Comparison of the onset and offset times of two available formulations of rocuronium bromide in an animal model.

Rocuronium bromide is a neuromuscular blocker in widespread use in anaesthesia, emergency and intensive care. Reports of reduced efficacy of a new different formulation of rocuronium bromide were submitted to Medsafe, the New Zealand Medicines and Medical Devices Safety Authority, in 2020. Given the requirement for rapid and predictable paralysis for patient safety the efficacy of the two available formulations of rocuronium bromide was investigated in an animal model. After ethics committee approval, 19 rats were anaesthetised and paralysis, defined as loss of tibialis anterior flexion on direct electrical stimulation of the sciatic nerve, was assessed by mechanomyography in response to ED90 doses of rocuronium.Paralysis was observed at a median of 12 seconds for the new different formulation: A, Hameln Pharma (interquartile range (IQR) 6-106 seconds) and 28 seconds for formulation B: Pfizer (IQR 12-68 seconds) P = 0.48. Offset of paralysis was observed after 293 seconds for formulation A (IQR 250-372 seconds) and 241 seconds for formulation B (IQR 220-263 seconds). While the differences observed were substantial, they were not statistically significant. Moreover, the direction of observed difference was towards a shorter median onset and longer offset for the newer formulation, a finding in the opposite direction to the initial clinical concern.Relevance to the clinical situation is indeterminate given the study was stopped at low numbers for futility and limitations around the clinical applicability of animal pharmacokinetics and dynamics. Nevertheless our findings provide some reassurance that the newly available different formulation of this critical use medication does not exhibit a substantial increase in time to onset.

pH Gradient Liposomes Extract Protein Bound Amitriptyline in Peritoneal Dialysis-Exploratory Work.

Poisoning is a significant cause of injury-related death worldwide. Dialysis is usually ineffective in removing the toxin once it has been absorbed because of drug protein binding and high volumes of distribution. In this work, we explore whether the addition of liposomes to peritoneal dialysate could extract protein bound amitriptyline. Liposomes were prepared using the thin film hydration method. In the in vitro experiment, 3 mL of 20% albumin with a concentration of 6000 nmol/L amitriptyline in a proprietary dialysis cartridge was dialysed against 125 mL of phosphate-buffered saline with and without 80 mg 1,2-dioleoyl-sn-glycero-3-phosphoglycerol (DOPG) liposomes. In the in vivo arm, peritoneal dialysis was undertaken in 6 rats with pH gradient liposome augmented dialysate after intravenous amitriptyline injection. Peritoneal blood flow was estimated by CO2 extraction. Total amitriptyline extracted was compared to freely dissolved (non-protein bound) and total amitriptyline perfusing the membrane during the peritoneal dwell. Mean liposome size for DOPG and acidic centre pH gradient liposomes was 119 nm and 430 nm, respectively. In the in vitro experiment, more amitriptyline was extracted into the liposome containing dialysate than the control dialysate (40 +/- 2 nmol/L vs. 27 +/- 1 nmol/L). In the in vivo experiment, the total amitriptyline in dialysate was 5240 +/- 2750 nmol. Mean total free amitriptyline perfusing the peritoneal membrane was 93 +/- 46 nmol. Mean total blood amitriptyline perfusing the peritoneal membrane was 23,920 +/- 6920 nmol. Two of the six animals were excluded due to overestimation of peritoneal blood flow. This exploratory work suggests the addition of liposome nanoparticles to peritoneal dialysate extracted protein bound amitriptyline from blood.

Non-NMDA Mechanisms of Analgesia in Ketamine Analogs.

Despite 50 years of clinical use and experimental endeavor the anesthetic, analgesic, and psychomimetic effects of ketamine remain to be fully elucidated. While NMDA receptor antagonism has been long held as ketamine's fundamental molecular action, interrogation of bespoke ketamine analogs with known absent NMDA binding, yet profound anesthetic and analgesia fingerprints, suggests alternative targets are responsible for these effects. Herein we describe experimental findings utilizing such analogs as probes to explore ketamine-based analgesic molecular targets. We have focused on two-pore potassium leak channels, identifying TWIK channels as a rational target to pursue further. While the totality of ketamine's mechanistic action is yet to be fully determined, these investigations raise the intriguing prospect of separating out analgesia and anesthetic effects from ketamine's undesirable psychomimesis-and development of more specific analgesic medications.

