Andreas Meissner

Thoracic epidural analgesia with low concentration of bupivacaine induces thoracic and lumbar sympathetic block: a randomized, double-blind clinical trial.

Background:Clinical benefits of thoracic epidural anesthesia (TEA) are partly ascribed to thoracic sympathetic block. However, data regarding sympathetic activity during TEA are scarce and contradictory. This prospective, randomized, double-blind study evaluated the segmental propagation of sympathetic block after low-concentration, high-volume TEA using digital thermography. Methods:Twenty-four patients were included in the study. Thoracic epidural catheters were placed at a median insertion level of T8–T9. Patients were accommodated for 20 min to the room temperature of 23° ± 0.3°C. Skin temperature was recorded by digital thermography. After baseline measurement of heart rate, arterial pressure, and core body and skin temperature, 10 ml saline (control group) or 10 ml bupivacaine, 0.25% (TEA group), respectively, was administered epidurally. Five minutes (t5) and 20 min (t20) after baseline measurements, hemodynamic parameters and core body temperature were again measured, and sensory block was identified by loss of cold–warm discrimination. In the thumb, the toe, and each thoracic dermatome, difference from baseline temperature was calculated at t5 and t20. Data were analyzed by Mann–Whitney U test. Results:Baseline characteristics did not differ among groups. Median spread of sensory block at t20 was T5–L5. At both t5 and t20, skin temperature decreased more in the control group than in the TEA group in all thoracic dermatomes (P < 0.05). Toe temperature increased in the TEA group compared with the control group (P < 0.05), whereas thumb temperature remained unchanged. Conclusion:TEA with 10 ml bupivacaine, 0.25%, induced thoracic and lumbar sympathetic block that precedes and exceeds sensory block. Caudal limit of sympathetic block could not be demonstrated in this study.

Effects of Thoracic Epidural Anesthesia with and without Autonomic Nervous System Blockade on Cardiac Monophasic Action Potentials and Effective Refractoriness in Awake Dogs

BackgroundThe effects of thoracic epidural anesthesia (TEA) on myocardial repolarization and arrhythmogenicity are only incompletely understood. This is primarily because of the lack of appropriate experimental models. In most of the studies performed thus far, TEA was used in anesthetized animals. Baseline anesthesia itself may have modified the effects of TEA. This study investigates right atrial and ventricular repolarization by recording monophasic action potentials after TEA in awake dogs. The authors hypothesized that an antiarrhythmic role of TEA exists, which may be related to a direct effect of TEA on myocardial repolarization. MethodsThe hypothesis was tested in an in vivo canine model, in which atrial and ventricular myocardial action potential duration and refractoriness are recorded by means of monophasic action potential catheters. ResultsThoracic epidural anesthesia significantly increased ventricular monophasic action potential duration for cycle lengths shorter than 350 ms. Changes in monophasic action potential duration were paralleled by a concomitant prolongation of effective refractory period (ERP) at higher rates so that the ratio of ERP to action potential duration was unaffected. ConclusionsThis model helps to study the role of TEA on ventricular repolarization and arrhythmogenicity. Because lengthening of repolarization and prolongation of refractoriness may, in some circumstances, be antiarrhythmic, TEA may be protective against generation of ventricular arrhythmias mediated, e.g., by increased sympathetic tone. The results also imply that the beneficial role of TEA might be stronger at the ventricular site as compared with the atrium. At atrial sites there was only a trend toward prolongation of repolarization even at short cycle lengths.

Limited upper thoracic epidural block and splanchnic perfusion in dogs.

