Hostname: page-component-78c5997874-8bhkd Total loading time: 0 Render date: 2024-11-10T19:30:06.773Z Has data issue: false hasContentIssue false
  • English
  • Français

Adverse Clinical Effects of Botulinum Toxin Intramuscular Injections for Spasticity

Published online by Cambridge University Press:  24 November 2015

Chetan P. Phadke Open the ORCID record for Chetan P. Phadke [Opens in a new window] ,
Chitra K. Balasubramanian ,
Alanna Holz ,
Caitlin Davidson ,
Farooq Ismail  and
Chris Boulias
Chetan P. Phadke*
Affiliation:
Spasticity Research Program, West Park Healthcare Centre, University of Toronto, Toronto, Ontario, Canada Faculty of Medicine, University of Toronto, Toronto, Ontario, Canada Faculty of Health, York University, Toronto, Ontario, Canada
Chitra K. Balasubramanian
Affiliation:
Clinical & Applied Movement Sciences, Brooks College of Health, University of North Florida, Florida, USA.
Alanna Holz
Affiliation:
Spasticity Research Program, West Park Healthcare Centre, University of Toronto, Toronto, Ontario, Canada
Caitlin Davidson
Affiliation:
Spasticity Research Program, West Park Healthcare Centre, University of Toronto, Toronto, Ontario, Canada
Farooq Ismail
Affiliation:
Spasticity Research Program, West Park Healthcare Centre, University of Toronto, Toronto, Ontario, Canada Faculty of Medicine, University of Toronto, Toronto, Ontario, Canada
Chris Boulias
Affiliation:
Spasticity Research Program, West Park Healthcare Centre, University of Toronto, Toronto, Ontario, Canada Faculty of Medicine, University of Toronto, Toronto, Ontario, Canada
*
Correspondence to: Chetan P. Phadke, Spasticity Research Program, West Park Healthcare Centre, Toronto, ON, Canada M6M 2J5. Email: chetan.phadke@westpark.org
Rights & Permissions [Opens in a new window]

Abstract

Objective: The adverse events (AEs) with botulinum toxin type-A (BoNTA), used for indications other than spasticity, are widely reported in the literature. However, the site, dose, and frequency of injections are different for spasticity when compared to the treatment for other conditions and hence the AEs may be different as well. The objective of this study was to summarize the AEs reported in Canada and systematically review the AEs with intramuscular botulinum toxin injections to treat focal spasticity. Methods: Data were gathered from Health Canada (2009-2013) and major electronic databases. Results: In a 4 year period, 285 AEs were reported. OnabotulinumtoxinA (n=272 events): 68% females, 53% serious, 18% hospitalization, and 8% fatalities. The type of AEs reported were – muscle weakness (19%), oropharyngeal (14%), respiratory (14%), eye related (8%), bowel/bladder related (8%), and infection (5%). IncobotulinumtoxinA (n=13): 38% females, 62% serious, and 54% hospitalization. The type of AEs reported were – muscle weakness (15%), oropharyngeal (15%), respiratory (38%), eye related (23%), bowel/bladder related (15%), and infection (15%). Commonly reported AEs in the literature were muscle weakness, pain, oropharyngeal, bowel/bladder, blood circulation, neurological, gait, and respiratory problems. Conclusion: While BoNTA is useful in managing spasticity, future studies need to investigate the factors that can minimize AEs. A better understanding of the underlying mechanisms of the AEs can also improve guidelines for BoNTA administration and enhance outcomes.

Résumé

Réactions indésirables à des injections intramusculaires de toxine botulique utilisée pour traiter la spasticité.Objectif: Les réactions indésirables (RI) à la toxine botulique de type A (BoNTA) utilisée à des fins autres que le traitement de la spasticité ont été abondamment rapportées dans la littérature. Cependant, le point d’injection, la dose et la fréquence des injections sont différents quand elle est utilisée pour traiter la spasticité par rapport à son utilisation pour traiter d’autres affections et donc les RI peuvent également être différentes. Le but de cette étude était de présenter un sommaire des RI rapportées au Canada et de revoir systématiquement les RI rencontrées lors d’injections intramusculaires de toxine botulique pour traiter la spasticité focale. Méthode: Nous avons recueilli les données de Santé Canada de 2009 à 2013 et ainsi que celles des principales bases de données électroniques. Résultats: Au cours d’une période de 4 ans, 285 RI ont été rapportées, dont 272 RI avec l’onabotulinum toxine A. Soixante-huit pour cent sont survenues chez des femmes, 53% étaient des RI sérieuses, 18% ont nécessité une hospitalisation et 8% ont été fatales. Les RI rapportées étaient de la faiblesse musculaire (19%), des RI oropharyngées (14%), respiratoires (14%), oculaires (8%), en lien à l’intestin / la vessie (8%) et infectieuses (5%). Avec l’incobotulinum toxine A (n=13) les RI rapportées sont survenues chez des femmes dans 38% des cas, 62% étaient sérieuses et 54% ont nécessité une hospitalisation. Ces RI étaient de la faiblesse musculaire (15%), des troubles oropharyngés (15%), respiratoires (38%), en lien avec les yeux (23%), en lien avec l’intestin / la vessie (15%) et infectieuses (15%). Les RI fréquemment rapportées dans la littérature étaient la faiblesse musculaire, la douleur, des troubles oropharyngés, intestinaux / vésicaux, circulatoires, neurologiques, des troubles de la démarche et des troubles respiratoires. Conclusion: Bien que la BoNTA soit utile dans le traitement de la spasticité, des études méritent d’être entreprises pour identifier les facteurs qui pourraient minimiser les RI. Une meilleure compréhension des mécanismes sous-jacents est également susceptible d’améliorer les lignes directrices concernant l’administration de la BoNTA ainsi que les résultats de ce traitement.

Keywords

botulinum toxinspasticityadverse effectssystematic reviewmuscle weaknesspaindysphagia
Type
Original Articles
Information
Canadian Journal of Neurological Sciences , Volume 43 , Issue 2 , March 2016 , pp. 298 - 310
Copyright
Copyright © The Canadian Journal of Neurological Sciences Inc. 2015 

Spasticity is a velocity dependent increase in resistance to stretch and is a common sign of upper motor neuron disorder that is seen in conditions such as stroke, multiple sclerosis (MS), cerebral palsy (CP), and brain injury. When untreated, spasticity in some patients can result in pain, deformity, impaired functional abilityReference Shaw, Rodgers and Price 1 , Reference Ward, Aguilar and De Beyl 2 , and significantly impact the quality of life. Botulinum toxin type-A (BoNTA) presynaptically blocks transmission at the neuromuscular junctionReference Turkel, Bowen, Liu and Brin 3 and is regarded as an effective treatment option for the management of focal spasticity. Delivered by intramuscular injection into the affected muscle, BoNTA causes local and temporary paresis of the muscle and may also provide an analgesic effect lasting for three to four monthsReference Shaw, Rodgers and Price 1 . Therefore, decrease in spasticity with BoNTA has the potential to improve range of motion, function, and participation in activities of daily living.

