Coordinated control of HFCWO and cough assist devices

The invention claimed is: 1. A respiratory therapy apparatus comprising a housing; a high frequency chest wall oscillator (HFCWO) supported in the housing and operationally coupled to a garment worn on a torso of a patient to deliver a HFCWO therapy to the patient, the HFCWO therapy comprising application to the garment of a first baseline positive pressure and pressure oscillations relative to the first baseline positive pressure; a mechanical insufflator/exsufflator (MIE) supported in the housing and coupled to the patient's airway via a patient interface to deliver MIE therapy to the patient, the MIE therapy comprising cycles of a positive insufflation pressure and a negative exsufflation pressure applied to the patient's airway via the patient interface; and a controller situated in the housing and operable to control the HFCWO therapy and the MIE therapy, wherein during application of the negative exsufflation pressure to the patient's airway, the controller signals the HFCWO to apply a second baseline positive pressure to the garment thereby to provide an extra squeeze to the patient's torso during application of the negative exsufflation pressure to the patient's airway, wherein the pressure oscillations of the HFCWO therapy are turned off by the controller during the extra squeeze. 2. The respiratory therapy apparatus of claim 1 , wherein the MIE therapy further comprises a rest cycle between each application of negative exsufflation pressure to the patient's airway and the subsequent application of positive insufflation pressure to the patient's airway. 3. The respiratory therapy apparatus of claim 2 , wherein, during the rest cycle of the MIE, the HFCWO is controlled by the controller to apply the first baseline pressure and pressure oscillations to the garment. 4. The respiratory therapy apparatus of claim 2 , wherein during MIE therapy, the controller controls the MIE to provide oscillations to the positive insufflation pressure or the negative exsufflation pressure or both. 5. The respiratory therapy apparatus of claim 2 , wherein, during the rest cycle, the controller operates the MIE to apply a positive rest pressure to the patient's airway that is less than the positive insufflation pressure. 6. The respiratory therapy apparatus of claim 2 , wherein the controller has a manual mode in which a user provides manual input as to when the MIE switches between application of the positive insufflation pressure and the negative exsufflation pressure. 7. The respiratory therapy apparatus of claim 2 , wherein the controller is configured to receive parameter settings for the MIE from a user, the parameter settings including the positive insufflation pressure, the negative exsufflation pressure, a rest pressure, and a flutter frequency. 8. The respiratory therapy apparatus of claim 1 , wherein the controller is configured to receive parameter settings from a user for the MIE, the parameter settings including an insufflation time, an exsufflation time, a rest time, and a predetermined number of respiratory cycles. 9. The respiratory therapy apparatus of claim 1 , wherein the controller is configured to receive parameter settings from a user for the HFCWO, the parameter settings including an oscillation frequency, the first baseline pressure, and the second baseline pressure. 10. A respiratory therapy apparatus comprising a housing; a first therapy delivery apparatus situated in the housing and operable to provide a first respiratory therapy to a patient; a second therapy delivery apparatus situated in the housing and operable to provide a second respiratory therapy to the patient; and a controller operable to control the first therapy delivery apparatus and the second therapy delivery apparatus to deliver a respiratory therapy to the patient, wherein during the first and second respiratory therapy, an oscillatory positive pressure having a first baseline pressure is provided to the patient's torso as part of the first respiratory therapy while a positive pressure is applied to the patient's airway as part of the second respiratory therapy and a nonoscillatory positive pressure squeeze at a second baseline pressure is provided to the patient's torso as part of the first respiratory therapy while a negative pressure is applied to the patient's airway as part of the second respiratory therapy, the second baseline pressure being greater than the first baseline pressure. 11. The respiratory therapy apparatus of claim 10 , wherein the first respiratory therapy is a high frequency chest wall oscillation (HFCWO) therapy. 12. The respiratory therapy apparatus of claim 11 , wherein the first therapy delivery apparatus comprises a high frequency chest wall oscillator operationally coupled to a garment worn by the patient to deliver the HFCWO therapy to the patient. 13. The respiratory therapy apparatus of claim 10 , wherein the second respiratory therapy comprises a Mechanical Insufflation-Exsufflation (MIE) therapy. 14. The respiratory therapy apparatus of claim 13 , wherein the second respiratory therapy delivery apparatus comprises a mechanical insufflator/exsufflator operationally coupled to a patient mask, mouthpiece, or tracheal tube to deliver the MIE therapy to the patient. 15. The respiratory therapy apparatus of claim 13 , wherein the MIE therapy includes an insufflation mode, an exsufflation mode, and an optional rest mode. 16. The respiratory therapy apparatus of claim 15 , wherein, during the insufflation mode, the controller provides the second respiratory therapy to the patient while maintaining the first respiratory therapy at a baseline. 17. The respiratory therapy apparatus of claim 15 , wherein, during the exsufflation mode, the controller controls the first respiratory therapy apparatus to apply the positive pressure squeeze to the patient's torso. 18. The respiratory therapy apparatus of claim 15 , wherein, during the rest mode, the controller provides the first respiratory therapy to the patient. 19. The respiratory therapy apparatus of claim 10 , wherein the controller is configured to accept manual inputs from a user to switch the second respiratory therapy apparatus between an insufflation mode, an exsufflation mode, and a rest mode. 20. The respiratory therapy apparatus of claim 10 , wherein the controller is configured to receive parameter settings from a user, the parameter settings including an insufflation time, an exsufflation time, a rest time, and a predetermined number of cycles. 21. The respiratory therapy apparatus of claim 10 , wherein the controller is configured to receive parameter settings from a user, the parameter settings including an oscillation frequency and a baseline pressure. 22. The respiratory therapy apparatus of claim 10 , wherein the controller is configured to receive parameter settings from a user, the parameter settings including an insufflation pressure, an exsufflation pressure, a rest pressure, and a flutter frequency.