Liposomes to Augment Dialysis in Preclinical Models: A Structured Review.

In recent years, a number of groups have been investigating the use of "empty" liposomes with no drug loaded as scavengers both for exogenous intoxicants and endogenous toxic molecules. Preclinical trials have demonstrated that repurposing liposomes to sequester such compounds may prove clinically useful. The use of such "empty" liposomes in the dialysate during dialysis avoids recognition by complement surveillance, allowing high doses of liposomes to be used. The "reach" of dialysis may also be increased to molecules that are not traditionally dialysable. We aim to review the current literature in this area with the aims of increasing awareness and informing further research. A structured literature search identified thirteen papers which met the inclusion criteria. Augmenting the extraction of ammonia in hepatic failure with pH-gradient liposomes with acidic centres in peritoneal dialysis is the most studied area, with work progressing toward phase one trials. Liposomes used to augment the removal of exogenous intoxicants and protein-bound uraemic and hepatic toxins that accumulate in these organ failures and liposome-supported enzymatic dialysis have also been studied. It is conceivable that liposomes will be repurposed from the role of pharmaceutical vectors to gain further indications as clinically useful nanomedical antidotes/treatments within the next decade.

Is lactate lower in septic patients who are prescribed beta blockers? Retrospective cohort study of an intensive care population.

OBJECTIVE: Elevated serum lactate has long been considered an important marker of sepsis severity. Increasing evidence supports catecholamine-stimulated aerobic glycolysis being a major contributor to the hyperlactataemia seen in sepsis. Beta-blockade may blunt such catecholamine mediated rise in lactate analogous to the way it can mask tachycardia. This could impact the way we evaluate sepsis severity and adequacy of initial treatment. The objective of this study is to investigate whether septic patients who were on beta-blocker treatment at presentation have lower serum lactate level. METHODS: Using a retrospective cohort design we gathered data on patients admitted to our base hospital intensive care unit with APACHE III diagnosis of sepsis and septic shock during the 2017 calendar year. Serum lactate, current medications, presenting vital signs, illness severity scores, laboratory data and mortality outcome were extracted from patients' medical record and the unit's clinical database. RESULTS: Of 189 records analysed, 49 patients were concurrently prescribed beta-blockers. More beta-blocked patients were male, beta-blocked patients were older, and a greater proportion of beta blocked patients had their first lactate measured as an inpatient. After regression to correct for identified significant covariates mean serum lactate was 0.87 (95% confidence interval 0.05-1.69) mmol/L lower in those prescribed beta blockers. CONCLUSIONS: In our cohort pre-existing beta blocker treatment was associated with lower serum lactate measurements in patients presenting with sepsis. Pre-existing beta blocker treatment may reduce serum lactate at presentation in patients with sepsis.

Structure-Activity Relationships for the Anaesthetic and Analgaesic Properties of Aromatic Ring-Substituted Ketamine Esters.

A series of benzene ring substituted ketamine N-alkyl esters were prepared from the corresponding substituted norketamines. Few of the latter have been reported since they have not been generally accessible via known routes. We report a new general route to many of these norketamines via the Neber (oxime to α-aminoketone) rearrangement of readily available substituted 2-phenycyclohexanones. We explored the use of the substituents Cl, Me, OMe, CF3, and OCF3, with a wide range of lipophilic and electronic properties, at all available benzene ring positions. The 2- and 3-substituted compounds were generally more active than 4-substituted compounds. The most generally acceptable substituent was Cl, while the powerful electron-withdrawing substituents CF3 and OCF3 provided fewer effective analogues.

KEA-1010, a ketamine ester analogue, retains analgesic and sedative potency but is devoid of Psychomimetic effects.