In addition to spasticity, BoNTA is also used for a variety of disorders and conditions involving injections in various body partsReference Truong, Stenner and Reichel 4 and is also increasingly being used for cosmetic improvementsReference Truong, Stenner and Reichel 4 . Although BoNTA is accepted as safe for therapeutic use, both local and systemic adverse events (AEs) have been reported in the literature 5 , Reference Merz 6 . Reported AEs related to BoNTA include the symptoms in different systems such as musculoskeletal (pain and weakness), neurologic, visual, oropharyngeal, respiratory, immune system, bowel and bladder, cardiovascular, resulting in extreme cases in anaphylaxis, and spontaneous death 5 - Reference Roche, Schnitzler, Genet, Durand and Bensmail 7 . However, these AEs were reported for a variety of conditions and not specifically for spasticityReference Coté, Mohan, Polder, Walton and Braun 8 .

Botulinum toxin type-A use for spasticity management may differ from that used for other conditions. Intramuscular injections for spasticity management are administered into skeletal muscles that can vary in size ranging from the small foot and hand muscles to large muscles such as quadriceps and gastro-soleus complex and may require injections in multiple sites in the same muscle. The unique sites for BoNTA injections into muscles with spasticity and features of the intramuscular injections specific to spasticity management are likely to result in AEs that differ from those experienced in the management of other conditions (visual problems, dystonia, and cosmetic purposes). Furthermore, the total dose injected in patients with spasticity is generally higher than other conditions. Currently, there are no data summarizing the AEs of BoNTA when used for spasticity management.

The knowledge of AEs specific to the BoNTA injections used to manage spasticity will assist physicians to make informed decisions and guide more effective management of spasticity. The purpose of this study was to investigate the AEs of BoNTA for spasticity management reported in Canada and in the medical literature. Specifically, we wanted to determine a) the most common AEs following BoNTA treatment for spasticity – a1) number and type of AEs reported to the federal drug regulation agency in Canada, a2) and in scientific literature, and b) the parameters of BoNTA treatment (such as type of toxin used, dosage, location of injection, diagnoses) associated with the AEs.

Methods

Health Canada is a federal department in Canada that maintains records of AEs of drugs including BoNTA reported by health care providers, pharmacists, or consumers. We requested Health Canada to provide us with details of AEs reported to Health Canada from 2009 to 2013 for intramuscular BoNTA injections (onabotulinumtoxinA and incobotulinumtoxinA) for spasticity. IncobotulinumtoxinA was approved for focal spasticity in upper limbs only in Canada in 2009 (much later than onabotulinumtoxinA approved in 2001 for spasticity in both upper and lower limbs 9 ) and hence we sought the data beginning from the year 2009. These are the two toxins that have received approval in Canada for the management of spasticity.

Data were compiled into sub-categories for descriptive analyses. The following categories were used to describe the data: a) Muscle AEs: hypotonia, asthenia, hypokinesia, abasia, and dysstasia; b) Oropharyngeal AEs: dysarthria, dysphagia, pharyngitis, feeding disorder, speech disorder, tongue paralysis, mastication disorder, altered saliva production, dysphonia, laryngospasm, vocal cord disorder, trismus, drooling, ageusia, stomatitis, aphagia, dry mouth, oral swelling, oral pain, tongue hemorrhage, tooth ache, slow speech, and eating disorder; c) Respiratory AEs – dyspnoea, cough, increased respiratory rate, pulmonary artery aneurysm, pulmonary embolism, choking, pneumonia, broncho-pneumonia, abnormal chest x-ray, diaphragmatic weakness and paralysis, aspiration pneumonia, mechanical ventilation, tracheostomy, asphyxia, pleural effusion, bronchospasm, chest pain, lung disorder, pulmonary fibrosis, crepitation and respiratory distress, metastases to lung, asthma; d) Eye related AEs: eyelid ptosis, abnormal pupillary light tests, blepharospasm, eyelid oedema, dry eye, eye swelling, photophobia, strabismus, visual impairment, vision blurred, diplopia, eye pruritus, ocular hyperaemia, eyelid function disorder, visual acuity reduced, excessive eye blinking; e) Bowel/Bladder AEs: constipation, nausea, vomiting, decreased appetite, intestinal ischemia, small intestinal obstruction, recto sigmoid cancer, fecal incontinence, gastrointestinal motility disorder, colon cancer, urinary incontinence and urinary retention, dysuria, hematuria, pollakiuria, urosepsis, bladder spasm, and urinary tract infection; f) Infection AEs: flu-like symptoms, streptococcal, pyrexia, chills, sepsis, and septic shock.

Systematic review search strategy

PubMed, EMBASE, CINAHL, and PEDro databases were searched using the key word combinations below (Figure 1). The keywords were selected from literature reviews and botulinum toxin type A drug monographs 5 , Reference Merz 6 that listed the AEs occurring from treatment with BoNTA. These keywords were then searched on PubMed to create a list of parallel medical subject headings (MeSH) terms. The key word combinations used in the database searches were aimed at increasing the likelihood of finding relevant articles. Additionally, the reference lists of relevant articles were searched to find more sources. These MeSH terms were reported in product monographs (for Botox – onabotulinumtoxinA and Xeomin – incobotulinumtoxinA; approved for use in Canada) as AEs of BoNTA.

MeSH term combinations

The MeSH terms botulinum toxins, type A and muscle spasticity were combined with the MeSH terms and key words as shown in Figure 1. These side effects are reported in product monographs (for onabotulinumtoxinA 5 and incobotulinumtoxinAReference Merz 6 ) as adverse effects of BoNTA.

Figure 1 MeSH terms and key words combined with MeSH terms botulinum toxins, type A and muscle spasticity.

Study selection

After performing the initial database search, two authors (AH and CD) scanned the titles and abstracts of the papers for relevance. Research papers were considered relevant if they discussed AEs of BoNTA for the treatment of spasticity in adults. The etiology of spasticity included in this review was broad and included stroke, MS, spinal cord injury (SCI), and CP. Systematic reviews were not included in this study but their reference lists were scanned for relevant articles. Once the databases had been searched and reviewed for relevance, the full texts of the remaining articles were procured by the investigators. The articles used in the review were subject to the following inclusion criteria: 1) English language publications, 2) human studies, 3) adult subjects (age >18 years), 4) publications from 1990 to 2013, 5) studies that used botulinum toxin type-A, 6) studies that investigated spasticity treatment, 7) studies that reported AEs. The two authors (AH and CD) mutually agreed to include or exclude the articles from the literature search based on the above criteria. If articles were found to not be relevant upon reading the full text, they were excluded.

Data extraction

Based on the above criteria, relevant articles were chosen and their results were extracted. Data such as the author, year of publication, type of AE experienced, diagnosis, brand and dose of toxin used, proportion of patients experiencing the AE, location of injection, and guidance technique were compiled into tables. The Oxford Centre for Evidence-Based Medicine (2011) levels of evidenceReference Howick, Chalmers and Library 10 were used to grade the quality of the articles. Each article was graded independently by two authors (AH and CD) and then compared. If there were any discrepancies, they were resolved through discussion and a level of evidence was agreed upon.

Results

Sources of AE data

For onabotulinumtoxinA: 34 reports (12%) came from community setting, 231 reports (85%) came from market authorization holder (manufacturer), and 7 reports (3%) from hospital setting. Overall consumers reported 42 events (15%) whereas clinicians or healthcare professionals reported 230 events (85%). For incobotulinumtoxinA: 1 report (8%) was from community setting and 12 reports (92%) came from market authorization holder. Clinicians or healthcare professionals reported 10 events (77%) and consumers reported 3 events (23%).

