System and method for monitoring composition in a sidestream system using a disposable sampling chamber

What is claimed is: 1. A detector device configured to measure composition of a flow of breathable gas received from a respiratory circuit, the detector device comprising: a housing; a removable flow path element forming an enclosed flow path for the flow of breathable gas, the removable flow path element comprising an inlet, a sampling chamber, a pump section including a membrane and an actuator interface coupled to the membrane, and an outlet, wherein the inlet and the outlet of the removable flow path element are positioned on adjacent sides of the housing; a flow path element dock formed by the housing, the flow path element dock being configured to removably engage the removable flow path element; a radiation source housed within the housing configured to emit electromagnetic radiation into the sampling chamber of the removable flow path element while the removable flow path element is docked in the flow path element dock; a sensor assembly housed within the housing configured such that, while the removable flow path element is docked in the flow path element dock and the radiation source emits electromagnetic radiation into the sampling chamber of the removable flow path element, the sensor assembly receives electromagnetic radiation that has been emitted by the radiation source and has passed through the flow path formed in the removable flow path element, the sensor assembly being further configured to generate an output signal conveying information related to one or more parameters of the received electromagnetic radiation for determining the composition of the breathable gas in the enclosed flow path; a pump actuator carried by the housing in a separate portion from the removable flow path element and driven by a pump, the pump actuator being configured to move the membrane in the pump section of the removable flow path element by moving the actuator interface to draw the flow of breathable gas through the enclosed flow path; a pressure sensor that contacts the membrane and is configured to measure a flow rate of the flow of breathable gas; and a controller housed within the housing configured to control both: (i) the pump actuator to maintain the flow rate of the flow of breathable gas through the enclosed flow path; and (ii) power provided to the radiation source; wherein the housing comprises: a first section carrying the pump actuator and a pump motor, the removable flow path element being positioned on the first section; and a second section carrying the radiation source, the sensor assembly and the controller, and the second section being configured to pivot with respect to the first section and the removable flow path element. 2. The detector device of claim 1 , wherein the pump actuator is further configured to detachably connect to the actuator interface of the removable flow path element. 3. The detector device of claim 1 , wherein the pump actuator carries a magnet configured to magnetically couple the removable flow path element to the pump actuator. 4. The detector device of claim 3 , wherein the magnet is a first magnet, the actuator interface includes a second magnet configured to magnetically couple to the first magnet, the first magnet and the second magnet comprising at least one of a permanent magnet, a ferromagnet and an electromagnetic magnet, and the first magnet comprises a protrusion configured for insertion into a corresponding recess of the actuator interface. 5. The detector device of claim 3 , wherein the pump actuator comprises a shaft with the magnet positioned at one end, the detector device comprising a spring, wherein the pump actuator is configured to be driven by the spring longitudinally in a first direction and the magnet longitudinally in an second direction opposite the first direction to move the membrane in corresponding first and second directions. 6. The detector device of claim 1 , wherein the outlet of the removable flow path element is connected with the respiratory circuit to exhaust the flow of breathable gas from the removable flow path element to the respiratory circuit. 7. The detector device of claim 1 , wherein the sampling chamber of the removable flow path element is orthogonal to the pump section of the removable flow path element. 8. The detector device of claim 1 , wherein the housing has a shape at the flow path element dock that is configured to accommodate a corresponding external shape of the removable flow path element, and wherein the flow path element dock is configured to removably engage the removable flow path element via at least one of a threaded engagement, an interlocking engagement, a friction fit and a snap fit. 9. The detector device of claim 1 , wherein the removable flow path element is configured to be removably coupled to the housing via a magnetic coupling. 10. The detector device of claim 1 , wherein the removable flow path element comprises a first guide configured to radially guide a shaft of the pump actuator to couple with the actuator interface, and wherein the housing comprises a second guide configured to restrict radial movement of the shaft, the first and second guides having a central opening to receive the shaft. 11. The detector device of claim 1 , wherein the membrane is a movable membrane and the removable flow path element comprises a rigid wall with an opening covered by the movable membrane. 12. The detector device of claim 1 , wherein the radiation source is a first radiation source configured to emit a first electromagnetic radiation, the detector device comprising a second radiation source separate from the first radiation source, the second radiation source configured to emit a second electromagnetic radiation in an optical path separate from an optical path of the first radiation source through the sampling chamber, wherein each of the separate optical paths is configured to be associated with a respective sensor of the sensor assembly, and wherein each respective sensor is configured to determine a level of a different gaseous constituent of the flow of breathable gas. 13. The device of claim 1 , wherein the second section is configured such that when the second section engages the flow path element, the detector assembly is configured to access a window of the flow path element. 14. A method of measuring composition of a flow of breathable gas received from a respiratory circuit, the method comprising acts of: removably docking a flow path element with a housing of a detector device, the removable flow path element having an inlet, a sampling chamber, a pump section comprising a membrane and an actuator interface coupled to the membrane, and an outlet, wherein the inlet and the outlet of the removable flow path element are positioned on adjacent sides of the housing; emitting electromagnetic radiation from a radiation source into the sampling chamber of the removable flow path element while the removable flow path element is docked with the housing, wherein the radiation source is housed within the housing; receiving electromagnetic radiation that has been emitted by the radiation source and has passed through an enclosed flow path of the removable flow path element onto a sensor assembly housed within the housing; generating an output signal conveying information related to one or more parameters of the electromagnetic radiation received onto the sensor assembly; actuating the membrane of the flow path element by moving the actuator interface of the removable flow path element through movement of a pump actuator carried by the housing in a separate portion from the removable flow path element to draw the flow of brea