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PLoS One. 2013; 8(3): e59159.
Published online Mar 11, 2013. doi:  10.1371/journal.pone.0059159
PMCID: PMC3594170
Reversal of Succinylcholine Induced Apnea with an Organophosphate Scavenging Recombinant Butyrylcholinesterase
Brian C. Geyer,¤ Katherine E. Larrimore, Jacquelyn Kilbourne, Latha Kannan, and Tsafrir S. Mor*
School of Life Sciences and The Biodesign Institute, Arizona State University, Tempe, Arizona, United States of America
M. Lucrecia Alvarez, Editor
TGen, United States of America
* E-mail: tsafrir.mor/at/asu.edu
Competing Interests: TM, BG, LK and KL are inventors on the following patent applications relating to plant-production of BChE: (1) TM and BG, "PRODUCTION AND USE OF HUMAN BUTYRYLCHOLINESTERASE." U.S. Patent Application 11/792,985, filed December 1 2005; (2) TM and BG, "PRODUCTION AND USE OF HUMAN BUTYRYLCHOLINESTERASE." WIPO Patent 2007040568, issued April 13, 2007; (3) LK, KL and TM, (2011) "Rapid & Large-Scale Plant-based, patent application filed with the US Patent Office. There are no further patents, products in development or marketed products to declare. This does not alter the authors' adherence to all the PLOS ONE policies on sharing data and materials, as detailed online in the journal's guide for authors.
Conceived and designed the experiments: BG TM. Performed the experiments: BG JK KL LK. Analyzed the data: BG KL TM. Wrote the paper: BG KL LK TM.
¤Current address: Harvard Affiliated Emergency Medicine, Residency, Brigham and Women's Hospital, Boston, Massachusetts, United States of America.
Received December 21, 2012; Accepted February 12, 2013.
Background
Concerns about the safety of paralytics such as succinylcholine to facilitate endotracheal intubation limit their use in prehospital and emergency department settings. The ability to rapidly reverse paralysis and restore respiratory drive would increase the safety margin of an agent, thus permitting the pursuit of alternative intubation strategies. In particular, patients who carry genetic or acquired deficiency of butyrylcholinesterase, the serum enzyme responsible for succinylcholine hydrolysis, are susceptible to succinylcholine-induced apnea, which manifests as paralysis, lasting hours beyond the normally brief half-life of succinylcholine. We hypothesized that intravenous administration of plant-derived recombinant BChE, which also prevents mortality in nerve agent poisoning, would rapidly reverse the effects of succinylcholine.
Methods
Recombinant butyrylcholinesterase was produced in transgenic plants and purified. Further analysis involved murine and guinea pig models of succinylcholine toxicity. Animals were treated with lethal and sublethal doses of succinylcholine followed by administration of butyrylcholinesterase or vehicle. In both animal models vital signs and overall survival at specified intervals post succinylcholine administration were assessed.
Results
Purified plant-derived recombinant human butyrylcholinesterase can hydrolyze succinylcholine in vitro. Challenge of mice with an LD100 of succinylcholine followed by BChE administration resulted in complete prevention of respiratory inhibition and concomitant mortality. Furthermore, experiments in symptomatic guinea pigs demonstrated extremely rapid succinylcholine detoxification with complete amelioration of symptoms and no apparent complications.
Conclusions
Recombinant plant-derived butyrylcholinesterase was capable of counteracting and reversing apnea in two complementary models of lethal succinylcholine toxicity, completely preventing mortality. This study of a protein antidote validates the feasibility of protection and treatment of overdose from succinylcholine as well as other biologically active butyrylcholinesterase substrates.
Rapid sequence intubation (RSI) combines a sedative and a neuromuscular blocking agent (NMBA) to prepare a critically ill patient for emergent intubation [1], [2]. RSI is considered a safe procedure in the well-controlled environment of the emergency department where a large, diverse and highly trained team is available to provide emergent intubation, and where increased safety is bolstered by the availability of a large variety of rescue devices [3]. In the pre-hospital arena, the role of RSI remains, however, controversial [4], [5], [6], [7]. While some studies have demonstrated benefit, particularly in specific groups such as head injury patients, other authorities stress the complexity of this procedure, the risks associated with inadequately qualified, trained and equipped personnel and the overall lack of large-scale risk-benefit validation [5], [6], [7], [8], [9]. The controversy is well-reflected in the official policy statement of the American College of Emergency Physicians (ACEP), which declares that it “is not an advocacy statement for or against the use of” RSI [8].
