Evaluation of a Clinical Decision Support System for the most evidence-based approach to managing perioperative anticoagulation.

STUDY OBJECTIVE: We explored the feasibility of a Clinical Decision Support System (CDSS) to guide evidence-based perioperative anticoagulation. DESIGN: Prospective randomised clinical management simulation multicentre study. SETTING: Five University and 11 general hospitals in Germany. PARTICIPANTS: We enrolled physicians (anaesthesiologist (n = 73), trauma surgeons (n = 2), unknown (n = 1)) with different professional experience. INTERVENTIONS: A CDSS based on a multiple-choice test was developed and validated at the University Hospital of Frankfurt (phase-I). The CDSS comprised European guidelines for the management of anticoagulation in cardiology, cardio-thoracic, non-cardio-thoracic surgery and anaesthesiology. Phase-II compared the efficiency of physicians in identifying evidence-based approach of managing perioperative anticoagulation. In total 168 physicians were randomised to CDSS (PERI-KOAG) or CONTROL. MEASUREMENTS: Overall mean score and association of processing time and professional experience were analysed. The multiple-choice test consists of 11 cases and two correct answers per question were required to gain 100% success rate (=22 points). MAIN RESULTS: In total 76 physicians completed the questionnaire (n = 42 PERI-KOAG; n = 34 CONTROL; attrition rate 54%). Overall mean score (max. 100% = 22 points) was significantly higher in PERI-KOAG compared to CONTROL (82 ± 15% vs. 70 ± 10%; 18 ± 3 vs. 15 ± 2 points; P = 0.0003). A longer processing time is associated with significantly increased overall mean scores in PERI-KOAG (≥33 min. 89 ± 10% (20 ± 2 points) vs. <33 min. 73 ± 15% (16 ± 3 points), P = 0.0005) but not in CONTROL (≥33 min. 74 ± 13% (16 ± 3 points) vs. <33 min. 69 ± 9% (15 ± 2 points), P = 0.11). Within PERI-KOAG, there is a tendency towards higher results within the more experienced group (>5 years), but no significant difference to less (≤5 years) experienced colleagues (87 ± 10% (19 ± 2 points) vs. 78 ± 17% (17 ± 4 points), P = 0.08). However, an association between professional experience and success rate in CONTROL has not been shown (71 ± 8% vs. 70 ± 13%, 16 ± 2 vs. 15 ± 3 points; P = 0.66). CONCLUSIONS: CDSS significantly improved the identification of evidence-based treatment approaches. A precise usage of CDSS is mandatory to maximise efficiency.

The janus-kinase inhibitor ruxolitinib in SARS-CoV-2 induced acute respiratory distress syndrome (ARDS).

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) causes COVID-19 (coronavirus disease 2019), which is associated with high morbidity and mortality, especially in elder patients. Acute respiratory distress syndrome (ARDS) is a life-threatening complication of COVID-19 and has been linked with severe hyperinflammation. Dexamethasone has emerged as standard of care for COVID-19 associated respiratory failure. In a non-randomized prospective phase II multi-center study, we asked whether targeted inhibition of Janus kinase-mediated cytokine signaling using ruxolitinib is feasible and efficacious in SARS-CoV-2- induced ARDS with hyperinflammation. Sixteen SARS-CoV-2 infected patients requiring invasive mechanical ventilation for ARDS were treated with ruxolitinib in addition to standard treatment. Ruxolitinib treatment was well tolerated and 13 patients survived at least the first 28 days on treatment, which was the primary endpoint of the trial. Immediate start of ruxolitinib after deterioration was associated with improved outcome, as was a lymphocyte-to-neutrophils ratio above 0.07. Together, treatment with the janus-kinase inhibitor ruxolitinib is feasible and might be efficacious in COVID-19 induced ARDS patients requiring invasive mechanical ventilation. The trial has been registered under EudraCT-No.: 2020-001732-10 and NCT04359290.

