Plasma and CSF morphine concentrations after i.m. and epidural administration

Morphine concentrations in plasma and CSF after i.m. and epidural morphine administration were assayed in patients undergoing surgery of the low abdomen. Morphine concentration in CSF after i.m. administration of this drug is remarkably lower than morphine concentration in plasma. The highest value is attained in CSF after about 90' and is followed by a slow downsloping to lowest values, which were observed 4 hours after drug administration. Kinetics of morphine passage into plasma after epidural administration is similar to that found after i.m. administration. In the latter experimental condition (epidural administration), concentrations of morphine in CSF 30' after administration are markedly lower than those found in plasma. However, 60 min. after epidural administration plasma and CSF morphine concentrations are similar, in particular CSF concentrations are 4 to 8 times higher than those obtained after i.m. administration. Such high levels persist for a long time.     

Serum morphine concentrations after buccal and intramuscular morphine administration.

1. This study compared serum concentrations of morphine after administration of a buccal tablet (25mg) with those after intramuscular injection (10mg). 2. Buccal morphine was administered to eleven healthy volunteers and intramuscular morphine was given to five preoperative surgical patients. Serum morphine concentrations were assayed by high performance liquid chromatography (h.p.l.c.) in samples taken up to 8 h after drug administration. 3. Mean maximum morphine concentrations were eight times lower after buccal administration than after intramuscular injection and occurred at a mean of 4 h later. Individual morphine concentration-time profiles showed marked interindividual variability after administration of the buccal tablet, consistent with considerable variation in tablet persistence time on the buccal mucosa.     

Correlation of saliva codeine concentrations with plasma concentrations after oral codeine administration.

A clinical study was designed to determine if there was a predictable relationship between saliva and plasma codeine concentrations. Drug-free volunteers (n = 17) were administered a 30-mg dose of liquid codeine phosphate. Plasma and saliva specimens were collected at various times for 24 h after administration. Plasma and saliva were analyzed for codeine and morphine by positive-ion chemical ionization gas chromatography-mass spectrometry. The plasma codeine concentrations peaked between 30 min and 2 h after administration and ranged from 19 to 74 ng/mL with a mean of 46 ng/mL. Despite decontamination procedures, elevated saliva codeine concentrations were detected at the early collection times because of contamination of the oral cavity from the liquid codeine. Codeine concentrations in the 15 min specimens ranged from 690 ng/mL to over 15,000 ng/mL. After the initial 2-h period, the mean codeine saliva concentrations declined at a rate similar to that observed in the plasma, but remained 3 to 4 times greater than the plasma concentrations. During the elimination phase, half-life estimates for codeine in plasma and saliva were found to be equivalent, 2.6 and 2.9 h, respectively. However, the area under the curve (AUC) estimate for codeine in saliva was 13 times greater than the plasma AUC. Contamination of the saliva resulted in elevated saliva/plasma (S/P) concentration ratios for the first 1 to 2 h after drug administration. Consequently, S/P ratios in specimens collected in the first 15 to 30 min ranged from 75 to 2580. However, after the absorption phase, a significant correlation between saliva and plasma concentrations was observed (r = 0.809, p < 0.05) and mean S/P ratios remained constant (mean = 3.7). Although small changes in saliva pH were predicted to produce profound changes in the S/P ratios for codeine, this was not observed in the current study. Therefore, saliva codeine concentrations could be used to estimate plasma concentrations through the use of the S/P ratio once the oral contamination has been eliminated. However, these estimates should be made cautiously. One must ensure that oral contamination is not a factor. Also, as with blood-drug concentrations, considerable intersubject variability was observed.     

