Marbofloxacin disposition after intravenous administration of a single dose in wild mallard ducks (Anas platyrhynchos)

Marbofloxacin, a fluoroquinolone developed specifically for veterinary use, has demonstrated considerable pharmokinetic variation among avian species. The goal of this study was to determine the disposition kinetics of marbofloxacin in mallard ducks (Anas platyrhynchos) after a single intravenous injection. Six wild mallard ducks were used in the study. Marbofloxacin was injected at a dose of 2 mg/kg into the basilic vein, and blood was subsequently collected at regular intervals from each bird. Plasma marbofloxacin concentrations were determined by using high-performance liquid chromatography. The volume of distribution at steady state was 1.78 +/- 0.37 L/kg, and the total plasma clearance was 0.59 +/- 0.08 L/kg per hour. Marbofloxacin had a relatively short permanence, with a elimination half-life of 2.81 +/- 1.20 hours, a terminal half-life of 2.43 +/- 0.61 hours, and a mean residence time of 2.99 +/- 0.52 hour. The maximum observed concentration (Cmax) and area under the curve (AUC) were 1.34 +/- 0.27 microg/mL and 3.75 +/- 0.56 microg x h/mL, respectively. Values of minimum inhibitory concentration (MIC), Cmax, and AUC have been used to predict the clinical efficacy of a drug in treating bacterial infections, with a Cmax: MIC value of 10 and an AUC: MIC ratio of 125-250 associated with optimal bactericidal effects. By using the study data and MIC breakpoints of 0.125 microg/mL or 0.2 microg/mL, values derived for Cmax: MIC were 9.37 +/- 0.99 and 5.85 +/- 0.62, respectively, and for AUC: MIC were 29.99 +/- 4.51 and 18.74 +/- 2.82, respectively. By using MIC values of 0.125 and 0.2 microg/mL and a target AUC: MIC = 125, the calculated optimal daily marbofloxacin dosages for mallard ducks were 9.24 and 14.78 mg/kg, respectively. These results suggest that, primarily because of the high total plasma clearance observed, the marbofloxacin dose for treatment of bacterial diseases in mallard ducks should be increased after intravenous administration. Intravenous doses of 10-15 mg/kg should be assessed by studying their potential toxicity and efficacy in sick birds.     

Pharmacokinetics of clindamycin administered orally to pigeons

To determine the plasma concentration of clindamycin in pigeons after oral administration, 12 rock pigeons (Columba livia) were used in a 2-phase study. In the first phase, 8 pigeons received clindamycin by gavage at 100 mg/kg as a single dose. Blood samples were collected at 0, 0.25, 0.5, 1, 2, 3, 4, and 6 hours, and the plasma was separated, frozen, and subsequently analyzed by liquid chromatography-mass spectrometry for clindamycin and its active metabolites, N-demethylclindamycin (NCLD) and clindamycin sulfoxide. Clindamycin was rapidly absorbed with plasma concentrations peaking at 0.5 hours at 1.43 microg/mL. The terminal half-life (t(1/2)) was 1.25 hours, and the mean residence time was 2.49 hours. N-demethylclindamycin was detected in 7 of 8 birds (88%), whereas clindamycin sulfoxide was not found in any samples. In phase 2, clindamycin was administered to 3 birds by gavage at 100 mg/ kg q6h for 5 doses. Mean peak plasma concentrations were 2.46 and 0.64 microg/mL, with trough concentrations of 0.11 and 0.44 microg/mL for clindamycin and NCLD, respectively. No adverse effects were observed in any birds. Based on an additive antimicrobial effect of NCLD with clindamycin, an oral dosage of 100 mg/kg q6h in pigeons should reach effective plasma concentrations against common susceptible pathogens. If dose proportionality exists, lower doses and longer intervals likely produce subtherapeutic concentrations to treat systemic infections. How well birds would tolerate an extended oral dose regimen, how frequently birds fail to produce the active metabolite critical for an additive effect, and the application of these results to other avian species require further study.     

Evaluation of efficacy and plasma concentrations of ropivacaine in continuous axillary brachial plexus block: high dose for surgical anesthesia and low dose for postoperative analgesia