Furthermore, disagreement exists over the ideal NMBA, but frequently centers on the non-depolarizing NMBA rocuronium and the depolarizing NMBA succinylcholine (SC, suxamethonium)[10], [11]. Of the two, consensus generally leans towards succinylcholine due to increased control afforded by the much shorter half-life, unless a contraindication exists [12], [13], [14]. Obvious contraindications include hyperkalemia, allergy, history of malignant hyperthermia, denervation syndromes or recent burn or crush injury. A more occult contraindication is delayed metabolism through the genetic absence of the SC hydrolyzing enzyme butyrylcholinesterase (BChE, plasma cholinesterase, pseudocholinesterase)[15].
This condition, succinylcholine apnea, is believed to exist in 1 in 1800 administrations of SC[16]. Of these, approximately 65% are caused by decreased SC hydrolysis by BChE variants with decreased hydrolytic function or decreased protein stability leading to lower effective serum levels[17]. Individuals who are homozygous in respect to the “atypical” (A) variant of the BChE gene (D70G, residual serum BChE activity is ~30% of normal)[18], [19] experience periods of apnea of approximately 2 hours upon receiving an i.v. dose of SC that would otherwise result in only 3–5 minute-long paralysis in people with the common or “usual” (U) allele [17], [20]. Homozygocity toward several (~48) other mutations in the BCHE locus lead to an even more drastic phenotype. These “silent” (S) variants of BChE and the affected patients are apneic for a much longer duration of 3–4 hours or even longer [17], [21]. While patients homozygous in respect to either the A or S variants are rare among the general population (~0.03% and ~0.01% respectively), heterozygotes are much more common (4% of the general population carry at least one A allele) and exhibit varying degrees of post-SA apnea depending on their specific combination of alleles and in direct correlation with their serum BChE activities [17].
The remaining cases of BChE deficiency are acquired through conditions decreasing circulating hepatoproteins such as cirrhosis [22], burns [23], [24], HELLP (hemolysis, elevated liver enzymes and low platelet count) syndrome [25], hepatic carcinoma [26] and malnutrition [27]. Furthermore, functional BChE deficiency can be acquired through the use of commonly prescribed drugs affecting production or function of BChE such as oral contraceptives [28], sertraline[29], cyclophosphamide[30], [31], [32], tacrine[33], phenelzine[34], bambuterol[35], metoclopramide[36], and ecothiophate[37], [38]. Beyond the rare case of genetic or acquired SC apnea, the ability to rapidly reverse the effects of SC could provide a significantly increased safety margin for the agent by allowing the return of spontaneous respirations and the pursuit of other management strategies including alternative medications and airway devices. This is particularly true in cases of upper airway obstruction where neuromuscular blockade carries the risk of airway collapse [39].
Current management approaches for post-SC apnea, a typically self-limiting condition, are supportive and highly resource intensive[40], mainly because of the lack of effective reversal agents. Anticholinesterases such as edrophonium and neostigmine, presumably intended to overcome cholinergic blockade by raising synaptic levels of acetylcholine, have been tested with underwhelming results [41]. The missing or nonfunctional serum BChE can be replaced by the active U-variant of the enzyme present in blood products like stabilized serum [42], fresh frozen plasma [43] or the purified enzyme (previously available for human use in Europe, but currently discontinued) [44] but the treatment carries the usual risks of blood-borne pathogens and prions, as well as the more common transfusion associated complications, including transfusion-related acute lung injury (TRALI)[45].
To take advantage of recent advances in biotechnology, we and others have hypothesized that purified recombinant human BChE would serve as an ideal antidote for SC apnea by avoiding risk of infection, TRALI and supply limitations [46], [47], [48]. Our group has previously demonstrated, in both mice and guinea pigs, the efficacy of recombinant BChE and acetylcholinesterase prophylaxis to prevent morbidity and mortality in organophosphate poisoning [49], [50]. These two animal species offer the prediction power expected of an animal model with small body sizes that limit the quantities of test materials required and ease of physiological measurements. Here we report SC hydrolysis and reversal of apnea and cardiovascular collapse with treatment of affected mice and guinea pigs by catalytic quantities of BChE.
Preparation of recombinant butyrylcholinesterase
Transgenic plants expressing a plant-optimized synthetic gene encoding full-length wild-type human BChE were created as previously described [51]. Briefly, stable Nicotiana benthamiana lines expressing a codon-optimized human butyrylcholinesterase were created and screened for maximal expression. The lines with highest accumulation were expanded from homozygous seed stocks and propagated under greenhouse conditions. Plant-derived BChE (pBChE) was prepared from mature 8–11 week old plants that were juiced in the presence of 150 mM sodium metabisulfite, and the juice was strained and clarified by centrifugation. The 30%–70% ammonium sulfate fraction (pH 4.0) was resuspended and subjected to two affinity chromatography steps, first through Concanavalin A-Sepharose 4B and then procainamide-agarose gel custom resin. Eluate was dialyzed against 0.125× phosphate-buffered saline (PBS), pH 7.4, then concentrated and stored with 0.02% azide at 4°C for up to 6 months. Prior to use, the preparation was dialyzed again against.125× PBS to remove azide. As previously described, our preparations of plant-derived BChE contain mostly tetramers (about a half) and monomers (about a third) [50].