CSF and plasma pharmacokinetics of intramuscular morphine

Summary Morphine concentrations in plasma and cerebrospinal fluid (CSF) were measured in 58 elderly patients after intramuscular administration of 10 mg morphine. The assay employed gas chromatography with electron capture detection. From 49 of the patients undergoing urological procedures plasma and lumbar CSF samples were obtained simultaneously as spinal analgesia was given, and in addition, repeated venous samples were obtained over 4 hours from 35 of the patients. A plasma-morphine concentration vs time plot was drawn from the mean values and a CSF-morphine vs time plot was calculated by pooling individual CSF concentrations and using the sliding mean technique. The individual CSF/plasma-morphine concentration ratio vs time was also plotted. In addition, 2 or 3 CSF and plasma samples were collected simultaneously from 3 patients undergoing thoracotomy. Large interindividual variation in the CSF concentration was found. The peak CSF level was reached after 3 h and, following pseudoequilibrium, CSF-morphine levels appeared only slightly lower than those found in plasma. The availability to spinal CSF amounted to no more than 0.005% of the administered dose. CSF-morphine concentrations were not related to plasma protein or albumin concentrations.     

Pharmacokinetics of pyrazinamide in plasma and CSF of rabbits following intravenous and oral administration

The pharmacokinetics of pyrazinamide (PZA) in cerebrospinal fluid (CSF) and plasma of 10 rabbits were studied after separate intravenous (i.v.) and oral (p.o.) administration, in a cross-over study. Concentrations of PZA in biological fluids were determined by high performance liquid chromatography (HPLC). After p.o. dose PZA was absorbed rapidly and peak plasma concentration was attained at 0.5 h post administration. After i.v. dose, the plasma PZA concentrations declined rapidly within 10 min and subsequently more slowly following a bi-exponential manner. No difference was observed in the area under plasma concentration-time curves indicating oral absorption was complete and no apparent first-pass metabolism occurred. The (mean +/- S.D.) elimination t1/2 after i.v. (1.04 +/- 0.18 h) was significantly shorter (P less than 0.0005) than that after oral (1.95 +/- 0.63 h) dose and the apparent volume of distribution was also significantly smaller (P less than 0.005) after i.v. (3.211 +/- 0.412 l) than after oral (5.936 +/- 1.607 l) administration. The elimination t1/2 of PZA in CSF was nearly identical to that in plasma after either i.v. (1.07 +/- 0.20 h) or p.o. (1.84 +/- 0.56 h) administration. There is no apparent barrier in rabbits for the penetration of PZA into CSF from the general circulation.     

Diazepam and N-desmethyldiazepam concentrations in saliva, plasma and CSF.

1 Salivary and plasma diazepam and nordiazepam concentrations were measured in 51 paired samples from four experimental situations. In seven of the patients CSF samples were estimated. 2 Correlation of 0.89 (P less than 0.001) was observed between salivary and plasma diazepam and 0.81 (P less than 0.001) between salivary and plasma nordiazepam. 3 Mean salivary diazepam was 1.6% (+/- 0.3%) of the plasma diazepam. It was found to vary markedly in an acute dosage study. Mean salivary nordiazepam was 2.9% (+/- 1%) of the plasma measure and was dependent on salivary flow rate. 4 CSF diazepam was in equilibrium with unbound plasma diazepam and salivary diazepam. 5 Mean protein binding of diazepam in vitro was 99.3% with no variations as a function of concentration. 6 The results suggest salivary diazepam and nordiazepam measures to be of value in epidemiological studies. However, they do not predict accurately the plasma total or unbound drug concentration from a salivary sample in an individual.     

Serum morphine concentration after oral administration of diamorphine hydrochloride and morphine sulphate.

1 Venous blood was obtained from patients with far-advanced cancer receiving either diamorphine (diacetylmorphine, heroin) hydrochloride (65 samples) or morphine sulphate (24 samples) regularly by mouth in doses from 2.5 mg to 90 mg every 4 h. 2 Samples were obtained within 30 min of the 09.00 h drug round. 3 Serial samples were also obtained over a 4 h period from three patients receiving diamorphine hydrochloride. 4 Assay of serum 'morphine equivalents' was by radioimmunoassay using an antibody that cross reacts almost equally with diamorphine, 6-0 monoacetylmorphine and morphine. 5 The serum concentration of opiates expressed as 'morphine equivalents' ranged from 11 ng/ml to 1440 ng/ml. 6 A highly significant positive linear correlation exists between the dose administered and the serum concentration (P less than 0.001) with respect to both drugs. 7 There was no difference between the two drugs in relation to the serum concentration achieved per 10 mg of opiate administered. 8 Higher oral doses of both diamorphine and morphine are now being used when indicated rather than, as before, resorting to injections when an oral dose in excess of 40 mg is indicated.     

