Butorphanol inhibits androgen biosynthesis and metabolism in rat immature Leydig cells in vitro.

Butorphanol is a synthetic opioid analgesic medication that is primarily used for the management of pain. Butorphanol may have an inhibitory effect on androgen biosynthesis and metabolism in rat immature Leydig cells. The objective of this study was to investigate the influence of butorphanol on androgen secretion by rat Leydig cells isolated from the 35-day-old male rats. Rat Leydig cells were cultured with 0.5-50 µM butorphanol for 3 h in vitro. Butorphanol at 5 and 50 µM significantly inhibited androgen secretion in immature Leydig cells. At 50 µM, butorphanol also blocked the effects of luteinizing hormone (LH) and 8bromo-cAMP-stimulated androgen secretion and 22R-hydroxycholesterol- and pregnenolone-mediated androgen production. Further analysis of the results showed that butorphanol downregulated the expression of genes involved in androgen production, including Lhcgr (LH receptor), Cyp11a1 (cholesterol side-chain cleavage enzyme), Srd5a1 (5α-reductase 1), and Akr1c14 (3α-hydroxysteroid dehydrogenase). Additionally, butorphanol directly inhibited HSD3B1 (3ß-hydroxysteroid dehydrogenase 1) and SRD5A1 activity. In conclusion, butorphanol may have side effects of inhibiting androgen biosynthesis and metabolism in Leydig cells.

The protective effects of butorphanol tartrate against homocysteine-induced blood-brain barrier dysfunction.

A high concentration of homocysteine (Hcy) has been recently reported to be closely associated with the development of stroke, which is related to the Hcy-induced blood-brain barrier (BBB) dysfunction. Butorphanol tartrate is a promising analgesic agent that targets the opiate receptor and shows promising protective effects on ischemia/reperfusion injury. The present research proposes to investigate the protective effect of butorphanol tartrate on Hcy-induced BBB disruption to explore the potential application of butorphanol tartrate in treating Hcy-induced stroke. Hcy was utilized to establish both an in vivo animal model and in vitro human brain vascular endothelial cells (HBVECs) injury model. We found that the increased diffusion of sodium fluorescein and Evan's blue, declined expression of Claudin-5, and increased production of interleukin- 6 (IL-6) and tumor necrosis factor-α (TNF-α) were observed in Hcy-treated mice, which were all significantly reversed by butorphanol tartrate. In Hcy-stimulated HBVECs, increased endothelial permeability and reduced expression levels of Claudin-5 and Krüppel-like factor 5 (KLF5) were observed, all of which were dramatically rescued by 2 and 5 µM butorphanol tartrate. Lastly, the protective function of butorphanol tartrate in Hcy-stimulated HBVECs was dramatically abolished by the knockdown of KLF5. Collectively, butorphanol tartrate showed protective effects on Hcy-induced BBB disruption by upregulating the KLF5/Claudin-5 axis.

Butorphanol tartrate mitigates cellular senescence against tumor necrosis factor -α (TNF-α) in human HC-A chondrocytes.

Aging is an important risk factor for osteoarthritis (OA). Butorphanol is a preoperative sedative and analgesic that possesses anti-inflammatory activity. However, the effect of butorphanol on OA has not been reported. Here we aimed to explore the effect of butorphanol tartrate on the cellular senescence of human chondrocyte-articular (HC-A) cells in response to tumor necrosis factor-α (TNF-α) stimulation. Butorphanol tartrate attenuated the TNF-α-caused cellular senescence of HC-A cells, with decreased positive senescence-associated-ß-galactosidase (SA-ß-gal) staining and elevated telomerase activity. Butorphanol tartrate prevented TNF-α-caused cell cycle arrest in the G0/G1 phase in HC-A cells and decreased p21 expression. The TNF-α-induced production of interleukin (IL)-6 and IL-8 in HC-A cells were mitigated by butorphanol tartrate. In addition, butorphanol tartrate reduced p-NF-κB p65/total p65 and p-STAT3/STAT3 ratios in HC-A cells cultured with TNF-α. Taken together, butorphanol tartrate protected HC-A cells from TNF-α-caused cellular senescence through inactivation of NF-κB and STAT3. These results imply that butorphanol tartrate might be used as a potential agent for the treatment of aging-related OA.

Multiple pathways are responsible to the inhibitory effect of butorphanol on OGD/R-induced apoptosis in AC16 cardiomyocytes.