UNLABELLED Epidural blockade leads to a sympathetic block in affected segments and an increase of sympathetic out-flow from various unblocked segments. A limited upper thoracic epidural block (LUTEB) is used during coronary artery surgery affecting the cardiac sympathetic fibers cephalad to the fifth thoracic segment. This block does not extend to the sympathetic fibers innervating the gastrointestinal organs. A LUTEB may lead to an increase of sympathetic activity in the unaffected splanchnic sympathetic segments and the decrease in splanchnic blood flow may contribute to gastrointestinal ischemia after cardiac surgery. We tested the hypothesis that a LUTEB decreases splanchnic perfusion in anesthetized dogs. Thirteen dogs were chronically instrumented with aortic and left atrial catheters, which were used for pressure measurement, as well as injection and withdrawal of reference samples. Thoracic epidural catheters were placed under general anesthesia the day before the experiment. Splanchnic blood flow was determined by using colored microspheres. Induction of a LUTEB did not change general hemodynamics in awake dogs. Propofol anesthesia induced an increase in heart rate that was abolished after LUTEB. LUTEB also decreased mean arterial pressure during propofol anesthesia. We conclude that thoracic epidural anesthesia had no effect on splanchnic blood flow. In propofol anesthetized animals, liver blood flow was increased compared with awake animals; however, it did not change after induction of LUTEB. IMPLICATIONS A sympathetic block in certain segments leads to increased sympathetic output in unblocked segments. For an upper thoracic epidural block, this might lead to impaired splanchnic perfusion. In awake and propofol-anesthetized, chronically instrumented dogs, however, a limited upper thoracic epidural blockade had no compromising effect on gastrointestinal perfusion.

The early response genes c-jun and HSP-70 are induced in regional cardiac stunning in conscious mammals.

OBJECTIVES A reversible contractile dysfunction without necrosis after transient myocardial ischemia has been termed stunning. The molecular mechanisms underlying this phenomenon are only now beginning to be unraveled. It is conceivable that the expression of early-response genes may play a crucial role in stunning. METHODS The expression of HSP-70, c-jun, and GRP-94 was investigated in a chronically instrumented dog model (n = 9). The left anterior descending coronary artery was occluded temporarily for 10 minutes after the animals had fully recovered from instrumentation. The wall thickening fraction was measured in the left anterior descending coronary artery and the nonischemic ramus circumflex of the left coronary artery-perfused region. When the wall thickening fraction of the left anterior descending coronary artery had recovered to 50% of preocclusion values, tissue samples were obtained from the areas perfused by the left anterior descending coronary artery and the nonischemic ramus circumflex of the left coronary artery. RESULTS The messenger RNA of HSP-70 was increased to 214% +/- 26% in the area perfused by the left anterior descending artery compared with that perfused by the nonischemic ramus circumflex of the left coronary artery. There was no difference in the messenger RNA of GRP-94. The HSP-70 content was elevated to 130% +/- 14% in the left anterior descending artery compared with the area perfused by the ramus circumflex of the left coronary artery, and the c-jun protein content was 70% +/- 25% higher in the ischemic area compared with the control area. CONCLUSIONS The induction of early-response genes observed here may indicate that they play an adaptive role in myocardial stunning, even in conscious mammals.

Inotropic Effects of Diadenosine Tetraphosphate in Isolated Canine Cardiac Preparations

We studied the effects of diadenosine tetraphosphate (AP4A) on the force of contraction in canine preparations. The force of contraction was measured in isolated electrically driven (1 Hz) atrial and ventricular cardiac trabeculae from adult dogs. AP4A (100 microM) alone and after prestimulation with 10 nM isoproterenol reduced force of contraction in atrial preparations by approximately 24%. Moreover, AP4A (100 microM) alone and after prestimulation with 10 nM isoproterenol reduced the force of contraction in ventricular preparations by 29 and 29%, respectively. The negative inotropic effects of AP4A were abolished by the A1-adenosine receptor antagonist 1,3-dipropyl-cyclopentyl-xanthine (DPCPX). In summary, in canine myocardium, AP4A alone and after prestimulation with a beta-adrenoceptor agonist exerts negative inotropic effects, which are probably mediated via A1-adenosine receptors.

