[Extracorporeal cardiopulmonary resuscitation (eCPR)]. / Extrakorporale kardiopulmonale Reanimation (eCPR).

Extracorporeal cardiopulmonary resuscitation (eCPR) is the implementation of extracorporeal membrane oxygenation (ECMO) in selected patients with cardiac arrest and may be considered when conventional CPR efforts fail, as written in the latest international guidelines. eCPR is a complex intervention that requires a highly trained team, specialized equipment, and multidisciplinary support within a healthcare system and it has the risk of several life-threatening complications. However, there are no randomized, controlled studies on eCPR, and valid predictors of benefit and outcome are lacking. Therefore, optimal timing, patient selection, location and method of implementation vary across centers. As utilization of eCPR has increased in recent years and more centers begin to perform eCPR, considerable uncertainties exist in the prehospital setting as well as in the emergency room. However, structured communication and clearly defined processes are essential especially at the interface between prehospital rescue teams and the eCPR team to achieve the highest possible benefit for cardiac arrest patients using eCPR. This article presents an algorithm for structured, evidence-based logistic considerations, patient selection, and implementation of eCPR as well as early care after establishment of extracorporeal life support (ECLS) which are mainly based on the German national recommendations for eCPR of DGIIN, DGK, DGTHG, DGfK, DGNI, DGAI, DIVI and GRC published in 2019 as well as the S3 guideline "Use of extracorporeal circulation (ECLS/ECMO) for cardiac and circulatory failure" and local standard operating procedures of the authors.

[Postcardiac arrest treatment guide]. / Praxisleitfaden für die Postreanimationsbehandlung.

BACKGROUND: Treatment after cardiac arrest has become more complex and interdisciplinary over the last few years. Thus, the clinically active intensive and emergency care physician not only has to carry out the immediate care and acute diagnostics, but also has to prognosticate the neurological outcome. AIM: The different, most important steps are presented by leading experts in the area, taking into account the interdisciplinarity and the currently valid guidelines. MATERIALS AND METHODS: Attention was paid to a concise, practice-oriented presentation. RESULTS AND DISCUSSION: The practical guide contains all important steps from the acute care to the neurological prognosis generation that are relevant for the clinically active intensive care physician.

[Transient loss of consciousness : Algorithm for the (differential) diagnosis of syncope at emergency department]. / Passagere Bewusstlosigkeit : Algorithmus für die Notaufnahme zur (Differenzial-)Diagnostik von Synkopen.

Transient loss of consciousness (TLoC) is a common complaint leading to presentation at the emergency department. This comprises a heterogeneous group of disorders including cerebral events, metabolic disturbances, intoxication, psychogenic patterns or any form of syncope. While many causes are benign and self-limited not requiring extensive in-hospital evaluation, others are potentially severe. The optimal evaluation of patients with TLoC/syncope follows a risk-adapted diagnostic algorithm in order to exclude life-threatening conditions and to identify those with high risk for further deterioration like structural heart diseases requiring further diagnostic evaluation. Low-risk patients can be discharged without further extensive diagnostic work up. This article presents an algorithm for structured, evidence-based care of the syncope patient in accordance with the recently launched "2018 ESC guidelines for the diagnosis and management of syncope" in order to ensure that patients requiring hospitalization are managed appropriately and those with benign causes are discharged safely. The English version of this algorithm is available at the end of the article under "Supplementary Material".

[Emergency Medicine : What do we need?] / Strukturen der Akut- und Notfallmedizin : Was benötigen wir?

The timely medical treatment of the population in emergency situations is an enormous challenge for the healthcare system and is becoming increasingly more important. Due to this development clinical acute and emergency medicine has undergone enormous progress and is in the process of further professionalization. Various specialist societies and medical associations have published essential position papers in recent years and demanded fundamentally new healthcare structures and assignments. Additionally, emergency medical healthcare structures and centers have already been established on the initiative of individual emergency medical specialist disciplines. The future challenge is the nationwide establishment, grouping and integration of the structures and processes within definitive healthcare centers. The main objective of all involved must be the optimal care of emergency patients.

