Multi-mode respiratory therapy apparatus, system, and method

The invention claimed is: 1. A respiratory therapy apparatus comprising a housing having a bottom wall, a pneumatic system carried by the housing, the pneumatic system including a first pressure source, at least one valve, and control circuitry, a pneumatic patient circuit, an outlet port carried by the housing, the pneumatic system being configured to deliver respiratory therapy to a patient via the outlet port and the pneumatic patient circuit, a nebulizer coupled to the pneumatic patient circuit, a nebulizer tray selectively couplable to a bottom of the housing when in a position of use so as to underlie at least a majority of the bottom wall, and a second pressure source carried by the nebulizer tray and operable to provide pressurized air to the nebulizer. 2. The respiratory therapy apparatus of claim 1 , wherein the first pressure source comprises a blower and the second pressure source comprises a pump. 3. The respiratory therapy apparatus of claim 1 , wherein the bottom wall of the housing has an opening through which an electrical cable is routed from the control circuitry to the second pressure source, the control circuitry being configured to turn the second pressure source on and off in response to user inputs. 4. The respiratory therapy apparatus of claim 3 , further comprising a graphical user interface (GUI) carried by the housing and coupled to the control circuitry, the GUI being operable to display at least one icon that is selectable by a user to turn the second pressure source on and off. 5. The respiratory therapy apparatus of claim 4 , wherein the at least one icon includes a nebulizer icon that is pressed successively to turn the second pressure source on and off. 6. The respiratory therapy apparatus of claim 5 , wherein the nebulizer icon is color coded to indicate whether the second pressure source is on or off. 7. The respiratory therapy apparatus of claim 3 , wherein a temperature signal from a temperature sensor located inside an interior region of the housing above the bottom wall is used by the control circuitry to turn the second pressure source off in response to the temperature signal indicating that a threshold temperature has been reached or exceeded. 8. The respiratory therapy apparatus of claim 7 , wherein the temperature signal from the temperature sensor is also used by the control circuitry to turn the first pressure source off in response to the temperature signal indicating that the threshold temperature has been reached or exceeded. 9. The respiratory therapy apparatus of claim 1 , wherein the second pressure source is operable regardless of whether the pneumatic system is being operated to deliver respiratory therapy to the patient. 10. The respiratory therapy apparatus of claim 9 , wherein, in the absence of respiratory therapy being delivered to the patient by the pneumatic system, the first pressure source is operated to deliver a minimum threshold positive pressure to the outlet port when the second pressure source is operated to provide pressurized air to the nebulizer. 11. The respiratory therapy apparatus of claim 10 , wherein the minimum threshold of positive pressure comprises about 5 centimeters of water (cmH2O). 12. The respiratory therapy apparatus of claim 1 , wherein the pneumatic patient circuit comprises a hose and a patient interface, the hose being coupled to the outlet port and the nebulizer being coupled to the patient interface, and further comprising a nebulizer port coupled to the tray and a tube that extends from the nebulizer port to the nebulizer. 13. The respiratory therapy apparatus of claim 12 , wherein the hose has a first outer diameter, the tube has a second outer diameter, and the first outer diameter is larger than the second outer diameter. 14. The respiratory therapy apparatus of claim 12 , wherein the hose comprises a corrugated hose having corrugations and the tube is devoid of corrugations. 15. The respiratory therapy apparatus of claim 12 , wherein the pneumatic patient circuit further comprises a filter housing having a first end configured to couple to the outlet port and a second end configured to attach to a first terminal end of the hose, a pneumatic passage extends between the first end and the second end of the filter housing, the filter housing further includes a first antenna surrounding the pneumatic passage and a transponder chip electrically coupled to the antenna. 16. The respiratory therapy apparatus of claim 15 , wherein the pneumatic circuit further comprises a filter carried by the filter housing, the first antenna and the transponder chip being situated between the filter and the second end of the filter housing such that filter is situated between the first end and the antenna and transponder chip. 17. The respiratory therapy apparatus of claim 15 , wherein the outlet port has an outlet passage therethrough and further comprising a second antenna surrounding the outlet passage. 18. The respiratory therapy apparatus of claim 17 , wherein the second antenna is operable to emit energy to the first antenna to power the transponder chip. 19. The respiratory therapy apparatus of claim 17 , wherein the control circuitry reads data from the transponder chip that is transmitted from the first antenna to the second antenna, the data including a total number of prior uses of the filter housing during prior sessions of respiratory therapy. 20. The respiratory therapy apparatus of claim 19 , wherein the control circuitry is configured to write new data to the transponder chip, the new data being transmitted from the second antenna to the first antenna, and the new data including a new total number of uses of the filter housing which comprises incrementing by one the total number of prior uses of the filter housing. 21. The respiratory therapy apparatus of claim 1 , wherein the control circuitry includes a graphical user interface (GUI) and a controller, the controller commanding the GUI to display a plurality of navigable screens that are usable to control features and functions of the respiratory therapy apparatus, a first group of screens of the plurality of navigable screens being usable to establish wireless communication between the control circuitry and a scanner which is operable to scan identification (ID) bar codes of the patient and a respiratory therapist for storage in the memory of the control circuitry, a second group of screens of the plurality of navigable screens being usable to select a first set of operating parameters for a first respiratory therapy, a third group of screens of the plurality of navigable screens being usable to select a second set of operating parameters for a second respiratory therapy, and a fourth group of screens of the plurality of navigable screens being usable to establish wireless communication between the control circuitry and a patient monitor that is operable to sense a physiological parameter of the patient.