Adrenal, plasma and urinary corticosteroids during single or repeated administration of morphine in cats.

Corticosteroids and ascorbic acid in the adrenal glands of adult cats have been investigated after single or repeated administration of morphine. Also plasma levels and urinary excretion of corticosteroids were determined. A significant increase in the content of corticosteroids in the glands and plasma was found after initial injection of morphine. After 7 days of consecutive morphine treatment a fall of corticosteroids in the glands was observed; after 2 weeks of daily injections the content of adrenal corticosteroids was significantly lower than in the control animals but no change was found in the plasma. Administration of the drug during 1 month led to a highly significant decrease of corticosteroids in the glands as well as in plasma. No significant change in adrenal ascorbic acids was found whether the adrenal corticosteroids were higher or lower than in the control cats. Urinary corticosteroids were high during the first week of morphine treatment but thereafter the excretion declined progressively and was lower than the control level after 13 days of treatment. The significant decrease of corticosteroids observed after repeated administration of morphine and the rise in adrenal corticosteroids found after the injection of nalorphine to the morphinized animals suggest that some kind of morphine dependence had been developed in the cats after repeated administration of the drug.     

Pharmacokinetics of morphine 3-esters after oral administration in rabbits.

Pharmacokinetics of three morphine 3-esters-3-(2,2-dimethylvaleroyl) morphine (A), 3-(2-phenylbenzoyl) morphine (B), and 3-(2,2-diphenylpropionyl) morphine (C) was characterized after single oral administration in rabbits. Blood was sampled up to 24 h and cerebro-spinal fluid (CSF) was collected with the last blood sample. The concentration of the morphine 3-esters, morphine, morphine 3-glucuronide and morphine 6-glucuronide were determined in plasma and CSF using HPLC UV-detection. The morphine 3-esters were suggested to be a subject to marked presystemic elimination, since, in comparison to the administration of the un-esterified morphine, relatively low concentrations of morphine and morphine glucuronides were detected in plasma. The rate of disposition of morphine was dependent on the hydrolytic stability of the esters. The mean (+/- S.E.) plasma half-life of morphine was 0.9 +/- 0.2 h, 2.5 +/- 0.6 h and 3.5 +/- 3.5 h after the administration of A, B and C, respectively, compared to 0.9 +/- 0.2 h as estimated after the administration of non-esterified morphine. An analgesic effect will be achieved, since morphine was detected in CSF even 24 h after the application of the ester pro-drugs. It is concluded that esterification at the 3-position may be adapted to obtain sustained plasma levels of morphine.     

Morphine and codeine in oral fluid after controlled poppy seed administration

Opiates are an important drug class in drug testing programmes. Ingestion of poppy seeds containing morphine and codeine can yield positive opiate tests and mislead result interpretation in forensic and clinical settings. Multiple publications evaluated urine opiate concentrations following poppy seed ingestion, but only two addressed oral fluid (OF) results; neither provided the ingested morphine and codeine dosage. We administered two 45 g raw poppy seed doses, each containing 15.7 mg morphine and 3.1 mg codeine, 8 h apart to 17 healthy adults. All OF specimens were screened by on‐site OF immunoassay Draeger DrugTest 5000, and confirmed with OF collected with Oral‐Eze® device and quantified by liquid chromatography‐tandem mass spectrometry (1 µg/L morphine and codeine limits of quantification). Specimens (n = 459) were collected before and up to 32 h after the first dose. All specimens screened positive 0.5 h after dosing and remained positive for 0.5–13 h at Draeger 20 µg/L morphine cut‐off. Maximum OF morphine and codeine concentrations (C_max) were 177 and 32.6 µg/L, with times to C_max (T_max) of 0.5–1 h and 0.5–2.5 h post‐dose, respectively. Windows of detection after the second dose extended at least 24 h for morphine and to 18 h for codeine. After both doses, the last morphine positive OF result was 1 h with 40 µg/L 2004 proposed US Substance Abuse and Mental Health Services Administration cut‐off, and 0.5 h with 95 µg/L cut‐off, recently recommended by the Driving under the Influence of Drugs and Medicines project. Positive OF morphine results are possible 0.5–1 h after ingestion of 15.7 mg of morphine in raw poppy seeds, depending on the cut‐off employed. Copyright © 2014 John Wiley & Sons, Ltd.     

