Increase in myocardial interstitial adenosine and net lactate production in brain-dead pigs: an in vivo microdialysis study

[Organ protective intensive care treatment and simulation-based training]

In Germany the extent of organ donation is still inadequate and not sufficient to address patients on the waiting lists. Nevertheless, intensive care treatment of potential organ donors does not receive adequate attention. However, because of the increasing age and comorbidities of organ donors in recent years, a sufficient intensive care treatment is indispensable for the success of organ transplantations. Sufficient randomized clinical trials are lacking. This article reviews the current literature and describes approaches for improvement. Multicentre studies and education of medical staff of intensive care units, for example in intensive care simulation for organ protection, could potentially be a successful approach. The improvement and establishment of curricular training and education particularly in simulation workshops might be a promising approach to enhance the quantity and quality of organ donations.

[Cardiac complications of acute brain injury]

The clinical importance of cardiovascular consequences resulting from cerebral injury has long been recognized. However, interactions between the brain and the cardiovascular system remain poorly defined and their importance for the management of patients suffering from acute brain injury is largely underestimated. This should have profound consequences on treatment strategies during anaesthesia and intensive cares of these patients, taking into account not only brain perfusion, but also cardiovascular optimisation. This report summarizes the main data available regarding the cardiovascular consequences of brain death, traumatic brain injury, stroke and epilepsy.

Improvement of Donor Myocardial Function after Treatment of Autonomic Storm During Brain Death

BACKGROUND

In experimental brain death models, autonomic storm (AS) triggers severe myocardial dysfunction, which can be attenuated by pharmacologic treatment. The aim of this study was to determine the incidence of AS in a cohort of human organ donors and to evaluate the potential interest of AS treatment on myocardial function, cardiac harvesting and transplantation.

METHODS

The cohort consisted of 152 patients. Among them, 46 patients were initially considered as potential cardiac donors (main criteria: age < 60 years, no history of cardiac disease). AS diagnosis included increased systolic arterial pressure > 200 mm Hg associated with tachycardia >140 beats/min. Heart acceptance criteria were associated creatine kinase (CK), troponin Ic, and left ventricle ejection fraction (LVEF) estimated by echocardiography and visual inspection.

RESULTS

AS was observed in 29 patients (63%). Hypertension was treated in 12 patients (esmolol n = 6, urapidil n = 5, nicardipine). Cardiac harvesting was performed in 28 donors (61%). LVEFs were significantly higher after AS treatment (no AS: 55.4 +/- 13.4%, untreated AS: 49.0 +/- 18.8%, treated AS: 63.9+ +/- 10.3%, P = 0.049). AS treatment was found to be independently associated with LVEF in > 50% of the cases (P = 0.034). Treatment of AS or the lack of AS were associated with an increased probability of successful cardiac transplantation (OR = 8.8; 95% CI 2.1-38.3, P = 0.002).

CONCLUSIONS

Treatment of hypertension during AS may attenuate brain death-induced myocardial dysfunction and increase the number of available cardiac grafts.

Endothelin-1 receptor antagonist prevents deterioration of left ventricular function and coronary flow reserve in brain-dead canine heart

BACKGROUND

Rapid hemodynamic deterioration is caused by induction of brain death, but the exact mechanism is still uncertain. The aim of this study was to investigate the contribution of endothelin-1 by using endothelin-1 receptor antagonist (TAK-044) in a canine brain-death model.

METHODS

Dogs were divided into 2 groups: (1) the TAK group, in which TAK-044 was intravenously injected 30 minutes before brain-death induction at a dose of 3 mg/kg; and (2) the control group. Brain death was induced by rapid inflation of a sub-durally placed balloon catheter. Left ventricular function and coronary flow reserve was compared between the 2 groups.

RESULTS

Brain death caused a transient hyperdynamic response followed by hemodynamic deterioration after 60 minutes in both groups. Left ventricular function, evaluated by the slope of the end-systolic pressure-volume relation was significantly decreased from 7.7 +/- 0.6 to 3.7 +/- 0.3 mm Hg/ml (p < 0.01) in the control group, but was not decreased in the TAK group (7.7 +/- 0.8 to 7.3 +/- 0.9 mm Hg/ml, p = 0.75). Coronary flow reserve, measured by direct injection of acetylcholine (3 microg) into the coronary artery, was significantly reduced at 60 minutes after brain death in the control group (264.8% to 176.6%, p < 0.01), but not in the TAK group (291.2% to 301.3%, p = 0.84). Exactly the same results were obtained when sodium nitroprusside (SNP; 100 microg) was administered.

