Angiotensin-converting enzyme inhibition and blood pressure response during total intravenous anaesthesia for minor surgery.

BACKGROUND: This study investigates whether long-term treatment with an angiotensin-converting enzyme inhibitor (ACEI) impairs the haemodynamic regulation during total intravenous anaesthesia (TIVA) for minor surgery. METHODS: In a prospective, two-armed observational study, 36 patients undergoing TIVA for minor surgery were studied. Seventeen were taking ACEIs regularly but no other antihypertensive medication (ACEI group); 19 patients without any cardiovascular medication served as controls (non-ACEI group). Haemodynamic variables were measured every minute during induction and every 5 min during surgery. The plasma levels of renin, angiotensin II, vasopressin and catecholamines were measured before and 18 min after the induction of anaesthesia. RESULTS: The mean arterial pressure decreased to the same extent in both the groups during the induction of TIVA. There were also no differences between the groups regarding the heart rate, systolic and diastolic arterial pressure, as well as the use of vasoconstrictors, and fluids during induction and throughout surgery. In the ACEI group, the plasma renin concentration was higher at baseline and after the induction of anaesthesia presumably due to the interruption of the negative renin-angiotensin feedback loop (P<0.05). Angiotensin II increased only in the non-ACEI group (6.2 ± 2.2 before vs. 9.6 ± 3.5 pg/ml after induction; P<0.05). In both groups, the plasma norepinephrine concentration decreased after the induction of TIVA (P<0.05). Plasma vasopressin and plasma epinephrine concentrations did not change in either group. CONCLUSION: Long-term ACEI treatment does not further aggravate the blood pressure decrease under TIVA during minor surgery, provided the induction procedure is slow, the patient is kept well hydrated and vasoconstrictors are promptly applied.

Correlation of exhaled nitric oxide with nitrogen oxides and selected cytokines in induced sputum of chronic obstructive pulmonary disease patients.

Assessment of exhaled nitric oxide (eNO) in patients with chronic obstructive pulmonary disease (COPD) provides seemingly conflicting results and the relationships between eNO and other sputum inflammatory mediators are relatively weakly recognized. In the present study we measured eNO in 63 subjects (14 non-smoking healthy controls and 49 COPD stable patients--15 patients at stage 0, 9 patients at stage 1, 16 patients at stage 2, and 9 patients at stage 3). Additionally, concentrations of cytokines (IL-8, TNF-alpha, TGF-beta1, GM-CSF, Eotaxin) and nitrogen oxides (as nitrite or nitrate) (NOs) were measured in induced sputum in these patients. We found that there were no significant differences between the means of either eNO or NOs levels in COPD patients (stage 0-2) and controls. The only significant difference was noted for NOs between the COPD stage 3 patients and controls (9.0+/-1.7 microM vs. 21.1+/-4.8 microM). There was no significant correlation between eNO and sputum NOs. No relationships existed between eNO and the examined cytokine levels, except for a single negative correlation with GM-CSF (r=-0.38, P=0.02). In contrast, NOs correlated positively with IL-8 levels (r=0.51, P<0.01) and IL-8 levels correlated negatively (r=-0.47, P<0.01) with FEV1. We conclude that exhaled NO, sputum NOs, and other sputum cytokines offer separate and additive information about the pathophysiological condition in COPD.

Effect of angiotensin II and endothelin-1 receptor blockade on the haemodynamic and hormonal changes after acute blood loss and after retransfusion in conscious dogs.

AIM: This study investigates angiotensin II and endothelin-1 mediated mechanisms involved in the haemodynamic, hormonal, and renal response towards acute hypotensive haemorrhage. METHODS: Conscious dogs were pre-treated with angiotensin II type 1 (AT1) and/or endothelin-A (ETA) receptor blockers or not. Protocol 1: After a 60-min baseline period, 25% of the dog's blood was rapidly withdrawn. The blood was retransfused 60 min later and data recorded for another hour. Protocol 2: Likewise, but preceded by AT1 blockade with i.v. Losartan. Protocol 3: Likewise, but preceded by ETA blockade with i.v. ABT-627. Protocol 4: Likewise, but with combined AT1 plus ETA blockade. RESULTS: In controls, haemorrhage decreased mean arterial pressure (MAP) by approximately 25%, cardiac output by approximately 40%, and urine volume by approximately 60%, increased angiotensin II (3.1-fold), endothelin-1 (1.13-fold), vasopressin (116-fold), and adrenaline concentrations (3.2-fold). Glomerular filtration rate and noradrenaline concentrations remained unchanged. During AT1 blockade, the MAP decrease was exaggerated (-40%) and glomerular filtration rate fell. During ETA blockade, noradrenaline increased after haemorrhage instead of adrenaline, and the MAP recovery after retransfusion was blunted. The decrease in cardiac output was similar in all protocols. CONCLUSIONS: Angiotensin II is more important than endothelin-1 for the short-term regulation of MAP and glomerular filtration rate after haemorrhage, whereas endothelin-1 seems necessary for complete MAP recovery after retransfusion. After haemorrhage, endothelin-1 seems to facilitate adrenaline release and to blunt noradrenaline release. Haemorrhage-induced compensatory mechanisms maintain blood flow more effectively than blood pressure, as the decrease in cardiac output--but not MAP--was similar in all protocols.

