent on the detected reflector driving gas entering into the patient circle system. 15. An anesthetic breathing apparatus as claimed in claim 14 wherein said control unit is configured to adapt said fresh gas composition to said detected reflector driving gas entering into the patient circle system by increasing an anesthetic agent concentration in said fresh gas composition that compensates for dilution by non-rebreathed reflector driving gas entering into said patient circle system via said reflector connection. 16. An anesthetic breathing apparatus as claimed in claim 13 wherein said control unit is configured to set an operational mode comprising adjusting a ratio of respective amounts of gas flow between said fresh gas line and said reflector driving gas line in real time. 17. An anesthetic breathing apparatus as claimed in claim 13 wherein said control unit is configured to set an operational mode comprising adapting a re-breathing fraction dependent on the detected reflector driving gas crossing over said volume reflector. 18. An anesthetic breathing apparatus as claimed in claim 17 wherein said control unit is configured to set an operational mode comprising calculating a leakage volume based on a difference of an inspiratory gas volume measured by said gas sensor unit comprising a volume exiting said volume reflector unit during inspiration and a volume entering said volume reflector unit during a preceding expiration. 19. An anesthetic breathing apparatus as claimed in claim 12 wherein said control unit is configured to set an operational mode comprising a low flow mode comprising delivery of oxygen, as said reflector driving gas, to said patient circle system via said reflector driving gas connection. 20. An anesthetic breathing apparatus as claimed in claim 12 wherein said control unit is configured to set an operational mode comprising stopping delivery of said reflector driving gas upon detection of said reflector driving gas crossing over said volume reflector unit. 21. An anesthetic breathing apparatus as claimed in claim 12 wherein said control unit is configured to set an operational mode comprising adjusting flow of said reflector driving gas to cause a front of a column of said reflector driving gas to reach said gas sensor unit at an end of said inspiration. 22. An anesthetic breathing apparatus as claimed in claim 21 wherein said control unit, in said operational mode comprising adjusting said flow of said reflector driving gas, is configured to prevent admixing of said reflector driving gas into said patient circle system. 23. An anesthetic breathing apparatus as claimed in claim 12 wherein said control unit is configured to set an operational mode comprising providing a humanly perceptible indication when said reflector driving gas crosses over said volume reflector unit. 24. A method for operating an anesthetic breathing apparatus comprising a patient circle system adapted to interact with a patient to allow re-breathing by the patient of gases exhaled by the patient, a common expiration and inspiration line in fluid communication with said patient circle, a volume reflector unit located in said common expiration and inspiration line, said volume reflector unit having a proximal end and a distal end, said distal end being connected via a reflector connection to said patient circle system, and said volume reflector unit comprising a reflector volume that receives patient gases from the patient circle system during expiration and said volume reflector unit being configured to return said patient gases from the reflector volume into the patient circle system during a subsequent inspiration, a reflector driving gas line configured to push a reflector driving gas into said proximal end of said volume reflector unit and to push said patient gases out of said distal end of said volume reflector unit during said inspiration into said common expiration and inspiration line and into said circle system, a fresh gas delivery line connected to said patient circle system at a fresh gas connection, said fresh gas connection being located downstream of said reflector connection in said patient circle system, a gas sensor unit configured to measure at least one property of a gas stream upstream of said fresh gas connection and downstream of said volume reflector unit and to generate a gas sensor signal representing said at least one property, and a control unit configured to receive said gas sensor signal and to detect, based on said at least one property of said gas stream measured by said gas sensor unit, a reflector driving gas that crosses over said volume reflector during said inspiration, said method comprising: automatically controlling admixing of said reflector driving gas crossing over said volume reflector unit into said circle system by automatically setting an operational mode, via said control unit, upon detecting said reflector driving gas crossing over said volume reflector unit during said inspiration, dependent on said at least one property of said gas stream measured by said gas sensor unit. 25. A method as claimed in claim 24 comprising, via said control unit, setting an operational mode comprising controlled admixture of said reflector driving gas into said patient circle system. 26. A method as claimed in claim 24 comprising, via said control unit, setting an operational mode comprising delivery of a fresh gas composition via said fresh gas connection dependent on the detected reflector driving gas entering into the patient circle system. 27. A method as claimed in claim 26 comprising, via said control unit, adapting said fresh gas composition to said detected reflector driving gas entering into the patient circle system by increasing an anesthetic agent concentration in said fresh gas composition that compensates for dilution by non-rebreathed reflector driving gas entering into said patient circle system via said reflector connection. 28. A method as claimed in claim 25 comprising, via said control unit, setting an operational mode comprising adjusting a ratio of respective amounts of gas flow between said fresh gas line and said reflector driving gas line in real time. 29. A method as claimed in claim 26 comprising, via said control unit, setting an operational mode comprising adapting a re-breathing fraction dependent on the detected reflector driving gas crossing over said volume reflector. 30. A method as claimed in claim 29 comprising, via said control unit, setting an operational mode comprising calculating a leakage volume based on a difference of an inspiratory gas volume measured by said gas sensor unit comprising a volume exiting said volume reflector unit during inspiration and a volume entering said volume reflector unit during a preceding expiration. 31. A method as claimed in claim 24 comprising, via said control unit, setting an operational mode comprising a low flow mode comprising delivery of oxygen, as said reflector driving gas, to said patient circle system via said reflector driving gas connection. 