Transmission of arterial oxygen partial pressure oscillations to the cerebral microcirculation in a porcine model of acute lung injury caused by cyclic recruitment and derecruitment.

6533b7d6fe1ef96bd1265be9

RESEARCH PRODUCT

Transmission of arterial oxygen partial pressure oscillations to the cerebral microcirculation in a porcine model of acute lung injury caused by cyclic recruitment and derecruitment.

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

subject

medicine.medical_specialty Swine Acute Lung Injury chemistry.chemical_element Blood Pressure Lung injury Anesthesia General Oxygen Microcirculation Internal medicine medicine Laser-Doppler Flowmetry Animals Lung Oxygen saturation (medicine)Ventilators Mechanical business.industry Microcirculation Hemodynamics Laser Doppler velocimetry Respiration Artificial respiratory tract diseases Oxygen Oxygen Saturation Measurement Anesthesiology and Pain Medicine Blood pressure chemistry Cerebral blood flow Anesthesia Cerebrovascular Circulation Cardiology business Blood Gas Monitoring Transcutaneous Bronchoalveolar Lavage Fluid Craniotomy

description

Cyclic recruitment and derecruitment (R/D) play a key role in the pathomechanism of acute lung injury (ALI) leading to respiration-dependent oscillations of arterial partial pressure of oxygen (Pa(O(2))). These Pa(O(2)) oscillations could also be forwarded to the cerebral microcirculation.In 12 pigs, partial pressure of oxygen was measured in the thoracic aorta (Pa(O(2))) and subcortical cerebral tissue (Pbr(O(2))). Cerebral cortical haemoglobin oxygen saturation (Sbr(O(2))), cerebral blood flow (CBF), and peripheral haemoglobin saturation (Sp(O(2))) were assessed by spectroscopy and laser Doppler flowmetry. Measurements at different fractions of inspired oxygen (F(I(O(2)))) were performed at baseline and during cyclic R/D.frequency domain analysis, the Mann-Whitney test, linear models to test the influence of Pa(O(2)) and systolic arterial pressure (SAP) oscillations on cerebral measurements.Parameters [mean (SD)] remained stable during baseline. Pa(O(2)) oscillations [10.6 (8) kPa, phase(reference)], systemic arterial pressure (SAP) oscillations [20 (9) mm Hg, phase(Pa(O(2))-SAP) -33 (72)°], and Sp(O(2))oscillations [1.9 (1.7)%, phase(Pa(O(2))-Sp(O(2))) 264 (72)°] were detected during lung R/D at 1.0. Pa(O(2)) oscillations decreased [2.7 (3.5) kPa, P=0.0008] and Sp(O(2)) oscillations increased [6.8 (3.9)%, P=0.0014] at F(I(O(2))) 0.3. In the brain, synchronized Pbr(O(2)) oscillations [0.6 (0.4) kPa, phase(Pa(O(2))-Pbr(O(2))) 90 (39)°], Sbr(O(2)) oscillations [4.1 (1.5)%, phase(Pa(O(2))-Sbr(O(2))) 182 (54)°], and CBF oscillations [198 (176) AU, phase(Pa(O(2))-CBF) 201 (63)°] occurred that were dependent on Pa(O(2)) and SAP oscillations.Pa(O(2)) oscillations caused by cyclic R/D are transmitted to the cerebral microcirculation in a porcine model of ALI. These cyclic oxygen alterations could play a role in the crosstalk of acute lung and brain injury.

year	journal	country	edition	language
2013-02-01	British journal of anaesthesia

10.1093/bja/aes376 https://pubmed.ncbi.nlm.nih.gov/23103776