Naloxone Improves Splanchnic Perfusion in Conscious Dogs through Effects on the Central Nervous System

Background In patients undergoing colonoscopy, naloxone has vasodilative properties. However, it remains unclear whether this effect is mediated by central or peripheral mechanisms. The aim of this study was to investigate whether these effects are mediated by an effect of naloxone on the central nervous system. Methods Twenty dogs were chronically instrumented for measurement of hemodynamic parameters. Splanchnic blood flow was determined using colored microspheres. Transthoracic echocardiographic examinations were performed to measure cardiac output. In each animal, two experiments were performed in a random order: experiment 1 was determination of splanchnic blood flow before and 5 min after intravenous administration of naloxone (63 &mgr;g/kg), and experiment 2 was determination of splanchnic blood flow before and 5 min after administration of naloxone methiodide (63 &mgr;g/kg), which does not cross the blood–brain barrier. Results Naloxone, but not naloxone methiodide, significantly increased blood flow to the stomach (from 0.41 ± 0.022 to 0.9 ± 0.016 # ml · g−1 · min−1 with naloxone), jejunum (from 0.31 ± 0.024 to 0.83 ± 0.083 # ml · g−1 · min−1 with naloxone), colon (from 0.41 ± 0.057 to 0.68 ± 0.008 # ml · g−1 · min−1 with naloxone), spleen (from 1.45 ± 0.21 to 2.13 ± 0.25 # ml · g−1 · min−1 with naloxone), pancreas (from 0.97 ± 0.021 to 1.25 ± 0.005 # ml · g−1 · min−1 with naloxone), and kidneys (from 3.24 ± 0.108 to 5.31 ± 0.26 # ml · g−1 · min−1 with naloxone), without altering cardiac output or arterial blood pressure in conscious dogs. There were no differences in the hemodynamics or cardiac output between the two experiments. Data are presented as mean ± SD. Conclusions The increased splanchnic perfusion after naloxone is not caused by direct peripheral vascular effects or increased cardiac output. Indirect vasodilative effects on splanchnic vessels mediated by actions of naloxone on the central nervous system account for the increased gastrointestinal perfusion after naloxone in dogs.

Thoracic Epidural Anesthesia Does Not Affect Functional Recovery From Myocardial Stunning in Sevoflurane-Anesthetized Dogs

OBJECTIVE A beneficial effect of thoracic epidural anesthesia (TEA) on recovery from myocardial stunning was previously shown in awake dogs. The aim of this study was to investigate the effects of TEA on recovery from myocardial stunning in sevoflurane-anesthetized dogs. DESIGN Randomized animal study. SETTING Animal laboratory of a university hospital. PARTICIPANTS Chronically instrumented mongrel dogs. INTERVENTIONS Six dogs were chronically instrumented for measurement of hemodynamics and myocardial wall thickening fraction (WTF). The following experiments were performed on separate days in a crossover fashion: (1) 10 minutes of ischemia of the left anterior descending (LAD) coronary artery during sevoflurane anesthesia without TEA and (2) 10 minutes of ischemia during sevoflurane anesthesia with TEA. MEASUREMENTS AND MAIN RESULTS WTF was measured awake (baseline) and at predetermined time points until complete recovery of myocardial function occurred. Induction of anesthesia led to a decrease of WTF compared with baseline. Induction of ischemia led to a further decrease of WTF to negative values, which returned to positive values within the first minute of reperfusion. There were no differences between the two experimental conditions at any of the time points measured. In awake dogs, TEA improved the recovery from myocardial stunning compared with the control experiment. There was no difference between conscious dogs with TEA or sevoflurane-anesthetized dogs with or without TEA. CONCLUSION TEA has no additional protective effect on the recovery of WTF during sevoflurane anesthesia.

