Patrick Schober

Monitoring tissue oxygenation by near infrared spectroscopy (NIRS): background and current applications.

Conventional cardiovascular monitoring may not detect tissue hypoxia, and conventional cardiovascular support aiming at global hemodynamics may not restore tissue oxygenation. NIRS offers non-invasive online monitoring of tissue oxygenation in a wide range of clinical scenarios. NIRS monitoring is commonly used to measure cerebral oxygenation (rSO2), e.g. during cardiac surgery. In this review, we will show that tissue hypoxia occurs frequently in the perioperative setting, particularly in cardiac surgery. Therefore, measuring and obtaining adequate tissue oxygenation may prevent (postoperative) complications and may thus be cost-effective. NIRS monitoring may also be used to detect tissue hypoxia in (prehospital) emergency settings, where it has prognostic significance and enables monitoring of therapeutic interventions, particularly in patients with trauma. However, optimal therapeutic agents and strategies for augmenting tissue oxygenation have yet to be determined.

Perioperative Hemodynamic Monitoring with Transesophageal Doppler Technology

Invasive cardiac output (CO) monitoring, traditionally performed with transpulmonary thermodilution techniques, is usually reserved for high-risk patients because of the inherent risks of these methods. In contrast, transesophageal Doppler (TED) technology offers a safe, quick, and less invasive method for routine measurements of CO. After esophageal insertion and focusing of the probe, the Doppler beam interrogates the descending aortic blood flow. On the basis of the measured frequency shift between the emitted and received ultrasound frequency, blood flow velocity is determined. From this velocity, combined with the simultaneously measured systolic ejection time, CO and other advanced hemodynamic variables can be calculated, including estimations of preload, afterload, and contractility. Numerous studies have validated TED-derived CO against reference methods. Although the agreement of CO values between TED and the reference methods is limited (95% limits of agreement: median 4.2 L/min, interquartile range 3.3–5.0 L/min), TED has been shown to accurately follow changes of CO over time, making it a useful device for trend monitoring. TED can be used to guide perioperative intravascular volume substitution and therapy, with vasoactive or inotropic drugs. Various studies have demonstrated a reduced postoperative morbidity and shorter length of hospital stay in patients managed with TED compared with conventional clinical management, suggesting that it may be a valuable supplement to standard perioperative monitoring. We review not only the technical basis of this method and its clinical application but also its limitations, risks, and contraindications.

Accuracy and precision of pseudo-continuous arterial spin labeling perfusion during baseline and hypercapnia: A head-to-head comparison with 15O H2O positron emission tomography

Measurements of the cerebral blood flow (CBF) and cerebrovascular reactivity (CVR) provide useful information about cerebrovascular condition and regional metabolism. Pseudo-continuous arterial spin labeling (pCASL) is a promising non-invasive MRI technique to quantitatively measure the CBF, whereas additional hypercapnic pCASL measurements are currently showing great promise to quantitatively assess the CVR. However, the introduction of pCASL at a larger scale awaits further evaluation of the exact accuracy and precision compared to the gold standard. (15)O H₂O positron emission tomography (PET) is currently regarded as the most accurate and precise method to quantitatively measure both CBF and CVR, though it is one of the more invasive methods as well. In this study we therefore assessed the accuracy and precision of quantitative pCASL-based CBF and CVR measurements by performing a head-to-head comparison with (15)O H₂O PET, based on quantitative CBF measurements during baseline and hypercapnia. We demonstrate that pCASL CBF imaging is accurate during both baseline and hypercapnia with respect to (15)O H₂O PET with a comparable precision. These results pave the way for quantitative usage of pCASL MRI in both clinical and research settings.