Ischemic heart disease is the leading cause of cardiovascular mortality, which is related to cardiac myocyte apoptosis. Butorphanol is an opioid receptor agonist with potential cardioprotective function. The purpose of this work is to explore the function and mechanism of butorphanol in oxygen and glucose deprivation/reperfusion (OGD/R)-induced cardiomyocyte apoptosis. The overlapping targets of ischemic heart disease and butorphanol were analyzed according to GeneCards, ParmMapper, Cytoscape, and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment analysis. Human cardiomyocyte AC16 cells were incubated with butorphanol and then stimulated with OGD/R. Cell injury was investigated by Cell Counting Kit-8, lactate dehydrogenase (LDH) assay kit, TUNEL staining, caspase-3 activity assay kit, and Western blotting. The proteins in signaling pathways were measured using Western blotting. A total of 93 overlapping targets of ischemic heart disease and butorphanol were obtained. Pathway analysis exhibited that these targets might be involved in multiple signaling pathways. Butorphanol alone showed little cytotoxicity to cardiomyocytes, and it protected against OGD/R-induced viability inhibition, LDH release, cell apoptosis, and increase of caspase-3 activity and expression levels of cleaved caspase-3 and Bim. Butorphanol promoted the activation of the phosphoinositide 3-kinase (PI3K)/protein kinase B (Akt)/forkhead box O (FoxO) and hypoxia-inducible factor-1α (HIF-1α)/vascular endothelial growth factor (VEGF) pathways and attenuated the activation of the mitogen-activated protein kinase (MAPK) signaling in OGD/R-treated cardiomyocytes. In conclusion, butorphanol prevents OGD/R-induced cardiomyocyte apoptosis through activating the PI3K/Akt/FoxO and HIF-1α/VEGF pathways and inactivating the MAPK pathway.

Effect of Packaging Materials and the Leached Iron on the Stability of Butorphanol Tartrate Injection.

The aim of this study was to investigate the effect of various parameters on the stability of butorphanol tartrate injection and to screen the optimal packaging material. The effect of the headspace oxygen levels, ampoule color, manufacturer, and size on the stability of butorphanol tartrate formulation were evaluated. The headspace oxygen levels controlled by nitrogen purging were found to be particularly effective in improving stability of the butorphanol formulation, especially below 2%. Although it is a photolabile drug, butorphanol tartrate was getting degraded at much higher extent in amber color ampoules in comparison to clear ampoules. The degradation by oxidation was found to be a free radical-mediated process catalyzed by the presence of iron ions leached from the amber ampoules. The ampoule manufacturers also had a significant effect on the stability of butorphanol. Two-milliliter ampoules provided a better stability of the butorphanol tartrate injection than 1mL ampoules as 2-mL ampoules had the lower headspace oxygen level at the same level of oxygen content. The oxidation mechanism of the butorphanol tartrate injection was investigated under various conditions, which include iron powder spiking, removal of excipients, exposure to oxygen/nitrogen, exposure to stainless steel and at different pH. Iron powder spiking, presence of citric acid, exposure to oxygen, exposure to stainless steel, and high pH accelerated the oxidative degradation. The effect of oxygen, iron ion and citric acid is in agreement with a metal-catalyzed oxidation mechanism called Udenfriend reaction. Based on the formulation test results, limiting headspace oxygen level, ampoule color, manufacturer, size, controlling iron ion contamination, and pH are recommended for formulation development. In conclusion, it can be suggested that this study can lead to a better understanding of the degradation mechanism of butorphanol tartrate; hence, it would contribute to the development of butorphanol tartrate injection with improved stability. Virous packaging materials have different effects on the stability of butorphanol tartrate injection, and the leached iron of packaging ampoules and stainless steel can trigger Udenfriend reaction with butorphanol tartrate and citric acid (CA), which lead to the oxydative degradation of butorphanol tartrate injection.

Molecular Interaction Between Butorphanol and κ-Opioid Receptor.