Canada adverse events

A total of 285 reports of AEs were made to Health Canada between 2009 – 2013; of which 272 reports were for onabotulinumtoxinA and 13 for incobotulinumtoxinA.

OnabotulinumtoxinA

Out of all reported events (n=272; one event refers to one AE reported in one patient, mean age 48±19 years; See Figure 2), 68% were reported in females, 53% were reported to be serious, 18% required hospitalization, and 8% resulted in death. The type of AEs reported were: muscle weakness (19%), oropharyngeal AEs (14%), respiratory AEs (14%), eye AEs (8%), bowel/bladder AEs (8%), and infection related AEs (5%).

Figure 2 Categories of adverse events as a percentage of total adverse events with onabotulinumtoxinA reported to Health Canada. (Note: Data from incobotulinumtoxinA is not reported here because of insufficient AE data to allow comparison with onabotulinumtoxinA.)

IncobotulinumtoxinA

Out of all reported events (n=13; mean age 59±15 years), 38% were reported in females, 62% were serious, 54% required hospitalization, but none resulted in death. The type of AEs reported were: muscle weakness (15%), oropharyngeal AEs (15%), respiratory AEs (38%), and eye related AEs (23%), bowel/bladder AEs (15%), and infection related AEs (15%).

In the onabotulinumtoxinA group, 33% cases, (out of the 125 cases where the dose was reported), received >360 units of BoNTA (approved maximum cumulative dose in Canada 5 ). In the incobotulinumtoxinA group, none of the 13 cases received more than 400 units of BoNTA (approved maximum cumulative dose in CanadaReference Merz 6 ). Data such as guidance technique used and type of upper motor neuron lesion were not available from Health Canada. Although not an adverse event, ineffectiveness of the toxin (44% onabotulinumtoxinA and 23% incobotulinumtoxinA) was one of the categories of information in the Health Canada data.

Systematic review of worldwide adverse events

The original search of the PubMed, EMBASE, CINAHL, and PEDro databases yielded 1346 articles (see Figure 3) and 50 articles were found to be relevant to the study topic. After a review of the full texts of these articles, 29 met the inclusion criteria and were included in this systematic review. Ten of these studies represented a high level of evidence (level 2). Nine studies were graded level 3 and the remaining ten were graded level 4 (see Tables 1, 2, 3). The total number of patients injected across the 29 studies was 2467; of this, 801 patients (32%) experienced AEs.

Figure 3 PRISMA 2009 Flow Diagram From: Moher D, Liberati A, Tetzlaff J, Altman DG, The PRISMA Group (2009). Preferred Reporting Items for Systematic Reviews: The PRISMA Statement. PLoS Med 6(6): e1000097. doi:10.1371/journal.pmed1000097 For more information, visit www.prisma-statement.org

Table 1 Adverse events in studies reporting use of onabotulinumtoxinA

MS-multiple sclerosis; CP-cerebral palsy; TBI-traumatic brain injury; SCI-spinal cord injury; ALS-amyotrophic lateral sclerosis; LOE-level of evidence (Oxford); UE-upper extremity; LE-lower extremity; EMG-electromyography; NA-not available; CT-computerized tomography; CK-creatine kinase; UTI-urinary tract infection

Table 2 Adverse events in studies reporting use of abobotulinumtoxinA

CK-creatine kinase; UTI-urinary tract infection; TBI-traumatic brain injury

MS-multiple sclerosis; CP-cerebral palsy; TBI-traumatic brain injury; SCI-spinal cord injury; ALS-amyotrophic lateral sclerosis; LOE-level of evidence (Oxford); UE-upper extremity; LE-lower extremity; EMG-electromyography; NA-not available; UTI-urinary tract infection

Table 3 Adverse events in studies reporting use of incobotulinumtoxinA

MS-multiple sclerosis; CP-cerebral palsy; LOE-level of evidence (Oxford); UE-upper extremity; EMG-electromyography

AEs such as muscle weakness,Reference Turkel, Bowen, Liu and Brin 3 , Reference Roche, Schnitzler, Genet, Durand and Bensmail 7 , Reference Muller, Cugy and Ducerf 11 - Reference Pullman, Greene, Fahn and Pedersen 29 hypertoniaReference Turkel, Bowen, Liu and Brin 3 , Reference Gusev, Banach and Simonow 17 , Reference Gordon, Brashear and Elovic 21 , Reference Hyman, Barnes and Bhakta 25 and other muscle related AEs such as cramps, incoordination, stiffness, general motor dysfunctionReference Turkel, Bowen, Liu and Brin 3 , Reference Roche, Schnitzler, Genet, Durand and Bensmail 7 , Reference Muller, Cugy and Ducerf 11 , Reference Gordon, Brashear and Elovic 21 were reported in 20 studies reviewed here. Injection site pain was reported in eight studiesReference Turkel, Bowen, Liu and Brin 3 , Reference Muller, Cugy and Ducerf 11 , Reference Barnes, Schnitzler, Medeiros, Aguilar, Lehnert-Batar and Minnasch 19 , Reference Gordon, Brashear and Elovic 21 , Reference Mohammadi, Balouch, Dengler and Kollewe 28 - Reference Kanovsky, Slawek and Denes 31 and non-injection site related pain (arthralgia, headache, myalgia, and abdominal and back pain) was also reported in twelve studiesReference Shaw, Rodgers and Price 1 , Reference Turkel, Bowen, Liu and Brin 3 , Reference Muller, Cugy and Ducerf 11 , Reference Gusev, Banach and Simonow 17 , Reference Simpson, Gracies, Yablon, Barbano, Brashear and Team 18 , Reference Gordon, Brashear and Elovic 21 - Reference Pittock, Moore and Hardiman 23 , Reference Hyman, Barnes and Bhakta 25 , Reference Kaji, Osako and Suyama 32 , Reference Kanovský, Slawek and Denes 33 . Furthermore, oropharyngeal AEs (dysphagia, dry mouth, pharyngitis, dysarthria, recurrent choking, and dysphonia) were reported in seven studiesReference Bakheit, Ward and McLellan 14 , Reference Crowner, Torres-Russotto, Carter and Racette 16 , Reference Gusev, Banach and Simonow 17 , Reference Pittock, Moore and Hardiman 23 , Reference Coban, Matur, Hanagasi and Parman 24 , Reference Bakheit, Fedorova, Skoromets, Timerbaeva, Bhakta and Coxon 30 , Reference Kanovsky, Slawek and Denes 31 and bowel and bladder AEs were reported in six studiesReference Shaw, Rodgers and Price 1 , Reference Crowner, Torres-Russotto, Carter and Racette 16 , Reference Gordon, Brashear and Elovic 21 , Reference Hyman, Barnes and Bhakta 25 , Reference Kanovský, Slawek and Denes 33 , Reference Bruggemann, Dognitz, Harms, Moser and Hagenah 34 . Circulation related AEs (peripheral edema, contusion/hematoma, hypertension, postural hypotension, erectile dysfunction, paleness) were reported in nine studiesReference Turkel, Bowen, Liu and Brin 3 , Reference Muller, Cugy and Ducerf 11 , Reference Barnes, Schnitzler, Medeiros, Aguilar, Lehnert-Batar and Minnasch 19 , Reference Gordon, Brashear and Elovic 21 , Reference Kanovsky, Slawek and Denes 31 - Reference Papadonikolakis, Vekris, Kostas, Korompilias and Soucacos 35 .

