Dynamic hyperinflation: comparison of jet ventilation versus conventional ventilation in patients with severe end-stage obstructive lung disease

High-frequency oscillatory ventilation as a rescue for severe asthma crisis in a child

Mechanical ventilation in the asthmatic child may be complicated by dynamic air trapping leading to hemodynamic compromise and cardiac arrest. High-frequency oscillatory ventilation is relatively contraindicated because it may cause hyperinflation compared to conventional mechanical ventilation. A 2-year-old girl (weight, 11 kg) with a history of asthma was admitted because of status asthmaticus. Despite treatment with intravenous methylprednisolone, continuous albuterol, terbutaline, aminophylline, and magnesium sulfate, she had persistent respiratory distress. She required endotracheal intubation and mechanical ventilation because of worsening respiratory fatigue and hypercarbia ((PCO₂), 96 mm Hg). Severe airflow obstruction persisted, and the hypercarbia worsened despite conventional mechanical ventilation (PCO₂ > 134 mm Hg). It was judged that the patient was at risk for dynamic air trapping leading to hemodynamic compromise and cardiac arrest. High-frequency oscillatory ventilation was started to overcome airflow obstruction, and a decrease in arterial PCO₂ to 87 mm Hg was observed within 2 h. High-frequency oscillatory ventilation was discontinued after 5 h, and conventional mechanical ventilation resumed. The patient was extubated after 5 days without further complications. In summary, this case shows that high-frequency oscillatory ventilation may be considered as a rescue treatment in children who have severe status asthmaticus with persistent airflow obstruction and hypercarbia unresponsive to pharmacological therapy and conventional mechanical ventilation.

Aspects of Anesthesia for Lung Transplantation

Anesthesia for lung transplantation is both a demand ing and rewarding experience. Success requires team- work, experience, knowledge of cardiorespiratory patho physiology and its anesthetic implications, appropriate use of noninvasive and invasive monitoring, and the ability to respond quickly and effectively to life- threatening perioperative events. Specific issues in clude management of a patient with end-stage lung and heart disease, lung isolation and one-lung ventilation, perioperative respiratory failure, pulmonary hyperten sion, and acute right ventricular failure. Recent ad vances include greater understanding of dynamic hyper inflation ("gas-trapping") during mechanical ventilation, perioperative use of inhaled nitric oxide and treatment of acute right ventricular failure. Successful anesthetic management leads to greater hemodynamic stability, improvement in gas exchange and a reduction in need for cardiopulmonary bypass, all of which should lead to improved patient outcome.

Jet ventilation for surgical interventions in the upper airway

The clinical applications of jet ventilation (JV) in ear, nose, and throat surgery can be best understood by the characteristics that distinguish this form of ventilation from conventional positive pressure ventilation. By definition, JV is based on the application of gas portions under high pressure through an unblocked catheter into the airway, which is open to the ambient air. Beneficial opportunities arise in JV, which otherwise are not available in regular ventilation.

Use of high-frequency jet ventilation for respiratory immobilization during coronary artery CT angiography

Multidetector ECG-gated CT angiography permits imaging of structures such as the coronary arteries and pulmonary veins with peripheral administration of contrast media. Respiratory motion artifact limits the applicability of this technique in critically ill patients due to an inability to cooperate with prolonged breath holds necessary for quality images. A case in which high-frequency jet ventilation via an uncuffed tracheostomy tube in an unmedicated patient permitted respiratory immobilization sufficient to acquire diagnostic images, is presented.

Alveolar recruitment of atelectasis under combined high-frequency jet ventilation: a computed tomography study

OBJECTIVE

To quantify the effect of superimposed high-frequency jet ventilation on lung recruitment in adult patients with acute lung injury.

DESIGN AND SETTING

Prospective clinical study in the intensive care unit of a university teaching hospital.

PATIENTS

Eight adults suffering from acute lung injury with a mean lung injury score of 2.6+/-0.6 and pronounced atelectasis in at least two lung quadrants. The cause was either pneumonia ( n=5) or postoperative sepsis ( n=3).

INTERVENTIONS

Superimposed high-frequency jet ventilation was initiated in patients following a mean of 4.4+/-1.7 days of conventional ventilation. Before and 4 h after the start of superimposed high-frequency jet ventilation differential lung volumes were determined by volumetry using computed tomography.

MEASUREMENTS AND RESULTS

Superimposed high-frequency jet ventilation significantly increased the lung volume of every patient due to alveolar recruitment. This was achieved despite lower peak inspiratory pressures and higher PaO(2)/FIO(2) ratios than with conventional ventilation.

CONCLUSIONS

Treatment with superimposed high-frequency jet ventilation for 4 h resulted in rapid alveolar recruitment in dependent lung areas, improved gas exchange, and better arterial oxygenation. It offers an effective and advantageous alternative to conventional ventilation for ventilatory management of respiratory insufficient patients.

Status asthmaticus treated by high-frequency oscillatory ventilation

We present a 2.5-year-old girl in severe asthma crisis who clinically deteriorated on conventional mechanical ventilation, but was successfully ventilated with high-frequency oscillatory ventilation (HFOV). Although HFOV is accepted as a technique for managing pediatric respiratory failure, its use in obstructive airway disease is generally thought to be contraindicated because of the risk of dynamic air-trapping. However, we suggest that obstructive airway disease can safely be managed with HFOV, provided certain conditions are met. These include the application of sufficiently high mean airway pressures to open and stent the airways ("an open airway strategy"), lower frequencies to overcome the greater attenuation of the oscillatory waves in the narrowed airways, permissive hypercapnia to enable reducing pressure swings as much as possible, longer expiratory times, and muscle paralysis to avoid spontaneous breathing.

Transesophageal echocardiographic assessment of right heart hemodynamics during high-frequency jet ventilation

STUDY OBJECTIVE

To evaluate right ventricular dimensions and function by echocardiography in anesthetized patients during superimposed high-frequency jet ventilation (HFJV).

DESIGN

Prospective clinical study.

SETTING

University hospital operating room.

PATIENTS

20 ASA physical status I patients undergoing elective minor otorhinolaryngological surgery, and undergoing conventional mechanical ventilation with subsequent superimposed HFJV.

INTERVENTIONS

Two-dimensional transesophageal echocardiography with a 5-MHz multiplane transducer to determine right ventricular dimensions and function from a mid-esophageal view. Insertion of a radial artery catheter for monitoring blood pressure and blood gases.

MEASUREMENTS AND MAIN RESULTS

Heart rate, mean arterial blood pressure, and right ventricular end-diastolic and end-systolic volumes determined by echocardiography, stroke volume, and ejection fraction. Measurements were performed after 10 minutes of conventional positive pressure ventilation (control) and after 10 minutes of subsequent superimposed HFJV at similar peak and positive end-expiratory airway pressures. Right ventricular systolic and diastolic volumes, stroke volume, and ejection fraction did not reveal statistical significant differences after transition to HFJV. Interventricular septum did not show any abnormalities in motion. In contrast, interatrial septum demonstrated momentary mid-systolic bows toward the left atrium in 9 of 17 patients (53%) during conventional ventilation, but in 15 of 17 patients (88%) during jet ventilation. Heart rate and mean arterial blood pressure remained unchanged, but arterial oxygen tension values were higher and arterial carbon dioxide tension values lower during HFJV.

CONCLUSION

Transesophageal echocardiographic evaluation of right heart hemodynamics did not show any significant difference after transition of ventilation to superimposed HFJV applying similar airway pressures. Furthermore, superimposed HFJV was safe and effective, it improved oxygenation, and it facilitated carbon dioxide elimination.