Stereochemistry and biological activity of chlorinated lipids: a study of danicalipin A and selected diastereomers.

The syntheses of (+)-16-epi- and (+)-11,15-di-epi-danicalipin A (2 and 3) are reported. The conformations of the parent diols 5 and 6 as well as the corresponding disulfates 2 and 3 were determined on the basis of J-based configuration analysis and supported by calculations. The impact of configuration on membrane permeability in Gram-negative bacteria and mammalian cell lines was assessed as well as cytotoxicity. Although diastereomer 2 showed similar behavior to natural (+)-danicalipin A (1), strikingly, the more flexible C11,C15-epimer 3 had no effect on permeability and proved equally or more toxic towards multiple cell lines.

Temporal profiles of extracellular nitric oxide metabolites following aneurysmal subarachnoid hemorrhage.

The temporal profile of nitric oxide metabolite concentrations i.e. nitrite and nitrate (NOx) was investigated in brain parenchyma of patients following aneurysmal subarachnoid hemorrhage (SAH). In a subset of ten patients (7F/3M, age: 47 +/- 14 yrs) included in a prospective clinical trial on neurochemical intensive-care monitoring, microdialysis (MD) probes (CMA70, Sweden) were implanted at time of aneurysm surgery. Samples from patients clipped electively (n = 3) were considered "normal" in regard to SAH patients (n = 7). MD was performed for 162 +/- 63 hrs. NOx was measured off-line using a highly sensitive, fluorometric assay (2-3-diaminonaphtalene, DAN). NOx concentrations determined from electively operated patients averaged 36.7 +/- 9.6 microM (n = 59, pooled data). Regardless of the development of delayed ischemic neurological deficits (DIND), SAH patients showed a specific temporal profile of NOx consisting of an initial peak followed by an exponential decay. In detail, NOx decreased from initial values of 46.2 +/- 34.8 microM to 23.5 +/- 9.0 microM on day 6-7 after SAH (p < 0.05). Following SAH extracellular concentrations of NO metabolites decrease over time. This is in agreement with hypothetical NO scavenging by products of hemolysis. However, subsequent development of DIND cannot be explained by a lack of vasodilatory NO alone.

Apstatin, a selective inhibitor of aminopeptidase P, reduces myocardial infarct size by a kinin-dependent pathway.

1. Inhibitors of the angiotensin converting enzyme (ACE) have been shown to exert their cardioprotective actions through a kinin-dependent mechanism. ACE is not the only kinin degrading enzyme in the rat heart. 2. Since aminopeptidase P (APP) has been shown to participate in myocardial kinin metabolism to the same extent as ACE, the aims of the present study were to investigate whether (a) inhibition of APP leads to a reduction of myocardial infarct size in a rat model of acute ischaemia and reperfusion, (b) reduction of infarct size is mediated by bradykinin, and (c) a combination of APP and ACE inhibition leads to a more pronounced effect than APP inhibition alone. 3. Pentobarbital-anaesthetized rats were subjected to 30 min left coronary artery occlusion followed by 3 h reperfusion. The APP inhibitor apstatin, the ACE-inhibitor ramiprilat, or their combination were administered 5 min before ischaemia. Rats receiving HOE140, a specific B(2) receptor antagonist, were pretreated 5 min prior to enzyme inhibitors. Myocardial infarct size (IS) was determined by tetrazolium staining and expressed as percentage of the area at risk (AAR). 4. IS/AAR% was significantly reduced in rats that received apstatin (18+/-2%), ramiprilat (18+/-3%), or apstatin plus ramiprilat (20+/-4%) as compared with those receiving saline (40+/-2%), HOE (43+/-3%) or apstatin plus HOE140 (49+/-4%). 5. Apstatin reduces IS in an in vivo model of acute myocardial ischaemia and reperfusion to the same extent than ramiprilat. Cardioprotection achieved by this selective inhibitor of APP is mediated by bradykinin. Combined inhibition of APP and ACE did not result in a more pronounced reduction of IS than APP-inhibition alone.