Neurologic AEs (epilepsy, seizure, convulsions, dystonia, paraesthesia, and hyperaesthesia)Reference Turkel, Bowen, Liu and Brin 3 , Reference Muller, Cugy and Ducerf 11 , Reference Crowner, Torres-Russotto, Carter and Racette 16 , Reference Gordon, Brashear and Elovic 21 , Reference Pittock, Moore and Hardiman 23 , Reference Suputtitada and Suwanwela 26 , Reference Kanovský, Slawek and Denes 33 and gait abnormalities and falls were reported in seven studies eachReference Shaw, Rodgers and Price 1 , Reference Crowner, Torres-Russotto, Carter and Racette 16 , Reference Simpson, Gracies, Yablon, Barbano, Brashear and Team 18 , Reference Joshi 20 , Reference Pittock, Moore and Hardiman 23 , Reference Hyman, Barnes and Bhakta 25 , Reference Kaji, Osako and Suyama 32 . Infection related AEs (flu like symptoms, abscess, infection, fever) were reported in five studiesReference Shaw, Rodgers and Price 1 , Reference Joshi 20 , Reference Hyman, Barnes and Bhakta 25 , Reference Dunne, Heye and Dunne 27 , Reference Opara, Hordyńska and Swoboda 36 . Respiratory AEs (cough, dyspnoea, respiratory distress, upper respiratory tract infection, chest infection, and orthopnea) were reported in six studiesReference Shaw, Rodgers and Price 1 , Reference Turkel, Bowen, Liu and Brin 3 , Reference Crowner, Torres-Russotto, Carter and Racette 16 , Reference Coban, Matur, Hanagasi and Parman 24 , Reference Hyman, Barnes and Bhakta 25 , Reference Kanovsky, Slawek and Denes 31 . General AEs (mild discomfort, dizziness, nausea, tooth disorder, somnolence, insomnia, and altered blood test results) were reported in eleven studiesReference Shaw, Rodgers and Price 1 , Reference Turkel, Bowen, Liu and Brin 3 , Reference Simpson, Gracies, Yablon, Barbano, Brashear and Team 18 , Reference Barnes, Schnitzler, Medeiros, Aguilar, Lehnert-Batar and Minnasch 19 , Reference Gordon, Brashear and Elovic 21 - Reference Pittock, Moore and Hardiman 23 , Reference Hyman, Barnes and Bhakta 25 , Reference Dunne, Heye and Dunne 27 , Reference Kaji, Osako and Suyama 32 , Reference Kanovský, Slawek and Denes 33 . Eye related AEs (diplopia, difficulty keeping eyes open, ptosis) were reported in three studiesReference Roche, Schnitzler, Genet, Durand and Bensmail 7 , Reference Bakheit, Ward and McLellan 14 , Reference Crowner, Torres-Russotto, Carter and Racette 16 .

Botulinum toxin type-A dosage injected in the studies included in this review varied widely – ranging from 10 – 800 units (onabotulinumtoxinA), 100 – 1500 units (Dysport - abobotulinumtoxinA), and 300 – 400 units (incobotulinumtoxinA). OnabotulinumtoxinA was used in thirteen, abobotulinumtoxinA in nine studies and incobotulinumtoxinA in three studies as the type of BoNTA toxin administered for spasticity treatment. Finally, four studies used a combination of both abobotulinumtoxinA and onabotulinumtoxinA as the BoNTA toxins for spasticity management.

The most commonly reported diagnosis where BoNTA was administered resulting in any AE was stroke in eighteen studies followed by MS in seven studies. Brain injury and CP were each the diagnoses in two of the studies and other less common diagnoses are reported in Tables 1, 2, and 3. Each of these diagnoses was reported in a combination or alone in one study reviewed. The BoNTA injection location was evenly distributed between upper extremity (34%), lower extremity (31%), and combined upper and lower extremity injection studies (31%).

Guidance technique: 17 studies used electromyography or electrical stimulation to localize the site of injections whereas 12 studies either used no guidance or used localization of anatomical landmarks and palpation.

Discussion

While AEs are routinely reported in the research studies and clinical trials using BoNTA treatments for a variety of indications, our study reports the data specific to spasticity. An in-depth understanding of possible AEs and the underlying mechanisms can help clinicians account for these potential AEs and manage spasticity effectively. These AEs can be explained by: (1) the local AEs of BoNTA; (2) the systemic effects from spread of the toxin to surrounding and remote areas via two possible routes. Systemic effects can be further explained by either a vascular spread or a retrograde axonal spread.

Local adverse events of BoNTA administration

Muscle related AEs such as weakness limited to the vicinity of the injected muscles was the second most common AE in Canada and the most commonly reported AE in the majority of the studies reviewed here. Muscle weakness can be attributed to the administration of excess quantity of toxinReference Hecht, Stolze and Auf dem Brinke 22 , Reference Hyman, Barnes and Bhakta 25 , Reference Lange, Brin, Warner, Fahn and Lovelace 37 , Reference Naidu, Smith, Sheedy, Adair, Yu and Graham 38 resulting in acute and severe muscle paresis. Local muscle atrophyReference Bakheit, Ward and McLellan 14 is proposed to result from continued blockade of neurotransmissionReference Joshi 20 causing effects similar to anatomic denervationReference Ghasemi, Salari, Khorvash and Shaygannejad 39 . In animal models, botulinum toxin has been shown to spread to muscles in the same compartment as the injected muscleReference Yucesoy, Emre Arıkan and Ateş 40 . The local spread of the toxin to nearby muscles within the same compartment can weaken the muscles and can contribute to decrease in force outputReference Yucesoy, Emre Arıkan and Ateş 40 . It has been suggested that total toxin injected in muscles throughout the body may increase weaknessReference Brin, Lyons and Doucette 41 , whereas others contest this viewReference Muller, Cugy and Ducerf 11 . Though considered reversibleReference Muller, Cugy and Ducerf 11 , Reference Joshi 20 , severe acute local weakness of the injected muscle can be counterproductive because it can lead to muscle imbalance and further loss of functionReference Roche, Schnitzler, Genet, Durand and Bensmail 7 .

Although dosage guidelines exist in treating children with spasticityReference Naidu, Smith, Sheedy, Adair, Yu and Graham 38 , Reference Heinen, Molenaers and Fairhurst 42 , similar guidelines are missing for treatment with BoNTA in adults with spasticityReference Wissel, Ward and Erztgaard 43 . Lack of clarity and consensus regarding dose can lead to physicians injecting too little or too much toxin when spasticity management with BoNTA is first initiated. Clear guidelines can prevent unwanted and serious AEs, give practical guidance regarding upper limits of BoNTA dose and change practice of BoNTA injectionsReference Naidu, Smith, Sheedy, Adair, Yu and Graham 38 . In addition, not all types of neurological lesions experience similar levels of spasticity across the limbs and may require different overall doses depending on the spasticity manifestation patternReference Phadke, Davidson, Ismail and Boulias 44 . Studies reporting doses in individual muscles and limbs across a variety of neurological lesions are emergingReference Phadke, Davidson, Ismail and Boulias 44 , Reference Esquenazi, Mayer and Lee 45 and will help guide physicians regarding dosages used by other practitioners.