ACE inhibition does not exaggerate the blood pressure decrease in the early phase of spinal anaesthesia.

BACKGROUND: This study investigates whether long-term treatment with an angiotensin converting enzyme inhibitor (ACEI) impairs the hemodynamic regulation during the early phase of spinal anaesthesia. METHODS: Forty-two patients undergoing minor surgery were studied. Twenty-one patients were long-term treated (ACEI group), while the other patients served as controls (nonACEI group). All patients received a balanced electrolyte solution (6 ml kg(-1)) 20 min before spinal anaesthesia. RESULTS: Mean arterial blood pressure decreased 19% in both groups within 20 min after spinal anaesthesia. Heart rate did not change in either group. Plasma renin concentration increased from 7.3 +/- 2.1 to 12.8 +/- 4 pg ml(-1) during spinal anaesthesia in nonACEI patients (P < 0.05), whereas an elevated plasma renin level remained unchanged in the nonACEI group. The angiotensin II concentration increased in both groups during spinal anaesthesia (P < 0.05). The vasopressin concentration did not change during spinal anaesthesia in the ACEI group, but increased from 1.2 +/- 0.3 to 2.2 +/- 0.5 pg ml(-1) in patients with ACEI treatment (P < 0.05). The norepinephrine concentration increased transiently 5 min after spinal anaesthesia in both groups, and returned to baseline levels within 15 min. CONCLUSION: Long-term ACEI treatment does not further exaggerate the blood pressure decrease in the early phase of spinal anaesthesia. The increase in vasopressin concentrations in ACEI treated patients seems to be sufficient to compensate for the inhibited renin-angiotensin system. In addition, the transient increase in plasma norepinephrine, which occurs independent of preoperative ACEI treatment, seems to be involved in blood pressure regulation during spinal anaesthesia.

Nifedipine inhibits the hypoxia-induced decrease in plasma renin activity in conscious dogs.

Acute hypoxia induces a decrease in plasma renin activity (PRA), mediated, e.g., by an increase in adenosine concentration, calcium channel activity, or inhibition of ATP-sensitive potassium channels. The decrease in PRA results in a decrease in angiotensin II (AngII) and plasma aldosterone concentration (PAC). This study investigates whether these hypoxia-induced mechanisms can be inhibited by the L-type voltage-dependent calcium channel antagonist nifedipine. Eight conscious, chronically tracheotomized dogs received a low sodium diet (0.5 mmol Na x kg body wt(-1) x day(-1)). The dogs were studied twice in randomized order, either with nifedipine infusion (1.5 microg x kg body wt(-1) x min(-1), Nifedipine) or without (Control). The dogs were breathing spontaneously: first hour, normoxia [inspiratory oxygen fraction (FiO2)=0.21]; second and third hour hypoxia (FiO2=0.1). In Controls, PRA (6.8+/-0.8 vs. 3.0+/-0.5 ngAngI x ml(-1) x min(-1)), AngII (13.3+/-1.9 vs. 7.3+/-1.9 pg/ml), and PAC (316+/-50 vs. 69+/-12 pg/ml) decreased during hypoxia (P<0.05). In Nifedipine experiments, PRA (6.5+/-0.9 vs. 10.5+/-2.4 ngAngI x ml(-1) x min(-1)) and AngII (14+/-1.1 vs. 18+/-3.9 pg/ml) increased during hypoxia, whereas the decrease in PAC (292+/-81 vs. 153+/-41 pg/ml) was blunted (P<0.05). These results foster the idea that the hypoxia-induced decrease in PRA involves L-type calcium channel activity.