Relation of cerebral energy metabolism and extracellular nitrite and nitrate concentrations in patients after aneurysmal subarachnoid hemorrhage.

In a prospective clinical investigation on neurochemical intensive care monitoring, the authors' aim was to elucidate the temporal profile of nitric oxide metabolite concentrations-that is, nitrite and nitrate (NO(x))--and compounds related to energy-metabolism in the cerebral interstitium of patients after aneurysmal subarachnoid hemorrhage (SAH). During aneurysm surgery, microdialysis probes were implanted in cerebral white matter of the vascular territory most likely affected by vasospasm. Temporal profiles of NO(x) were analyzed in a subset of 10 patients (7 female, 3 male, mean age = 47 +/- 14 years). Microdialysis was performed for 152 +/- 63 hours. Extracellular metabolites (glucose, lactate, pyruvate, glutamate) were recovered from the extracellular fluid of the cerebral parenchyma. NO(x) was measured using a fluorometric assay. After early surgery, SAH patients revealed characteristic decreases of NO(x) from initial values of 46.2 +/- 34.8 micromol/L to 23.5 +/- 9.0 micromol/L on day 7 after SAH (P < 0.05). Decreases in NO(x) were seen regardless of development of delayed ischemia (DIND). Overall NO(x) correlated intraindividually with glucose, lactate, and glutamate (r = 0.58, P < 0.05; r = 0.32, P < 0.05; r = 0.28, P < 0.05; respectively). After SAH, cerebral extracellular concentrations of NO metabolites decrease over time and are associated with concomitant alterations in energy-or damage-related compounds. This could be related to reduced NO availability, potentially leading to an imbalance of vasodilatory and vasoconstrictive factors. On the basis of the current findings, however, subsequent development of DIND cannot be explained by a lack of vasodilatory NO alone.

Potentiation of kinin analogues by ramiprilat is exclusively related to their degradation.

The potentiation of kinin actions represents a cardioprotective property of ACE inhibitors. Although a clear contribution to this effect is related to the inhibition of bradykinin (BK) breakdown, the high efficacy of potentiation and the ability of ACE inhibitors to provoke a B(2)-receptor-mediated response even after receptor desensitization has also triggered hypotheses concerning additional mechanisms of kinin potentiation. The application of kinin analogues with enhanced metabolic stability for the demonstration of degradation-independent mechanisms of potentiation, however, has yielded inconsistent results. Therefore, the relation between the susceptibility of B(2)-agonists to ACE and the potentiation of their actions by ACE inhibitors was investigated with the use of minimally modified kinin derivatives that varied in their degree of ACE resistance. The B(2)-agonists BK, D-Arg-[Hyp(3)]-BK, [Hyp,(3) Tyr(Me)(8)]-BK, [DeltaPhe(5)]-BK, [D-NMF(7)]-BK, and [Phe(8)psi(CH(2)-NH)Arg(9)]-BK were tested for degradation by purified rabbit ACE and for their potency in contracting the endothelium-denuded rabbit jugular vein in the absence and presence of ramiprilat. Purified ACE degraded D-Arg-[Hyp(3)]-BK and [Hyp,(3) Tyr(Me)(8)]-BK at 81% and 71% of BK degradation activity, respectively, whereas other peptides were highly ([DeltaPhe(5)]-BK) or completely ([D-NMF(7)]-BK, [Phe(8)psi(CH(2)-NH)Arg(9)]-BK) resistant. The EC(50) of BK-induced venoconstriction (1.15+/-0.2 nmol/L) was reduced by a factor of 5.7 in the presence of ramiprilat. Likewise, D-Arg-[Hyp(3)]-BK and [Hyp,(3) Tyr(Me)(8)]-BK were both significantly potentiated by a factor of 4.4, whereas the activities of the other agonists were not affected. Ramiprilat exerted no influence on the maximum contraction induced by any of the agonists. It is concluded that the potentiation of kinin analogues during ACE inhibition correlates quantitatively with the susceptibility of each substance to degradation by ACE. As such, no evidence of degradation-independent potentiating actions of ACE inhibitors could be obtained.