While low doses can result in ineffectiveness of the toxin, high doses can potentially increase the AEsReference Caleo, Antonucci, Restani and Mazzocchio 46 - Reference Kaji, Osako and Suyama 48 . One third (33%) of the patients receiving onabotulinumtoxinA received doses greater than the maximal cumulative dose recommended in the product monograph. In the studies reviewed here, 7/17 studies (41%) injected greater than 360 units of onabotulinumtoxinA, 7/13 studies (54%) injected greater than 1000 units (maximum recommended cumulative dose 49 ) of abobotulinumtoxinA, and none of the studies exceeded the maximal cumulative dose recommended in the product monograph for incobotulinumtoxinA. Thus, it is possible that high dose may be one of the factors underlying muscle weakness. Some studies in this systematic review also reported hypertonia as an AE. It has been suggested that hypertonia may not be in response to BoNTA but rather a normal variation in toneReference Hyman, Barnes and Bhakta 25 in response to various environmental factorsReference Phadke, Balasubramanian, Ismail and Boulias 50 . Additionally, another factor contributing to hypertonia may be the unmasking of underlying spasticity post-BoNTA injections in adjacent and/or synergistic uninjected muscles in response to reduction of spasticity in injected musclesReference Gusev, Banach and Simonow 17 .

Injection site pain was not reported as an AE in Canada in spite of several studies reviewed in the literature reporting this AE. A possible reason injection site pain was not reported to Health Canada was because pain is expected during a procedure such as repetitive intramuscular BoNTA injectionsReference Gordon, Brashear and Elovic 21 . Application of ice packs is known to decrease BoNTA injection related painReference Fung, Phadke, Kam, Ismail and Boulias 51 and ice packs may have a more therapeutic role in managing local injection related pain. Pain and other local injection site AEs such as bruising, burning, and hypersensitivity may be preventable in some instances by exercising caution in the technique of injecting BoNTAReference Kaji, Osako and Suyama 32 . One study reported higher frequency of AEs in the BoNTA groupReference Gusev, Banach and Simonow 17 but, it should be noted, some placebo-controlled studies report similar frequency of treatment related AEs in the BoNTA and the placebo groupsReference Shaw, Rodgers and Price 1 , Reference Turkel, Bowen, Liu and Brin 3 , Reference Hyman, Barnes and Bhakta 25 , Reference Kanovsky, Slawek and Denes 31 , Reference Kaji, Osako and Suyama 32 , Reference Kaji, Osako and Suyama 48 . It is possible that at least some of the AEs may be related to injection technique. Close to half (41%) of the studies included in this review either used no guidance or anatomical landmarks and palpation and none of the studies used ultrasound guidance. It is possible that lack of precision during injections as afforded by electromyelography (EMG) and electrical stimulationReference Chin, Nattrass, Selber and Graham 52 may be a contributing factor towards some of the AEs. Other local AEs such as skin reactions (e.g., rash) have been attributed to allergic responsesReference Bruggemann, Dognitz, Harms, Moser and Hagenah 34 to the toxin; however, such minor AEs are less common.

Seven studies included in this review reported non-injection site related pain (e.g. myalgia and headache) as an AE. In all these studies, BoNTA injections were predominantly delivered in the upper limbs; however, it is not clear what factors may have resulted in AEs such as headache and myalgia. Paradoxically, BoNTA has been used to treat myalgia in upper extremityReference Wendel and Cole 53 and thus, the mechanism underlying AEs such as myalgia and headache after BoNTA injections is unclear. Botulinum toxin type-A is typically injected in multiple muscles and multiple sites within a muscle. It is possible that multiple injection sites caused bruising and the cumulative effect was seen in the form of myalgia. Hands are known to have significantly larger sensory cortical representation than legs and four out of seven studies reporting pain involved injections in hand muscles. It is possible that multiple injections in the hand area may be responsible for myalgia. Presentation of headache may be a result of systemic effects of BoNTA.

Systemic adverse events of BoNTA

Relatively serious AEs in association with BoNTA including hospitalization, or fatality, have also been reported in addition to AEs in categories like oropharyngeal, respiratory, eyes, bowel/bladder, and infection. Mechanisms underlying some of these AEs have been proposed but conclusive evidence is lacking. Two possible systems of spread (vascular and retrograde axonal spread) have been suggested in the literatureReference Garner, Straube, Witt, Gasser and Oertel 54 .

a) Vascular spread: Direct administration into blood circulation is unlikely because typically needles are aspirated for blood before injections; however, the distant AEs of BoNTA suggest that vascular spread is possible through means other than direct administration into the blood stream. Botulinum toxin type-A can induce autonomic effects such as biliary colic and impact the gastrointestinal autonomic pathwaysReference Schnider, Brichta, Schmied and Auff 55 , impair the cardiovascular autonomic pathwaysReference Girlanda, Vita, Nicolosi, Milone and Messina 56 , and inhibit autonomic cholinergic pathways in the bladderReference MacKenzie, Burnstock and Dolly 57 . Although it is difficult to imagine a direct link between the respiratory and immunity related AEs of BoNTA, other factors may indirectly be responsible. Cholinergic receptors in the pharyngeal and laryngeal sphincters are likely to be inhibited by systemic spread of BoNTA and may be the primary reason for dysphagia/dysphonia. Additionally, incoordination of the laryngeal and pharyngeal sphincter activity can compromise airway protection and make patients vulnerable to aspiration of oral and esophageal contentsReference Naidu, Smith, Sheedy, Adair, Yu and Graham 38 , Reference Nigam and Nigam 58 . Aspiration may be one of the indirect mechanisms responsible for respiratory AEs and may also lead to possible immunity related AEs. One of the suggested mechanisms for transport of the toxin from one part of the body (neck) to a remote location (toes) is through the circulatory systemReference Lange, Brin, Warner, Fahn and Lovelace 37 . The short time interval between injection and onset of distant effects, in some cases within 24 hoursReference Naidu, Smith, Sheedy, Adair, Yu and Graham 38 , Reference Girlanda, Vita, Nicolosi, Milone and Messina 56 , also suggests that the toxin is transported systemically via vascular spread. Vascular spread via absorption through the capillary system remains a possibility. It is possible that a combination of both vascular and retrograde axonal spread of the toxin is responsible for distant AEsReference Papadonikolakis, Vekris, Kostas, Korompilias and Soucacos 35 , Reference Garner, Straube, Witt, Gasser and Oertel 54 .

For instance, Hyman in 2000Reference Hyman, Barnes and Bhakta 25 administered abobotulinumtoxinA to the hip adductor muscles of the upper thigh and postulated that the toxin could locally spread to the muscles around the pelvic floor, resulting in an increased incidence of urinary and fecal incontinence with BoNTA treatments. The relaxing anticholinergic effect of BoNTA on the striated and bladder wall muscles may be the underlying mechanism resulting in increased residual urineReference Naidu, Smith, Sheedy, Adair, Yu and Graham 38 , Reference Schnider, Berger, Schmied, Fertl and Auff 59 . Dysphagia, another serious AE, has been shown to occur in some patients. The close proximity of neck and proximal upper extremity muscles injected with BoNTA could result in the diffusion of the toxin into the surrounding muscles explaining the AE of dysphagiaReference Nigam and Nigam 58 , Reference Shaw and Rodgers 60 . However, three out of five studies reporting dysphagia as an AE injected the toxin in distant muscle groups, such as distal upper extremity muscle groups or even lower extremity muscle groups. Such a distant anticholinergic effect on the autonomic nervous system is unlikely through local spread of the toxin and a systemic spread has been suggested even when toxin is injected in sites anatomically adjacent to the locus of AEsReference Naidu, Smith, Sheedy, Adair, Yu and Graham 38 , Reference Girlanda, Vita, Nicolosi, Milone and Messina 56 .

