DISCLAIMER:
This page contains scientific and medical publications for purposes of scientific information exchange. These publications may discuss uses that have not been approved or cleared by the US Food and Drug Administration. The publications linked to on this site are all third-party peer-reveiwed publications or documents from scientific meetings which disclose any contribution of devices and/or technical support by Bunnell, in accordance with the publisher’s conflict-of-interest disclosure policy. The Life Pulse HFV is indicated for use in ventilating critically ill infants with pulmonary interstitial emphysema (PIE). Infants studied ranged in birth weight from 750 to 3,529 grams and in gestational age from 24 to 41 weeks. The Life Pulse High Frequency Ventilator is also indicated for use in ventilating critically ill infants with respiratory distress syndrome (RDS) complicated by pulmonary air leaks who are, in the opinion of their physicians, failing on conventional ventilation. The infants studied ranged in birth weight from 600 to 3,660 grams and in gestational age from 24 to 38 weeks.
This page contains scientific and medical publications for purposes of scientific information exchange. These publications may discuss uses that have not been approved or cleared by the US Food and Drug Administration. The publications linked to on this site are all third-party peer-reveiwed publications or documents from scientific meetings which disclose any contribution of devices and/or technical support by Bunnell, in accordance with the publisher’s conflict-of-interest disclosure policy. The Life Pulse HFV is indicated for use in ventilating critically ill infants with pulmonary interstitial emphysema (PIE). Infants studied ranged in birth weight from 750 to 3,529 grams and in gestational age from 24 to 41 weeks. The Life Pulse High Frequency Ventilator is also indicated for use in ventilating critically ill infants with respiratory distress syndrome (RDS) complicated by pulmonary air leaks who are, in the opinion of their physicians, failing on conventional ventilation. The infants studied ranged in birth weight from 600 to 3,660 grams and in gestational age from 24 to 38 weeks.
ADDITIONAL ARTICLES & ABSTRACTS
By Topic
Summary of Abstracts
Airleaks
Decreased Gas Flow through Pneumothoraces in Neonates Receiving High-Frequency Jet versus Conventional Ventilation
Multicenter Controlled Trial Comparing High-Frequency Jet Ventilation and Conventional Mechanical Ventilation in Newborn Infants with Pulmonary Interstitial Emphysema
Use of High-Frequency Jet Ventilation in the Management of Congenital Tracheosophageal Fistula Associated with Respiratory Distress Syndrome
ARDS
High-Frequency Jet Ventilation in Children with the Adult Respiratory Distress Syndrome Complicated by Pulmonary Barotrauma
Cardiac
High-Frequency Jet Ventilation for Respiratory Failure After Congenital Heart Surgery
High-Frequency Jet Ventilation Improves Cardiac Function After the Fontan Procedure
High-Frequency Jet Versus Conventional Ventilation in Infants Undergoing Blalock - Taussig Shunts
Chronic Lung Disease
High-Frequency Jet Ventilation Improves Gas Exchange in Extremely Immature Infants with Evolving Chronic Disease
HFV Comparisons
Comparison of HFOV and HFJV in Cats with Normal Lungs
Proximal and Tracheal Airway Pressures During Different Modes of Mechanical Ventilation an Animal Model Study
Neonates with PPHN Treated with (iNO) and HFOV Compared to (iNO) and HFJV
Switching to HFJV from HFOV
Using HFJV to Monitor HFOV
Use of High-Frequency Jet Ventilation in Neonates with Hypoxemia Refractory to High Frequency Oscillatory Ventilation
iNO
Inhaled Nitric Oxide (iNO) Delivery with HFJV
Neonates with PPHN Treated with (iNO) and HFOV Compared to (iNO) and HFJV
Meconium Aspiration
Meconium Aspiration and HFJV
Congenital Diaphragmatic Hernia
Protocolized approach to the management of congenital diaphragmatic hernia: benefits of reducing variability in care
HFJV during Initial Management, Stabilization, and Transport of Newborn Infants with Congential Diaphragmatic Hernia: A Case Series
Heliox
Heliox Administration During HFJV Augments Carbon Dioxide Clearance
HFJV Using a Helium-Oxygen Mixture
PPHN
Neonates with PPHN Treated with (iNO) and HFOV Compared to (iNO) and HFJV
Controlled Prospective Randomized Comparison HFJV and CMV in Neonates with Respiratory Failure and PPHN
RDS
Multicenter Controlled Clinical Trial of High-Frequency Jet Ventilation in Preterm Infants with Uncomplicated RDS
Ventilatory Response to Combined HFJV and CMV for the Rescue Treatment of Severe Neonatal Lung Disease
Transport
Safety and Efficacy of High-Frequency Jet Ventilation in Neonatal Transport
