Your search keyword '"Erik K. Hartmann"' showing total 3 results

1. Pulmonary effects of expiratory-assisted small-lumen ventilation during upper airway obstruction in pigs

Author

Arno Schad, Matthias David, Jens Kamuf, Rainer Thomas, Alexander Ziebart, Bastian Duenges, Tanghua Liu, Andreas Garcia-Bardon, and Erik K. Hartmann

Subjects

Male, medicine.medical_specialty, Partial Pressure, Acute Lung Injury, Sus scrofa, Pulmonary effects, Lumen (anatomy), Lung injury, Tidal Volume, medicine, Animals, Pulmonary Gas Exchange, business.industry, Hemodynamics, respiratory system, Airway obstruction, medicine.disease, Respiration, Artificial, Tension pneumothorax, respiratory tract diseases, Airway Obstruction, Oxygen, Disease Models, Animal, Anesthesiology and Pain Medicine, Anesthesia, Breathing, Histopathology, Tracheotomy, business, Perfusion

Abstract

Summary Novel devices for small-lumen ventilation may enable effective inspiration and expiratory ventilation assistance despite airway obstruction. In this study, we investigated a porcine model of complete upper airway obstruction. After ethical approval, we randomly assigned 13 anaesthetised pigs either to small-lumen ventilation following airway obstruction (n = 8) for 30 min, or to volume-controlled ventilation (sham setting, n = 5). Small-lumen ventilation enabled adequate gas exchange over 30 min. One animal died as a result of a tension pneumothorax in this setting. Redistribution of ventilation from dorsal to central compartments and significant impairment of the distribution of ventilation/perfusion occurred. Histopathology demonstrated considerable lung injury, predominantly through differences in the dorsal dependent lung regions. Small-lumen ventilation maintained adequate gas exchange in a porcine airway obstruction model. The use of this technique for 30 min by inexperienced clinicians was associated with considerable end-expiratory collapse leading to lung injury, and may also carry the risk of severe injury.

Published

2015

2. Ventilation/perfusion ratios measured by multiple inert gas elimination during experimental cardiopulmonary resuscitation

Author

Stefan Boehme, Tanghua Liu, Klaus Ulrich Klein, Matthias David, James E. Baumgardner, Erik K. Hartmann, Klaus Markstaller, M. Szczyrba, and Bastian Duenges

Subjects

business.industry, medicine.medical_treatment, Hemodynamics, General Medicine, Return of spontaneous circulation, medicine.disease, Ventilation/perfusion ratio, Anesthesiology and Pain Medicine, Anesthesia, Ventricular fibrillation, medicine, Pulmonary shunt, Cardiopulmonary resuscitation, medicine.symptom, business, Perfusion, Shunt (electrical)

Abstract

Background During cardiopulmonary resuscitation (CPR) the ventilation/perfusion distribution (VA/Q) within the lung is difficult to assess. This experimental study examines the capability of multiple inert gas elimination (MIGET) to determine VA/Q under CPR conditions in a pig model. Methods Twenty-one anaesthetised pigs were randomised to three fractions of inspired oxygen (1.0, 0.7 or 0.21). VA/Q by micropore membrane inlet mass spectrometry-derived MIGET was determined at baseline and during CPR following induction of ventricular fibrillation. Haemodynamics, blood gases, ventilation distribution by electrical impedance tomography and return of spontaneous circulation were assessed. Intergroup differences were analysed by non-parametric testing. Results MIGET measurements were feasible in all animals with an excellent correlation of measured and predicted arterial oxygen partial pressure (R2 = 0.96, n = 21 for baseline; R2 = 0.82, n = 21 for CPR). CPR induces a significant shift from normal VA/Q ratios to the high VA/Q range. Electrical impedance tomography indicates a dorsal to ventral shift of the ventilation distribution. Diverging pulmonary shunt fractions induced by the three inspired oxygen levels considerably increased during CPR and were traceable by MIGET, while 100% oxygen most negatively influenced the VA/Q. Return of spontaneous circulation were achieved in 52% of the animals. Conclusions VA/Q assessment by MIGET is feasible during CPR and provides a novel tool for experimental purposes. Changes in VA/Q caused by different oxygen fractions are traceable during CPR. Beyond pulmonary perfusion deficits, these data imply an influence of the inspired oxygen level on VA/Q. Higher oxygen levels significantly increase shunt fractions and impair the normal VA/Q ratio.

Published

2014

3. PaO2oscillations caused by cyclic alveolar recruitment can be monitored in pig buccal mucosa microcirculation

Author

Kristin Engelhard, Klaus Ulrich Klein, Tanghua Liu, Erik K. Hartmann, Klaus Markstaller, Christian Werner, Matthias David, Line Heylen, M. Szczyrba, and Stefan Boehme

Subjects

medicine.medical_specialty, Pathology, Respiratory rate, business.industry, chemistry.chemical_element, General Medicine, Blood flow, Lung injury, Laser Doppler velocimetry, Oxygen, Microcirculation, Anesthesiology and Pain Medicine, Respiratory failure, chemistry, Internal medicine, Cardiology, Medicine, business, Oxygen saturation (medicine)

Abstract

BACKGROUND Cyclic alveolar recruitment and derecruitment play a role in the pathomechanism of acute lung injury and may lead to arterial partial pressure of oxygen (PaO(2) ) oscillations within the respiratory cycle. It remains unknown, however, if these PaO(2) oscillations are transmitted to the microcirculation. The present study investigates if PaO(2) oscillations can be detected in the pig buccal mucosa microcirculation. METHODS Respiratory failure was induced by surfactant depletion in seven pigs. PaO(2) oscillations caused by cyclic recruitment and derecruitment were measured in the thoracic aorta by fast fluorescence quenching of oxygen technology. Haemoglobin oxygen saturation, haemoglobin amount and blood flow in the buccal mucosa microcirculation were determined by combined fast white light spectrometry and laser Doppler flowmetry additionally to systolic arterial pressure. Measurements were performed during baseline conditions and during cyclic recruitment and derecruitment. RESULTS Measurements remained stable during baseline. Respiratory-dependent oscillations occurred in the systemic circulation [PaO(2) oscillations 92 (69-172) mmHg; systolic arterial pressure oscillations 33 (13-35) %] and were related to the respiratory rate (5.0 ± 0.2/min) as confirmed by Fourier analysis. Synchronised oscillations were detected to the pig buccal mucosa microcirculation [haemoglobin oxygen saturation oscillations 3.4 (2.7-4.9) %; haemoglobin amount oscillations 8.5 (2.3-13.3) %; blood flow oscillations 66 (18-87) %]. The delay between PaO(2) -\ and microcirculatory oxygen oscillations was 7.2 ± 2.8 s. CONCLUSION The present study suggests that PaO(2) oscillations caused by cyclic recruitment and derecruitment were transmitted to the buccal mucosa microcirculation. This non-invasive approach of measuring oxygen waves as a surrogate parameter of cyclic recruitment and derecruitment could be used to monitor PaO(2) oscillations at the bedside.

Published

2012