CONCLUSIONS

TAK-044 can prevent the deterioration of left ventricular function and coronary flow reserve that follows induction of brain death, suggesting that endothelin-1 could play an important role in hemodynamic deterioration by impairment of coronary microcirculation after brain death.

Growth regulation of the vascular system: an emerging role for adenosine

The importance of metabolic factors in the regulation of angiogenesis is well understood. An increase in metabolic activity leads to a decrease in tissue oxygenation causing tissues to become hypoxic. The hypoxia initiates a variety of signals that stimulate angiogenesis, and the increase in vascularity that follows promotes oxygen delivery to the tissues. When the tissues receive adequate amounts of oxygen, the intermediate effectors return to normal levels, and angiogenesis ceases. An emerging concept is that adenosine released from hypoxic tissues has an important role in driving the angiogenesis. The following feedback control hypothesis is proposed: AMP is dephosphorylated by ecto-5′-nucleotidase, producing adenosine under hypoxic conditions in the extracellular space adjacent to a parenchymal cell (e.g., cardiomyocyte, skeletal muscle fiber, hepatocyte, etc.). Extracellular adenosine activates A2receptors, which stimulates the release of vascular endothelial growth factor (VEGF) from the parenchymal cell. VEGF binds to its receptor (VEGF receptor 2) on endothelial cells, stimulating their proliferation and migration. Adenosine can also stimulate endothelial cell proliferation independently of VEGF, which probably involves modulation of other proangiogenic and antiangiogenic growth factors and perhaps an intracellular mechanism. In addition, hemodynamic factors associated with adenosine-induced vasodilation may have a role in the development and remodeling of the vasculature. Once a new capillary network has been established, and the diffusion/perfusion capabilities of the vasculature are sufficient to supply the parenchymal cells with adequate amounts of oxygen, adenosine and VEGF as well as other proangiogenic and antiangiogenic growth factors return to near-normal levels, thus closing the negative feedback loop. The available data indicate that adenosine might be an essential mediator for up to 50–70% of the hypoxia-induced angiogenesis in some situations; however, additional studies in intact animals will be required to fully understand the quantitative importance of adenosine.

Physiologic changes during brain stem death—lessons for management of the organ donor

The widespread physiologic changes that follow brain stem death lead to a high incidence of complications in the donor and jeopardize vital organ function. Strategies for the management of organ donors exist whereby the rapid physiologic decline seen after brain stem death can be stabilized by active donor resuscitation so that the functional integrity of potentially transplantable organs is maintained. Understanding the complex physiologic changes that occur after brain stem death is crucial to the development of effective donor management strategies. This article reviews the pathophysiologic changes that occur after brain stem death and discusses controversies in donor management.

Endothelial activation through brain death?

BACKGROUND

Brain death induces myocardial dysfunction and multifocal microscopic myocardial necrosis in dogs; however, the pathogenetic pathways between brain death and cardiac damage remain incompletely understood. We hypothesized that brain death might induce a propensity toward coronary vasospasms, possibly by endothelial dysfunction. We therefore studied the effect of serotonin and acetylcholine on tension generated by isolated coronary artery segments from control and brain dead dogs.

METHODS

Coronary segments were isolated 1 hour after brain death that was induced by the inflation (15 ml saline) of an extradurally placed balloon or from sham-operated time-matched controls. Studied were the effect of serotonin on isometric tension, with and without pre-constriction with prostaglandin F(2alpha) (PGF(2alpha)), and the effect of acetylcholine after pre-constriction.

RESULTS

Coronary segments from brain dead dogs exhibited severe vasoconstriction when serotonin (10(-7), 10(-6), and 10(-5) mol/liter) was administered, a reaction that was barely detectable in control segments. After pre-construction with PGF(2alpha), serotonin caused only significant vasodilation in a concentration of 10(-5) mol/liter, unlike in control segments where 10(-6) mol/liter had already induced a highly significant vasodilation. The reaction on acetylcholine was identical in both groups.

CONCLUSION

Brain death induces changes in coronary vasoreactivity in dogs, with a highly increased sensitivity for the vasospastic effects of serotonin. It is, however, not merely caused by aspecific endothelial dysfunction, as evidenced by the normal reaction on acetylcholine. These alterations in coronary artery properties might contribute to the myocardial damage seen after brain death.