Therapeutic hypercapnia for prevention of secondary ischemia after severe subarachnoid hemorrhage: physiological responses to continuous hypercapnia.

Temporary hypercapnia has been shown to increase cerebral blood flow (CBF) and might be used as a therapeutical tool in patients with severe subarachnoid hemorrhage (SAH). It was the aim of this study was to investigate the optimum duration of hypercapnia. This point is assumed to be the time at which buffer systems become active, cause an adaptation to changes of the arterial partial pressure of carbon dioxide (PaCO2) and annihilate a possible therapeutic effect. In this prospective interventional study in a neurosurgical ICU the arterial partial pressure of carbon dioxide (PaCO2) was increased to a target range of 55 mmHg for 120 min by modification of the respiratory minute volume (RMV) one time a day between day 4 and 14 in 12 mechanically ventilated poor-grade SAH-patients. Arterial blood gases were measured every 15 min. CBF and brain tissue oxygen saturation (StiO2) were the primary and secondary end points. Intracranial pressure (ICP) was controlled by an external ventricular drainage. Under continuous hypercapnia (PaCO2 of 53.17 ± 5.07), CBF was significantly elevated between 15 and 120 min after the start of hypercapnia. During the course of the trial intervention, cardiac output also increased significantly. To assess the direct effect of hypercapnia on brain perfusion, the increase of CBF was corrected by the parallel increase of cardiac output. The maximum direct CBF enhancing effect of hypercapnia of 32% was noted at 45 min after the start of hypercapnia. Thereafter, the CBF enhancing slowly declined. No relevant adverse effects were observed. CBF and StiO2 reproducibly increased by controlled hypercapnia in all patients. After 45 min, the curve of CBF enhancement showed an inflection point when corrected by cardiac output. It is concluded that 45 min might be the optimum duration for a therapeutic use and may provide an optimal balance between the benefits of hypercapnia and risks of a negative rebound effect after return to normal ventilation parameters.Trial registration: The study was approved by the institutional ethics committee (AZ 230/14) and registered at ClinicalTrials.gov (Trial-ID: NCT01799525). Registered 01/01/2015.

[Update Extracorporeal Lung Support]. / Organersatzverfahren: Update Lungenersatzverfahren.

Extracorporeal lung support is increasingly implemented worldwide in clinical practice in patients with severe acute respiratory distress syndrome (ARDS) and is required when mechanical ventilation is unable to establish sufficient pulmonary gas exchange or if the respirator settings are persistent elevated with an increased risk for ventilator induced lung injury (VILI). Besides that, hypercapnic respiratory failure in patients with acute exacerbation of COPD (AECOPD) or acute respiratory syndrome (ARDS) is common and may require extracorporeal elimination of carbon dioxide by ECCO2R, which also has been increasingly used in the clinical setting. For both therapeutic regimes there is up to date no clear evidence for a significant reduction in mortality in patients with ARDS. Therefore extracorporeal lung support should be still considered as a rescue therapy. In this review, based on a selective literature research and clinical experience of the authors, management of patients with extracorporeal lung assist, focusing on ECMO and ECCO2R is summarized.

COVID-19 Induced Acute Respiratory Distress Syndrome-A Multicenter Observational Study.

Background: Proportions of patients dying from the coronavirus disease-19 (COVID-19) vary between different countries. We report the characteristics; clinical course and outcome of patients requiring intensive care due to COVID-19 induced acute respiratory distress syndrome (ARDS). Methods: This is a retrospective, observational multicentre study in five German secondary or tertiary care hospitals. All patients consecutively admitted to the intensive care unit (ICU) in any of the participating hospitals between March 12 and May 4, 2020 with a COVID-19 induced ARDS were included. Results: A total of 106 ICU patients were treated for COVID-19 induced ARDS, whereas severe ARDS was present in the majority of cases. Survival of ICU treatment was 65.0%. Median duration of ICU treatment was 11 days; median duration of mechanical ventilation was 9 days. The majority of ICU treated patients (75.5%) did not receive any antiviral or anti-inflammatory therapies. Venovenous (vv) ECMO was utilized in 16.3%. ICU triage with population-level decision making was not necessary at any time. Univariate analysis associated older age, diabetes mellitus or a higher SOFA score on admission with non-survival during ICU stay. Conclusions: A high level of care adhering to standard ARDS treatments lead to a good outcome in critically ill COVID-19 patients.