BACKGROUND: Ketamine, a widely used anaesthetic and analgesic agent, is known to improve the analgesic efficacy of opioids and to attenuate central sensitisation and opioid-induced hyperalgesia. Clinical use is, however, curtailed by unwanted psychomimetic effects thought to be mediated by N-methyl-D-aspartate (NMDA) receptor antagonism. KEA-1010, a ketamine ester-analogue designed for rapid offset of hypnosis through hydrolysis mediated break-down, has been shown to result in short duration sedation yet prolonged attenuation of nociceptive responses in animal models. Here we report on behavioural effects following KEA-1010 administration to rodents. METHODS: KEA-1010 was compared with racemic ketamine in its ability to produce loss of righting reflex following intravenous injection in rats. Analgesic activity was assessed in thermal tail flick latency (TFL) and paw incision models when injected acutely and when co-administered with fentanyl. Tail flick analgesic assessment was further undertaken in morphine tolerant rats. Behavioural aberration was assessed following intravenous injection in rats undergoing TFL assessment and in auditory pre-pulse inhibition models. RESULTS: KEA-1010 demonstrated an ED50 similar to ketamine for loss of righting reflex following bolus intravenous injection (KEA-1010 11.4 mg/kg [95% CI 10.6 to 12.3]; ketamine (racemic) 9.6 mg/kg [95% CI 8.5-10.9]). Duration of hypnosis was four-fold shorter in KEA-1010 treated animals. KEA-1010 prolonged thermal tail flick responses comparably with ketamine when administered de novo, and augmented morphine-induced prolongation of tail flick when administered acutely. The analgesic effect of KEA-1010 on thermal tail flick was preserved in opioid tolerant rats. KEA-1010 resulted in increased paw-withdrawal thresholds in a rat paw incision model, similar in magnitude yet more persistent than that seen with fentanyl injection, and additive when co-administered with fentanyl. In contrast to ketamine, behavioural aberration following KEA-1010 injection was largely absent and no pre-pulse inhibition to acoustic startle was observed following KEA-1010 administration in rats. CONCLUSIONS: KEA-1010 provides antinociceptive efficacy in acute thermal and mechanical pain models that augments standard opioid analgesia and is preserved in opioid tolerant rodents. The NMDA channel affinity and psychomimetic signature of the parent compound ketamine is largely absent for KEA-1010.

Transcriptional changes in response to ketamine ester-analogs SN 35210 and SN 35563 in the rat brain.

BACKGROUND: Ketamine ester analogs, SN 35210 and SN 35563, demonstrate different pharmacological profiles to ketamine in animal models. Both confer hypnosis with predictably rapid offset yet, paradoxically, SN35563 induces a prolonged anti-nociceptive state. To explore underlying mechanisms, broad transcriptome changes were measured and compared across four relevant target regions of the rat brain. RESULTS: SN 35563 produced large-scale alteration of gene expression in the Basolateral Amygdala (BLA) and Paraventricular Nucleus of the Thalamus (PVT), in excess of 10x that induced by ketamine and SN 35210. A smaller and quantitatively similar number of gene changes were observed in the Insula (INS) and Nucleus Accumbens (ACB) for all three agents. In the BLA and PVT, SN 35563 caused enrichment for gene pathways related to the function and structure of glutamatergic synapses in respect to: release of neurotransmitter, configuration of postsynaptic AMPA receptors, and the underlying cytoskeletal scaffolding and alignment. CONCLUSION: The analgesic ketamine ester analog SN 35563 induces profound large-scale changes in gene expression in key pain-related brain regions reflecting its unique prolonged pharmacodynamic profile.

Ketamine esters and amides as short-acting anaesthetics: Structure-activity relationships for the side-chain.

N-Aliphatic ester analogues of the non-opioid ketamine (1) retain effective anaesthetic/analgesic properties while minimising ketamine's psychomimetic side-effects. We show that the anaesthetic/analgesic properties of these ester analogues depend critically on the length (from 2 to 4 carbons), polarity and steric cross-section of the aliphatic linker chain. More stable amide and ethylsulfone analogues generally showed weaker anaesthetic/analgesic activity. There was no correlation between the anaesthetic/analgesic properties of the compounds and their binding affinities for the N-methyl-d-aspartate (NMDA) receptor.

Liposome supported peritoneal dialysis in rat amitriptyline exposure with and without intravenous lipid emulsion.