Pathways of bradykinin degradation in blood and plasma of normotensive and hypertensive rats.

Kinins are vasoactive peptide hormones that can confer protection against the development of hypertension. Because their efficacy is greatly influenced by the rate of enzymatic degradation, the activities of various kininases in plasma and blood of spontaneously hypertensive rats (SHR) were compared with those in normotensive Wistar-Kyoto rats (WKY) to identify pathogenic alterations. Either plasma or whole blood was incubated with bradykinin (10 microM). Bradykinin and kinin metabolites were measured by high-performance liquid chromatography. Kininase activities were determined by cumulative inhibition of angiotensin I-converting enzyme (ACE), carboxypeptidase N (CPN), and aminopeptidase P (APP), using selective inhibitors. Plasma of WKY rats degraded bradykinin at a rate of 13.3 +/- 0.94 micromol x min(-1) x l(-1). The enzymes ACE, APP, and CPN represented 92% of this kininase activity, with relative contributions of 52, 25, and 16%, respectively. Inclusion of blood cells at physiological concentrations did not extend the activities of these plasma kininases further. No differences of kinin degradation were found between WKY and SHR. The identical conditions of kinin degradation in WKY and SHR suggest no pathogenic role of kininases in the SHR model of genetic hypertension.

Potentiation of the vascular response to kinins by inhibition of myocardial kininases.

Inhibitors of angiotensin I-converting enzyme (ACE) are very efficacious in the potentiation of the actions of bradykinin (BK) and are able to provoke a B(2) receptor-mediated vasodilation even after desensitization of this receptor. Because this activity cannot be easily explained only by an inhibition of kinin degradation, direct interactions of ACE inhibitors with the B(2) receptor or its signal transduction have been hypothesized. To clarify the significance of degradation-independent potentiation, we studied the vasodilatory effects of BK and 2 degradation-resistant B(2) receptor agonists in the isolated rat heart, a model in which ACE and aminopeptidase P (APP) contribute equally to the degradation of BK. Coronary vasodilation to BK and to a peptidic (B6014) and a nonpeptidic (FR190997) degradation-resistant B(2) agonist was assessed in the presence or absence of the ACE inhibitor ramiprilat, the APP inhibitor mercaptoethanol, or both. Ramiprilat or mercaptoethanol induced leftward shifts in the BK dose-response curve (EC(50)=3.4 nmol/L) by a factor of 4.6 or 4.9, respectively. Combined inhibition of ACE and APP reduced the EC(50) of BK to 0.18 nmol/L (ie, by a factor of 19) but potentiated the activity of B6014 (EC(50)=1.9 nmol/L) only weakly without altering that of FR190997 (EC(50)=0.34 nmol/L). Desensitization of B(2) receptors was induced by the administration of BK (0.2 micromol/L) or FR190997 (0.1 micromol/L) for 30 minutes; the vascular reactivity to ramiprilat or increasing doses of BK was tested thereafter. After desensitization with BK, but not FR190997, an additional application of ramiprilat provoked a B(2) receptor-mediated vasodilation. High BK concentrations were still effective at the desensitized receptor. The process of desensitization was not altered by ramiprilat. These results show that in this model, all potentiating actions of ACE inhibitors on kinin-induced vasodilation are exclusively related to the reduction in BK breakdown and are equivalently provoked by APP inhibition. The desensitization of B(2) receptors is overcome by increasing BK concentrations, either directly or through the inhibition of ACE. These observations do not suggest any direct interactions of ACE inhibitors with the B(2) receptor or its signal transduction but point to a very high activity of BK degradation in the vicinity of the B(2) receptor in combination with a stimulation-dependent reduction in receptor affinity.

Pharmacology and cardiovascular implications of the kinin-kallikrein system.