Atrial natriuretic peptide ameliorates hypoxic pulmonary vasoconstriction without influencing systemic circulation.

UNLABELLED: Hypoxic pulmonary vasoconstriction (HPV) is encountered during ascent to high altitude. Atrial natriuretic peptide (ANP) could be an option to treat HPV because of its natriuretic, diuretic, and vasodilatory properties. Data on effects of ANP on pulmonary and systemic circulation during HVP are conflicting, partly owing to anesthesia, surgical stress or uncontrolled dietary conditions. Therefore, ten conscious, chronically tracheotomized dogs were studied under standardized dietary conditions. The dogs were trained to breathe spontaneously at a ventilator circuit. PROTOCOL: 30min of normoxia [inspiratory oxygen fraction (F(i)O(2))=0.21] were followed by 30min of hypoxia without ANP infusion (Hypoxia I, F(i)O(2)=0.1). While maintaining hypoxia an intravenous infusion of atrial natriuretic peptide was started with 50ng x kg body wt(-1) x min(-1) for 30min (Hypoxia+ANP1=low dose), followed by 1000ng x kg body wt(-1) x min(-1) for 30min (Hypoxia+ANP2=high dose). Thereafter, ANP infusion was stopped and hypoxia maintained for a final 30min (Hypoxia II). Compared to normoxia, mean pulmonary arterial pressure (MPAP) (16+/-0.7 vs. 26+/-1.3mmHg) and pulmonary vascular resistance (PVR) (448+/-28 vs. 764+/-89dyn x s(-1) x cm(-5)) increased during Hypoxia I and decreased during Hypoxia+ANP 1 (MPAP 20+/-1mmHg, PVR 542+/-55dyn x s(-1) x cm(-5)) (P<0.05). The higher dose of ANP did not further decrease MPAP or PVR, but started to have a tendency to decrease mean arterial pressure and cardiac output. We conclude that low dose ANP is able to reduce HPV without affecting systemic circulation during acute hypoxia.

Hemodynamic, renal, and endocrine responses to acute ET(A) blockade at different ANG II plasma levels.

Angiotensin (ANG) II effects may be partly mediated by endothelin (ET)-1. This study analyses the hemodynamic, renal, and hormonal responses of acute ET(A) receptor antagonism (LU-135252) at two ANG II plasma levels in eight conscious dogs. Protocol 1 involved a 60-min baseline, followed by two doses of ANG II for 60 min each (4 and 20 ng. kg(-1). min(-1)), termed ANG II 4 (slightly increased) and ANG II 20 (pathophysiologically increased ANG II plasma concentration). Protocol 2 was the same as protocol 1 but included 15 mg/kg iv LU-135252 after the baseline period. Protocol 3 was a 3-h time control. ANG II without LU-135252 did not increase plasma big ET-1 and ET-1, whereas LU-135252 increased ET-1 transiently after injection. This transient ET-1 increase was not reflected in urinary ET-1 excretion. The ANG II induced decreases in sodium, water, and potassium excretion, glomerular filtration rate, and fractional sodium excretion were not different with and without LU-135252. Mean arterial pressure increased during ANG II and was not lower with LU-135252 (-6 mmHg, not significant). Most importantly, during ANG II 20 LU-135252 prevented the decrease in cardiac output. Simultaneously, systemic vascular resistance increased 40% less, pulmonary vascular resistance was maintained at baseline levels, and central venous and wedge pressure were lower. Because ANG II stimulated endothelin de novo synthesis should just have started after 2 h of ANG II infusion, there must be mechanisms other than blocking the coupling of de novo synthesized endothelins to the ET(A) receptors to explain the effects of acute ET(A) receptor inhibition in our setting.

Evidence that the renin decrease during hypoxia is adenosine mediated in conscious dogs.