Brain death significantly reduces isolated pancreatic islet yields and functionality in vitro and in vivo after transplantation in rats

Although approximately 1 million islets exist in the adult human pancreas, current pancreas preservation and islet isolation techniques recover <50%. Presently, cadaveric donors remain the sole source of pancreatic tissue for transplantation. Brain death is characterized by activation of proinflammatory cytokines and organ injury during preservation and reperfusion. In this study, we assessed the effects of brain death on islet isolation yields and functionality. Brain death was induced in male 250- to 350-g Lewis rats by inflation of a Fogarty catheter placed intracranially. The rats were mechanically ventilated for 2, 4, and 6 h before removal of the pancreas (n = 6). In controls, the catheter was not inflated (n = 6). Shortly after brain death induction, a significant increase in serum tumor necrosis factor-alpha (TNF-alpha), interleukin (IL)-1beta, and IL-6 was demonstrated in a time-dependent manner. Upregulation of TNF-alpha, IL-1beta, and IL-6 mRNA was noted in the pancreas. Brain death donors presented lower insulin release after glucose stimulation assessed by in situ perfusion of the pancreas. Islet recovery was reduced in brain death donors compared with controls (at 6 h 602.3 +/- 233.4 vs. 1,792.5 +/- 325.4 islet equivalents, respectively; P < 0.05). Islet viability assessed in dissociated islet cells and in intact cultured islets was reduced in islets recovered from brain death donors, an effect associated with higher nuclear activities of NF-kappaB p50, c-Jun, and ATF-2. Islet functionality evaluated in vitro by static incubation and in vivo after intraportal transplantation in syngeneic streptozotocin-induced diabetic rats was significantly reduced in preparations obtained from brain death donors. In conclusion, brain death significantly reduced islet yields and functionality. These observations may lead to strategies to reduce the effects of brain death on pancreatic islets and improve the results in clinical transplantation.

Analyse des critères qui participent à la décision de prélèvement cardiaque chez les patients en état de mort encéphalique

OBJECTIVES

The number of cardiac transplantation procedures does not increase because of the lack of donor hearts despite an increase in the number of brain-dead organ donors. The criteria used to select a donor heart are not formally standardized. The aim of the present study was to analyze the criteria that contribute to the selection of a donor heart.

TYPE OF STUDY

Descriptive, retrospective study.

PATIENTS AND METHOD

Clinical parameters, the initial causes that lead to brain death, maximum doses of catecholamines, several biochemical markers of myocardial ischaemia/necrosis as well as several echocardiography criteria were extracted from a prospectively collected database. Univariate and multivariate (logistic regression) analyses were performed with the "harvested heart" as dependent variable and the above-cited independent variables.

RESULTS

One hundred and eighty consecutive brain-dead patients admitted from 1st October 1998 to 31st December 2000 out of which 112 gave at least one organ were analyzed. Among these 112 patients, 59 (39 males and 20 females) were pre-selected as potential heart donors. Only 44 hearts were harvested. Logistic regression analysis showed that harvesting of the heart was more probable if the donor were a male, had no left ventricle systolic wall motion abnormalities, had low doses of norepinephrine and low serum troponin Ic concentrations.

CONCLUSION

After an initial phase of selection, the final decision to harvest a heart is based on several criteria. These results should be an incentive to conceive a score that could allow a more formal decision process for heart harvesting.

Measurement of interstitial lactate during hypoxia-induced dilatation in isolated pressurised porcine coronary arteries

Lactate is formed in the coronary arterial wall and in the myocardium as a consequence of ischaemia and infarction. We combined direct measurement of coronary artery diameter and interstitial arterial wall lactate concentration ex vivo in order to ascertain the possible role of lactate in hypoxia-induced vasodilatation. The wall of porcine coronary arteries, precontracted during an intraluminal pressure of 40 mmHg by addition of prostaglandin F2alpha, was cannulated using a microdialysis catheter, and exposed to hypoxia for 60 min, followed by 45 min of reoxygenation. The exchange fraction of [14C]lactate over the microdialysis membrane increased from 0.38 +/- 0.04 to 0.52 +/- 0.05 (P < 0.001) during the study period. Coronary artery diameter increased by 15.5 +/- 2.0 % (n = 20) during hypoxia (P < 0.001, compared to normoxic controls) and interstitial lactate concentration rose from 1.07 +/- 0.21 to 2.50 +/- 0.40 mmol x l(-1) during hypoxia (P < 0.01) and was unchanged in controls. The increase in coronary artery diameter correlated with the increase in interstitial lactate concentration in the period between 30 and 60 min of hypoxia (r = 0.62; P = 0.02). Dichloroacetate (10(-5) M), an agent that reduces lactate generation by activating pyruvate dehydrogenase, abolished hypoxia-induced lactate production, but caused a further increase in coronary arterial diameter (30.2 +/- 4.4 %, n = 9; P < 0.001 vs. hypoxia and no dichloroacetate). Under control conditions, the addition of L-lactate (10(-3)-10(-2) M) increased dose-dependently coronary arterial diameter by 22.0 +/- 4.2 % (n = 5) and interstitial lactate concentration from 0.52 +/- 0.04 to 5.70 +/- 0.66 mmol x l(-1) (P < 0.001). There was a correlation between the increase in coronary artery diameter and interstitial lactate concentration (r = 0.60; P = 0.02). The present observations represent the first direct measurements of metabolites by microdialysis in a blood vessel wall. The lactate concentration may affect, but is not essential for, hypoxia-induced vasodilatation in porcine coronary arteries.