Kinins are peptide hormones that can exert a significant influence on the regulation of blood pressure and vascular tone due to their vasodilatatory, natriuretic and growth modulating activity. Their cardiovascular involvement in physiological and pathophysiological situations has been studied intensively since inhibitors for angiotensin I-converting enzyme and selective receptor antagonists have become available for pharmacologically potentiating or inhibiting kinin-mediated reactions. Molecular biological analysis and the establishment of genetically modified animal models have also allowed newer information to be acquired on this subject. In this review, the components and cardiovascularly relevant mechanisms of the kinin-kallikrein system shall be described. Organ-specific effects concerning the kidneys, the vascular system, the heart and nervous tissue shall also be illustrated. On this issue, the physiological functions and pathophysiological implications of the kinin-kallikrein system should be clearly distinguished from the many, mostly endothelium-mediated protective effects which occur during ACE inhibition due to the potentiation of kinin effects. Finally, a view shall also be cast upon newly discovered targets of action, which could be exploited for therapeutically altering the kinin-kallikrein system.

Identification of kallidin degrading enzymes in the isolated perfused rat heart.

Kallidin (KD) is an important vasoactive kinin whose physiological effects are strongly dependent on its degradation through local kininases. In the present study, we examined the spectrum of these enzymes and their contribution to KD degradation in isolated perfused rat hearts. By inhibiting angiotensin-converting enzyme (ACE), aminopeptidase M (APM) and neutral endopeptidase (NEP) with ramiprilat (0.25 microM), amastatin (40 microM) and phosphoramidon (1 microM), respectively, relative kininase activities were obtained. APM (44%) and ACE (35%) are the main KD degrading enzymes in rat heart; NEP (7%) plays a minor role. A participation of carboxypeptidase N (CPN) could not be found.

Intravascular and interstitial degradation of bradykinin in isolated perfused rat heart.

1. Bradykinin (BK) has been shown to exert cardioprotective effects which are potentiated by inhibitors of angiotensin I-converting enzyme (ACE). In order to clarify the significance of ACE within the whole spectrum of myocardial kininases we investigated BK degradation in the isolated rat heart. 2. Tritiated BK (3H-BK) or unlabelled BK was either repeatedly perfused through the heart, or applied as an intracoronary bolus allowing determination of its elution kinetics. BK metabolites were analysed by HPLC. Kininases were identified by ramiprilat, phosphoramidon, diprotin A and 2-mercaptoethanol or apstatin as specific inhibitors of ACE, neutral endopeptidase 24.11 (NEP), dipeptidylaminopeptidase IV and aminopeptidase P (APP), respectively. 3. In sequential perfusion passages, 3H-BK concentrations in the perfusate decreased by 39% during each passage. Ramiprilat reduced the rate of 3H-BK breakdown by 54% and nearly abolished [1-5]-BK generation. The ramiprilat-resistant kininase activity was for the most part inhibited by the selective APP inhibitor apstatin (IC50 0.9 microM). BK cleavage by APP yielded the intermediate product [2-9]-BK, which was rapidly metabolized to [4-9]-BK by dipeptidylaminopeptidase IV. 4. After bolus injection of 3H-BK, 10% of the applied radioactivity were protractedly eluted, indicating the distribution of this fraction into the myocardial interstitium. In samples of such interstitial perfusate fractions, 3H-BK was extensively (by 92%) degraded, essentially by ACE and APP. The ramiprilat- and mercaptoethanol-resistant fraction of interstitial kininase activity amounted to 14%, about half of which could be attributed to NEP. Only the product of NEP, [1-7]-BK, was continuously generated during the presence of 3H-BK in the interstitium. 5. ACE and APP are located at the endothelium and represent the predominant kininases of rat myocardium. Both enzymes form a metabolic barrier for the extravasated fraction of BK. Thus, only interstitial, but not intravascular concentrations of BK are increased by kininase inhibitors to the extent that a significant potentiation of BK effects could be explained. NEP contributes less than 5% to the total kininase activity, but is the only enzyme which is exclusively present in the interstitial space.