32. A method as claimed in claim 24 comprising, via said control unit, setting an operational mode comprising stopping delivery of said reflector driving gas upon detection of said reflector driving gas crossing over said volume reflector unit. 33. A method as claimed in claim 24 comprising, via said control unit, setting an operational mode comprising adjusting flow of said reflector driving gas to cause a front of a column of said reflector driving gas to reach said gas sensor unit at an end of said inspiration. 34. A method as claimed in claim 33 comprising, in said operational mode comprising adjusting said flow of said reflector driving gas, preventing admixing of said reflector driving gas into said patient circle system. 35. A method as claimed in claim 24 comprising, via said control unit, setting an operational mode comprising providing a humanly perceptible indication when said reflector driving gas crosses over said volume reflector unit. 36. A method for operating an anesthetic breathing apparatus comprising a patient circle system adapted to interact with a patient to allow re-breathing by the patient of gases exhaled by the patient, a common expiration and inspiration line in fluid communication with said patient circle, a volume reflector unit located in said common expiration and inspiration line, said volume reflector unit having a proximal end and a distal end, said distal end being connected via a reflector connection to said patient circle system, and said volume reflector unit comprising a reflector volume that receives patient gases from the patient circle system during expiration and said volume reflector unit being configured to return said patient gases from the reflector volume into the patient circle system during a subsequent inspiration, a reflector driving gas line configured to push a reflector driving gas into said proximal end of said volume reflector unit and to push said patient gases out of said distal end of said volume reflector unit during said inspiration into said common expiration and inspiration line and into said circle system, a fresh gas delivery line connected to said patient circle system at a fresh gas connection, said fresh gas connection being located downstream of said reflector connection in said patient circle system, a gas sensor unit, said method comprising: with said gas sensor unit, measuring said at least one property of said gas stream upstream of said fresh gas connection and downstream of said volume reflector unit with said gas sensor unit; andin said control unit, automatically detecting said reflector driving gas crossing over said volume reflector during said inspiration dependent on said at least one property of said gas stream measured by said gas sensor unit. 37. A non-transitory computer-readable data storage medium encoded with programming instructions, said data storage medium being loaded into a computerized control unit of an anesthetic breathing apparatus comprising a patient circle system adapted to interact with a patient to allow re-breathing by the patient of gases exhaled by the patient, a common expiration and inspiration line in fluid communication with said patient circle, a volume reflector unit located in said common expiration and inspiration line, said volume reflector unit having a proximal end and a distal end, said distal end being connected via a reflector connection to said patient circle system, and said volume reflector unit comprising a reflector volume that receives patient gases from the patient circle system during expiration and said volume reflector unit being configured to return said patient gases from the reflector volume into the patient circle system during a subsequent inspiration, a reflector driving gas line configured to push a reflector driving gas into said proximal end of said volume reflector unit and to push said patient gases out of said distal end of said volume reflector unit during said inspiration into said common expiration and inspiration line and into said circle system, a fresh gas delivery line connected to said patient circle system at a fresh gas connection, said fresh gas connection being located downstream of said reflector connection in said patient circle system, a gas sensor unit configured to measure at least one property of a gas stream upstream of said fresh gas connection and downstream of said volume reflector unit and to generate a gas sensor signal representing said at least one property, said programming instructions causing said control unit to: receive said gas sensor signal and to detect, based on said at least one property of said gas stream measured by said gas sensor unit, a reflector driving gas that crosses over said reflector during said inspiration; andautomatically control admixing of said reflector driving gas crossing over said volume reflector unit into said circle system by automatically setting an operational mode, via said control unit, upon detecting said reflector driving gas crossing over said volume reflector unit during said inspiration, dependent on said at least one property of said gas stream measured by said gas sensor unit. 38. A non-transitory computer-readable data storage medium encoded with programming instructions, said data storage medium being loaded into a computerized control unit of an anesthetic breathing apparatus comprising a patient circle system adapted to interact with a patient to allow re-breathing by the patient of gases exhaled by the patient, a common expiration and inspiration line in fluid communication with said patient circle, a volume reflector unit located in said common expiration and inspiration line, said volume reflector unit having a proximal end and a distal end, said distal end being connected via a reflector connection to said patient circle system, and said volume reflector unit comprising a reflector volume that receives patient gases from the patient circle system during expiration and said volume reflector unit being configured to return said patient gases from the reflector volume into the patient circle system during a subsequent inspiration, a reflector driving gas line configured to push a reflector driving gas into said proximal end of said volume reflector unit and to push said patient gases out of said distal end of said volume reflector unit during said inspiration into said common expiration and inspiration line and into said circle system, a fresh gas delivery line connected to said patient circle system at a fresh gas connection, said fresh gas connection being located downstream of said reflector connection in said patient circle system, and a gas sensor unit, said programming instructions causing said control unit to: operate said gas sensor unit to measure said at least one property of said gas stream upstream of said fresh gas connection and downstream of said volume reflector unit with said gas sensor unit; andautomatically detect said reflector driving gas crossing over said volume reflector during said inspiration dependent on said at least one property of said gas stream measured by said gas sensor unit.