BACKGROUND: The misuse of opioids stems, in part, from inadequate knowledge of molecular interactions between opioids and opioid receptors. It is still unclear why some opioids are far more addictive than others. The κ-opioid receptor (KOR) plays a critical role in modulating pain, addiction, and many other physiological and pathological processes. Butorphanol, an opioid analgesic, is a less addictive opioid with unique pharmacological profiles. In this study, we investigated the interaction between butorphanol and KOR to obtain insights into the safe usage of this medication. METHODS: We determined the binding affinity of butorphanol to KOR with a naltrexone competition study. Recombinant KORs expressed in mammalian cell membranes (Chem-1) were used for G-protein activation studies, and a human embryonic kidney-293 (HEK-293) cell line stably transfected with the human KOR was used for ß-arrestin study as previously described in the literature. The effects of butorphanol on KOR internalization were investigated using mouse neuroblastoma Neuro2A cells stably transfected with mKOR-tdTomato fusion protein (N2A-mKOR-tdT) cells overexpressing KOR. The active-state KOR crystal structure was used for docking calculation of butorphanol to characterize the ligand binding site. Salvinorin A, a full KOR agonist, was used as a control for comparison. RESULTS: The affinity of KOR for butorphanol is characterized by Kd of 0.1 ± 0.02 nM, about 20-fold higher compared with that of the µ-opioid receptor (MOR; 2.4 ± 1.2 nM). Our data indicate that butorphanol is more potent on KOR than on MOR. In addition, butorphanol acts as a partial agonist of KOR in the G-protein activation pathway and is a full agonist on the ß-arrestin recruitment pathway, similar to that of salvinorin A. The activation of the ß-arrestin pathway is further confirmed by KOR internalization. The in silico docking model indicates that both salvinorin A and butorphanol share the same binding cavity with the KOR full agonist MP1104. This cavity plays an important role in determining either agonist or antagonist effects of the ligand. CONCLUSIONS: In conclusion, butorphanol is a partial KOR agonist in the G-protein activation pathway and a potent KOR full agonist in the ß-arrestin recruitment pathway. The structure analysis offers insights into the molecular mechanism of KOR interaction and activation by butorphanol.

Compatibility of butorphanol and droperidol in 0.9% sodium chloride injection.

PURPOSE: The compatibility and stability of butorphanol tartrate and droperidol in polyvinyl chloride (PVC) bags and glass bottles stored at 4°C and 25°C for up to 15 days were studied. METHODS: Admixtures were assessed initially and for 15 days after preparation in PVC bags and glass bottles using 0.9% sodium chloride injection as a diluent and stored at 4°C and 25°C. The initial drug concentrations were 0.08 mg/mL for butorphanol tartrate and 0.05 mg/mL for droperidol. Samples were withdrawn from each container immediately after preparation and at predetermined intervals (2, 4, 8, 24, 48, 72, 120, 168, 240, and 360 hours after preparation). The solutions were visually inspected for precipitation, cloudiness, and discoloration at each sampling interval. Drug concentrations were determined using a validated high-pressure liquid chromatography method. RESULTS: After 15 days of storage, all formulations tested retained >98% of the initial concentrations of both drugs. The drug mixtures were clear in appearance, and no color change or precipitation was observed. Throughout this period, pH values remained stable. CONCLUSION: Admixtures of butorphanol tartrate 0.08 mg/mL and droperidol 0.05 mg/mL in 0.9% sodium chloride injection were stable for at least 360 hours when stored in PVC bags or glass bottles at 4°C and 25°C and protected from light.

Pharmacokinetics and intramuscular bioavailability of a single dose of butorphanol in Asian elephants (Elephas maximus).

Captive Asian elephants (Elephas maximus) are susceptible to lameness resulting from foot and joint pain, including chronic arthritis. In the past, opioid analgesics, such as butorphanol, have been used clinically for pain management. However, dosages used in treating elephants were often extrapolated from data in horses, with no pharmacokinetic information on the specific agents used in elephant species. In this pharmacokinetic study, six adult captive Asian elephants (5 female, 1 male castrate) were administered a 0.015 mg/kg dose of butorphanol by both i.v. and i.m. routes. A complete crossover design was used with a 3-wk washout period between treatments. Serial blood samples were collected immediately prior to butorphanol administration and at 5, 10, 20, and 40 min and 1, 1.5, 2, 3, 4, 5, 6, 8, 10, and 24 h after administration. The butorphanol analysis was performed using a validated liquid chromatography-mass spectrophotometric assay with a limit of quantitation of 0.025 ng/ml. The mean Cmax after i.m. administration was 7.9 ng/ml, with a corresponding Tmax, of 40 min and t(1/3), of 7.1 h. After i.v. administration, the mean Vd(ss) was 1.4 L/kg and the mean Cl(p) was 0.26 L/kg/h. Mean i.m. bioavailability was 37%. The results indicate that butorphanol used at 0.015 mg/kg i.m. or i.v. could be useful in elephants when given for pain control.