Cerebral blood flow and glucose metabolism in healthy volunteers measured using a high-resolution PET scanner

BackgroundPositron emission tomography (PET) allows for the measurement of cerebral blood flow (CBF; based on [15O]H2O) and cerebral metabolic rate of glucose utilization (CMRglu; based on [18 F]-2-fluoro-2-deoxy-d-glucose ([18 F]FDG)). By using kinetic modeling, quantitative CBF and CMRglu values can be obtained. However, hardware limitations led to the development of semiquantitive calculation schemes which are still widely used. In this paper, the analysis of CMRglu and CBF scans, acquired on a current state-of-the-art PET brain scanner, is presented. In particular, the correspondence between nonlinear as well as linearized methods for the determination of CBF and CMRglu is investigated. As a further step towards widespread clinical applicability, the use of an image-derived input function (IDIF) is investigated.MethodsThirteen healthy male volunteers were included in this study. Each subject had one scanning session in the fasting state, consisting of a dynamic [15O]H2O scan and a dynamic [18 F]FDG PET scan, acquired at a high-resolution research tomograph. Time-activity curves (TACs) were generated for automatically delineated and for manually drawn gray matter (GM) and white matter regions. Input functions were derived using on-line arterial blood sampling (blood sampler derived input function (BSIF)). Additionally, the possibility of using carotid artery IDIFs was investigated. Data were analyzed using nonlinear regression (NLR) of regional TACs and parametric methods.ResultsAfter quality control, 9 CMRglu and 11 CBF scans were available for analysis. Average GM CMRglu values were 0.33 ± 0.04 μmol/cm3 per minute, and average CBF values were 0.43 ± 0.09 mL/cm3 per minute. Good correlation between NLR and parametric CMRglu measurements was obtained as well as between NLR and parametric CBF values. For CMRglu Patlak linearization, BSIF and IDIF derived results were similar. The use of an IDIF, however, did not provide reliable CBF estimates.ConclusionNonlinear regression analysis, allowing for the derivation of regional CBF and CMRglu values, can be applied to data acquired with high-spatial resolution current state-of-the-art PET brain scanners. Linearized models, applied to the voxel level, resulted in comparable values. CMRglu measurements do not require invasive arterial sampling to define the input function.Trial registrationClinicalTrials.gov NCT00626080

From system to organ to cell: oxygenation and perfusion measurement in anesthesia and critical care

Maintenance or restoration of adequate tissue oxygenation is a main goal of anesthesiologic and intensive care patient management. Pathophysiological disturbances which interfere with aerobic metabolism may occur at any stage in the oxygen cascade from atmospheric gas to the mitochondria, and there is no single monitoring modality that allows comprehensive determination of “the oxygenation”. To facilitate early detection of tissue hypoxia (or hyperoxia) and to allow a goal directed therapy targeted at the underlying problem, the anesthesiologist and intensive care physician require a thorough understanding of the numerous determinants that influence cellular oxygenation. This article reviews the basic physiology of oxygen uptake and delivery to tissues as well as the options to monitor determinants of oxygenation at different stages from the alveolus to the cell.

Preconditioning, but not postconditioning, with Sevoflurane reduces pulmonary neutrophil accumulation after lower body ischaemia/reperfusion injury in rats

Background and objectives Aortic ischaemia and reperfusion may induce pulmonary sequestration of neutrophil granulocytes. Preconditioning and postconditioning with volatile anaesthetics confer protection against reperfusion injury in various organs, such as heart, kidneys or brain. We tested the hypothesis that pre‐ or postconditioning with Sevoflurane attenuates pulmonary neutrophil accumulation after ischaemia/reperfusion injury of the aorta. Methods Anaesthetized and mechanically ventilated Wistar rats underwent laparotomy and were randomly assigned to one of the following groups: Sham (n = 10), ischaemia/reperfusion (n = 8, lower body ischaemia by clamping of the infrarenal aorta for 2 h followed by 3 h of reperfusion), preconditioning (n = 10, 2.0% Sevoflurane administered over 30 min prior to ischaemia) and postconditioning (n = 9, 2.0% Sevoflurane during reperfusion). Following reperfusion, the lungs were removed for microscopic determination of neutrophil accumulation. Results Ischaemia/reperfusion induced a significant increase in pulmonary neutrophil accumulation (mean ± SD, 29.9 ± 7.4 vs. 15.8 ± 6.6 neutrophils per microscopic field in ischaemia/reperfusion vs. Sham, respectively, P < 0.001). Sevoflurane preconditioning resulted in a lower neutrophil count (20.3 ± 7.1 neutrophils, P < 0.001 vs. ischaemia/reperfusion), while postconditioning showed no effects (25.8 ± 9.8 neutrophils vs. ischaemia/reperfusion, not significant). Conclusions Preconditioning, but not postconditioning, with Sevoflurane reduces pulmonary neutrophil accumulation after ischaemia/reperfusion injury of the lower body. Since neutrophil accumulation plays a major role in the pathophysiology of acute lung injury, our data suggest a protective effect of Sevoflurane preconditioning on remote pulmonary ischaemia/reperfusion injury.