This study investigated whether adenosine mediates the decrease in plasma renin activity (PRA) during acute hypoxia. Eight chronically tracheotomized, conscious beagle dogs were kept under standardized environmental conditions and received a low-sodium diet (0.5 mmol.kg body wt(-1).day(-1)). During the experiments, the dogs were breathing spontaneously via a ventilator circuit: first hour, normoxia (21% inspiratory concentration of O(2)); second and third hours, hypoxia (10% inspiratory concentration of O(2)). Each of the eight dogs was studied twice in randomized order in control and theophylline experiments. In theophylline experiments, theophylline, an A(1)-receptor antagonist, was infused intravenously during hypoxia (loading dose: 3 mg/kg within 30 min, maintenance: 0.5 mg. kg(-1). h(-1)). In theophylline experiments, PRA (5.9 +/- 0.8 ng ANG I. ml(-1). h(-1)) and ANG II plasma concentration (15.9 +/- 2.3 pg/ml) did not decrease during hypoxia, whereas plasma aldosterone concentration decreased from 277 +/- 63 to 132 +/- 23 pg/ml (P < 0.05). In control experiments, PRA decreased from 6.8 +/- 0.8 during normoxia to 3.0 +/- 0.5 ng ANG I. ml(-1). h(-1) during hypoxia, ANG II decreased from 13.3 +/- 1.9 to 7.3 +/- 1.9 pg/ml, and plasma aldosterone concentration decreased from 316 +/- 50 to 70 +/- 13 pg/ml (P < 0.05). Thus infusion of the adenosine receptor antagonist theophylline inhibited the suppression of the renin-angiotensin system during acute hypoxia. The decrease in aldosterone occurred independently and is apparently directly related to hypoxia. In conclusion, it is likely that adenosine mediates the decrease in PRA during acute hypoxia in conscious dogs.

Angiotensin II formation and endothelin clearance in ARDS patients in supine and prone positions.

OBJECTIVE: In patients with acute respiratory distress syndrome (ARDS), the prone position may enhance oxygenation by changing ventilation/perfusion ratio. In this study, we investigated whether the prone position affects the net balance between pulmonary endothelin (ET-1) and angiotensin II (Ang II) production and clearance, two metabolic functions of lung endothelial cells. SETTING: Anaesthesiological intensive care unit of a university hospital. PATIENTS: Ten ARDS patients (Murray score > 2.5) were studied in both the supine position (SP) and the prone position (PP). MEASUREMENTS AND DESIGN: Blood samples were taken simultaneously from the patient in SP for assessment of mixed venous and arterial ET-1 and Ang II concentrations, and plasma renin concentration (PRC). This was repeated after 60 min in SP, immediately after turning the patient into PP, and 60 min thereafter. Net arterial/mixed venous ET-1 clearances and net Ang II formations were calculated. RESULTS: arterial oxygen tension increased from SP to PP by an average of 60 mmHg, about 20%. Arterial ET-1 concentrations of ARDS patients were 1.57 +/- 1.1 pg/ml (mean +/- SD) and within the range of healthy persons. Net ET-1 clearances were negative in SP, indicating pulmonary release of ET-1, and did not change in PP. Arterial Ang II concentrations (73 +/- 56 pg/ml) as well as PRC (126 +/- 85 pg/ml) were markedly elevated. Net transpulmonary Ang II formation did not change. CONCLUSION: Acute changes of oxygenation in ARDS patients by positioning do not induce any short-term effects on pulmonary ET-1 net clearance or Ang II net formation.

Acute hypoxic pulmonary vasoconstriction in conscious dogs decreases renin and is unaffected by losartan.

Acute hypoxic pulmonary vasoconstriction (HPV) may be mediated by vasoactive peptides. We studied eight conscious, chronically tracheostomized dogs kept on a standardized dietary sodium intake. Normoxia (40 min) was followed by hypoxia (40 min, breathing 10% oxygen, arterial oxygen pressures 36 +/- 1 Torr) during both control (Con) and losartan experiments (Los; iv infusion of 100 microg. min-1. kg-1 losartan). During hypoxia, minute ventilation (by 0.9 l/min in Con, by 1.3 l/min in Los), cardiac output (by 0.36 l/min in Con, by 0.30 l/min in Los), heart rate (by 11 beats/min in Con, by 30 beats/min in Los), pulmonary artery pressure (by 9 mmHg in both protocols), and pulmonary vascular resistance (by 280 and 254 dyn. s. cm-5 in Con and Los, respectively) increased. Mean arterial pressure and systemic vascular resistance did not change. In Con, PRA decreased from 4.2 +/- 0.7 to 2.5 +/- 0.5 ng ANG I. ml-1. h-1, and plasma ANG II decreased from 11.9 +/- 3.0 to 8.2 +/- 2.1 pg/ml. The renin-angiotensin system is inhibited during acute hypoxia despite sympathetic activation. Under these conditions, ANG II AT1-receptor antagonism does not attenuate HPV.