In vivo recording of monophasic action potentials in awake dogs

Assessment of cardiac repolarization in dogs in vivo is of interest in numerous experimental canine models. Previous studies have used monophasic action potentials (MAPs) to investigate repolarization in vitro and in vivo in anesthetized animal models. Therefore, an approach for recording MAPs in awake dogs without the interference of anesthesia is desirable. We describe an experimental technique to record MAPs in conscious dogs by means of conventional rubber introducers which are implanted into the internal jugular vein. Atrial as well as ventricular MAPs can be simultaneously measured without complications. Pacing thresholds are low and stable over time. Continuous MAP recordings of stable amplitude can be achieved from the same endocardial site for periods up to 1h. Antegrade and retrograde atrioventricular nodal conduction properties can be assessed. Programmed stimulation can be performed to simultaneously determine local refractory periods and MAP duration at cycle lengths from 500 to 200ms. In awake, unsedated dogs measuring MAPs via rubber introducers permits safe, long-term recording of MAPs. Such recordings may be useful for safety pharmacologic studies in evaluating cardiovascular and noncardiovascular drugs with respect to their effects on repolarization. In various canine in vivo models including in vivo models of long QT syndrome, heart failures or sudden cardiac death, the present technique permits electrophysiologic measurements without the interference of anesthesia.

EVALUATION OF ELECTRICAL VELOCIMETRY TO DETERMINE CARDIAC OUTPUT AFTER CARDIAC SURGERY.: 203-S

Introduction : The development of a non-invasive procedure to determine cardiac output without the risks of invasive techniques is still a major issue. Electrical Velocimetry is a new method for the determination of cardiac output and stroke volume by the non-invasive measurement. According to the theory, erythrocytes change their random orientation in the descending aorta during diastole to an alignment during systole, resulting in a change of the electrical conductivity of blood. Hypothesis : The scope of this trial was to determine the correlation between Thermodilution cardiac output (TDCO) and Electrical Velocimetry (EVCO) in patients after the first 24 hours after cardiac surgery. This group of patients was chosen as these patients have been shown to have the lowest correlation with bioelectrical methods. Methods : After approval of the institutions ethical committee, standard ECG surface electrodes were utilized for noninvasive measurement of thoracic electrical conductivity (Aesculon). SV and CO by EV was determined according to the Bernstein-Osypka equation. Thermodilution values were obtained at the same time with a HelligeMarquette-system. Bland-Altman analysis was used to assess accuracy. Meissner, Andreas; Korsmeier, Peter; Van Aken, Hugo K; Etz, Christian; Schmidt, Christoph

Recovery from myocardial stunning is faster with desflurane compared to propofol in chronically instrumented dogs

Volatile anesthetics exert a protective role in myocardial ischemia. An increase in sympathetic tone might exert deleterious effects on the ischemic myocardium. The use of the volatile anesthetic desflurane in myocardial ischemia is controversial because of its sympathetic activation. We compared propofol and desflurane on myocardial stunning in chronically instrumented dogs. Mongrel dogs (n = 8) were chronically instrumented for measurement of heart rate, left atrial, aortic, and left ventricular pressure, rate of rise of left ventricular pressure, and myocardial wall-thickening fraction (WTF). An occluder around the left anterior descending artery (LAD) allowed the induction of reversible LAD-ischemia. Two experiments were performed in a cross-over fashion on separate days: 1) Induction of 10 min of LAD-ischemia during desflurane anesthesia and 2) Induction of 10 min of LAD-ischemia during propofol anesthesia. Both anesthetics were discontinued immediately after completion of ischemia. WTF was measured at predetermined time points until complete recovery from ischemic dysfunction occurred. Both anesthetics caused a significant decrease of WTF in the LAD-perfused myocardium. LAD-ischemia led to a further significant decrease of LAD-WTF in both groups. During the first 3 h of reperfusion, WTF was significantly larger in the desflurane group. Mean arterial pressure and heart rate were greater during ischemia and the first 10 min of reperfusion in the desflurane group compared with the propofol group. Recovery from myocardial stunning in dogs was faster when desflurane was used at the time of ischemia as compared with propofol anesthesia. The mechanism for this difference is unclear, but sympathetic activation by desflurane was not a limiting factor for ischemic tolerance in chronically instrumented dogs.