Lysis Onset Time as Diagnostic Rotational Thromboelastometry Parameter for Fast Detection of Hyperfibrinolysis

Background:Rotational thromboelastometry is increasingly used to detect hyperfibrinolysis, which is a predictor of unfavorable outcome in patients with coagulation disturbances. In an in vitro study, the authors investigated which thromboelastometric hemostatic parameters could be valuable for fast diagnosis of the severity of hyperfibrinolysis and confirmed their findings in a patient population with hyperfibrinolysis. Methods:Thromboelastometry was performed after adding increasing concentrations of tissue plasminogen activator (0 to 400 ng/ml) to citrated blood samples of 15 healthy volunteers. Lysis parameters included the clotting time, maximum clot firmness, maximum lysis, and lysis onset time (LOT). The relation of tissue plasminogen activator with the LOT was further investigated in a patient population with out-of-hospital cardiac arrest and hyperfibrinolysis. Results:The LOT showed a dose-dependent association with increasing tissue plasminogen activator concentrations. Late, intermediate, or fulminant hyperfibrinolysis was associated with an average LOT (mean ± SD) of 42.7 ± 13.8, 23.2 ± 8.2, and 17.5 ± 4.6 min in the in vitro study and estimated 42.2 ± 8.3, 29.1 ± 1.2, and 14.6 ± 7.7 min in patients, respectively. The authors found a moderately negative correlation between patient plasma tissue plasminogen activator levels and the LOT (r = −0.67; P = 0.01). Conclusion:This study shows that the LOT may be used for fast detection of severe hyperfibrinolysis, with a better resolution than the maximum lysis, and should be further evaluated for optimization of therapeutic strategies in patients with severe clot breakdown.

Repeatability of quantitative 18F-fluoromethylcholine PET/CT studies in prostate cancer

Repeatable quantification is essential when using 18F-fluoromethylcholine PET/CT to monitor treatment response in prostate cancer. It has been shown that SUV normalized to the area under the blood activity concentration curve (SUVAUC) provides a better correlation with full kinetic analysis than does standard SUV. However, the precision of SUVAUC is not known yet. The purpose of this study was to assess the repeatability of various semiquantitative 18F-fluoromethylcholine parameters in prostate cancer. Methods: Twelve patients (mean age ± SD, 64 ± 8 y) with metastasized prostate cancer underwent two sets of 18F-fluoromethylcholine PET/CT scans, on consecutive days. Each set consisted of a 30-min dynamic PET/CT scan of the chest after intravenous administration of 200 MBq of 18F-fluoromethylcholine, followed by a whole-body PET/CT scan at 40 min. The dynamic scan was used to derive the area under the blood activity concentration curve. Lesion uptake was derived from the whole-body scan using various types of volumes of interest: maximum, peak, and mean. Each of these parameters was normalized to injected activity per body weight, area under the blood activity concentration curve, and blood concentration itself at 40 min, resulting in several types of SUVs: SUV, SUVAUC, and SUVTBR. The test–retest repeatability of these metrics, as well as metabolic tumor volume (MTV) and total uptake of choline in the lesion, were studied. The level of agreement between test–retest data and reliability was assessed using Bland–Altman plots, repeatability coefficients, and intraclass correlation coefficients (ICCs). Results: A total of 67 choline-avid metastases were identified: 44 bone lesions and 23 lymph node lesions. In the case of SUVmax, the repeatability coefficients for SUV, SUVAUC, and SUVTBR were 26% (ICC, 0.95), 31% (ICC, 0.95), and 46% (ICC, 0.89), respectively. Similar values were obtained for SUVpeak and SUVmean. The repeatability of SUVAUC was comparable to that of SUVmax, SUVpeak, and SUVmean. Tissue type and tumor localization did not affect repeatability. An MTV of less than 4.2 cm3 had larger variability than larger volumes (repeatability coefficient, 45% vs. 29%; P = 0.048). The repeatability coefficient did not significantly differ between lesions with SUVpeak above or below the median value of 8.3 (19% vs. 28%; P = 0.264). Conclusion: The repeatability of SUVAUC was comparable to that of standard SUV. The repeatability coefficients of various semiquantitative 18F-fluoromethylcholine parameters (SUV, MTV, and total uptake in the lesion) were approximately 35%. Larger differences are likely to represent treatment effects.

