Abstract: Oscillatory ventilator configured for oscillating at a plurality of specifically tuned sinusoidal frequencies simultaneously a ventilation gas for delivery to a lung region of a patient and a ventilator control system, in communication with the oscillatory ventilator, to control a sinusoidal waveform input for the oscillatory ventilator, wherein the sinusoidal waveform input comprises the plurality of specifically tuned sinusoidal frequencies each of which sinusoidal frequencies are below the acoustic range.

Abstract: The present invention relates to systems and methods for multi-frequency oscillatory ventilation (MFOV). The system uses a broadband flow waveform more suitable for the heterogeneous mechanics of the lung. The system provides more efficient gas exchange and enhanced lung recruitment at lower airway pressures.

Abstract: Oscillatory ventilator configured for oscillating at a plurality of specifically tuned sinusoidal frequencies simultaneously a ventilation gas for delivery to a lung region of a patient and a ventilator control system, in communication with the oscillatory ventilator, to control a sinusoidal waveform input for the oscillatory ventilator, wherein the sinusoidal waveform input comprises the plurality of specifically tuned sinusoidal frequencies each of which sinusoidal frequencies are below the acoustic range.

Abstract: The present invention relates to systems and methods for multi-frequency oscillatory ventilation (MFOV). The system uses a broadband flow waveform more suitable for the heterogeneous mechanics of the lung. The system provides more efficient gas exchange and enhanced lung recruitment at lower airway pressures.

Abstract: A method and system for choosing suitable sites for catheter delivery ablative energy is provided that includes a catheter/ablation structure that is positioned on a potential ablation site on a heart. The catheter/ablation structure produces one or more electrograms recorded at the potential ablation site. A signal processing unit receives from the catheter/ablation structure the recorded one or more intercardiac electrograms from the potential ablation site and performing Fast Fourier Transform (FFT) on the recorded one or more intercardiac electrograms as so to produce one or more spectral power distributions of the potential ablation site. A display unit displays the one or more spectral power distributions so as to determine whether the potential RF ablation site exhibit necessary spectral properties for the delivery of the ablative energy. A ablative energy generator unit provides the ablative energy to the potential ablation site using the catheter/ablation structure.

Abstract: A method and system for choosing suitable sites for catheter delivery ablative energy is provided that includes a catheter/ablation structure that is positioned on a potential ablation site on a heart. The catheter/ablation structure produces one or more electrograms recorded at the potential ablation site. A signal processing unit receives from the catheter/ablation structure the recorded one or more intercardiac electrograms from the potential ablation site and performing Fast Fourier Transform (FFT) on the recorded one or more intercardiac electrograms as so to produce one or more spectral power distributions of the potential ablation site. A display unit displays the one or more spectral power distributions so as to determine whether the potential RF ablation site exhibit necessary spectral properties for the delivery of the ablative energy. A ablative energy generator unit provides the ablative energy to the potential ablation site using the catheter/ablation structure.

Abstract: A method is disclosed for determining a peak end expiratory pressure in a mechanical ventilator system for providing respiratory assistance to a patient. The method includes the steps of determining characteristic values for a plurality of frequencies at each of a plurality of peak end expiratory pressures, and selecting an optimal peak end expiratory pressure value responsive to the characteristic values.

Abstract: A pneumatic ventilation system delivers high amplitude, low frequency oscillatory flows while maintaining the load impedance at a specified mean pressure, thereby accurately controlling mean airway pressure, oscillation amplitude, and frequency content allowing use in applications to optimize high frequency ventilation protocols in patients. The pneumatic ventilation system includes a pneumatic pressure oscillator based on a proportional solenoid valve to provide forced oscillatory excitations to a respiratory system over a bandwidth suitable for mechanical impedance measurements and high frequency ventilation.