[Unusual Case of a a Severely Injured Toddler - Pre- and Early Hospital Treatment and Happy End Despite Obstacles]. / Ungewöhnlicher Fall eines schweren Polytraumas beim Kleinkind ­ Happy End trotz Fallstricken.

A 16-month-old boy suffers a massive trauma (open dislocated pelvic fracture and decollement with haemorrhagic shock) due to a traffic accident. We present the characteristics and obstacles in the prehospital and early hospital emergency care of this severe and rare trauma in a pediatric patient with an emphasis on medical-operational tactics.

Controlled Hypercapnia Enhances Cerebral Blood Flow and Brain Tissue Oxygenation After Aneurysmal Subarachnoid Hemorrhage: Results of a Phase 1 Study.

BACKGROUND: This study investigated if cerebral blood flow (CBF) regulation by changes of the arterial partial pressure of carbon dioxide (PaCO2) can be used therapeutically to increase CBF and improve neurological outcome after subarachnoid hemorrhage (SAH). METHODS: In 12 mechanically ventilated poor-grade SAH-patients, a daily trial intervention was performed between day 4 and 14. During this intervention, PaCO2 was decreased to 30 mmHg and then gradually increased to 40, 50, and 60 mmHg in 15-min intervals by modifications of the respiratory minute volume. CBF and brain tissue oxygen saturation (StiO2) were the primary and secondary endpoints. Intracranial pressure was controlled by an external ventricular drainage. RESULTS: CBF reproducibly decreased during hyperventilation and increased to a maximum of 141 ± 53 % of baseline during hypercapnia (PaCO2 60 mmHg) on all days between day 4 and 14 after SAH. Similarly, StiO2 increased during hypercapnia. CBF remained elevated within the first hour after resetting ventilation to baseline parameters and no rebound effect was observed within this time-span. PaCO2-reactivities of CBF and StiO2 were highest between 30 and 50 mmHg and slightly decreased at higher levels. CONCLUSION: CBF and StiO2 reproducibly increased by controlled hypercapnia of up to 60 mmHg even during the period of the maximum expected vasospasm. The absence of a rebound effect within the first hour after hypercapnia indicates that an improvement of the protocol is possible. The intervention may yield a therapeutic potential to prevent ischemic deficits after aneurysmal SAH.

Controlled transient hypercapnia: a novel approach for the treatment of delayed cerebral ischemia after subarachnoid hemorrhage?

OBJECT: The authors undertook this study to investigate whether the physiological mechanism of cerebral blood flow (CBF) regulation by alteration of the arterial partial pressure of carbon dioxide (PaCO2) can be used to increase CBF after aneurysmal subarachnoid hemorrhage (aSAH). METHODS: In 6 mechanically ventilated patients with poor-grade aSAH, the PaCO2 was first decreased to 30 mm Hg by modification of the respiratory rate, then gradually increased to 40, 50 and 60 mm Hg for 15 minutes each setting. Thereafter, the respirator settings were returned to baseline parameters. Intracerebral CBF measurement and brain tissue oxygen saturation (StiO2), measured by near-infrared spectroscopy (NIRS), were the primary and secondary end points. Intracranial pressure (ICP) was controlled by external ventricular drainage. RESULTS: A total of 60 interventions were performed in 6 patients. CBF decreased to 77% of baseline at a PaCO2 of 30 mm Hg and increased to 98%, 124%, and 143% at PaCO2 values of 40, 50, and 60 mm Hg, respectively. Simultaneously, StiO2 decreased to 94%, then increased to 99%, 105%, and 111% of baseline. A slightly elevated delivery rate of cerebrospinal fluid was noticed under continuous drainage. ICP remained constant. After returning to baseline respirator settings, both CBF and StiO2 remained elevated and only gradually returned to pre-hypercapnia values without a rebound effect. None of the patients developed secondary cerebral infarction. CONCLUSIONS: Gradual hypercapnia was well tolerated by poor-grade SAH patients. Both CBF and StiO2 reacted with a sustained elevation upon hypercapnia; this elevation outlasted the period of hypercapnia and only slowly returned to normal without a rebound effect. Elevations of ICP were well compensated by continuous CSF drainage. Hypercapnia may yield a therapeutic potential in this state of critical brain perfusion. Clinical trial registration no.: NCT01799525 ( ClinicalTrials.gov ).