Liposome supported peritoneal dialysis is a recently described technique which may eventually be applicable in the clinical scenario of the intoxicated patient. We evaluated the hypothesis that intravenous injection of lipid emulsion (ILE) would augment acidic pH gradient liposome supported peritoneal dialysis (LSPD). Orogastrically amitriptyline dosed rats were treated with either Sodium bicarbonate (NaHCO3) intravenously and standard intraperitoneal dialysate (Group A); NaHCO3 intravenously and LSPD (Group B); or ILE and LSPD (Group C). The primary endpoint was dialysate amitriptyline concentration after a 60 min dwell. Secondary analysis included an estimate of extraction ratio for peritoneal blood flow (ERs). There were significantly higher intraperitoneal concentrations of amitriptyline and ERs in the two groups treated with LSPD (Group B, p = 0.02, Group C, p < 0.01 vs. Group A). There was no observed effect for ILE on intraperitoneal amitriptyline concentration or ERs (p > 0.20). LSPD increased the amitriptyline concentration in peritoneal dialysate. No further increase was demonstrated with ILE. This may be either because such an effect is absent, or type II error. Exploratory analysis suggests LSPD may be driven by total rather than free drug concentrations.

Magnetic extraction of toxin binding liposomes; a method to ameliorate drug toxicity? Preliminary in vitro/ in vivo study.

AIM: Removal of a toxin from the body once absorbed is usually not possible. We describe the use of magnetite containing pH gradient 'MagnepH' liposomes to overcome limitations preventing removal. METHODS: MagnepH liposomes were added to albumin solution containing amitriptyline and dosed intravenously in rats prior to amitriptyline injection. Albumin solution or drawn blood was exposed to a magnet and sampled. RESULTS: One third of amitriptyline was extracted in vitro. In vivo amitriptyline concentrations were 1830 nmol/l (controls) and 10870 nmol/l (MagnepH; n = 2). Amitriptyline extraction increased from 0.6% (control) to 10.4% (MagnepH; 95% CI for difference 2.0-17.6%). CONCLUSION: MagnepH liposomes sequestered amitriptyline and could then be extracted. This method has potential to ameliorate limitations to extracorporeal removal of toxins in poisoning.

Lipid emulsion in local anesthetic toxicity.

PURPOSE OF REVIEW: Enthusiasm for regional anesthesia has been driven by multimodal benefits to patient outcomes. Despite widespread awareness and improved techniques (including the increasing use of ultrasound guidance for block placement), intravascular sequestration and the attendant risk of local anesthetic systemic toxicity (LAST) remains. Intravenous lipid emulsion (ILE) for the treatment of LAST has been endorsed by anesthetic regulatory societies on the basis of animal study and human case report data. The accumulated mass of reporting now permits objective interrogation of published literature. RECENT FINDINGS: Although incompletely elucidated the mechanism of action for ILE in LAST seemingly involves beneficial effects on initial drug distribution (i.e., pharmacokinetic effects) and positive cardiotonic and vasoactive effects (i.e., pharmacokinetic effects) acting in concert. Recent systematic review by collaborating international toxicologic societies have provided reserved endorsement for ILE in bupivacaine-induced toxicity, weak support for ILE use in toxicity from other local anesthetics, and largely neutral recommendation for all other drug poisonings. Work since publication of these recommendations has concluded that there is a positive effect on survival for ILE when animal models of LAST are meta-analyzed and evidence of a positive pharmacokinetic effect for lipid in human models of LAST. SUMMARY: Lipid emulsion remains first-line therapy (in conjunction with standard resuscitative measures) in LAST. Increasing conjecture as to the clinical efficacy of ILE in LAST, however, calls for high-quality human data to refine clinical recommendations.

Inhibition of astrocyte metabolism is not the primary mechanism for anaesthetic hypnosis.

Astrocytes have been promoted as a possible mechanistic target for anaesthetic hypnosis. The aim of this study was to explore this using the neocortical brain slice preparation. The methods were in two parts. Firstly, multiple general anaesthetic compounds demonstrating varying in vivo hypnotic potency were analysed for their effect on "zero-magnesium" seizure-like event (SLE) activity in mouse neocortical slices. Subsequently, the effect of astrocyte metabolic inhibition was investigated in neocortical slices, and compared with that of the anaesthetic drugs. The rationale was that, if suppression of astrocytes was both necessary and sufficient to cause hypnosis in vivo, then inhibition of astrocytic metabolism in slices should mimic the anaesthetic effect. In vivo anaesthetic potency correlated strongly with the magnitude of reduction in SLE frequency in neocortical slices (R(2) 37.7 %, p = 0.002). Conversely, SLE frequency and length were significantly enhanced during exposure to both fluoroacetate (23 and 20 % increase, respectively, p < 0.01) and aminoadipate (12 and 38 % increase, respectively, p < 0.01 and p < 0.05). The capacity of an anaesthetic agent to reduce SLE frequency in the neocortical slice is a good indicator of its in vivo hypnotic potency. The results do not support the hypothesis that astrocytic metabolic inhibition is a mechanism of anaesthetic hypnosis.