Biochemical analysis
Assay of butyrylthiocholine hydrolysis followed the method of Ellman as described in [51]. Succinylcholine hydrolase activity was monitored by the method of George and co-workers [52] with modifications to fit a 96-well plate format. Briefly, our standard succinylcholine-hydrolysis buffer contained 100 mM NaH2PO4/Na2HPO4 buffer pH 7.5, 0.77 mM phenol, 0.15 mM 4-aminoantipyrine, 1 U/mL choline oxidase, and 1.2 U/mL horse radish peroxidase type I. Appropriate volumes of 10× stock solutions (in 100 mM NaH2PO4/Na2HPO4 buffer pH 7.5) were pre-mixed and dispensed at 160 µL aliquots onto 96-well plates followed by addition of the substrate succinylcholine chloride (20 µl, final concentrations as indicated). Reactions were started by addition of pBChE (4.74 nM) to yield a final well volume of 200 µl. Hydrolysis was monitored by recording absorbance changes at 500 nm. Self hydrolysis rates were measured on samples that contained no enzyme and were subtracted from the enzymatically catalyzed reaction rates. A choline standard curve was similarly created by using the same assay except that choline chloride replaced succinylcholine (final concentration range of 10–100 µM).
Kinetic analysis was done according to Radić et al. [53] as follows. Initial enzyme velocity, V0, was plotted as a function of substrate concentration and the results were fitted by nonlinear regression using GraphPad Prism to the following equation:
where [SC] is the concentration of SC, Vmax is maximal velocity, KM is the Michaelis-Menten constant, KSS is the dissociation constant of substrate from the enzyme's peripheral binding site, and b is a factor that reflects the efficiency of hydrolysis of the substrate in the presence of another substrate molecule bound at the peripheral site (with substrate activation when b>1).
In vivo experiments
All animal experiments were conducted in accordance to specific protocols approved by the Institutional Care and Use Committee of Arizona State University (approval number 07-911R).
Mouse experiments were conducted as follows. Male FVB/N mice (Mus musculus, 8–12 weeks old) were anesthetized by injection of ketamine/xylazine/acepromazide cocktail at the dose of 0.05 mL per 25 g of total body weight (concentrations were, respectively 21 mg/mL, 2.4 mg/mL, and 0.3 mg/mL). Anesthetized mice were assessed for respiratory rate by counting respirations for 30 seconds using a Littman model 3000 electronic stethoscope placed on the mouse left mid axillary line and extrapolating the per minute rate. Mice were then injected intravenously (tail vein) with 1 mg/kg succinylcholine (time 0 min). At time +3 min mice were injected with pBChE (0.6 mg/kg, ~11 U per animal, n = 3) in 0.9% saline (or 0.9% saline vehicle control, n = 3) and respiratory rate was obtained as above at the indicated time points. At time +15 minutes all surviving mice were euthanized by CO2 asphyxiation and subsequent cervical dislocation. At no time during the experiment did the mice receive any other therapy including, but not limited to, airway protection/management, artificial ventilations, compressions, or any pharmacological assistance.
Guinea pig experiments were conducted as follows. Male Hartley guinea pigs (Cavia porcellus, 8 weeks old) were anesthetized with 90 mg/kg ketamine and 10 mg/kg xylazine. Once anesthetized, baseline heart rate (beats per minute) and SpO2 (%) were obtained using a Surgivet Plus Veterinary Anesthesia and Monitoring Module, model #V3404. Guinea pigs (3 per group) were then intravenously (leg vein) injected at t = 0 with SC at either low dose (0.167 mg/kg, experiment I) or a high dose (0.334 mg/kg, experiment II). Heart rate and SpO2 were obtained every minute throughout the course of the experiment. At time +1 min, groups of three apneic guinea pigs were injected with either pBChE in 0.9% saline at a low dose (0.09 mg/kg, ~24 U per animal, experiment I), high dose (0.19 mg/kg, ~48 U per animal, experiment II), or 0.9% saline vehicle control (experiment I and II). At t = +15 minutes, all surviving guinea pigs were euthanized by CO2 asphyxiation and subsequent cervical dislocation. As above, guinea pigs received no additional care or therapy during experimentation.