Enhanced binding of nor-binaltorphimine to kappa-opioid receptors in rats dependent on butorphanol.

Autoradiographic characterization of binding for brain kappa(1) ([(3)H]CI-977) and kappa(2) ([(3)H]bremazocine) in the presence of DAMGO ([D-Ala(2),N-Me-Phe(4),Gly(5)-ol]-enkephalin), DPDPE ([D-Pen(2), D-Pen(5)]-enkephalin), and U-69,593 opioid receptors, in the presence of different concentrations of a selective unlabeled kappa-opioid receptor antagonist, nor-binaltorphimine (nor-BNI), was performed in rats in which dependence on or withdrawal from butorphanol had been established. Dependence was induced by a 72 hr intracerebroventricular (i.c.v.) infusion with butorphanol (26 nmol/microl/hr; butorphanol dependent). Butorphanol withdrawal was produced by terminating the infusion of butorphanol in dependent animals. Responses were studied 7 hr following termination (butorphanol withdrawal). IC(50) values from competition studies were estimated by fitting inhibition curves for both kappa(1)- and kappa(2)-opioid receptor assays. In both dependent and withdrawal groups, the IC(50) values obtained against [(3)H]CI-977 or [(3)H]bremazocine with nor-BNI were decreased (ratios of approximately 0.03-0.21 and approximately 0.05-0.42 vs. control, respectively) in brain regions, including frontal cortex, nucleus accumbens, claustrum, dorsal endopiriform nucleus, caudate putamen, parietal cortex, posterior basolateral amygdaloid nucleus, dorsomedial hypothalamus, hippocampus, posterior paraventricular thalamic nucleus, periaqueductal gray, substantia nigra, superficial gray layer of the superior colliculus, ventral tegmental area, and locus coeruleus, compared with control. These results indicate that, in butorphanol-dependent and butorphanol-withdrawal rats, the brain kappa(1)- and kappa(2)-opioid receptors developed a supersensitivity to antagonist binding.

The pharmacodynamics of thiopental, medetomidine, butorphanol and atropine in beagle dogs.

This study evaluated the quality of anaesthesia and some of the haemodynamic effects induced by a combination of thiopental, medetomidine, butorphanol and atropine in healthy beagle dogs (n = 12). Following premedication with atropine (ATR, 0.022 mg/kg intravenously (i.v.)) and butorphanol (BUT, 0.22 mg/kg i.v.), medetomidine (MED, 22 micrograms/kg intramuscularly (i.m.)) was administered followed in 5 min by thiopental (THIO, 2.2 mg/kg i.v.). Heart rate, systolic blood pressure (SBP), diastolic blood pressure (DBP) and mean arterial blood pressure (MBP) were monitored continuously with an ECG and direct arterial blood pressure monitor. Atipamezole (ATI, 110 micrograms/kg i.v.) was administered to half of the dogs (n = 6) following surgery to evaluate the speed and quality of arousal from anaesthesia. Anaesthesia was characterized by excellent muscle relaxation, analgesia and absence of purposeful movement in response to surgical castration. Arousal following antagonism of medetomidine was significantly faster (P < 0.05) than in unantagonized dogs. Recoveries were smooth but recovery times following atipamezole administration were highly variable among dogs (sternal time range 6-38 min, standing time range 9-56 min). Medetomidine caused a significant (P < 0.05) increase in SBP, DBP and MBP. Atropine prevented the medetomidine induced bradycardia. In conclusion, this combination provided adequate surgical anaesthesia in healthy beagle dogs. At the dosages used in this study, it seems prudent that this combination should be reserved for dogs free of myocardial disease.

[The mu, delta and kappa properties of various opioids].

Recently, the highly selective mu, delta and kappa radiolabeled opioid ligands, such as 3H-DAGO (mu ligand), 3H-DPDPE (delta ligand) and 3H-U69593 (kappa ligand) are available. Using the kappa-homogeneous preparations from human placenta and mu-enriched gerbil cerebellum membrane preparations with these highly selective radiolabeled opioid ligands, clinically used opioids were tested for their mu, delta and kappa properties. The mu agonists such as morphine and fentanyl display a very low affinity for delta and kappa receptor. Among the agonist-antagonist, buprenorphine and butorphanol appeared to be the most highly selective agonists for mu and kappa opioid receptors, respectively. Most ligands identified as specific agonists are in fact only selective and appear to interact at more than one receptor type.