Renal and hemodynamic effects of losartan in conscious dogs during controlled mechanical ventilation.

In 12 conscious dogs, we investigated whether the angiotensin II-receptor antagonist losartan increases renal sodium excretion and urine volume during controlled mechanical ventilation (CMV) with positive end-expiratory pressure. In four experimental protocols, the dogs were extracellular volume (ECV) expanded (electrolyte solution, 0.5 ml. kg-1. min-1 iv) or not and received losartan (100 micrograms. kg-1. min-1 iv) or not. They breathed spontaneously during the 1st and 4th hour and received CMV with positive end-expiratory pressure (mean airway pressure 20 cmH2O) during the 2nd and 3rd hours. In the expansion group, dogs with losartan excreted approximately 18% more sodium (69 +/- 7 vs. 38 +/- 5 micromol. min-1. kg-1) and 15% more urine during the 2 h of CMV because of a higher glomerular filtration rate (5.3 +/- 0.3 vs. 4.5 +/- 0.2 ml. min-1. kg-1) and the tubular effects of losartan. In the group without expansion, sodium excretion (2.0 +/- 0.6 vs. 2.6 +/- 1.0 micromol. min-1. kg-1) and glomerular filtration rate (3.8 +/- 0.3 vs. 3.8 +/- 0.4 ml. min-1. kg-1) did not change, and urine volume decreased similarly in both groups during CMV. Plasma vasopressin and aldosterone increased in both groups, and plasma renin activity increased from 4.9 +/- 0.7 to 7.8 +/- 1.3 ng ANG I. ml-1. h-1 during CMV in nonexpanded dogs without losartan. Mean arterial pressure decreased by 10 mmHg in nonexpanded dogs with losartan. In conclusion, losartan increases sodium excretion and urine volume during CMV if the ECV is expanded. If the ECV is not expanded, a decrease in mean arterial blood pressure and/or an increase in aldosterone and vasopressin during CMV attenuates the renal effects of losartan.

Renal nerves are not involved in sodium and water retention during mechanical ventilation in awake dogs.

BACKGROUND: The role of renal nerves during positive end-expiratory pressure ventilation (PEEP) has only been investigated in surgically stressed, anesthetized, unilaterally denervated dogs. Anesthesia, sedation, and surgical stress, however, decrease urine volume and sodium excretion and increase renal sympathetic nerve activity independent of PEEP. This study investigated in awake dogs the participation of renal nerves in mediating volume and water retention during PEEP. METHODS: Eight tracheotomized, trained, awake dogs were used. The protocol consisted of 60 min of spontaneous breathing at a continuous positive airway pressure of 4 cm H2O, followed by 120 min of controlled mechanical ventilation with a mean PEEP of 15-17 cm H2O (PEEP), and 60 min of continuous positive airway pressure. Two protocols were performed on intact dogs, in which volume expansion had (hypervolemic; electrolyte solution, 0.5 ml x kg(-1) x min(-1)) and had not (normovolemic) been instituted. This was repeated on the same dogs 2 or 3 weeks after bilateral renal denervation. RESULTS: Hypervolemic dogs excreted more sodium and water than did normovolemic dogs. There was no difference between intact and renal-denervated dogs. Arterial pressure did not decrease when continuous positive airway pressure was switched to PEEP. Plasma renin activity, aldosterone, and antidiuretic hormone concentrations were greater in normovolemic dogs. The PEEP increased aldosterone and antidiuretic hormone concentrations only in normovolemic dogs. CONCLUSIONS: In conscious dogs, renal nerves have no appreciable contribution to sodium and water retention during PEEP. Retention in normovolemic dogs seems to be primarily caused by an activation of the renin-angiotensin system and an increase in the antidiuretic hormone. Excretion rates depended on the volume status of the dogs.

[Effect of blood viscosity on the function of isolated perfused porcine kidney after cold preservation]. / Einfluss der Blutviskosität auf die Funktion der isoliert perfundierten Schweineniere nach Kältekonservierung.