Statistical analyses
Statistical analyses were carried out using the GraphPad Prism software. Log-rank (Mantel-Cox) test was used to determine significance of the difference between survival curves. Comparisons between mean values of heart rate and Sp02 were tested using 1-way analysis of variance (ANOVA) followed by Bonferroni's Multiple Comparison Test. Results were also analyzed by 2-way ANOVA (testing simultaneous effects of time and BChE treatment) and simple t-tests, and the inferences based on these analyses were very similar to those obtained by the 1-way ANOVA analysis described above.
Initial characterization of plant-derived, recombinant human butyrylcholinesterase (pBChE) was previously published and was found to be indistinguishable from that of the human plasma-derived enzyme in its ability to interact with its acetylcholine and butyrylcholine substrates and various inhibitors [50], [51], [54]. These studies included detailed in-vitro and in-vivo demonstration of the ability of the plant-derived enzyme to scavenge organophosphate pesticides and nerve-agents (“nerve gasses”). Here we extend these studies in order to investigate the potential of pBChE to reverse SC-induced apnea and therefore determined its SC hydrolytic capacity. Succinylcholine hydrolysis by pBChE proceeded in a linear time-dependent manner with BChE (data not shown) allowing us to calculate the initial enzyme velocity (V0). Conducting the experiment at increasing SC concentrations and plotting the V0 values as a function of the SC concentration (Fig. 1) allowed us to obtain the Michaelis constant (KM = 57±7 µM) and the turnover number (kcat = 516±33 min−1, Fig. 1). The catalytic efficiency (kcat/KM) was calculated to be 9×106 M−1min−1. These values were consistent with previously published results for human BChE (KM = 35 µM and kcat = 600 min−1)[55]. Differences might be attributed to the difference in the assay used in the published research that employed an SA thioester analog. As is the case with many other substrates of BChE, hydrolysis of SC by the enzyme was shown to exhibit substrate activation, presumably due to allosteric interactions involving the peripheral substrate binding site.
Figure 1
Figure 1
Plant-derived BChE undergoes substrate activation by its succinylcholine substrate.
To test our study's hypothesis that pBChE could reverse succinylcholine-induced apnea, we turned to animal-models in two species. Initial studies were conducted with mice that were administered intravenous SC, 1 mg/kg, a dose which constituted about >3× LD50 (0.28 mg/kg) [56] and in our hands proved to be lethal to 100% of tested animals. Mice were then randomized to receive either 15 U BChE or vehicle control (0.9% saline) at 3 min following SC injection. Respiratory rate was monitored every five minutes following SC injection. While all three mice receiving SC +0.9% saline succumbed to the SC-induced respiratory depression and subsequently died, all three mice receiving SC+15 U BChE survived (Fig. 2).
Figure 2
Figure 2
Plant-derived BChE protects mice from SC-induced apnea.
To further understand the effect and kinetics of BChE-mediated SC detoxification using continuous vital sign monitoring, we moved to a larger rodent model of SC toxicity. Utilizing guinea pigs, we intravenously injected groups of three animals with either 0.167 mg/kg (~LD50, Fig. 3) or a larger dose that leads to 100% mortality (0.334 mg/kg, Fig. 4). Complete apnea and resultant decreases in oxygen saturation were seen in both groups at 1 min following SC injection, at which time study animals received either 24 U (Fig. 3), 48 U BChE or vehicle control (0.9% saline, Fig. 3 and Fig. 4). Animals in all four groups went on to demonstrate an absence of measurable pulse and oxygen saturation within 2 to 3 min following SC injection (Fig. 3 and and4).4). Within 2 minutes, guinea pigs receiving BChE recovered spontaneous respirations, their venous oxygenation level had risen to about 50% and their heart rate was at baseline. In fact, median time to recovery was 0.8 min for animals treated with the low dose of SC and 1.7 min for the high dose of SC. We witnessed a fairly consistent response of post-anoxic tachycardia in recovering guinea pigs at 5 min post SC injection, however by 7 min post SC injection all vital signs had returned to baseline in all animals treated by BChE. In striking contrast, only two of the three saline-treated control animals survived with a median time to recovery of 4.8 min. Thus, control animals experienced slower recovery (median ratio saline/BChE = 6.0, 95% confidence interval of 5.8 to 6.2) following a low-dose SC exposure. In this case the hazard ratio of BChE-treated and controls was 15.34 (95% confidence interval of 1.418 to 166.0). Moreover, all animals exposed to high dose of SC without BChE treatment died without any recovery of viable signs. At no point following loss of measurable pulse and venous oxygen saturation did these signs return in animals receiving the high dose of SC without the treatment +0.9% saline.