Adenosine- and adenine-nucleotide-mediated inhibition of normal and transformed keratinocyte proliferation is dependent upon dipyridamole-sensitive adenosine transport

Extracellular adenosine and its related nucleotides have been referred to as retaliatory metabolites that can be released into the extracellular environment during inflammation, wounding, and other pathologic states. We have previously reported that these compounds reversibly inhibit the proliferation of normal keratinocyte cultures and we now demonstrate that these compounds also arrest the proliferation of transformed keratinocytes. Although our study shows that keratinocytes express mRNA corresponding to the A2B purinoreceptors and that adenosine or AMP treatment elevates intracellular cAMP in these cells, our study also demonstrates that dipyridamole-inhibitable transport of adenosine into the keratinocyte is central to the mechanism by which adenosine and adenine nucleotides arrest proliferation in these cells. In support of this mechanism, our results demonstrate that human keratinocytes express mRNA corresponding to the recently cloned dipyridamole-sensitive human equilibrative nucleoside transporter. Interestingly, coincubation with adenosine deaminase reverses the antiproliferative action of adenosine and exerts no effect on the antiproliferative activity of the adenine nucleotides, thus supporting a model in which adenine nucleotides are enzymatically converted to adenosine and transported into the keratinocyte in a tightly coupled and adenosine-deaminase-resistant manner. Analysis of adenosine- and adenosine-monophosphate-treated keratinocytes demonstrated that quiescence is induced within 12-24 h, and fluorescence-activated cell sorter analysis suggests that treatment with these compounds may result in the inhibition of keratinocyte proliferation at both G1 and S phases of the cell cycle. In addition to their documented antiproliferative action on other cell types, adenosine, adenine nucleotides, and related analogs may also represent a potential new class of pharmacologic regulators of keratinocyte proliferation in vivo.

Consequences of inspired oxygen fraction manipulation on myocardial oxygen pressure, adenosine and lactate concentrations: a combined myocardial microdialysis and sensitive oxygen electrode study in pigs

Adenosine is a potent vasodilator whose concentration has been shown to increase in cardiac tissue in response to hypoxia. However, the time-dependent relationship between the levels of myocardial interstitial adenosine and tissue oxygenation has not yet been completely established. Therefore, the purpose of this study was to investigate the complex relationship between tissue myocardial oxygen tension (PtiO(2)) and interstitial myocardial adenosine and lactate concentrations by developing a new technique which combines a cardiac microdialysis probe and a Clark-type P O(2)electrode. The combined and the single microdialysis probes were implanted in the left ventricular myocardium of anesthetized pigs. The consequences of the combined use of microdialysis and P O(2)probes on myocardial PtiO(2)and microdialysis performances against glucose were evaluated. A moderate but significant reduction in the relative recovery against glucose of the combined probe was observed when compared to that of the single microdialysis probe (42+/-2 v 32+/-1%, mean+/-S.E. M.n=5 P<0.05), at 2microl/min microdialysis probe perfusion flow. Similarly, myocardial oxygen enrichment, measured by the P O(2)electrode, was negligible when microdialysis probe perfusion flow was 2microl/min. Systemic hypoxia (FiO(2)=0.08) resulted in a significant decrease in PtiO(2)from 30+/-4 to 11+/-2 mmHg, limited increase in coronary blood flow (CBF), and a significant increase in myocardial adenosine and lactate concentrations from 0.34+/-0.05 to 0.98+/-0.06micromol/l and from 0.45+/-0.05 to 0.97+/-0.06 mmol/l respectively (P<0.05). Increasing the FiO(2)to 0.3 restored the PtiO(2)and hemodynamic parameters to baseline values with no changes in interstitial adenosine and lactate concentrations. Nevertheless, myocardial interstitial adenosine remained significantly higher than baseline values. In conclusion, this study demonstrates the ability of a combined probe to measure simultaneously regional myocardial PtiO(2)and metabolite concentration during hypoxia. The hypoxia-induced increase in myocardial adenosine persists after correction of hypoxia. The physiological significance of this observation requires further studies.