With the new method of gas exchange and dialysis carried out simultaneously with a standard dialysis module, for the first time normothermic ex-vivo whole blood perfusion of pig kidneys becomes practicable under nearly physiological conditions. To show the possibility of animal experiment replacements we use slaughter house kidneys to investigate functional abilities of the perfusion method. Slaughter house kidneys show a state of acute ischemic renal failure due to the unavoidable time of ischemia and cold preservation. Nevertheless they show a specific functional metabolism up to 4 hours of perfusion time. For the future, the new perfusion model seems suitable to investigate acute organ rejection and perfusion phenomena on pig kidneys, which are most interesting for xenotransplantation.

Inhaled nitric oxide does not change transpulmonary angiotensin II formation in patients with acute respiratory distress syndrome.

STUDY OBJECTIVE: To investigate the effect of short-term inhalation of nitric oxide (NO) on transpulmonary angiotensin II formation in patients with severe ARDS. DESIGN: Prospective, clinical study. SETTING: Anesthesiology ICU of a university hospital. PATIENTS: Ten ARDS patients who responded to inhalation of 100 ppm NO by decreasing their pulmonary vascular resistance (PVR) by at least 20 dyne x s x cm(-5) were included in the study. INTERVENTIONS AND MEASUREMENTS: In addition to standard treatment, the patients inhaled 0, 1, and 100 ppm NO in 20-min intervals. Fraction of inspired oxygen was 1.0. Hemodynamics were measured and recorded online. Mixed venous (pulmonary arterial catheter) and arterial (arterial catheter) blood samples were taken simultaneously for hormonal analyses at the end of each inhalation period. RESULTS: Pulmonary arterial pressure decreased from 33+/-2 mm Hg (0 ppm NO, mean+/-SEM) to 29+/-2 mm Hg (1 ppm NO, p<0.05), and to 27+/-2 mm Hg (100 ppm NO, p<0.05, vs 0 ppm). PVR decreased from 298+/-56 (0 ppm NO) to 243+/-45 dyne x s x cm(-5) (1 ppm NO, not significant [NS]), and to 197+/-34 dyne x s x cm(-5) (100 ppm NO, p<0.05, vs 0 ppm). Arterial oxygen pressure increased from 174+/-23 mm Hg (0 ppm NO) to 205+/-26 mm Hg (1 ppm NO, NS), and to 245+/-25 mm Hg (100 ppm NO, p <0.05, vs 0 ppm). Mean plasma angiotensin II concentrations were 85+/-20 (arterial) and 57+/-13 pg/mL (mixed venous) during 0 ppm NO and did not change during inhalation of 1 and 100 ppm NO. Mean transpulmonary plasma angiotensin II concentration gradient (=difference between arterial and mixed venous blood values) was 28+/-8 pg/mL (range, 0 to 69) during 0 ppm NO and did not change during inhalation of 1 and 100 ppm NO. Mean transpulmonary angiotensin II formation (transpulmonary angiotensin II gradient multiplied with the cardiac index) was 117+/-39 ng/min/m2 (range, 0 to 414) during 0 ppm NO and did not change during inhalation of 1 and 100 ppm NO. Mean arterial plasma cyclic guanosine monophosphate concentration was 11+/-2 pmol/mL (0 ppm NO), did not change during 1 ppm NO, and increased to 58+/-8 pmol/mL (100 ppm NO, p<0.05). Arterial plasma concentrations of aldosterone (142+/-47 pg/mL), atrial natriuretic peptide (114+/-34 pg/mL), angiotensin-converting enzyme (30+/-5 U/L), and plasma renin activity (94+/-26 ng/mL/h of angiotensin I) did not change. CONCLUSION: The decrease of PVR by short-term NO inhalation in ARDS patients was not accompanied by changes in transpulmonary angiotensin II formation. Our results do not support any relationship between transpulmonary angiotensin II formation and the decrease in PVR induced by inhaled NO.

[A new method of ex vivo whole blood perfusion of isolated mammalian organs, exemplified by the kidney of swine]. / Eine neue Methode zur Ex-vivo-Vollblut-Perfusion isolierter Warmblüterorgane, dargestellt an der Niere von Schweinen.

A new method for the ex vivo perfusion of organs from large mammals is described. Gas exchange and dialysis are carried out simultaneously with a low-flux polysulfon dialysis module. The dialysate (e.g. Tyrode solution) is aerated with a mixture of oxygen and carbon dioxide to ensure gas exchange with the blood. Dialysis is carried out in a closed thermostatically controlled system. Monitoring of ultrafiltration is maintained by continuously weighing the blood reservoir and adjusting an afferent and efferent blood pump. Initial results obtained with isolated pig kidneys demonstrate the suitability of the new method for use as a model for the replacement of animal experiments. Theoretically, clinical application in the area of in vivo regional organ perfusion may also be possible.