Figure 3
Figure 3
Plant-derived BChE facilitate recovery of guinea pigs treated with sublethal dose of SC.
Figure 4
Figure 4
Plant-derived BChE fully protects guinea pigs from high-dose SC-induced apnea.
This study demonstrates the capability of plant-derived recombinant human BChE to completely reverse the effects of SC paralysis and respiratory compromise in two small animal models where no additional supportive care was provided. Our work provides a natural extension to previous work that demonstrated the proof of principle for enzyme replacement therapy to counteract the effects of profound neuromuscular SC blockade in patients with BChE deficiencies [42], [43], [44]. All of these previous reports centered around the human plasma enzyme, as present in various blood products or purified from the latter. Plasma-derived BChE is expensive, exists in greatly limited supply, and is, consequently, of limited utility. Our work demonstrates, for the first time, the application of recombinant BChE produced in a sustainable fashion in plants as an antidote to SC-induced neuromuscular blockade. Plant-based production platforms as a source for protein pharmaceuticals are only now beginning to be tapped into with a recent approval of carrot-cell derived glucocerebrosidase for the treatment of Gaucher disease [57], [58]. Our results provide, in two small animal models, the proof of principle that SC-induced apnea can be reversed by administration of plant-produced recombinant human BChE. While our studies were conducted in small number of animals, they provide evidence that is statistically significant, for full protection afforded by the plant-produced enzyme. Additional future tests will aim to look at more subtle biological outcomes (e.g. immune responses to the plant-derived biologics), to determine the safety and efficacy and are likely to require larger number of subjects per group to yield the necessary power.
The ability to rapidly reverse the effects of SC may have profound clinical implications in cases ranging from genetic or acquired SC apnea to SC overdose and particularly traditional RSI utilizing SC as the paralytic. Failed airways are a relatively common event in both the emergency department and the prehospital arena and the decision to adopt an alternate strategy may be hampered by lingering paralysis and the absence of spontaneous respirations. While RSI in emergency medical service is common in some areas, many other agencies have removed paralytics from the drug box of first responders over concerns of apnea, prolonged hypoxia and cardiovascular collapse. In addition to simulation, increased training intervals and close oversight, pharmacological reversal of SC paralysis may increase the safety margin associated with RSI in prehospital medicine.
In broad terms, the search for antidotes must balance efficacy with practicality. While recombinant proteins offer the potential for rational design and mutation of naturally occurring molecules, the increased cost and relatively decreased shelf life encourages exploration of alternate uses for these technologies so they can be applied toward multiple indications. Treatment of SC-induced apnea offers an alternative use for recombinant BChE, beyond scavenging of organophosphate nerve agents in a chemical warfare/terrorism scenario [47], [50], [51], that may provide increased patient safety in the use of RSI in both hospital and pre-hospital care. Moreover, SC is used in clinical contexts beyond RSI, for example in conjunction with electroconvulsive therapy, where BChE variants may have a negative impact as was recently shown by Mollerup and Gätke [59]. Further potential use of BChE includes rapid cocaine detoxification in overdose as well as pharmacological protection of cocaine “packers” during GI clearance [60], [61], [62].
Determination of the appropriate agent and venue for RSI must balance safety and efficacy with continuous measurement of patient outcomes. The availability of plant-derived BChE to rapidly clear SC and reverse apnea should add a new facet to the debate over the ideal paralytic and potentially prevent some of the more common outcomes of prolonged hypoxia during the management of difficult airways using SC [10], [11], [12], [13], [14]. Beyond the rare case of genetic or acquired SC apnea, the ability to rapidly reverse the effects of SC could provide a significantly increased safety margin for the agent by allowing the return of spontaneous respirations and the pursuit of other management strategies including alternative drugs and airway devices. While we acknowledge that a reversal drug to remove excess SC leading to neuromuscular blockade is only one aspect of a much more complicated clinical scenario, we hope that the preclinical work presented would revive interest in testing plant-derived BChE as a tool to counteract SC-induced paralysis in a clinical setting. Such a clinical trial will have to take place following Phase I trials to demonstrate safety of this protein drug. Work at our lab continues toward this goal.
Conclusions
In two complementary small animal models of succinylcholine-induced apnea, recombinant butyrylcholinesterase reversed apnea, desaturation and loss of pulse and prevented mortality. Use of BChE may provide an additional tool to increase the safety of succinylcholine in emergent intubation.
