[Myths and evidence on the use of botulinum toxin: neuropharmacology and dystonia]. / Mitos y evidencias en el empleo de la toxina botulinica: neurofarmacologia y distonias.

INTRODUCTION: Botulinum toxin type A (BTA) is a bacterial endotoxin, whose therapeutic use has had a dramatic impact on different neurological disorders, such as dystonia and spasticity. AIM: To analyze and summarize different questions about the use of BTA in our clinical practice. DEVELOPMENT: A group of experts in neurology developed a list of topics related with the use of BTA. Two groups were considered: neuropharmacology and dystonia. A literature search at PubMed, mainly for English language articles published up to June 2016 was performed. The manuscript was structured as a questionnaire that includes those questions that, according to the panel opinion, could generate more controversy or doubt. The initial draft was reviewed by the expert panel members to allow modifications, and after subsequent revisions for achieving the highest degree of consensus, the final text was then validated. Different questions about diverse aspects of neuropharmacology, such as mechanism of action, bioequivalence of the different preparations, immunogenicity, etc. were included. Regarding dystonia, the document included questions about methods of evaluation, cervical dystonia, blepharospasm, etc. CONCLUSION: This review does not pretend to be a guide, but rather a tool for continuous training of residents and specialists in neurology, about different specific areas of the management of BTA.

TITLE: Mitos y evidencias en el empleo de la toxina botulinica: neurofarmacologia y distonias.Introduccion. La toxina botulinica de tipo A (TBA) ha supuesto una verdadera revolucion terapeutica en neurologia, y en la actualidad es el tratamiento rutinario en las distonias focales y la espasticidad. Objetivo. Plantear, revisar y responder cuestiones controvertidas en relacion con la neurofarmacologia de la TBA y su uso en las distonias en la practica clinica habitual. Desarrollo. Un grupo de expertos en trastornos del movimiento reviso una lista de temas controvertidos relacionados con la farmacologia de la TBA y su uso en las distonias. Revisamos la bibliografia e incluimos articulos relevantes especialmente en ingles, pero tambien, si su importancia lo merece, en castellano y en frances, hasta junio de 2016. El documento se estructuro como un cuestionario que incluyo las preguntas que podrian generar mayor controversia o duda. El borrador inicial del documento fue revisado por los miembros del panel y se realizaron las modificaciones necesarias hasta alcanzar el mayor grado de consenso. Incluimos preguntas sobre diferentes aspectos de la neurofarmacologia, especialmente el mecanismo de accion, la bioequivalencia de los diferentes preparados y la inmunogenicidad. En relacion con el subapartado de las distonias, se incluyeron aspectos sobre la evaluacion y el tratamiento de las distonias focales. Conclusiones. Esta revision no pretende ser una guia, sino una herramienta practica destinada a neurologos y medicos internos residentes interesados en esta area, dentro de diferentes ambitos especificos del manejo de la TBA.

A novel strategy for development of recombinant antitoxin therapeutics tested in a mouse botulism model.

Antitoxins are needed that can be produced economically with improved safety and shelf life compared to conventional antisera-based therapeutics. Here we report a practical strategy for development of simple antitoxin therapeutics with substantial advantages over currently available treatments. The therapeutic strategy employs a single recombinant 'targeting agent' that binds a toxin at two unique sites and a 'clearing Ab' that binds two epitopes present on each targeting agent. Co-administration of the targeting agent and the clearing Ab results in decoration of the toxin with up to four Abs to promote accelerated clearance. The therapeutic strategy was applied to two Botulinum neurotoxin (BoNT) serotypes and protected mice from lethality in two different intoxication models with an efficacy equivalent to conventional antitoxin serum. Targeting agents were a single recombinant protein consisting of a heterodimer of two camelid anti-BoNT heavy-chain-only Ab V(H) (VHH) binding domains and two E-tag epitopes. The clearing mAb was an anti-E-tag mAb. By comparing the in vivo efficacy of treatments that employed neutralizing vs. non-neutralizing agents or the presence vs. absence of clearing Ab permitted unprecedented insight into the roles of toxin neutralization and clearance in antitoxin efficacy. Surprisingly, when a post-intoxication treatment model was used, a toxin-neutralizing heterodimer agent fully protected mice from intoxication even in the absence of clearing Ab. Thus a single, easy-to-produce recombinant protein was as efficacious as polyclonal antiserum in a clinically-relevant mouse model of botulism. This strategy should have widespread application in antitoxin development and other therapies in which neutralization and/or accelerated clearance of a serum biomolecule can offer therapeutic benefit.