BACKGROUND AND OBJECTIVES: Ropivacaine is a potent local anesthetic that, experimentally at low concentrations, produces an effective block of pain conducting nerve fibers. Therefore, it was hypothesized that 0.1% and 0.2% ropivacaine would provide clinically adequate postoperative analgesia in continuous axillary plexus block. METHODS: Sixty patients (ASA I-II) scheduled for elective hand or forearm surgery received 5 mg/kg of 0.75% ropivacaine for axillary block using nerve stimulator technique. One hour later, in random order, a continuous infusion of either 0.1% ropivacaine (0.125 mg/kg/h), 0.2% ropivacaine (0.25 mg/kg/h) or saline 6 to 11 mL/h was started. RESULTS: The mean total ropivacaine dose for the surgical block was 5.1 to 5.2 mg/kg with the supplementation. All patients were pain free for the first 12 to 15 hours after the block. The need for postoperative analgesics during the infusion was similar in all groups. After the initial block, the maximum plasma concentrations (mean 2.5 microg/mL) were measured at 45 or 60 minutes after injection. The highest individual plasma concentration was 4.2 microg/mL. Despite the high venous peak concentration, no toxic reactions were observed. The mean peak plasma concentration (Cmax) was 2.2+/-0.5 microg/mL for saline, 2.6+/-0.8 microg/mL for 0.1% ropivacaine, and 2.6+/-0.7 microg/mL for 0.2% ropivacaine. During the continuous infusion of 24 hours, the ropivacaine concentration declined steadily. CONCLUSIONS: Ropivacaine is safe and effective for axillary brachial plexus block. The continuous infusion of 0.1% or 0.2% ropivacaine was no more beneficial than an infusion of saline in relieving postoperative pain in patients having elective hand surgery. None of the infusions were sufficient to adequately treat the patients' pain without the addition of adjunct agents.     

Antibiotic prophylaxis with cefazolin and gentamicin in cardiac surgery for children less than ten kilograms

OBJECTIVE: Antibiotic prophylaxis is recommended in pediatric cardiac surgery, but no data concerning the current antibiotic regimen were available. DESIGN: Prospective study from April to June 2000. SETTING: University hospital operating room and postoperative intensive care unit. PARTICIPANTS: Nineteen consecutive infants less than 10 kg with normal renal function undergoing cardiac surgery with cardiopulmonary bypass longer than 30 minutes. INTERVENTIONS: Intravenous administration of cefazolin, 40 mg/kg, and gentamicin, 5 mg/kg, at induction of anesthesia; followed by cefazolin, 35 mg/kg every 8 hours, and gentamicin, 2 mg/kg every 12 hours, over 48 hours. MEASUREMENTS AND MAIN RESULTS: Levels of serum antibiotics were measured: cefazolin (microbiologic) and gentamicin (fluorescence immunoassay) with 8 intraoperative and 5 postoperative samplings. Intraoperatively, cefazolin levels decreased from 166 +/- 44 (mean +/- standard deviation) down to 54 +/- 16 microg/mL and gentamicin from 20.8 +/- 9.5 down to 5.9 +/- 1.5 microg/mL. The postoperative trough levels were 12 +/- 7, 15 +/- 10, and 19 +/- 22 microg/mL for cefazolin and 1.1 +/- 0.5, 0.8 +/- 0.4, and 0.8 +/- 0.9 microg/mL for gentamicin. CONCLUSIONS: Antibiotic serum levels are consistent with satisfactory efficacy, but intraoperative gentamicin peak levels appeared too high.     

The effects of intravenous lidocaine administration on the minimum alveolar concentration of isoflurane in cats

Lidocaine decreases the minimum alveolar concentration (MAC) of inhaled anesthetics and has been used clinically to reduce the requirements for other anesthetic drugs. In this study we examined the effects of lidocaine on isoflurane MAC in cats. Six cats were studied. In Experiment 1, the MAC of isoflurane was determined. An IV bolus of lidocaine 2 mg/kg was then administrated and venous plasma lidocaine concentrations were measured to determine pharmacokinetic values. In Experiment 2, lidocaine was administered to achieve target plasma concentrations between 1 and 11 microg/mL and the MAC of isoflurane was determined at each lidocaine plasma concentration. Actual lidocaine plasma concentrations were 1.06 +/- 0.12, 2.83 +/- 0.39, 4.93 +/- 0.64, 6.86 +/- 0.97, 8.86 +/- 2.10, and 9.84 +/- 1.34 microg/mL for the target concentrations of 1, 3, 5, 7, 9, and 11 microg/mL, respectively. The MAC of isoflurane in this study was 2.21% +/- 0.17%, 2.14% +/- 0.14%, 1.88% +/- 0.18%, 1.66% +/- 0.16%, 1.47% +/- 0.13%, 1.33% +/- 0.23%, and 1.06% +/- 0.19% at lidocaine target plasma concentrations of 0, 1, 3, 5, 7, 9, and 11 microg/mL, respectively. Lidocaine, at target plasma concentrations of 1, 3, 5, 7, 9, and 11 microg/mL, linearly decreased isoflurane MAC by -6% to 6%, 7% to 28%, 19% to 35%, 28% to 45%, 29% to 53%, and 44% to 59%, respectively. We conclude that lidocaine decreases the MAC of isoflurane.     