Funding Statement
This work was funded in part by the National Institutes of Health CounterACT Program through the National Institute of Neurological Disorders and Stroke under the U-54-NSO58183-01 award, a consortium grant awarded to USAMRICD and contracted to TM under the research cooperative agreement number W81XWH-07-2-0023. The opinions or assertions contained herein are the private views of the authors and are not to be construed as official or as reflecting the views of the Department of the Army or the Department of Defense. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
1. Merlin MA, Safdar H, Calabrese S, Lewinsky A, Manfre J, et al. (2010) Prehospital rapid sequence intubation in an emergency medical services system with two advanced life support providers. Prehospital and disaster medicine 25: 341–345. [PubMed]
2. Mace SE (2008) Challenges and advances in intubation: rapid sequence intubation. Emergency medicine clinics of North America 26: : 1043–1068 x. [PubMed]
3. Gudzenko V, Bittner EA, Schmidt UH (2010) Emergency airway management. Respiratory care 55: 1026–1035. [PubMed]
4. Zelicof-Paul A, Smith-Lockridge A, Schnadower D, Tyler S, Levin S, et al. (2005) Controversies in rapid sequence intubation in children. Current opinion in pediatrics 17: 355–362. [PubMed]
5. Wang HE, Davis DP, O'Connor RE, Domeier RM (2006) Drug-assisted intubation in the prehospital setting (resource document to NAEMSP position statement). Prehospital emergency care 10: 261–271. [PubMed]
6. Davis DP (2008) Should invasive airway management be done in the field? CMAJ: Canadian Medical Association journal = journal de l'Association medicale canadienne 178: 1171–1173. [PMC free article] [PubMed]
7. Lossius HM, Sollid SJ, Rehn M, Lockey DJ (2011) Revisiting the value of pre-hospital tracheal intubation: an all time systematic literature review extracting the Utstein airway core variables. Critical care 15: R26. [PMC free article] [PubMed]
8. ACEP (2011) Drug-assisted intubation in the prehospital setting. Policy statement. Annals of emergency medicine 58: 113–114. [PubMed]
9. Davis DP, Ochs M, Hoyt DB, Bailey D, Marshall LK, et al. (2003) Paramedic-administered neuromuscular blockade improves prehospital intubation success in severely head-injured patients. J Trauma 55: 713–719. [PubMed]
10. Herbstritt A, Amarakone K (2012) Towards evidence-based emergency medicine: best BETs from the Manchester Royal Infirmary. BET 3: is rocuronium as effective as succinylcholine at facilitating laryngoscopy during rapid sequence intubation? Emergency medicine journal: EMJ 29: 256–258. [PubMed]
11. Perry JJ, Lee JS, Sillberg VA, Wells GA (2008) Rocuronium versus succinylcholine for rapid sequence induction intubation. Cochrane database of systematic reviews: CD002788. [PubMed]
12. Mallon WK, Keim SM, Shoenberger JM, Walls RM (2009) Rocuronium vs. succinylcholine in the emergency department: a critical appraisal. The Journal of emergency medicine 37: 183–188. [PubMed]
13. Strayer RJ (2010) Rocuronium vs. succinylcholine revisited. The Journal of emergency medicine 39: 345–346; author reply 346–347. [PubMed]
14. Sorensen MK, Bretlau C, Gatke MR, Sorensen AM, Rasmussen LS (2012) Rapid sequence induction and intubation with rocuronium-sugammadex compared with succinylcholine: a randomized trial. British journal of anaesthesia 108: 682–689. [PubMed]
15. Masson P, Carletti E, Nachon F (2009) Structure, activities and biomedical applications of human butyrylcholinesterase. Protein and peptide letters 16: 1215–1224. [PubMed]
16. Bauld HW, Gibson PF, Jebson PJ, Brown SS (1974) Aetiology of prolonged apnoea after suxamethonium. Br J Anaesth 46: 273–281. [PubMed]
17. Soliday FK, Conley YP, Henker R (2010) Pseudocholinesterase deficiency: a comprehensive review of genetic, acquired, and drug influences. AANA journal 78: 313–320. [PubMed]