Simultaneous fitting of R- and S-ibuprofen plasma concentrations after oral administration of the racemate

AIMS: To assess the pharmacokinetic equivalence of two different formulations of ibuprofen lysinate with special focus on the expected effects. METHODS: Sixteen healthy volunteers received cross-over ibuprofen lysinate as either one tablet of 400 mg ('test') or two tablets of 200 mg ('reference'). Ibuprofen plasma concentrations were followed up for 10 h. Bioequivalence was assessed by standard noncompartmental methods. Ibuprofen plasma concentrations were fitted with a model that took bioinversion of R- to S-ibuprofen into account. RESULTS: Peak plasma concentrations of R- and S-ibuprofen were 18.1 and 20 microg ml(-1) (test), and 18.2 and 20 microg ml(-1) (reference). Areas under the plasma concentration vs. time curves were 39.7 and 67.5 microg ml(-1) h (test), and 41.1 and 68.2 microg ml(-1) h (reference). Clearance of R-ibuprofen was 5.2 (test) and 5 l h(-1) (reference). A specific plasma concentration was reached with the test formulation about 5 min later than with the reference. Parameters from compartmental modelling were (given for R-and then for S-ibuprofen): body clearance: 4.9 and 4.64 l h(-1), central volume of distribution: 2.8 and 4.1 l, intercompartment clearance: 5.1 and 5.45 l h(-1), peripheral volume of distribution: 4.1 and 5.2 l. The absorption rate constant was 1.52 h(-1), and the test but not the reference formulation had a lag time of 0.1 h. Simulations showed similarity between formulations of the expected effects except for a calculated delay of 6 min with the test formulation. CONCLUSIONS: Ibuprofen formulations were bioequivalent. The pharmacokinetic model may serve as a basis for future pharmacokinetic/pharmacodynamic calculations after administration of racemic ibuprofen.     

Huperzine A in rat plasma and CSF following intranasal administration

This paper presents to investigate the levels of Huperzine A in plasma and CSF of rats after three different kinds of administrations and to find out whether intranasal administration is the best route to transfer the drug into the CNS. The drugs of two doses (167 and 500 microg/kg) were administered to male Sprague-Dawley rats intravenously, intranasally and intragastricly, respectively. Series plasma and cerebrospinal fluid (CSF) samples were collected from femoral artery and cisterna magna for 6h. The drug concentrations were determined by HPLC-fluorescence method. The AUC(plasma) and the AUC(CSF) of intranasal administration were 90.3% and 127.7% in low dose group (167 microg/kg) and 91.3% and 69.4% in high dose group (500 microg/kg) compared with intravenous administration. The AUC(plasma) and the AUC(CSF) of intragastric administration were 98.9% and 52.1% in high dose group (500 microg/kg) compared with intravenous administration.     

Plasma morphine-3-glucuronide, morphine-6-glucuronide and morphine concentrations in patients receiving long-term epidural morphine.