Reversal of lipophilic weak bases using pH gradient acidic centre liposomes: demonstration of effect in dabigatran-induced anticoagulation.

INTRODUCTION: Liposomes have recently emerged as rational vehicles for drug detoxification. Modification of the core pH may further enhance the ability of liposomes to sequester lipophilic toxins that are weak bases. Dabigatran, a reversible inhibitor of thrombin, has been widely promoted as a novel oral anticoagulant. As a lipophilic weak-base, it provides a rational target for reversal with acidic-centred liposomal preparations. The present study tests the hypothesis that acidic centre liposomes will reverse dabigatran induced anticoagulation. METHOD: Following enteric dabigatran dosing in vitro assessment of thrombin clotting times (TCT) was undertaken in rabbit plasma spiked with incremental liposome concentrations. Tail vein bleeding was assessed following intravenous liposome injection in rats after enteric dabigatran administration. RESULTS: Liposomes achieved reversal of TCT to baseline at low levels of thrombin inhibition, and partial reversal of TCT at higher levels. Liposomes completely reversed the effects of dabigatran on rat tail vein bleeding time (134.0 (6.7) s liposomes vs. 410 (37.8) s control; p < 0.01). CONCLUSION: Dabigatran-induced coagulopathy was reversed in vitro and in vivo by acidic-centred liposomes. pH-modified liposomes are a promising investigational entity in the antidotal treatment of pharmacologic weak bases that are lipid soluble at physiologic pH.

Determination of the Hypnotic Potency in Rats of the Novel Ketamine Ester Analogue SN 35210.

BACKGROUND: Ketamine is a rapidly acting dissociative anaesthetic drug with additional sympathomimetic, analgesic, and antidepressant properties. Despite these advantages, clinical use is curtailed by prolonged psychomimetic effects apparent over the entire dose spectrum. In this study, we report on the hypnotic potency of SN 35210, the first ketamine ester-analogue designed for rapid offset via esterase-mediated hydrolysis. METHODS: Thirty-three adult Sprague Dawley rats received intravenous racemic ketamine (n = 14), racemic SN 35210 (n = 19), S-enantiomer SN 35210 (n = 17), or R-enantiomer SN 35210 (n = 15), in crossover design. The ability to induce loss of righting reflex (LORR) at a given dose, the duration of righting reflex loss, and the time to return of normal behaviours were recorded. The ED50 for LORR was determined for all agents. RESULTS: The ED50 for righting reflex loss was racemic ketamine 9.6 (95% CI 8.5-10.9) mg/kg, racemic SN 35210 10.4 (95% CI 9.5-11.5) mg/kg, S-enantiomer SN 35210 10.6 (95% CI 9.1-11.8), and R-enantiomer SN 35210 10.3 (95% CI 9.1-11.4) mg/kg. The duration of righting reflex loss and time to return to normal behaviours were approximately 5 times greater for racemic ketamine than all 3 SN 35210 ester analogues. CONCLUSIONS: Racemic, and R and S-enantiomer SN 35210, produced LORR in rats at similar doses to the parent compound ketamine. The duration of righting reflex loss, and duration of behavioural aberration, was significantly reduced for all SN 35210 analogues.

Development of Rapidly Metabolized and Ultra-Short-Acting Ketamine Analogs.