[If mechanical ventilation comes to its limits: extracorporeal lung assist]. / Lungenersatzverfahren - Wenn Beatmung alleine nicht mehr reicht: Extrakorporale Lungenassistenzverfahren.

Extracorporeal lung assist can be performed pumpless by using the arterio-venous driving pressure or pumpdriven in a veno-venous mode. Oxygenation is maintained via the native lungs and depends mainly on mean airway pressure during mechanical ventilation.Extracorporeal lung assist can be part of a multimodal treatment concept in patients with acute lung injury. It aims at a further reduction of the applied tidal volume and peak pressures in order to reduce the intensity of the pulmonary and systemic inflammatory response which is the main factor for the development of multi-organ failure in this group of patients. Eventually patients with acute exacerbation of a chronic pulmonary disease might also benefit from extracorporeal ventilation.

[If the extracorporeal lung assist comes to its limit: use and management of extracorporeal membrane oxygenation in severe acute respiratory distress syndrome]. / Lungenersatzverfahren - Einsatz und Management extrakorporaler Lungenersatzverfahren.

In patients with the most severe forms of acute respiratory distress syndrome (ARDS) refractory to conventional mechanical ventilation and adjunctive or rescue therapies like kinetic therapy, inhaled vasodilators or extracorporeal CO2-elimination (extracorporeal lung assist), the use of the extracorporeal membrane oxygenation (ECMO) can secure gas exchange. Due to technical improvements and miniaturization, the new ECMO system is safer and simpler. Nowadays the ECMO-systems are heparin-coated, so that there is no need of therapeutic systemic anticoagulation, and thus bleeding complications are less frequent. Recent data suggests, that outcome of patients with severe ARDS treated with ECMO may improve. This review describes the function and the management of ECMO-therapy in ARDS-patients.

[Which perioperative tidal volume for patients with healthy lungs undergoing elective surgery? A qualitative systematic review of current evidence]. / Intraoperative Beatmung--Welches Tidalvolumen sollte bei lungengesunden Patienten angewandt werden? Eine qualitativ-systematische Ubersichtsarbeit.

BACKGROUND: Lung-protective ventilation strategies for patients suffering from acute lung injury (ALI/ARDS) are well- accepted measures to improve outcome including mortality. But what tidal volume is the best for the patient with non-injured lungs undergoing elective surgery? METHODS: We searched the literature for studies that analysed perioperative tidal volume in patients not suffering from ALI/ARDS. RESULTS: 10 studies were detected that matched our query. Mostly on patients undergoing major or cardiac surgery. CONCLUSION: Only a few studies exist which examine the effect of protective ventilation settings on healthy lungs of patients not being critical-ill. The reported results are very heterogeneous and do not strongly support a lung- protective ventilation strategy. However, apart from reasoning based on pre-clinical experimental data, there is some clinical evidence, that suggests using lower tidal volumes in patients undergoing major or cardiac surgery, even if the patient does not present with an ALI/ARDS and is not critically ill at the time when the surgical procedure is performed.