The effect of the addition of epinephrine on early systemic absorption of epidural ropivacaine in humans

The addition of epinephrine to ropivacaine has not been recommended because ropivacaine has intrinsic vasoconstrictor properties. However, few pharmacokinetic data are available on the addition of epinephrine to epidural ropivacaine in humans. In this prospective, double-blinded study, we randomized patients having elective abdominal hysterectomy to receive epidural ropivacaine 1.5 mg/kg, diluted in 15 mL, either with (epinephrine group, n = 12) or without (plain group, n = 12) epinephrine 5 microg/mL and then measured arterial and venous plasma concentrations of ropivacaine at intervals up to 180 min. We found that arterial and venous plasma ropivacaine concentrations were smaller in the epinephrine group compared with the plain group in the first 60 min after the drug administration (P < 0.01). Mean (+/- SD) maximum total plasma ropivacaine concentration was smaller in the epinephrine group (arterial, 0.92 +/- 0.32 microg/mL; venous, 0.82 +/- 0.33 microg/mL) compared with the plain group (1.31 +/- 0.39 microg/mL and 1.31 +/- 0.50 microg/mL, respectively; P = 0.01). Time to maximum total plasma ropivacaine concentration was not significantly different between groups (mean +/- SD; arterial, 16 +/- 2 min; venous, 23 +/- 2 min in the epinephrine group versus 9 +/- 2 min and 12 +/- 3 min, respectively, in the plain group; P = 0.08). Arterial plasma ropivacaine concentrations were larger than venous concentrations during the first hour (P < 0.01); the arterio-venous difference decreased exponentially, and the rate and magnitude of this decrease was unaffected by epinephrine. We conclude that the addition of epinephrine 5 microg/mL to ropivacaine reduced the early systemic plasma concentrations of ropivacaine after epidural injection and may be useful for decreasing the risk of toxicity from systemic absorption of epidural ropivacaine. IMPLICATIONS: The addition of epinephrine 5 microg/mL to epidural ropivacaine reduced the systemic arterial and venous plasma concentrations of ropivacaine in the first hour and the maximum plasma concentration of ropivacaine. Epinephrine may be a useful additive for reducing the risk of systemic toxicity when large doses of ropivacaine are given epidurally.     

The effects of epidural insertion site and surgical procedure on plasma lidocaine concentration

We compared the plasma lidocaine concentrations associated with continuous epidural infusion at different insertion sites in patients during surgery using epidural plus general anesthesia. In Study 1, there were 12 patients in each of four surgical groups in whom blood loss was expected to be <400 mL. The four groups were as follows: the lower extremity, the lower abdomen, the upper abdomen, and the lung. Liver surgery was excluded from Study 1. Study 2 comprised patients undergoing radical hysterectomy or radical prostatectomy (a radical operation group, n = 12) and hepatectomy (a hepatectomy group, n = 12) in whom the expected surgical blood loss was more than 1500 mL. All patients initially received 0.1 mL/kg followed by a continuous infusion of 0.1 mL. kg(-1). h(-1) of 1.5% lidocaine, and plasma concentrations of lidocaine were measured at 15, 30, 60, 90, and 120 min and every 60 min thereafter to 300 min. The plasma lidocaine concentration during surgery did not change regardless of the infusion site or the surgical site, other than the liver. The plasma concentrations of lidocaine in the hepatectomy group increased significantly at 180 min (2.9 +/- 0.6 microg/mL, P < 0.01), 240 min (3.5 +/- 0.7 microg/mL, P < 0.01), and 300 min (3.6 +/- 0.74 microg/mL, P < 0.01) compared with that at 15 min (2.0 +/- 0.3 microg/mL), and these values were significantly larger than those in all other groups.     

Pharmacokinetics of amrinone in neonates and infants

OBJECTIVE: To evaluate the pharmacokinetics of amrinone and its metabolites in neonates and infants after reconstructive surgery for congenital heart disease. DESIGN: Prospective study. SETTING: Pediatric intensive care unit in a university hospital. PARTICIPANTS: Fifteen neonates aged less than 1 month with transposition of the great arteries and 14 infants aged 2 to 6 months with complete atrioventricular septal defect. INTERVENTIONS: Amrinone, loading dose of 2 mg/kg, was administered before weaning from cardiopulmonary bypass, followed by a maintenance infusion of 7.5 microg/kg/min. MEASUREMENTS AND MAIN RESULTS: Blood samples to determine plasma concentrations of amrinone, N-acetylamrinone, and N-glycolylamrinone were drawn before amrinone administration, frequently after the loading dose, every 6 hours during the maintenance infusion, and until 48 hours after the end of the infusion. Amrinone clearance was 2.4 +/- 0.9 mL/kg/min in neonates and 3.2 +/- 1.2 mL/kg/min in infants (p < 0.05). The volume of distribution at steady-state was smaller (p < 0.05) in neonates than in infants. The elimination half-life of amrinone was 10.7 +/- 6.7 hours in neonates and 6.1 +/- 1.4 hours in infants (p < 0.05). There was a linear correlation between the clearance of amrinone and the body surface area (r = 0.67; p < 0.05). The ratio of the plasma concentration of N-acetylamrinone to that of amrinone did not differ between neonates and infants. CONCLUSIONS: Amrinone is eliminated at a slower rate in neonates than in infants. The rate of acetylation of amrinone appears to be similar; the differences in the elimination capacity of amrinone are mainly due to the immature renal function in neonates.     