HFJV Fundamentals
High PEEP During HFJV Improves Oxygenation and Ventilation in Preterm Lambs
Setting PEEP During HFJV to Replicate MAP of HFOV
Effect of Closed Endotracheal Tube Suction Method, Catheter Size, and Post-Suction Recruitment During High-Frequency Jet Ventilation in an Animal Model
Mean Airway Pressure and Mean Alveolar Pressure During High-Frequency Jet Ventilation in Rabbits
A General Dimensionless Equation of Gas Transport by High-Frequency Ventilation - Venegas
The Respiratory Dead Space - Henderson
Case Studies
Two Case Studies
Diagnosis-Related Criteria in the Consideration of Extracorporeal Membrane Oxygenation in Neonates Previously Treated with High-Frequency Jet Ventilation
Marked Reduction in Mean Airway Pressure and Oxygenation Index Using High Frequency Jet Ventilation in Neonates with Refractory Hypoxemic Respiratory Failure
High-Frequency Jet Ventilation and Surfactant Treatment of Newborns with Severe Respiratory Failure
Ventilation of a 7 year old Victim of Crush Injury to the Upper Chest with Tracheobronchial Tears Using High Frequency Jet Ventilation
Summary of Abstracts
Airleaks
Decreased Gas Flow through Pneumothoraces in Neonates Receiving High-Frequency Jet versus Conventional Ventilation
Multicenter Controlled Trial Comparing High-Frequency Jet Ventilation and Conventional Mechanical Ventilation in Newborn Infants with Pulmonary Interstitial Emphysema
Use of High-Frequency Jet Ventilation in the Management of Congenital Tracheosophageal Fistula Associated with Respiratory Distress Syndrome
ARDS
High-Frequency Jet Ventilation in Children with the Adult Respiratory Distress Syndrome Complicated by Pulmonary Barotrauma
Cardiac
High-Frequency Jet Ventilation for Respiratory Failure After Congenital Heart Surgery
High-Frequency Jet Ventilation Improves Cardiac Function After the Fontan Procedure
High-Frequency Jet Versus Conventional Ventilation in Infants Undergoing Blalock - Taussig Shunts
Chronic Lung Disease
High-Frequency Jet Ventilation Improves Gas Exchange in Extremely Immature Infants with Evolving Chronic Disease
HFV Comparisons
Comparison of HFOV and HFJV in Cats with Normal Lungs
Proximal and Tracheal Airway Pressures During Different Modes of Mechanical Ventilation an Animal Model Study
Neonates with PPHN Treated with (iNO) and HFOV Compared to (iNO) and HFJV
Switching to HFJV from HFOV
Using HFJV to Monitor HFOV
Use of High-Frequency Jet Ventilation in Neonates with Hypoxemia Refractory to High Frequency Oscillatory Ventilation
iNO
Inhaled Nitric Oxide (iNO) Delivery with HFJV
Neonates with PPHN Treated with (iNO) and HFOV Compared to (iNO) and HFJV
Meconium Aspiration
Meconium Aspiration and HFJV
Congenital Diaphragmatic Hernia
Protocolized approach to the management of congenital diaphragmatic hernia: benefits of reducing variability in care
HFJV during Initial Management, Stabilization, and Transport of Newborn Infants with Congential Diaphragmatic Hernia: A Case Series
Heliox
Heliox Administration During HFJV Augments Carbon Dioxide Clearance
HFJV Using a Helium-Oxygen Mixture
PPHN
Neonates with PPHN Treated with (iNO) and HFOV Compared to (iNO) and HFJV
Controlled Prospective Randomized Comparison HFJV and CMV in Neonates with Respiratory Failure and PPHN
RDS
Multicenter Controlled Clinical Trial of High-Frequency Jet Ventilation in Preterm Infants with Uncomplicated RDS
Ventilatory Response to Combined HFJV and CMV for the Rescue Treatment of Severe Neonatal Lung Disease
Transport
Safety and Efficacy of High-Frequency Jet Ventilation in Neonatal Transport
HFJV Fundamentals
High PEEP During HFJV Improves Oxygenation and Ventilation in Preterm Lambs
Setting PEEP During HFJV to Replicate MAP of HFOV
Effect of Closed Endotracheal Tube Suction Method, Catheter Size, and Post-Suction Recruitment During High-Frequency Jet Ventilation in an Animal Model
Mean Airway Pressure and Mean Alveolar Pressure During High-Frequency Jet Ventilation in Rabbits
A General Dimensionless Equation of Gas Transport by High-Frequency Ventilation - Venegas
The Respiratory Dead Space - Henderson
Case Studies
Two Case Studies
Diagnosis-Related Criteria in the Consideration of Extracorporeal Membrane Oxygenation in Neonates Previously Treated with High-Frequency Jet Ventilation
Marked Reduction in Mean Airway Pressure and Oxygenation Index Using High Frequency Jet Ventilation in Neonates with Refractory Hypoxemic Respiratory Failure
High-Frequency Jet Ventilation and Surfactant Treatment of Newborns with Severe Respiratory Failure
Ventilation of a 7 year old Victim of Crush Injury to the Upper Chest with Tracheobronchial Tears Using High Frequency Jet Ventilation