Remote effects (muscle weakness): The weakness of muscles contralateral to the injected muscle was extremely rare and reported in very few studiesReference Thomas and Simpson 12 , Reference Varghese-Kroll and Elovic 13 , Reference Borg-Stein, Pine, Miller and Brin 15 . Local diffusion of the toxin through tissue planes and across the midline to the contralateral side is proposed as a mechanism for contralateral weaknessReference Thomas and Simpson 12 . Generalized weakness of muscles distant and remote to injection sites is much less common but nevertheless reported as an AE in some studiesReference Bakheit, Ward and McLellan 14 .

b) Retrograde axonal spread: Along with vascular systemic toxin spread, retrograde axoplasmic spread of the toxinReference Garner, Straube, Witt, Gasser and Oertel 54 , Reference Wiegand, Erdmann and Wellhöner 61 is the second possible mechanism for the observed distant AEs. Limited evidence exists in the literature based on human studies with evidence predominantly derived from animal studiesReference Caleo, Antonucci, Restani and Mazzocchio 46 . Based on a cat model, Wiegand (1976) demonstrated retrograde axonal transport of the toxin into the corresponding spinal cord segments using radioactive BoNTAReference Wiegand, Erdmann and Wellhöner 61 ; however, it was not clear if BoNTA remained enzymatically active after traveling into the spinal cord. More recent evidence shows retrograde transport of enzymatically active toxin molecules via microtubules in the axon to both sensory and motor regions in the spinal cord after intramuscular and intraneural injections of BoNTAReference Matak, Bach-Rojecky, Filipović and Lacković 62 , Reference Matak, Riederer and Lacković 63 . In fact, anti-nociceptive effect of BoNTA may occur through retrograde spread of BoNTA from the sensory nerves in the periphery to the central nervous systemReference Matak, Bach-Rojecky, Filipović and Lacković 62 . Additionally, BoNTA may share a similar time course as fast and long-range retrograde axonal transport to the central nervous systemReference Restani, Giribaldi and Manich 64 .

Lack of change in spinal reflex amplitude (H-reflexes) post-BoNTA has been suggested to refute the theory of retrograde axonal spreadReference Koman, Mooney, Smith, Walker and Leon 65 . However, both H-reflex and M-max (maximal motor response to electrical stimulation) are known to decrease after BoNTA and the ratio of Hmax/Mmax may not be an appropriate measure of central nervous system changeReference Phadke, Ismail and Boulias 66 . A better measure is reflex inhibition, and BoNTA injections have been reported to decrease recurrent or Renshaw-cell inhibition in persons post-strokeReference Caleo, Antonucci, Restani and Mazzocchio 46 , Reference Marchand-Pauvert, Aymard, Giboin, Dominici, Rossi and Mazzocchio 67 . Although both systemic vascular and axonal spread of the toxin is possible, the prolonged latency in appearance of some AEs such as the distant weakness is uncharacteristic of a mode of vascular toxin spread. Retrograde transport in such cases appears more likely. Thus, evidence points towards retrograde axonal uptake of the toxin and spread to the CNS and may be the underlying mechanism resulting in both distant muscular as well as the neurologic AEs seen in the studies included in this review. It should be noted however, that distant effects may also be in response to the intrafusal uptake of the toxin in the muscles spindles as well as neuroplastic changes post-BoNTA injectionsReference Caleo, Antonucci, Restani and Mazzocchio 46 , Reference Phadke, On, Kirazli, Ismail and Boulias 68 .

Preventable adverse events

It has been suggested that some of the AEs may be preventable. DoseReference Caleo, Antonucci, Restani and Mazzocchio 46 , Reference Nigam and Nigam 58 , Reference Borodic, Ferrante, Pearce and Smith 69 , injection techniqueReference Nigam and Nigam 58 and volumeReference Brodsky, Swope and Grimes 70 are some of the suggested preventable factors that can potentially affect distant spread of the toxin. Data from Canada shows that the most prevalent AE of BoNTA injections (onabotulinumtoxinA and incobotulinumtoxinA) was muscles weakness (range 15-19%); however, the percentage of oropharyngeal and respiratory problems (14-38%) among all AEs was much higher than pain (8-15%). With 33% cases with AEs receiving more than 360 units of onabotulinumtoxinA, it is possible that higher than typical dosesReference Phadke, Davidson, Ismail and Boulias 44 may be related to the AEs. It is also possible that some of the AEs of BoNTA injections are unrelated to the BoNTA treatment. Some patients treated with BoNTA may have pre-existing and co-morbid conditions such as seizure disordersReference Varghese-Kroll and Elovic 13 and in cases like these an AE of seizure can be better explained by the pre-existing condition rather than the effect of BoNTA injections. Minor AEs like minor falls, sitting imbalance, and minor gait abnormalities reported after BoNTA treatment may be related to the muscle weakness caused by the toxinReference Joshi 20 . For example, Pittock et al (2003) reported over-weakening of muscles with BoNTA injections resulting in a deterioration of the step length discrepancy observed in their patient populationReference Pittock, Moore and Hardiman 23 .

Non-responsiveness to treatment with BoNTA

Non-responsiveness to BoNTA could be as a result of a variety of factors reviewed elsewhereReference Benecke 71 . Possible factors include misdiagnosis, insufficient dose, first injection cycle placebo, problems with toxin storage and preparation, and administrationReference Joshi 20 , Reference Benecke 71 . Although 41% of the studies reviewed here either used no guidance or anatomical landmarks and palpation, we do not have information regarding guidance technique used to inject BoNTA in the AEs reported to Health Canada. Electrical stimulation, EMG, and ultrasound are well-established, precise, and beneficial guidance techniquesReference Walker, Lee, Bahroo, Hedera and Charles 72 . It is possible that use of imprecise guidance techniques such as palpation or anatomical landmarks alone may have resulted in problems with administration such as injecting the wrong muscle. Another possible reason for lack of clinical effect is immunoresistance to BoNTA, which refers to ineffectiveness of the toxin as a result of development of neutralizing antibodies against the toxinReference Benecke 71 . However, immunoresistance is reported to be very low with abobotulinumtoxinA (6.6%) in patients with spasticity and dystoniaReference Truong, Brodsky and Lew 73 and onabotulinumtoxinA (3%)Reference Anderson, Rivest and Stell 74 , Reference Zuber, Sebald, Bathien, de Recondo and Rondot 75 .