Plasma tranexamic acid concentrations during cardiopulmonary bypass

Although tranexamic acid is used to reduce bleeding after cardiac surgery, there is large variation in the recommended dose, and few studies of plasma concentrations of the drug during cardiopulmonary bypass (CPB) have been performed. The plasma tranexamic acid concentration reported to inhibit fibrinolysis in vitro is 10 microg/mL. Twenty-one patients received an initial dose of 10 mg/kg given over 20 min followed by an infusion of 1 mg. kg(-1). h(-1) via a central venous catheter. Two patients were removed from the study secondary to protocol violation. Perioperative plasma tranexamic acid concentrations were measured with high-performance liquid chromatography. Plasma tranexamic acid concentrations (microg/mL; mean +/- SD [95% confidence interval]) were 37.4 +/- 16.9 (45.5, 29.3) after bolus, 27.6 +/- 7.9 (31.4, 23.8) after 5 min on CPB, 31.4 +/- 12.1 (37.2, 25.6) after 30 min on CPB, 29.2 +/- 9.0 (34.6, 23.8) after 60 min on CPB, 25.6 +/- 18.6 (35.1, 16.1) at discontinuation of tranexamic acid infusion, and 17.7 +/- 13.1 (24.1, 11.1) 1 h after discontinuation of tranexamic acid infusion. Four patients with renal insufficiency had increased concentrations of tranexamic acid at discontinuation of the drug. Repeated-measures analysis revealed a significant main effect of abnormal creatinine concentration (P = 0.02) and time (P < 0.001) on plasma tranexamic acid concentration and a significant time x creatinine concentration interaction (P < 0.001). IMPLICATIONS: A 10 mg/kg initial dose of tranexamic acid followed by an infusion of 1 mg.kg(-1).h(-1)produced plasma concentrations throughout the cardiopulmonary bypass period sufficient to inhibit fibrinolysis in vitro. The dosing of tranexamic acid may require adjustment for renal insufficiency.     

Lidocaine with fentanyl, compared to morphine, marginally improves postoperative epidural analgesia in children

PURPOSE: To compare the epidural administration of fentanyl (1 microg/mL) combined with lidocaine 0.4% to preservative-free morphine for postoperative analgesia and side effects in children undergoing major orthopedic surgery. METHODS: In a prospective, double-blind study, 30 children, ASA I-II, 2-16-yr-old, were randomly allocated to receive immediately after surgery either epidural F-L (epidural infusion at a rate of 0.1-0.35 mL/kg/hr of 1 microg/mL of fentanyl and lidocaine 0.4%) or epidural M (bolus of 20 microg/kg of morphine in 0.5 mL/kg saline every eight hours). Both groups received 40 mg/kg of iv metamizol (dipyrone) every six hours. In the F-L Group, blood samples were taken on the second and third postoperative day to determine total lidocaine concentrations. Adequacy of analgesia using adapted pediatric pain scales (0-10 score) and side-effects were assessed every eight hours postoperatively. RESULTS: Resting pain scores were under 4, 95% of the time in the F-L Group and 87% of the time in the M Group (Chi square=4.674, P <0.05). The frequency of complications was very similar in both groups. The F-L Group total plasma lidocaine concentrations were directly related to the dose received, and below the toxic range in all patients. CONCLUSIONS: Postoperative epidural fentanyl with lidocaine infusion provides slightly better analgesia than conventional bolus administration of epidural morphine. Side-effects or risk of systemic toxicity were not augmented by the addition of lidocaine to epidural opioids.     

Continuous fascia iliaca compartment block in children: a prospective evaluation of plasma bupivacaine concentrations, pain scores, and side effects

We sought to determine the plasma concentrations of bupivacaine and its main metabolite after continuous fascia iliaca compartment (FIC) block in children. Twenty children (9.9 +/- 4 yr, 38 +/- 19 kg) received a continuous FIC block for either postoperative analgesia (n = 16) or femoral shaft fracture (n = 4). A bolus dose of 0.25% bupivacaine (1.56 +/- 0.3 mg/kg) with epinephrine was followed by a continuous administration of 0.1% bupivacaine (0.135 +/- 0.03 mg. kg(-)(1). h(-)(1)) for 48 h. Plasma bupivacaine levels were determined at 24 h and 48 h by using gas liquid chromatography. Heart rate, arterial blood pressure, respiratory rate, side effects, and pain scores were recorded at 4-h intervals during 48 h. No significant differences were found between mean plasma bupivacaine levels at 24 h (0.71 +/- 0.4 microg/mL) and at 48 h (0.84 +/- 0.4 microg/mL) (P = 0.33). FIC block provided adequate analgesia in most cases. No severe adverse effects were noted. We conclude that the bupivacaine plasma concentrations during continuous FIC block in children are within the safety margins. FIC block is well tolerated, and provides satisfactory pain relief in most cases. IMPLICATIONS: In this study, we have shown that, in children, continuous fascia iliaca compartment block, a technique providing neural blockade of the thigh and the anterior part of the knee, was associated with safe plasma bupivacaine concentrations, was well tolerated, and provided satisfactory pain scores in most cases.     