Plasma morphine concentrations were measured in five cancer patients receiving long-term epidural morphine administration. Peak concentrations were observed within 1 h of dosage and concentrations then declined biexponentially. Plasma morphine-3-glucuronide (M3G) and morphine-6-glucuronide (M6G) concentrations were measured in two patients and plasma M3G concentrations were observed to be much higher than plasma M6G and morphine concentrations. Peak plasma M6G concentrations occurred within 1.0 h of dosing and plasma M6G concentrations then remained higher than plasma morphine concentrations.     

Ampicillin concentrations in human oral tissues following a single oral administration of lenampicillin.

1. Ampicillin concentrations in serum (n = 20), gingiva (n = 12), jawbone (n = 13), dental follicle (n = 12), radicular granuloma (n = 2) and radicular cyst (n = 2) were measured in specimens obtained during 0.5-2.5 hr after a single oral administration of lenampicillin (equivalent to 500 mg of ampicillin). 2. Measurable ampicillin concentrations were found in all serum and tissues. 3. Ampicillin concentrations in serum and tissues except for some gingiva and jawbone exceeded MIC for 90% of clinically isolated strains of alpha-hemolytic Streptococci. 4. Ampicillin concentrations in gingiva and jawbone were below the MIC for 90% in 2 out of 12 and 4 out of 13 specimens, respectively.     

Analgesic effect and plasma concentrations of codeine and morphine after two dose levels of codeine following oral surgery

Summary A double blind randomised cross over investigation was carried out in 25 male patients undergoing two oral surgical extractions, one for each lower wisdom tooth. The two extractions were performed about 6 weeks apart and were carried out under local anaesthesia. One hour after each extraction the patients randomly received 90 or 45 mg codeine. During the following 5 h the patients rated the intensity of their pain on a visual analogue scale. Blood was simultaneously sampled and assayed for codeine and its metabolite morphine.Mean pain intensity difference was just significantly higher after 90 mg codeine compared to 45 mg. The mean plasma concentrations of codeine and morphine were significantly higher after the 90 mg dose. However, for the two dose levels of codeine there was no obvious relationship between the difference in analgesic effect and the difference in the plasma concentration of codeine or morphine. The plasma concentrations of morphine were 2–3% of those of codeine and the levels were relatively low. Local formation of morphine from codeine within the human brain should therefore be investigated.Four patients were unable to demethylate codeine to a detectable plasma concentration of morphine after 90 mg codeine. In those patients the analgesic effect during the first hours was better after 90 mg codeine than after 45 mg.This suggests some analgesic effect of codeine itself.The work was presented in part at the Fourth World Congress on Pain, Adelaide, Australia, April 1–6, 1990     

Haemodynamic effects and plasma concentrations of labetalol during long-term treatment of essential hypertension

1 Fifteen men with untreated essential hypertension in WHO stage 1 were studied on an outpatient basis to evaluate the haemodynamic long-term effect of a new α- and β-adrenergic receptor blocker, labetalol.

2 Oxygen consumption, heart rate, cardiac output (Cardiogreen) and intraarterial brachial pressure were recorded at rest in a supine and sitting position, and during steady state work at 300, 600 and 900 kpm/min.

3 The subjects were treated with labetalol (dose 200-800 mg/day) as the sole drug for 1 year. The haemodynamic study was then repeated and the concentration of labetalol in plasma 2-2.5 h after the morning dose was measured.

4 Mean arterial blood pressure was reduced approximately 23% at rest and 21% during exercise. The heart rate was decreased 15% at rest and 16% during exercise. There was a compensatory increase in the stroke volume and consequently the cardiac index was reduced less than the heart rate, 7% at rest supine and 10% during exercise. There was a significant decrease in total peripheral resistance at rest supine (16%) and during exercise (12%).

5 No serious side-effects were seen, but two subjects almost syncopated in the sitting position after the 900 kpm/min work load at the restudy.

6 There was no correlation between the plasma concentration and the effect of labetalol.

7 The haemodynamic changes differ from those seen after long-term therapy with drugs possessing only β-adrenoceptor blocking properties, and agree well with what should be expected with a drug which possesses both α- and β-adrenoceptor blocking properties.