Short-term ACE inhibition has no effect on sodium and water excretion during PEEP ventilation.

The short-term effect of intravenous (i.v.) angiotensin converting enzyme (ACE) inhibitor enalaprilat in 10 critically ill patients, being ventilated with positive end-expiratory pressure (PEEP), on sodium and water excretion was investigated. Mean arterial pressure (MAP) decreased. Heart rate and central venous pressure (CVP) did not change. Glomerular filtration rate (GFR), urine volume (V) and sodium excretion (UNaV) decreased in two patients with reduced MAP. GFR, V and UNaV increased in two patients with decreased MAP. No relation between changes in MAP and excretion was observed in six patients. ACE decreased in all patients. Plasma renin activity increased, aldosterone decreased, while atrial natriuretic peptide as well as antidiuretic hormone did not change. Enalaprilat did not facilitate sodium and water excretion during ventilation with PEEP. Decreased MAP indicates that the investigated patients were very dependent on their renin-angiotensin system to maintain systemic perfusion pressure. Base-line MAP and CVP values were no predictors of haemodynamic and excretory changes following acute ACE inhibition.

Vasopressin and renin-angiotensin maintain arterial pressure during PEEP in nonexpanded, conscious dogs.

Increases of plasma arginine vasopressin (AVP) and plasma renin activity (PRA) during controlled mechanical ventilation (CMV) with positive end-expiratory pressure (PEEP) induce positive fluid balances by decreasing renal excretion. We investigated whether elevated levels of AVP and/or PRA maintain mean arterial pressure (MAP) during PEEP under conditions where plasma volume is not expanded. Six conscious chronically tracheotomized beagle dogs, kept under standardized conditions, were investigated in four protocols. They were 1) control: 1 h spontaneous breathing with a continuous positive airway pressure of 4 cmH2O (CPAP 4) followed by 2 h CMV with PEEP, resulting in a mean airway pressure of approximately 20 cmH2O (CMV 20 referred to as "PEEP"); 2) vasopressin blockade: 1 h CPAP 4, 2 h PEEP after intravenous application of an AVP V1-receptor antagonist (AVPA); 3) converting enzyme inhibition: 1 h CPAP 4, 2 h PEEP plus angiotensin-converting enzyme inhibition (ACEI); and 4) combined blockade: 1 h CPAP 4, 2 h PEEP plus AVPA + ACEI. In AVPA + ACEI, MAP decreased during PEEP from 101 +/- 4 to 75 +/- 10 mmHg, glomerular filtration rate (GFR) decreased from 3.6 +/- 0.3 to 1.7 +/- 0.7 ml.min-1.kg body wt-1, heart rate increased from 95 +/- 10 to 122 +/- 7 beats/min, plasma aldosterone increased from 62 +/- 26 to 353 +/- 63 pg/ml, plasma epinephrine increased from 81 +/- 15 to 352 +/- 89 pg/ml (all changes P < 0.05), and plasma norepinephrine did not change. Neither MAP nor GFR changed during PEEP in control experiments in which both PRA and AVP increased, in AVPA experiments in which PRA increased, or in ACEI experiments in which AVP increased. We conclude that both AVP and angiotensin II contribute to the maintenance of MAP and GFR during PEEP. When both hormones are inhibited, no immediate compensation exists to prevent an acute fall in MAP and GFR.

High water intake combined with low sodium intake abolishes the antidiuretic effect of angiotensin II in conscious dogs.

1. We studied post-prandial changes in renal function in dogs adapted to either low or high sodium intake with and without concomitant post-prandial infusion of angiotensin II. Six trained dogs were exposed to diets containing either 0.5 or 14.5 mmol Na+ day-1 kg-1 body weight (low or high sodium respectively). They were studied from 20 min before to 4 h after food intake. In half of the experiments a physiological dose of angiotensin II (4 ng min-1 kg-1 body weight) was administered after food intake for four post-prandial hours. The water intake was high and equal on both diets (91 ml day-1 kg-1 body weight). 2. On a high-salt diet post-prandial sodium excretion and urine volume increased considerably above fasting values. This post-prandial increase was attenuated when angiotensin II was infused (post-prandial sodium excretion was 31% +/- 3% of intake without versus 10% +/- 1% with angiotensin II, post-prandial urine volume was 22% +/- 2% without versus 8% +/- 1% with angiotensin II, P < 0.05). Post-prandial increases in glomerular filtration rate and fractional sodium excretion were attenuated during angiotensin II infusion in dogs on a high-salt diet. 3. On a low-salt diet post-prandial sodium excretion remained low with or without angiotensin II infusion, whereas urine volume increased post-prandially, and this increase was greater when angiotensin II was administered (40% +/- 3% versus 34% +/- 2% of intake, P < 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)

Methohexital impairs osmoregulation. Studies in conscious and anesthetized volume-expanded dogs.