Pharmacokinetics and pharmacodynamics of ropivacaine 2 mg/mL, 5 mg/mL, or 7.5 mg/mL after ilioinguinal blockade for inguinal hernia repair in adults

The aim of our study was to evaluate the pharmacokinetics and pharmacodynamics of ropivacaine in ilioinguinal-iliohypogastric blocks (IIB). After ethics committee approval and informed consent, 80 male adults scheduled for inguinal hernia repair were enrolled and randomized into four groups. After induction of general anesthesia, an IIB was performed double blinded in Groups 1, 2, and 3 with 0.25 mL/kg ropivacaine 2 mg/mL, 5 mg/mL, or 7.5 mg/mL and with saline in the Control group. Plasma concentration of ropivacaine was determined in venous blood using reversed-phase high-performance liquid chromatography. IIB with ropivacaine resulted in peak plasma concentrations of 0.3+/-0.15 microg/mL (Group 1) (mean +/- SD), 0.75+/-0.45 microg/mL (Group 2), or 1.57+/-0.82 microg/mL (Group 3). These concentrations occurred after 30 (15-60) min, median (range), 30 (10-60) min, and 45 (15-60) min, in the respective groups. Three of 19 patients in Group 1, 6 of 18 in Group 2, and 5 of 20 in Group 3 did not need any additional analgesics within 24 h postoperatively, but all 20 control patients did. Time to the first demand for analgesia was significantly shorter in the Control group (median 0.3 h [range 0-2.8]) compared with 1.5 h (0.5-24 h), 2 h (0.5-24 h), and 2 h (1.0-24 h) in Groups 1, 2, and 3, respectively. Three patients in Group 3 had a postoperative motor block of the femoral nerve. In conclusion, a ropivacaine dose of 0.25 mL/kg of 5 mg/mL seems adequate for IIB accompanying general anesthesia for postoperative pain relief. However, the pharmacokinetic results obtained suggest that even larger doses (0.25 mL/kg of 7.5 mg/mL ropivacaine) for IIB do not result in plasma concentrations in a toxic range. IMPLICATIONS: Ropivacaine, a new local anesthetic, proved to be effective for pain relief after hernia repair in ilioinguinal blocks accompanying general anesthesia. Plasma concentrations peaked after 30-45 min, and were within safe limits after application of 0.25 mL/kg of 2, 5, or 7.5 mg/mL ropivacaine.     

Pharmacokinetics of intermittent intraperitoneal ceftazidime

Ceftazidime is currently recommended as an alternative first-line agent in the treatment of peritonitis and for Pseudomonas peritonitis. The pharmacokinetics of intermittent intraperitoneal (i.p.) ceftazidime have been poorly characterized. This study was designed to characterize the pharmacokinetic disposition of a single dose of ceftazidime in anuric and non-anuric CAPD patients, over 48 hours. This was a prospective, open label, pharmacokinetic study. The study was conducted in an independent, outpatient dialysis center. Ten volunteer continuous ambulatory peritoneal dialysis (CAPD) patients with and without residual renal function, no peritonitis or antibiotics in the previous 4 weeks, and on CAPD for at least 2 months were recruited. Patients received a single dose of i.p. ceftazidime (15 mg/kg) in the first daytime exchange over a 6-hour dwell, after an overnight dwell. Serum, urine, and dialysate were collected over a 48-hour period. A high-pressure liquid chromatography (HPLC) assay was used to analyze ceftazidime in these samples. Pharmacokinetic parameters were calculated. Six of the 10 patients were non-anuric with a mean residual renal creatinine clearance of 2.9 +/- 1.6 mL/min. The mean +/- SD bioavailability was 72% +/- 14%, and the volume of distribution was 0.34 +/- 0.08 L/kg. The mean serum elimination half-life of 22 +/- 5 hours. The peritoneal clearance was 5.74 +/- 1.6 mL/min. No difference was detected between anuric and nonanuric patients. Mean plasma and dialysate concentrations at 24 hours were 24 +/- 6 microg/mL and 18 +/- 7 microg/mL, respectively, and were 12.0 +/- 3.6 microg/mL and 7.4 +/- 3.1 microg/mL at 48 hours, respectively. Once-daily i.p. dosing of ceftazidime achieves serum and dialysate levels greater than the MIC of sensitive organisms over 48 hours.     