18. McGuire MC, Nogueira CP, Bartels CF, Lightstone H, Hajra A, et al. (1989) Identification of the structural mutation responsible for the dibucaine-resistant (atypical) variant form of human serum cholinesterase. Proceedings of the National Academy of Sciences of the United States of America 86: 953–957. [PubMed]
19. Masson P, Legrand P, Bartels CF, Froment MT, Schopfer LM, et al. (1997) Role of aspartate 70 and tryptophan 82 in binding of succinyldithiocholine to human butyrylcholinesterase. Biochemistry 36: 2266–2277. [PubMed]
20. Viby-Mogensen J, Hanel HK (1978) Prolonged apnoea after suxamethonium: an analysis of the first 225 cases reported to the Danish Cholinesterase Research Unit. Acta Anaesthesiol Scand 22: 371–380. [PubMed]
21. Manoharan I, Boopathy R, Darvesh S, Lockridge O (2007) A medical health report on individuals with silent butyrylcholinesterase in the Vysya community of India. Clinica chimica acta; international journal of clinical chemistry 378: 128–135. [PubMed]
22. Garello E, Battista S, Bar F, Niro GA, Cappello N, et al. (1999) Evaluation of hepatic function in liver cirrhosis: clinical utility of galactose elimination capacity, hepatic clearance of D-sorbitol, and laboratory investigations. Dig Dis Sci 44: 782–788. [PubMed]
23. Han TH, Martyn JA (2011) Neuromuscular pharmacodynamics of mivacurium in adults with major burns. Br J Anaesth 106: 675–679. [PMC free article] [PubMed]
24. Gault DT, Everitt AS, Gordon PW, Eve MD, Moody FM (1987) Serum cholinesterase levels after thermal injury. Is treatment required? Burns, including thermal injury 13: 208–212. [PubMed]
25. Lurie S, Sadan O, Oron G, Fux A, Boaz M, et al. (2007) Reduced pseudocholinesterase activity in patients with HELLP syndrome. Reproductive sciences 14: 192–196. [PubMed]
26. Hamamoto Y, Niino K, Ishiyama H, Hosoya T (2004) Impact of pretreatment cholinesterase level on survival of inoperable intrahepatic or hepatic-hilar carcinomas treated with three-dimensional conformal radiotherapy. Radiation medicine 22: 316–323. [PubMed]
27. Niazi A, Leonard IE, O'Kelly B (2004) Prolonged neuromuscular blockade as a result of malnutrition-induced pseudocholinesterase deficiency. Journal of clinical anesthesia 16: 40–42. [PubMed]
28. Fuller BH, Berger GM (1990) Automation of serum cholinesterase assay-paediatric and adult reference ranges. S Afr Med J 78: 577–580. [PubMed]
29. Zencirci B (2010) Sertraline-induced pseudocholinesterase enzyme deficiency. International journal of general medicine 3: 375–378. [PMC free article] [PubMed]
30. Bodur E (2010) Human serum butyrylcholinesterase interactions with cisplatin and cyclophosphamide. Biochimie 92: 979–984. [PubMed]
31. Koseoglu V, Chiang J, Chan KW (1999) Acquired pseudocholinesterase deficiency after high-dose cyclophosphamide. Bone marrow transplantation 24: 1367–1368. [PubMed]
32. Norris JC (2003) Prolonged succinylcholine apnoea resulting from acquired deficiency of plasma cholinesterase. Anaesthesia 58: 1137. [PubMed]
33. Chrispin P (1995) Tacrine. Lancet 345: 1248. [PubMed]
34. Bodley PO, Halwax K, Potts L (1969) Low serum pseudocholinesterase levels complicating treatment with phenelzine. British medical journal 3: 510–512. [PMC free article] [PubMed]
35. Fisher DM, Caldwell JE, Sharma M, Wiren JE (1988) The influence of bambuterol (carbamylated terbutaline) on the duration of action of succinylcholine-induced paralysis in humans. Anesthesiology 69: 757–759. [PubMed]
36. Kao YJ, Turner DR (1989) Prolongation of succinylcholine block by metoclopramide. Anesthesiology 70: 905–908. [PubMed]
37. Kramer LP (1982) Eye drops and apnea. Canadian Medical Association journal 127: 1078–1079. [PMC free article] [PubMed]