Transesophageal Doppler devices: A technical review

Monitoring of aortic blood flow, conducting large portions of the cardiac output (CO), allows conclusions on the global hemodynamic status of patients. For this purpose, transesophageal Doppler (TED) devices have been developed, which interrogate the descending aorta and calculate aortic blood flow velocity using the Doppler principle. The recorded velocity–time curve can be used to estimate CO as well other advanced hemodynamic parameters such as preload, afterload and myocardial contractility. Clinical studies in perioperative patients have demonstrated a reduced postoperative morbidity and shorter length of hospital stay when TED is used to guide fluid management. However, several assumptions are needed to translate the measured Doppler frequency shift to hemo- dynamic variables and discrepancies between the assumed and the actual condition may introduce a considerable risk for erroneous calculations. A correct interpretation of the displayed parameters requires profound knowledge on the technical basis of this method as well as its technical limitations. Our review focuses on these technical aspects which the clinician should be familiar with to allow proper use of TED monitoring devices.

Inverse intubation in entrapped trauma casualties: a simulator based, randomised cross-over comparison of direct, indirect and video laryngoscopy.

Background Airway management in entrapped casualties with restricted access to the head is challenging. If tracheal intubation is required and conventional laryngoscopy is not possible, intubation must be attempted in a face-to-face approach. Traditionally, this is performed with a standard laryngoscope held in the right hand with the blade facing upward. Recently, alternative methods have been developed to facilitate difficult intubations, and we hypothesised that such techniques are also useful for face-to-face intubations. Methods 24 (trainee) anaesthesiologists attempted tracheal intubation in a patient simulator (SimMan, Laerdal, Norway) using three techniques in random order: (1) direct laryngoscopy (Macintosh blade #3), (2) indirect optical laryngoscopy (Airtraq, Prodol, Spain) and (3) video laryngoscopy (McGrath, Aircraft Medical, UK). The manikin was sitting with the neck immobilised and only accessible from the left anterolateral side. Success rate (percentage (95% CI)) and tube insertion time (median (IQR)) were recorded. Results Success rate did not differ significantly (Airtraq and McGrath 100% (84% to 100%), direct laryngoscopy 88% (68% to 96%)). Intubation was faster with Airtraq (25 s (22–34), p<0.001) and direct laryngoscopy (34 s (22–48), p<0.05) compared with the McGrath technique (55 s (37–96)). Conclusions All three techniques have a high success rate, but the usefulness of the video laryngoscope is limited due to longer intubation duration. Inverse direct laryngoscopy showed reasonable intubation times and, given the widespread availability of Macintosh laryngoscopes, seems a useful technique. Intubation was always successful and tended to be fastest with the Airtraq device, suggesting that this technique may be a promising alternative.