Serious adverse events

Data reported in this study represents events occurring across several countries. Of all AEs reported in Canada, 8% were deaths and this number was much lower than the 13% deaths reported among all AEs reported in USReference Coté, Mohan, Polder, Walton and Braun 8 . None of the studies included in this review reported death as an AE barring one where the deaths of study participants were unrelated to the toxinReference Turkel, Bowen, Liu and Brin 3 . The Health Canada data did not detail reasons for hospitalization (18% of all AEs) and the description of serious AEs (53% of all AEs). It is possible that some of the serious AEs may have been iatrogenicReference Coban, Matur, Hanagasi and Parman 24 ; however the presence of comorbidities can also partly explain some of the serious AEs. It should be noted that there was no indication from Health Canada data if there was a causal relationship between adverse events and toxin use.

Diversity of data

Out of the 29 articles reviewed, ten were from the United States of America (USA), five from the United Kingdom (UK) and the rest of the studies were from Germany (three), Turkey, Poland, Czech Republic, and France (two each), Japan, Thailand, and Greece (one each). Thus, in spite of a bias of studies in the USA and the UK, there was a reasonable representation from other countries barring the African and South American Continents.

Limitations

OnabotulinumtoxinA has been available for clinical use since the 1980s 76 and approved for upper or lower limb spasticity since 2001 9 ; whereas incobotulinumtoxinA has become available in Canada in 2009 77 . Additionally, onabotulinumtoxinA is approved for use in patients with focal spasticity in both upper and lower limbs 5 , whereas incobotulinumtoxinA is approved for use for spasticity in only upper limbs in patients with strokeReference Merz 6 . The differences in availability and approval for use (in addition to some differences in provincial formularies) can potentially explain the significantly fewer AEs with incobotulinumtoxinA. All these factors can play a role in the number and type of AEs and need to be taken into account when comparing the absolute numbers of AEs experienced with each preparation and interpreting the data.

Conclusions

Clinicians need to be aware of muscle weakness as a primary potential AE followed by oropharyngeal and respiratory problems associated with BoNTA injections for spasticity management. Mechanisms underlying these AEs need to be investigated using both animal and human models. Importantly, understanding the reasons for the AEs may assist in identifying risk factors and developing guidelines for minimizing occurrence of AEs with BoNTA treatments.

DISCLOSURES

Chetan Phadke has the following disclosure: Merz Pharma - Grant recipient; Farooq Ismail has the following disclosures: Allergan Inc. - Consultant, Honoraria/Speaker’s fees, Merz Pharma - Consultant, Honoraria/Speaker’s fees, Merz Pharma - Grant recipient, Grant support; Chris Boulias has the following disclosures: Allergan Inc. - Consultant, Honoraria, Merz Pharma - Consultant, Honoraria, Merz Pharma - Grant recipient, Grant; Chitra Balasubramanian, Alanna Holz, Caitlin Davidson do not have anything to disclose.