Butorphanol: characterization of agonist and antagonist effects in rhesus monkeys.

The effects of butorphanol were studied in assays of antinociception, respiratory depression, sedation, diuresis and reinforcing effects in rhesus monkeys, and opioid binding in monkey brain. Butorphanol (0.003-0.1 mg/kg s.c.) was effective in the warm-water tail withdrawal assay in 50 degrees C water but not in 55 degrees C. Over a similar dose range, butorphanol caused substantial respiratory depression, without an obvious plateau. Constrained quadazocine apparent pA2 analysis on the respiratory depressant and antinociceptive effects of butorphanol yielded different values between the two assays (respiratory depression pA2 = 6.61; antinociception pA2 = 8.26). Butorphanol (0.1 mg/kg) antagonized the antinociceptive effects of etonitazene in 55 degrees C water, but caused a nonparallel leftward shift in the U50,488 dose-effect curve; both effects were probably due to butorphanol's intermediate efficacy at mu receptors. Butorphanol (0.0001-0.003 mg/kg per injection i.v.) was self-administered; unlike other mu opioid agonists, its maximum effect was depressed after pretreatment with quadazocine (0.01-1.0 mg/kg). Butorphanol (0.003-0.32 mg/kg) was devoid of substantial sedative or muscle relaxant effects, as measured by observational rating scales. Butorphanol (0.01-0.1 mg/kg s.c.), unlike U50,488 (0.01-0.32 mg/kg) did not cause diuresis. Kappa agonist or antagonist effects of butorphanol were not detected in the present studies. This profile is consistent with butorphanol's binding characteristics in rhesus monkey brain which indicated 12-fold mu:kappa selectively and 34-fold mu:delta selectivity.

The opioid receptor binding of dezocine, morphine, fentanyl, butorphanol and nalbuphine.

The ability of morphine, fentanyl, butorphanol, nalbuphine, and dezocine to compete with radiolabeled ligands for binding at the mu1, mu2, kappa1, and delta opioid receptors and the sigma receptor was characterized. In the absence of sodium, the potency of opioid receptor competition at each receptor site was found to be: mu1-fentanyl > butorphanol > morphine > or = dezocine = nalbuphine; mu2-butorphanol > fentanyl > nalbuphine > morphine = dezocine; kappa1-butorphanol > nalbuphine >> morphine > or = dezocine > fentanyl; and delta-butorphanol > nalbuphine > or = dezocine > morphine > fentanyl. For all five compounds, competition at the sigma receptor was weak, with nalbuphine and dezocine having Kis of approximately 0.5 microM and the other opioids having Kis of greater than 1 microM. Since the presence of 100 mM NaCl during the competitive binding decreased the K(i), to varying degrees, of all five opioids at the mu1 and delta receptors and of some of the opioids at the mu2 and kappa1 receptors, the five compounds studied appear to differ in efficacy at the five receptor sites.

Effects of 5,5'-dithiobis-(2-nitrobenzoic acid) on opiate binding to both the membrane-bound receptor and the partially purified opiate receptor.

Pretreatment of partially purified opiate receptor from rat brains with 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB) decreased opiate agonist binding more effectively than that of antagonist. This agent, at a concentration that inhibits only 3H-agonist binding, increases the IC50 values of agonists but not those of antagonists. We also observed similar effects of DTNB on opiate binding to the membrane-bound receptor that are in good agreement with the published data. Moreover, there was an excellent correlation between the IC50 values of the two different preparations. However, opiate binding to the partially purified receptor was about a thousandfold more sensitive to DTNB than binding to this membrane-bound receptor. Dithiothreitol, a sulfide bond reducing agent, reversed the effects of DTNB on the opiate binding.

Butorphanol and nalbuphine: a pharmacologic comparison.

The agonist/antagonist analgesics, butorphanol (Stadol) and nalbuphine (Nubain), are being increasingly employed as intravenous sedation agents; nalbuphine will be available in the future as an oral analgesic. The drugs possess numerous pharmacologic similarities and some dissimilarities. Both are equianalgesic (and nalbuphine is equipotent) with morphine parenterally and codeine orally. Their pharmacokinetics are similar; nalbuphine has a longer duration of action. Both may precipitate an abstinence syndrome in narcotic-dependent persons and will probably be associated with low-level drug abuse potential. They are both agonists of the kappa opioid receptor and partial agonists of the mu receptor. Butorphanol is a partial agonist of the sigma receptor responsible for psychotomimetic effects. The incidence of adverse effects is low, sedation being the most common. In cardiac-risk patients, nalbuphine does not increase cardiac work or oxygen requirements; nor do increasing doses of nalbuphine increase the duration of respiratory depression. Both drugs possess plateau respiratory depressant actions.