BACKGROUND: Ketamine is a well-established, rapidly acting dissociative anesthetic. Clinical use is limited by prolonged psychotomimetic phenomena on emergence, often requiring the coadministration of additional hypnotic drugs. We hypothesized that the development of ketamine ester analogs with ultrashort offset times might markedly reduce the dysphoric emergence phenomena and, hence, increase the utility of a ketamine-like hypnotic and analgesic. Here, we describe the results of studies that seek to define the pharmacology of 5 esters of ((1-(2-chlorophenyl)-2-oxocyclohexyl)amino)pentanoate hydrochloride, the first ketamine analogs designed to be susceptible to ultrarapid metabolism. METHODS: Five norketamine ester analogs (R1-R5) were compared by ability to produce loss of righting and nociceptive blunting in rats. Toxicity testing was performed for 2 analogs (R1, R5) with 50% lethal dose (LD50) estimation in rats. In vitro metabolic stability was tested in rabbit plasma and whole blood by high-performance liquid chromatography. Behavioral and hemodynamic effects were observed in rabbits. We estimated the pharmacokinetics of these analogs in rabbits. RESULTS: All 5 norketamine esters produced rapid loss of righting reflex and diminished pedal withdrawal with ultrarapid offset in the models studied (return of righting reflex 87 seconds [interquartile range (IQR) 78-131] R1 vs 996 seconds [IQR 840-1304] ketamine in rats; P < 0.01). The LD50 was comparable to that of ketamine (LD50 R1 50.2 mg/kg [95% confidence interval, 30-63]). For all analogs, hydrolysis to sole carboxylic acid derivatives was most rapid in vivo (clearance 1.61 L/kg/min R1 [IQR 0.40-2.42]), followed by whole blood and then plasma. Analog R5 demonstrated relatively greater nociceptive blunting than hypnotic effect (P < 0.001; pedal withdrawal score comparison with R1). CONCLUSIONS: The 5 norketamine ester analogs retain the hypnotic characteristics of the parent compound, yet display rapid offset due to ultrarapid metabolism.

Co-administration of phospholipid emulsion with first dose bacteriocidal antibiotic may retard progression of the sepsis response in gram negative septicaemia.

Endotoxic lipopolysaccharide (LPS) is a major constituent of the outer membrane of the gram-negative bacillus, and its' release a potent pro-inflammatory stimulus. Unchecked the cytokine cascades unleashed by blood borne LPS leads to clinical manifestations of severe sepsis and septic shock. Experimentally exogenous administration of cell-wall specific bacteriocidal drugs are known to precipitate endotoxin release and contribute to development of the sepsis syndrome. Mitigation of the inflammatory septic response with intravenous infusion of phospholipid emulsion has been demonstrated in vivo, with phospholipid credited with binding and neutralizing circulating endotoxin. We therefore propose co-administration of phospholipid emulsion preparations in conjunction with potent cell wall specific antibacterial agents in gram-negative sepsis - hypothesizing that released LPS may be immediately sequestered by phospholipid thereby blunting the severity of the developing septic response.

LIPAEMIC report: results of clinical use of intravenous lipid emulsion in drug toxicity reported to an online lipid registry.

The use of intravenous lipid emulsion (ILE) as an antidote has prompted significant academic and clinical interest. Between August 2009 and August 2012, data from cases of ILE use in intoxicated patients in different hospitals on different continents were voluntarily entered into a registry based on the world wide web (www.lipidregistry.org). Here, we report data from this project. Participating centers were given access to the registry following institutional subscription. Specifically sought were details of the individual patients' presenting condition, indications for ILE use, ILE administration regimen, potential complications, and of clinical outcome. Forty-eight uses of ILE were reported from 61 participating centers. Ten cases of local anesthetic systemic toxicity were reported; all (10/10) survived. Thirty-eight cases of intoxication by other agents were reported [30 decreased conscious state, 8 cardiovascular collapse (3 deaths)]. There was an elevation in GCS (p < 0.0001) and increased systolic blood pressure (p = 0.012) from immediately prior to ILE administration to 30 min after use. One serious and two minor adverse effects of ILE use were recorded in 48 reported cases (one case of bronchospastic reaction, one case of hyperamylasemia and one case of interference with laboratory testing). In this series of cases reported to the registry, improvements were seen for GCS in patients with central nervous system toxicity and in systolic blood pressure in shocked patients over a short time frame after the injection of ILE. Few adverse effects were recorded. Clinical trials and the reporting of drug concentrations after ILE use are necessary to further elucidate the role of ILE in clinical toxicology.