Todd W Allum, 494052 Emerson Dr, Livermore, CA 94551

8118024, Feb 21, 2012

Jul 13, 2006

11/486346

Douglas F. DeVries - Kenmore WA, US
Todd Allum - Redlands CA, US

CareFusion 203, Inc. - San Diego CA

A61M 16/00
A62B 9/02

12820421, 12820024, 12820418, 12820524

A portable mechanical ventilator having a ROOTS blower is configured to provide a desired gas flow and pressure to a patient circuit. The mechanical ventilator includes a flow meter operative to measure gas flow produced by the ROOTS blower and an exhalation control module configured to operate an exhalation valve connected to the patient circuit. A bias valve connected between the ROOTS blower and the patient circuit is specifically configured to generate a bias pressure relative to the patient circuit pressure at the exhalation control module. The bias valve is further configured to attenuate pulsating gas flow produced by the ROOTS blower such that gas flowing to the mass flow meter exhibits a substantially constant pressure characteristic. The bias pressure facilitates closing of the exhalation valve at the start of inspiration, regulates positive end expiratory pressure during exhalation, and purges sense lines via a pressure transducer module.

D662200, Jun 19, 2012

Mar 31, 2011

29/388700

Darius Eghbal - Oakland CA, US
Todd W. Allum - Livermore CA, US
Joseph Cipollone - Laguna Niguel CA, US
Anthony D. Wondka - Thousand Oaks CA, US

Breathe Technologies, Inc. - Irvine CA

2902

D241101, D241105

8479379, Jul 9, 2013

Nov 3, 2008

12/263769

Todd W. Allum - Livermore CA, US
Edgardo F. Marcello - Irvine CA, US
Stephen C. Hanson - Palm Desert CA, US

CareFusion 202, Inc. - San Diego CA

B23P 21/00
F01C 21/00

29714, 29705, 29709, 292815, 29468, 2940705, 2940708, 2988202, 418189, 73487, 73570

Roots-type blowers with helical cycloidal rotors exhibit variation in leakback flow with angular position intrinsic to these rotor geometries. Calibration of individual blowers using a combination of high-resolution alignment and enhanced detection of residual noise phenomena permits noise in as-produced blowers to be significantly attenuated. Intrinsic lower limits of noise induced by leakback variation are associated with manufacturing tolerances, necessary clearances, and particular geometric considerations. Gross alignment errors (excluding contact between rotors) produce a characteristic noise pulse rate that is three times the shaft rate. Proper alignment suppresses this and reveals a pulse sequence at double this rate and at about half of the amplitude of faulty alignment. The novel process explains the error mechanisms and defines repeatable calibration methods for a mass-production environment, introducing appropriate gauges and methods for the task.

2009014, Jun 4, 2009

Mar 18, 2008

12/050541

Todd W. ALLUM - Redlands CA, US

Pulmonetic Systems, Inc. - Minneapolis MN

F01C 1/24

4182065, 4182061

A Roots-type blower with helical cycloidal rotors features relief recesses in the chamber walls, isolated from the input and output ports. The relief recesses counter variation in leakback flow with angular position intrinsic to helical cycloidal rotors, attenuating a noise source.

2009025, Oct 8, 2009

Apr 8, 2008

12/099588

Todd W. Allum - Redlands CA, US
Malcom R. Williams - San Clemente CA, US
Joseph Cipollone - Moreno Valley CA, US

PULMONETIC SYSTEMS, INC. - Minneapolis MN

A61M 16/00

12820426

A bi-directional flow sensor is adapted for reducing pneumatic noise during pressure sensing with a flow passing through the flow sensor. The flow sensor comprises a hollow, tubular member having a throat section disposed between a ventilator end and a patient end. A flow restrictor is disposed in the throat section and is adapted to measure differential pressure in the flow. A baffle is mounted at the ventilator end and is adapted to minimize non-axial flow at pressure taps located on opposing ends of the flow restrictor. The patient end includes a flow obstruction configured to promote uniform velocity across the flow at the pressure taps during exhalation flow from the patient end to the ventilator end. The flow sensor minimizes pneumatic noise to less than 0.1 LPM to allow accurate patient flow measurement and triggering of inhalation and exhalation phases at flow rates of 0.2 LPM.

2010007, Mar 25, 2010

Aug 21, 2009

12/545708

Todd Allum - Livermore CA, US
Anthony D. Wondka - Thousand Oaks CA, US
Joseph Cipollone - San Ramon CA, US

Breathe Technologies - San Ramon CA

A61M 16/00
A61M 16/06
A61M 16/20
A61M 16/16

12820327, 12820525, 12820418, 12820524, 12820423

Methods, systems and devices are described for providing mechanical ventilation support of a patient using an open airway patient interface. The system includes gas delivery circuit and patient interface configurations to optimize performance and efficiency of the ventilation system. A ventilation system may include a ventilator for supplying ventilation gas. A patient interface may include distal end in communication with a patient airway, a proximal end in communication with ambient air, and an airflow channel between the distal end and the proximal end. A gas delivery circuit may be adapted to attach to the patient interface without occluding the patient interface to allow ambient air to flow from outside the patient interface to the patient airway. The ventilation gas may entrain air from ambient and from the patient airway.

2010025, Oct 7, 2010

Apr 2, 2010

12/753853

Anthony D. Wondka - Thousand Oaks CA, US
Todd Allum - Livermore CA, US
Joseph Cipollone - San Ramon CA, US
Gregory Kapust - San Ramon CA, US
Darius Eghbal - Oakland CA, US
Joey Aguirre - San Ramon CA, US
Anthony Gerber - San Francisco CA, US

Breathe Technologies, Inc. - San Ramon CA

A61M 16/10
A61M 16/00

12820312, 12820423

A non-invasive ventilation system may include a nasal interface. The nasal interface may include a left outer tube with a left distal end adapted to impinge a left nostril, at least one left opening in the left distal end in pneumatic communication with the left nostril, and a left proximal end of the left outer tube in fluid communication with ambient air. The left proximal end of the left outer tube may curve laterally away from a midline of a face. A right outer tube may be similarly provided. One or more left jet nozzles may direct ventilation gas into the left outer tube, and one or more right jet nozzles may direct ventilation gas into the right outer tube. The jet nozzles may be in fluid communication with the pressurized gas supply.

2010025, Oct 7, 2010

Apr 2, 2010

12/753846

Joseph Cipollone - San Ramon CA, US
Gregory Kapust - San Ramon CA, US
Todd Allum - Livermore CA, US
Anthony D. Wondka - Thousand Oaks CA, US
Darius Eghbal - Oakland CA, US
Joey Aguirre - San Ramon CA, US
Anthony Gerber - San Francisco CA, US

Breathe Technologies, Inc. - San Ramon CA

A61M 16/00

12820423

A non-invasive ventilation system may include an interface. The interface may include at least one gas delivery jet nozzle adapted to be positioned in free space and aligned to directly deliver ventilation gas into an entrance of a nose. The at least one gas delivery jet nozzle may be connected to a pressurized gas supply. The ventilation gas may entrain ambient air to elevate lung pressure, elevate lung volume, decrease the work of breathing or increase airway pressure, and wherein the ventilation gas is delivered in synchrony with phases of breathing. A support for the at least one gas delivery jet nozzle may be provided. A breath sensor may be in close proximity to the entrance of the nose. A patient may spontaneous breathe ambient air through the nose without being impeded by the interface.