Pharmacokinetics of oral tramadol drops for postoperative pain relief in children aged 4 to 7 years--a pilot study

Tramadol hydrochloride is an analgesic with mu receptor activity suitable for administration to children as oral drops. As the serum concentration profile and pharmacokinetic parameters in young children are not known via this route, we studied 24 healthy ASA 1 children to determine those parameters. The children's mean age was 5.3 +/- 1.1 years and their mean weight was 17.8 +/- 3.1 kg. They underwent general anesthesia with sevoflurane for dental surgery. The mean duration of anesthesia was 27.9 +/- 10.1 minutes. Tramadol 1.5 mg/kg (this dose was chosen because we have previously shown it to be effective in providing analgesia following pediatric dental surgery) was administered as oral drops 30 minutes before anesthesia. Venous blood samples were taken following the tramadol at 30-minute intervals for 4 hours, every 2 hours for 6 hours, and every 4 hours for 12 hours. The samples were centrifuged and the serum stored at -20 degrees C, and nonstereoselective gas chromatography was used to determine the concentration of (+) and (-) tramadol enantiomers plus their o-demethyltramadol (M1) metabolite concentrations. The tramadol absorption was rapid, the maximum measured serum concentration present occurring before the first sample at 30 minutes. That first sample had a concentration of 352 +/- 83.4 ng/mL. The concentration remained above the 100 ng/mL analgesic level until 6.8 +/- 0.9 hours. The elimination half-life was 3.6 +/- 1.1 hours, the serum clearance 5.6 +/- 2.7 mL/kg/min, and the volume of distribution 4.1 +/- 1.2 L/kg. The (+) enantiomer concentration was 14.2 +/- 4.9% greater than that of the (-) enantiomer. The M1 metabolites had a (-) enantiomer concentration 92.3 +/- 75.1% greater than the (+) enantiomer. From the peak concentration at 4.5 +/- 1.5 hours, the concentration of the metabolite was approximately one third that of the parent drug. The M1 elimination half-life was 5.8 +/- 1.7 hours. Apart from the rapid rise in the serum concentration, these kinetic parameters are similar to those seen in healthy young adults. The concentration profile supports an effective clinical duration in the region of 7 hours.     

Small-dose dopamine increases epidural lidocaine requirements during peripheral vascular surgery in elderly patients

We studied 20 patients over the age of 65 yr undergoing prolonged peripheral vascular surgery under continuous lidocaine epidural anesthesia, anticipating that the increased hepatic metabolism caused by small-dose IV dopamine would lower plasma lidocaine concentrations. Subjects were assigned (random, double-blinded) to receive either a placebo IV infusion or dopamine, 2 microg. kg(-1). min(-1) during and for 5 h after surgery. Five minutes after the IV infusion was started, 20 mL of 2% lidocaine was injected through the epidural catheter. One-half hour later, a continuous epidural infusion of 2% lidocaine at 10 mL/h was begun. The epidural infusion was temporarily decreased to 5 mL/h or 5 mL boluses were added to maintain a T8 analgesic level. Arterial blood samples were analyzed for plasma lidocaine concentrations regularly during and for 5 h after surgery. Plasma lidocaine concentrations increased continuously during the epidural infusion and, despite wide individual variation, were similar for the two groups throughout the observation period. During the observation period, the mean maximal plasma lidocaine concentration was 5.8 +/- 2.3 microg/mL in the control group and 5.7 +/- 1.2 microg/mL in the dopamine group. However, the mean hourly lidocaine requirement during surgery was significantly different, 242 +/- 72 mg/h for control and 312 +/- 60 mg/h for dopamine patients (P < 0.03). At the end of Hour 4, the last period when all 20 patients were still receiving the epidural lidocaine infusion, the total lidocaine requirement was significantly different, 1088 +/- 191 mg for the control group and 1228 +/- 168 mg for the dopamine group (P < 0.05). Despite very large total doses of epidural lidocaine (1650 +/- 740 mg, control patients, and 1940 +/- 400, dopamine patients) mean maximal plasma concentrations remained below 6 microg/mL, and no patient exhibited signs or symptoms of toxicity. We conclude that small-dose IV dopamine increased epidural lidocaine requirements, presumably as a consequence of increased metabolism. IMPLICATIONS: We tested dopamine, a drug that increases liver metabolism of the local anesthetic lidocaine to determine if it would prevent excessively large amounts of lidocaine in the blood during prolonged epidural anesthesia in elderly patients. Dopamine did not alter the blood levels of lidocaine, but it did increase the lidocaine dose requirement to maintain adequate epidural anesthesia.     