38. Bauld HW (1983) Eye drops and apnea. Canadian Medical Association journal 128: 894. [PMC free article] [PubMed]
39. Ruskin K, Rosenbaum SH (2011) Anesthesia Emergencies. Oxford, New York: Oxford University Press. 395 p.
40. Barker I (2003) The management of succinylcholine apnoea. Anaesthesia 58: 1144. [PubMed]
41. Bevan DR, Donati F (1983) Succinylcholine apnoea: attempted reversal with anticholinesterases. Can Anaesth Soc J 30: 536–539. [PubMed]
42. Mets B, Woolf BH (1990) Is there a use for stabilised human serum in the treatment of Scoline apnoea? A case report. S Afr Med J 77: 311–312. [PubMed]
43. Gill RS, O'Connell N, Scott RP (1991) Reversal of prolonged suxamethonium apnoea with fresh frozen plasma in a 6-week-old infant. Anaesthesia 46: 1036–1038. [PubMed]
44. Østergaard D, Jensen FS, Viby-Mogensen J (1995) Reversal of intense mivacurium block with human plasma cholinesterase in patients with atypical plasma cholinesterase. Anesthesiology 82: 1295–1298. [PubMed]
45. Harle CC, McKendrick R (2004) Fresh frozen plasma for succinylcholine apnoea. Anaesthesia 59: 89; author reply 89–90. [PubMed]
46. Mor TS, Soreq H (2004) Human cholinesterases from Plants for detoxification. In: Goodman RM, editor. Encyclopedia of Plant and Crop Science. New York: Marcel Dekker, Inc. pp. 564–567.
47. Ashani Y (2000) Prospective of human butyrylcholinesterase as a detoxifying antidote and potential regulator of controlled-release drugs. Drug Dev Res 50: 298–308.
48. Saxena A, Sun W, Luo C, Myers TM, Koplovitz I, et al. (2006) Bioscavenger for protection from toxicity of organophosphorus compounds. J Mol Neurosci 30: 145–148. [PubMed]
49. Evron T, Geyer BC, Cherni I, Muralidharan M, Kilbourne J, et al. (2007) Plant-derived human acetylcholinesterase-R provides protection from lethal organophosphate poisoning and its chronic aftermath. Faseb J 21: 2961–2969. [PMC free article] [PubMed]
50. Geyer BC, Kannan L, Garnaud PE, Broomfield CA, Cadieux CL, et al. (2010) Plant-derived human butyrylcholinesterase, but not an organophosphorous-compound hydrolyzing variant thereof, protects rodents against nerve agents. Proc Natl Acad Sci USA 107: 20251–20256. [PubMed]
51. Geyer BC, Kannan L, Cherni I, Woods RR, Soreq H, et al. (2010) Transgenic plants as a source for the bioscavenging enzyme, human butyrylcholinesterase Plant Biotechnol J. 8: 873–886. [PubMed]
52. George PM, Joyce SL, Abernethy MH (1988) Screening for plasma cholinesterase deficiency: an automated succinylcholine based assay. Clinical biochemistry 21: 159–162. [PubMed]
53. Radic Z, Pickering NA, Vellom DC, Camp S, Taylor P (1993) Three distinct domains in the cholinesterase molecule confer selectivity for acetyl- and butyrylcholinesterase inhibitors. Biochemistry 32: 12074–12084. [PubMed]
54. Geyer BC, Woods RR, Mor TS (2008) Increased organophosphate scavenging in a butyrylcholinesterase mutant. Chem Biol Interact 175: 376–379. [PubMed]
55. Lockridge O (1990) Genetic variants of human serum cholinesterase influence metabolism of the muscle relaxant succinylcholine. Pharmacology & therapeutics 47: 35–60. [PubMed]
56. Lewis RJ (1996) Sax's Dangerous Properties of Industrial Materials. New York, NY: Van Nostrand Reinhold. 192–195 p.
57. Buyel JF, Fischer R (2013) Processing heterogeneous biomass: Overcoming the hurdles in model building. Bioengineered 4. [PMC free article] [PubMed]
58. Zimran A, Brill-Almon E, Chertkoff R, Petakov M, Blanco-Favela F, et al. (2011) Pivotal trial with plant cell-expressed recombinant glucocerebrosidase, taliglucerase alfa, a novel enzyme replacement therapy for Gaucher disease. Blood 118: 5767–5773. [PubMed]
59. Mollerup HM, Gätke MR (2011) Butyrylcholinesterase gene mutations in patients with prolonged apnea after succinylcholine for electroconvulsive therapy. Acta anaesthesiologica Scandinavica 55: 82–86. [PubMed]
60. Gao Y, Brimijoin S (2004) An engineered cocaine hydrolase blunts and reverses cardiovascular responses to cocaine in rats. J Pharmacol Exp Ther 310: 1046–1052. [PubMed]
61. Brimijoin S, Gao Y, Anker JJ, Gliddon LA, Lafleur D, et al. (2008) A cocaine hydrolase engineered from human butyrylcholinesterase selectively blocks cocaine toxicity and reinstatement of drug seeking in rats. Neuropsychopharmacology: official publication of the American College of Neuropsychopharmacology 33: 2715–2725. [PMC free article] [PubMed]
62. Lynch TJ, Mattes CE, Singh A, Bradley RM, Brady RO, et al. (1997) Cocaine detoxification by human plasma butyrylcholinesterase. Toxicol Appl Pharmacol 145: 363–371. [PubMed]
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