Botulinum neurotoxin vaccines: past, present, and future.

In the early 1930s, a formalin-inactivated toxoid against botulinum neurotoxin was first tested in humans. In 1965, a pentavalent botulinum toxoid (PBT) received Investigational New Drug (IND) status under the Centers for Disease Control's IND 161 (for at-risk workers), and in 1991 under the United States Army's Office of the Surgeon General IND 3723 (for military deployment). This PBT vaccine has been shown to be safe, with over 20,000 injections given to date, and continues to be used in at-risk individuals. During the past decade, recombinant DNA technology has been employed to develop second-generation vaccines to prevent botulism. Recombinant subunit vaccines utilizing the receptor-binding domains of botulinum neurotoxin (BoNT) have been shown to be safe and efficacious in protecting animal models against BoNT serotypes A, B, C1, D, E, and F. In 2004, the first recombinant subunit vaccine [rBV A/B (Pichia pastoris) vaccine] was tested in humans during a phase I clinical trial. Results from that study demonstrated that the recombinant bivalent vaccine was safe and well tolerated at all dosage levels tested and stimulated serotype-specific neutralizing antibodies among the majority of vaccine recipients.

A review of WHO International Standards for botulinum antitoxins.

Clostridium botulinum produces the most potent known toxins, with seven distinct serotypes currently defined (A-G). These toxins can cause a life threatening systemic toxicity whether through natural causes such as food poisoning, infant botulism, wound botulism, or through use as bio-terror agents (e.g. inhalational botulism). It was realised early on that standard reference botulinum antitoxins were required to reduce the variation between assays and ensure a consistent potency of therapeutic antitoxins and vaccines, and to define the serotype. This led to the International Unit being defined by the World Health Organisation (WHO) in the 1960s with the establishment of the first International Standards (IS) for serotypes A-F. Since then botulinum antitoxin ISs have been used world wide as the 'yard stick' to measure the neutralising potency of antitoxins. These primary WHO ISs are used to calibrate in house working reagents that are more extensively utilised. A definition of the International Unit for serotype G antitoxin has yet to be defined or accepted by the WHO and urgently needs addressing. However, before September 11th 2001 there was very little interest in botulinum antitoxin IS and as a result stocks of most of the original preparations are now completely exhausted or depleted and replacements long overdue. We have reviewed the extensive history and availability of the primary WHO ISs and interim materials. All type A and B antitoxin materials were recently assayed and their relative activities confirmed against the original IS preparations. The recent increase in demand for these materials has further exacerbated the shortage. We describe here the production and characterization of stable freeze dried potential candidate replacements along with a new prospective first IS for type G antitoxin. Available toxin A reference preparations are also briefly reviewed.

Detection of antibodies against botulinum toxins.

After immunisation with botulinum vaccine, antibodies to multiple epitopes are produced. Only some of these will have the capacity to neutralise the toxin activity. In fact, the ability of toxoid vaccine to induce toxin neutralising antibodies has provided the basis for the use of therapeutic antitoxins and immunoglobulins for the prophylaxis and treatment of diseases caused by bacterial toxins. Increasing indications for the chronic use of botulinum toxin for therapy have inevitably resulted in concern for patients becoming unresponsive because of the presence of circulating toxin-specific antibodies. Highly sensitive and relevant assays to detect only clinically relevant toxin neutralising antibodies are essential. Although immunoassays often provide the sensitivity, their relevance and specificity is often questioned. The mouse protection LD(50) bioassay is considered most relevant but can often only detect 10 mIU/ml of antitoxin. This sensitivity, although sufficient for confirming protective immunity, is inadequate for patients undergoing toxin therapy. An intramuscular paralysis assay improves the sensitivity to ca. 1 mIU/ml, and a mouse ex vivo diaphragm assay, with sensitivity of < 0.5 mIU/ml, is the most sensitive functional assay to date for this purpose. Alternative approaches for the detection of antibodies to botulinum toxin have included in vitro endopeptidase activity neutralisation. Unlike any other functional assay, this approach is not reliant on serotype-specific antibodies for specificity. Most recent promising developments are focused on cellular assays utilising primary rat embryonic cord cells or more conveniently in vitro differentiated established cell lines such as human neuroblastoma cells.