Translocation of endotoxin and acute-phase proteins in malleolar fractures

BACKGROUND AND OBJECTIVE: Translocation of endotoxins was demonstrated for multiple injury but not for minor trauma such as isolated malleolar fractures. Major trauma leads to substantial changes in the plasma concentration of acute-phase proteins. However, isolated malleolar fractures are minor trauma. The objective of this study was to elucidate the kinetics of endotoxemia and the ability of plasma to inactivate endotoxin of patients operated on malleolar fractures and to demonstrate the early time course of the acute-phase proteins C-reactive protein, transferrin, alpha1-acid glycoprotein, haptoglobin, and interleukin-6 and to correlate them with the amount of endotoxemia. METHODS: Thirty patients with malleolar fractures were operated on within 6 hours after injury. Blood was collected immediately after admission and regularly up to 96 hours after surgery. RESULTS: Preoperative endotoxin plasma levels were increased compared with that of healthy individuals (0.05 +/- 0.017 vs. 0.02 EU/mL). Endotoxemia peaked 0.5 hours after the surgical procedure at 0.096 +/- 0.03 (p < 0.05 vs. healthy) and decreased to almost normal values after 24 hours. The ability of the plasma to inactivate endotoxin was significantly reduced after the surgical procedure compared with normal subjects (recovery, 0.17 +/- 0.028 EU/mL vs. 0.04 +/- 0.01 EU/mL; p < 0.05). Plasma interleukin-6 peaked 0.5 hours postoperatively (114 +/- 11 pg/mL, p < 0.05 vs. healthy), decreasing thereafter. C-Reactive protein peaked at 45 +/- 5 mg/mL (p < 0.05) 48 hours after injury. Transferrin decreased significantly postoperatively (2.41 +/- 0.12 mg/mL vs. pre-OP 2.65 +/- 0.1 mg/mL) and remained on this level for 96 hours. Both, alpha1-acid glycoprotein and haptoglobin increased postoperatively until day 4 (0.78 +/- 0.06 mg/mL to 1.15 +/- 0.08 mg/mL and 1.51 +/- 0.12 mg/mL to 3.24 +/- 0.22 mg/mL). There was no correlation between endotoxemia and the concentrations of the acute-phase proteins and interleukin-6. CONCLUSION: Surgery for malleolar fractures is associated with temporary endotoxemia and temporary reduced endotoxin inactivation capacity of the plasma. The injury and the surgical procedure leads to substantial changes in the plasma concentrations of acute-phase proteins. The relation between endotoxemia and acute-phase response is not dose dependent.     

Continuous infusion versus bolus administration of sufentanil and midazolam for mitral valve surgery

OBJECTIVE: In the present study, the authors compared continuous infusion to bolus administration of sufentanil and midazolam in patients undergoing mitral valve surgery. The purpose of the study was to evaluate the hemodynamic variability, total dose, effective plasma drug concentrations, and simplicity of the two anesthetic techniques. DESIGN: Prospective, randomized study. SETTING: University hospital. PARTICIPANTS: Thirty patients scheduled for elective mitral valve surgery. INTERVENTIONS: Induction of anesthesia was similar in both groups and consisted of sufentanil, up to 2 microg/kg, and midazolam, 0.05 to 0.15 mg/kg, followed by atracurium, 0.5 mg/kg. Anesthesia was maintained in the bolus group with predetermined boluses of sufentanil, 2 microg/kg, and midazolam, 0.03 mg/kg. Boluses were not administered if blood pressure was within 20% of baseline. The continuous-infusion group received sufentanil, 3.6 microg/kg/h, and midazolam, 0.08 mg/kg/h, started immediately after induction. The infusion rate was reduced to sufentanil, 1.8 microg/kg/h, and midazolam, 0.04 mg/kg/h, after sternotomy and was discontinued at skin closure. Atracurium was infused at a rate of 0.5 mg/kg/h up to sternal closure in both groups. No inhalation agents were used. MEASUREMENTS AND MAIN RESULTS: Hemodynamic variability between the groups was not significant. Total sufentanil dose was 773 +/- 186 microg in the continuous-infusion group and 610 +/- 184 microg in the bolus group (p = 0.01). Total midazolam dose was 14.4 +/- 3 mg and 11.2 +/- 3 mg in the continuous-infusion and bolus groups, respectively. There were 3.46 (range, 0 to 7) additional bolus injections in the bolus group and 0.31 (range, 0 to 1) in the continuous-infusion group (p < 0.001). Plasma sufentanil concentrations at extubation were similar in both groups (0.5 ng/mL). Plasma midazolam concentrations at extubation in the bolus group (17 +/- 6.7 ng/mL) were similar to those in the continuous-infusion group (23 +/- 5 ng/mL). CONCLUSION: The simplicity of the continuous infusion is a major advantage. This technique provides hemodynamically safe and stable conditions similar to those of bolus administration.     