BACKGROUND: Anesthetic agents influence central regulations. This study investigated the effects of methohexital anesthesia on renal and hormonal responses to acute sodium and water loading in dogs in the absence of surgical stress. METHODS: Fourteen experiments (two in each dog) were performed in seven well-trained, chronically tracheotomized beagle dogs kept in highly standardized environmental and dietary conditions (2.5 mmol sodium and 91 ml water/kg body weight daily). Experiments lasted 3 h, while the dogs were conscious (7 experiments) or, after 1 h control, while they were anesthetized (7 experiments) with methohexital (initial dose 6.6 mg/kg body weight and maintenance infusion 0.34 mg.min-1.kg-1 body weight) over a period of 2 h. In both experiments, extracellular volume expansion was performed by intravenous infusion of a balanced isoosmolar electrolyte solution (0.5 ml.min-1.kg-1 body weight). Normal arterial blood gases were maintained by controlled mechanical ventilation. In another five dogs the same protocol was used, and vasopressin (0.05 mU.min-1.kg-1 body weight) was infused intravenously during methohexital anesthesia. RESULTS: Values are given as means. During methohexital anesthesia, mean arterial pressure decreased from 108 to 101 mmHg, and heart rate increased from 95 to 146 beats/min. Renal sodium excretion decreased; urine volume increased; and urine osmolarity decreased from 233 to 155 mosm/l, whereas plasma osmolarity increased from 301 to 312 mosm/l because of an increase in plasma sodium concentration from 148 to 154 mmol/l. Plasma renin activity, plasma aldosterone concentration, plasma atrial natriuretic peptide, and plasma antidiuretic hormone concentrations (range 1.8-2.8 pg/ml) did not change in either protocol. In the presence of exogenous vasopressin (antidiuretic hormone 3.3 pg/ml), water diuresis did not occur, and neither plasma osmolarity nor the plasma concentration of sodium changed. CONCLUSIONS: Methohexital may impair osmoregulation by inhibiting adequate pituitary antidiuretic hormone release in response to an osmotic challenge.

Cardiac baroreflex sensitivity and sodium excretion are reduced both by a deficit and an excess of dietary salt in the conscious dog.

In 10 conscious, chronically instrumented beagle dogs we studied the effects of four different dietary sodium intakes (mmol Na/kg body wt/day: 14.5 [excess], 7.5 [high], 2.5 [normal], and 0.5 [low] [plus an additional standardized sodium depletion produced by peritoneal dialysis several days before the experiments]) on cardiac baroreflex sensitivity and renal response to an acute saline load. Full sigmoid barocurves were produced by intravenous injection of phenylephrine (2.5 to 20 micrograms/kg) and nitroglycerine (2.5 to 30 micrograms/kg). The gain of this relationship was significantly decreased by both an excess and low sodium intake (8.0 +/- 1.0 and 8.3 +/- 0.8 beats/min/mm Hg, respectively) when compared with the 2.5 and 7.5 (12.1 +/- 1.4 and 16.0 +/- 1.7 beats/min/mm Hg, respectively) mmol Na/kg/day sodium intake. Water and sodium excretion in response to saline infusion were lower in the 0.5 and 14.5 mmol/kg/day sodium intake groups in spite of the higher atrial natriuretic peptide and lower plasma renin activity and plasma aldosterone levels in the latter. Mean arterial blood pressure, heart rate, and central venous pressure increased during saline loading in all groups; hematocrit and plasma protein concentration decreased similarly in all groups. The results suggest that the rapid renal homeostatic response to an acute salt load in animals kept chronically on normal or moderately increased dietary sodium intake is regulated by baroreflex control of the renal homeostatic response. Excess dietary sodium intake attenuates baroreflex sensitivity and delays sodium and water excretion after acute loading.