[Opioid receptor interactions of butorphanol, a narcotic antagonist analgesic, and its metabolites].

The Opioid receptor affinities of butorphanol (BT) and its main metabolites, norbutorphanol (NB) and hydroxybutorphanol (HB), were determined by an in vitro receptor binding assay using crude synaptosomal membrane preparations of rat brain. BT showed high affinities to all types of the receptor except the alpha type (phencyclidine binding site), resulting in displacements of the bindings of mu (dihydromorphine)-, delta (D-Ala2-D-Leu5-enkephalin)- and kappa (ethylketocyclazocine)-ligands with more potency than morphine and ketocyclazocine, and it preferentially bound to mu- and kappa-opioid receptors. NB bound to the mu-binding site with affinity higher than that of pentazocine and to the kappa-binding site with the lowest affinity. HB exclusively bound to the mu-binding site with lower affinity. The affinities of BT, NB, HB and morphine to the alpha-site were smaller than those of pentazocine and ketocyclazocine. In the presence of 100 mM NaCl or by treating with 500 microM 5,5'-dithiobis (2-nitrobenzoic acid), the binding capacity of the membrane preparation was altered, and BT behaved as a typical antagonist. NB showed an agonistic property, and HB behaved as an antagonist. BT appears to be a mu-opioid receptor antagonist and has a kappa-receptor agonist-like character.

Placental transfer and other physiologic studies with intravenous butorphanol in the anesthetized pregnant ewe.

In clinical evaluation, butorphanol has been used in labor pain with analgesia and newborn outcome comparable to meperidine. Only limited placental transfer studies have been done in the human. The placental transfer and effect of intravenous butorphanol (2 mg) on avrious cardiovascular parameters were determined in anesthetized sheep. Serum butorphanol was determined by a specific radioimmunoassay. Butorphanol 2 mg intravenously did not affect the measured cardiovascular parameters in either ewe or fetus. Butorphanol could be demonstrated in the fetal circulation within one minute of administration and appeared to reach equilibrium in the maternal circulation rapidly and to remain in equilibrium thereafter. A biexponential decline of butorphanol was observed in the maternal serum with a terminal elimination half-life of 50 minutes. The data suggest butorphanol distribution in the pregment ewe can be conceptualized by the two compartment model, with the fetus as part of the peripheral compartment. These studies support the clinical finding from other studies that butorphanol appears to be a safe analgesic for use in labor pain.

Disposition of parenteral butorphanol in man.

The metabolism and elimination of 3H-butorphanol (levo-3, 14-dihydroxy-N-(cyclobutylmethyl)[15-3H]morhinan) tartrate were determined in man after therapeutic im (2 mg) and iv (1 mg) doses. As judged from urinary excretion of radioactivity, the im dose was completely absorbed. Butorphanol was rapidly distributed to tissues, had a plasma half-life of about 3 hr, and was extensively metabolized prior to elimination. The major route of elimination was renal, with fecal excretion being a minor route. Hydroxybutorphanol [3, 14-dihydroxy-N-(trans-3'-hydroxycyclobutylmethyl)morphinan] was isolated and identified as a major urinary metabolite and was also present in the plasma. The disposition of butorphanol is compared and contrasted to the disposition of morphine and pentazocine.

Pharmacokinetics of subcutaneous and intramuscular butorphanol in dogs.

Butorphanol tartrate was administered intramuscularly and subcutaneously to adult male and female dogs at a dose of 0.25 mg/kg. No significant absorption lag time and no significant difference bwtween peak intramuscular and subcutaneous serum concentrations were observed. The mean peak serum concentration was 29 ng/ml at mean times of 28 min after subcutaneous administration and 40 min after intramuscular administration. There were no significant differences in the pharmacokinetics of butorphanol in dogs with either route. The serum half-life was 1.62 hr, and the serum clearance was 3.45 liters/kg/hr. The apparent volume of distribution of butorphanol was 7.96 liters/kg. Although considerable inter- and intraanimal variation in Cmax and AUC was observed, there was no significant difference in the area under the serum concentration versus time curves, and the two administration routes were considered bioequivalent.