The pharmacokinetics of the intravenous formulation of fentanyl citrate administered orally in children undergoing general anesthesia

The bioavailability of oral transmucosal fentanyl citrate (OTFC) in children is similar to that of fentanyl solution administered orally to adults. We hypothesized that administering an oral fentanyl solution to children would result in similar fentanyl plasma concentrations and pharmacokinetic variables as administering comparable doses of OTFC. In this pilot study, 10 healthy children requiring postoperative analgesia were enrolled. Each received the undiluted IV fentanyl formulation orally (approximately 10-15 microg/kg; maximum, 400 microg). Venous blood samples were collected from 15 to 600 min after administration. Pharmacokinetic variables were determined using noncompartmental analysis and were compared with a previously studied population of children who received a similar dose of OTFC. Pharmacokinetic variables for the orally administered IV fentanyl formulation were as follows: time to reach peak concentration = 1.7 +/- 1.6 h, peak concentration = 1.83 +/- 1.19 ng/mL, half-life = 4.7 +/- 2.8 h, area under the plasma concentration time curve = 6.46 +/- 3.96 h . ng(-1) . mL(-1), apparent oral volume of distribution (V/F) = 17.5 +/- 7.2 L/kg, apparent oral clearance (CL/F) = 3.33 +/- 2.25 L . kg(-1) . h(-1). Although both OTFC and orally administered IV fentanyl resulted in similar pharmacokinetic variables and plasma concentrations for a given dose, there was marked interpatient variability, particularly in the early hours after oral administration of the IV formulation of fentanyl. This suggests that this method of administration be used with caution until further data are available.     

Gentamicin pharmacokinetics during slow daily home hemodialysis

BACKGROUND: Gentamicin is commonly used in hemodialysis patients. Gentamicin pharmacokinetics during traditional hemodialysis have been described. Slow daily home (SDH) hemodialysis (7 to 9 hours a day/6 days a week) use is increasing due to benefits observed with increased hemodialysis. We determined gentamicin pharmacokinetics for SDH hemodialysis patients. METHODS: Eight patients (four male and four female) received a single intravenous dose of 0.6 mg/kg gentamicin post-hemodialysis. Blood samples were collected at 5, 10, 15, 30, and 60 minutes after dose. The next day patients underwent a typical SDH hemodialysis (high-flux F50NR dialyzer) session. Blood samples were taken at 0, 5, 15, 60, 120, 240, 360, 480 minutes during and 15, 30 and 60 minutes post-hemodialysis. Baseline and 24-hour urine samples were collected. Pharmacokinetic parameters were calculated assuming a one-compartment model. RESULTS: Patients were 42.5 +/- 13.1 years old (mean +/- SD). Inter-, intra-, and post-hemodialysis collection periods were 17.0 +/- 2.1 hours, 8.1 +/- 0.4 hours, and 1.1 +/- 0.1 hours, respectively. Intra-, and interdialytic gentamicin half-lives were different (intradialytic, 3.7 +/- 0.8 hours; interdialytic, 20.4 +/- 4.7 hours; P < 0.0001). Hemodialysis clearance accounted for 70.5% gentamicin total clearance. Renal clearance correlated with glomerular filtration rate (GFR) (renal clearance=1.2 GFR; r2=0.98; P < 0.001). Mean peak and trough of hemodialysis concentrations were 1.8 +/- 0.6 microg/mL and 0.5 +/- 0.2 microg/mL, respectively. Post-hemodialysis rebound was 3.1 +/- 8.8% at 1 hour. CONCLUSION: Pharmacokinetic model predicts 2.0 to 2.5 mg/kg dose gentamicin post-hemodialysis would provide peak (1 hour post-dose) and trough (end of SDH hemodialysis session) concentrations of 6.0 to 7.5 microg/mL and 0.7 to 0.8 microg/mL, respectively. This would provide adequate coverage for most gram-negative organisms in SDH hemodialysis patients.     

A comparison of target- and manually controlled infusion propofol and etomidate/desflurane anesthesia in elderly patients undergoing hip fracture surgery

Elderly patients have a higher risk of developing adverse drug reactions during anesthesia, especially anesthesia affecting cardiovascular performance. In this prospective randomized study we compared quality of induction, hemodynamics, and recovery in elderly patients scheduled for hip fracture surgery and receiving either etomidate/desflurane (ETO/DES) or target-controlled (TCI) or manually controlled (MAN) propofol infusion for anesthesia. Sixteen patients were anesthetized with ETO (0.4 mg/kg) followed by DES titrated from an initial end-tidal concentration of 2.5%. Eighteen patients received propofol TCI at an initial plasma concentration of 1 microg/mL and titrated upwards by 0.5-microg/mL steps. Fifteen patients received a bolus induction of propofol 1 mg/kg over 60 s followed by an infusion initially set at 5 mg . kg(-1) . h(-1). All received a bolus (20 microg/kg) followed by an infusion of 0.4 microg . kg(-1) . min(-1) alfentanil. According to hemodynamics, concentrations of DES or propofol (TCI group) and propofol infusion rate (MAN group) were respectively adjusted by a step of 20% and 50%. In the TCI and ETO/DES groups, the time spent at a mean arterial blood pressure within 15% and 30% of baseline values was more than 60% and 80% of anesthesia time, whereas in the MAN group it was <30% and 60%, respectively. In the MAN group more anesthetic drug adjustments were recorded (6.4 +/- 2.8 versus 2.5 +/- 1.2 [ETO/DES] and 2.6 +/- 1 [TCI]). TCI improves the time course of propofol's hemodynamic effects in elderly patients.