References

1. Shaw, L, Rodgers, H, Price, C, et al. BoTULS: a multicentre randomised controlled trial to evaluate the clinical effectiveness and cost-effectiveness of treating upper limb spasticity due to stroke with botulinum toxin type A. Health Technol Assess. 2010;14:1-113, iii-iv.Google Scholar
2. Ward, AB, Aguilar, M, De Beyl, Z, et al. Use of botulinum toxin type A in management of adult spasticity--a European consensus statement. J Rehabil Med. 2003;35(2):98-99.CrossRefGoogle ScholarPubMed
3. Turkel, CC, Bowen, B, Liu, J, Brin, MF. Pooled analysis of the safety of botulinum toxin type A in the treatment of poststroke spasticity. Arch Phys Med Rehab. 2006;87:786-792.CrossRefGoogle ScholarPubMed
4. Truong, DD, Stenner, A, Reichel, G. Current clinical applications of botulinum toxin. Curr Pharm Des. 2009;15:3671-3680.Google Scholar
5. Allergan Inc. C.Botox Product Monograph (Canada). 2013. http://www.allergan.ca/assets/pdf/ca_botox_pm.pdf. Accessed Date of approval: October 10,2013.Google Scholar
6. Merz, C. Xeomin Product Monograph. Merz Canada Ltd.; 2011.Google Scholar
7. Roche, N, Schnitzler, A, Genet, FF, Durand, MC, Bensmail, D. Undesirable distant effects following botulinum toxin type a injection. Clin Neuropharmacol. 2008;31:272-280.Google Scholar
8. Coté, TR, Mohan, AK, Polder, JA, Walton, MK, Braun, MM. Botulinum toxin type A injections: adverse events reported to the US Food and Drug Administration in therapeutic and cosmetic cases. J Am Acad Dermatol. 2005;53:407-415.Google Scholar
9. DGNews. Canada Approves Botox (Botulinum Toxin Type A) For Focal Spasticity. DocGuide.com. 2001. http://www.docguide.com/canada-approves-botox-botulinum-toxin-type-focal-spasticity.Google Scholar
10. Howick, J, Chalmers, I, Library, JL, et al. The Oxford 2011 Levels of Evidence. 2011; http://www.cebm.net/index.aspx?o=5653. Accessed 4th October, 2012.Google Scholar
11. Muller, F, Cugy, E, Ducerf, C, et al. Safety and self-reported efficacy of botulinum toxin for adult spasticity in current clinical practice: a prospective observational study. Clin Rehabil. Feb 2012;26(2):174-179.CrossRefGoogle ScholarPubMed
12. Thomas, AM, Simpson, DM. Contralateral weakness following botulinum toxin for poststroke spasticity. Muscle Nerve. Sep 2012;46(3):443-448.CrossRefGoogle ScholarPubMed
13. Varghese-Kroll, E, Elovic, EP. Contralateral weakness and fatigue after high-dose botulinum toxin injection for management of poststroke spasticity. Am J Phys Med Rehabil. 2009;88:495-499.Google Scholar
14. Bakheit, AM, Ward, CD, McLellan, DL. Generalised botulism-like syndrome after intramuscular injections of botulinum toxin type A: a report of two cases. J Neurol Neurosurg Psychiatry. 1997;62:198.Google Scholar
15. Borg-Stein, J, Pine, ZM, Miller, JR, Brin, MF. Botulinum toxin for the treatment of spasticity in multiple sclerosis. New observations. Am J Phys Med Rehabil. 1993;72:364-368.CrossRefGoogle ScholarPubMed
16. Crowner, BE, Torres-Russotto, D, Carter, AR, Racette, BA. Systemic weakness after therapeutic injections of botulinum toxin a: a case series and review of the literature. Clin Neuropharmacol. 2010;33:243-247.Google Scholar
17. Gusev, Y, Banach, M, Simonow, A, et al. Efficacy and Safety of Botulinum Type A Toxin in Adductor Spasticity Due to Multiple Sclerosis. J Musculoskelet Pain. 2008;16(3):175-188.Google Scholar
18. Simpson, DM, Gracies, JM, Yablon, SA, Barbano, R, Brashear, A, Team, BTS. Botulinum neurotoxin versus tizanidine in upper limb spasticity: a placebo-controlled study. J Neurol Neurosurg Psychiatry. 2009;80:380-385.Google Scholar
19. Barnes, M, Schnitzler, A, Medeiros, L, Aguilar, M, Lehnert-Batar, A, Minnasch, P. Efficacy and safety of NT 201 for upper limb spasticity of various etiologies--a randomized parallel-group study. Acta Neurol Scand. 2010;12:295-302.Google Scholar
20. Joshi, T. Unwanted Muscle Weakness following Botulinum Neurotoxin A Administration in Spinal Cord Injury with Literature Review. Indian J Phys Med Rehab. 2012;23:20-24.Google Scholar
21. Gordon, MF, Brashear, A, Elovic, E, et al. Repeated dosing of botulinum toxin type A for upper limb spasticity following stroke. Neurology. 2004;63:1971-1973.Google Scholar
22. Hecht, MJ, Stolze, H, Auf dem Brinke, M, et al. Botulinum neurotoxin type A injections reduce spasticity in mild to moderate hereditary spastic paraplegia--report of 19 cases. Mov Disord. 2008;23:228-233.Google Scholar
23. Pittock, SJ, Moore, AP, Hardiman, O, et al. A double-blind randomised placebo-controlled evaluation of three doses of botulinum toxin type A (Dysport) in the treatment of spastic equinovarus deformity after stroke. Cerebrovasc Dis. 2003;15:289-300.Google Scholar
24. Coban, A, Matur, Z, Hanagasi, HA, Parman, Y. Iatrogenic botulism after botulinum toxin type A injections. Clin Neuropharmacol. 2010;33:158-160.Google Scholar
25. Hyman, N, Barnes, M, Bhakta, B, et al. Botulinum toxin (Dysport) treatment of hip adductor spasticity in multiple sclerosis: a prospective, randomised, double blind, placebo controlled, dose ranging study. J Neurol Neurosurg Psychiatry. 2000;68:707-712.Google Scholar
26. Suputtitada, A, Suwanwela, NC. The lowest effective dose of botulinum A toxin in adult patients with upper limb spasticity. Disabil Rehabil. 2005;27:176-184.Google Scholar
27. Dunne, JW, Heye, N, Dunne, SL. Treatment of chronic limb spasticity with botulinum toxin A. J Neurol Neurosurg Psychiatry. 1995;58:232-235.Google Scholar
28. Mohammadi, B, Balouch, SA, Dengler, R, Kollewe, K. Long-term treatment of spasticity with botulinum toxin type A: an analysis of 1221 treatments in 137 patients. Neurol Res. 2010;32:309-313.CrossRefGoogle ScholarPubMed
29. Pullman, S, Greene, P, Fahn, S, Pedersen, S. Approach to the treatment of limb disorders with botulinum toxin A. Experience with 187 patients. Arch Neurol. J996;53:617-624.CrossRefGoogle Scholar
30. Bakheit, AM, Fedorova, NV, Skoromets, AA, Timerbaeva, SL, Bhakta, BB, Coxon, L. The beneficial antispasticity effect of botulinum toxin type A is maintained after repeated treatment cycles. J Neurol Neurosurg Psychiatry. 2004;75:1558-1561.Google Scholar
31. Kanovsky, P, Slawek, J, Denes, Z, et al. Efficacy and safety of treatment with incobotulinum toxin A (botulinum neurotoxin type A free from complexing proteins; NT 201) in post-stroke upper limb spasticity. J Rehab Med. 2011;43:486-492.Google Scholar
32. Kaji, R, Osako, Y, Suyama, K, et al. Botulinum toxin type A in post-stroke lower limb spasticity: a multicenter, double-blind, placebo-controlled trial. J Neurol. 2010;257:1330-1337.Google Scholar
33. Kanovský, P, Slawek, J, Denes, Z, et al. Efficacy and safety of botulinum neurotoxin NT 201 in poststroke upper limb spasticity. Clin Neuropharmacol. 2009;32:259-265.CrossRefGoogle ScholarPubMed
34. Bruggemann, N, Dognitz, L, Harms, L, Moser, A, Hagenah, J. Skin reactions after intramuscular injection of Botulinum toxin A: a rare side effect. BMJ Case Rep. 2009;2009.CrossRefGoogle ScholarPubMed
35. Papadonikolakis, AS, Vekris, MD, Kostas, JP, Korompilias, AV, Soucacos, PN. Transient erectile dysfunction associated with intramuscular injection of botulinum toxin type A. J South Orthop Assoc. 2002;11:116-118.Google Scholar
36. Opara, J, Hordyńska, E, Swoboda, A. Effectiveness of botulinum toxin A in the treatment of spasticity of the lower extremities in adults - preliminary report. Ortop Traumatol Rehabil. 2007, May-Jun 2007;9(3):277-285.Google Scholar
37. Lange, DJ, Brin, MF, Warner, CL, Fahn, S, Lovelace, RE. Distant effects of local injection of botulinum toxin. Muscle Nerve. 1987;10:552-555.Google Scholar
38. Naidu, K, Smith, K, Sheedy, M, Adair, B, Yu, X, Graham, HK. Systemic adverse events following botulinum toxin A therapy in children with cerebral palsy. Dev Med Child Neurol. 2010;52:139-144.CrossRefGoogle ScholarPubMed
39. Ghasemi, M, Salari, M, Khorvash, F, Shaygannejad, V. A literature review on the efficacy and safety of botulinum toxin: an injection in post-stroke spasticity. Int J Prev Med. 2013;4(Suppl 2):S147-S158.Google ScholarPubMed
40. Yucesoy, CA, Emre Arıkan, Ö, Ateş, F. BTX-A administration to the target muscle affects forces of all muscles within an intact compartment and epimuscular myofascial force transmission. J Biomech Eng. 2012;134:111002.Google Scholar
41. Brin, MF, Lyons, KE, Doucette, J, et al. A randomized, double masked, controlled trial of botulinum toxin type A in essential hand tremor. Neurology. 2001;56:1523-1528.Google Scholar
42. Heinen, F, Molenaers, G, Fairhurst, C, et al. European consensus table 2006 on botulinum toxin for children with cerebral palsy. Eur J Paediatr Neurol. 2006;10:215-225.Google Scholar
43. Wissel, J, Ward, AB, Erztgaard, P, et al. European consensus table on the use of botulinum toxin type A in adult spasticity. J Rehabil Med. 2009;41:13-25.CrossRefGoogle ScholarPubMed
44. Phadke, CP, Davidson, C, Ismail, F, Boulias, C. The effect of neural lesion type on botulinum toxin dosage: a retrospective chart review. PMR. 2014;6:406-411.Google Scholar
45. Esquenazi, A, Mayer, N, Lee, S, et al. Patient registry of outcomes in spasticity care. Am J Phys Med Rehabil. 2012;91:729-746.Google Scholar
46. Caleo, M, Antonucci, F, Restani, L, Mazzocchio, R. A reappraisal of the central effects of botulinum neurotoxin type A: by what mechanism? J Neurochem. 2009;109:15-24.Google Scholar
47. Calne, S. Local treatment of dystonia and spasticity with injections of botulinum-A toxin. Axone. 1993;14:85-88.Google Scholar
48. Kaji, R, Osako, Y, Suyama, K, et al. Botulinum toxin type A in post-stroke upper limb spasticity. Curr Med Res Opin. 2010;26:1983-1992.Google Scholar
49. Monograph D. Highlights of prescribing information. http://www.dysport.com/hcp/PDFs/Dysport_Patiens_PI_Aug2012.pdf. Accessed 31st March, 2015.Google Scholar
50. Phadke, CP, Balasubramanian, CK, Ismail, F, Boulias, C. Revisiting physiologic and psychologic triggers that increase spasticity. Am J Phys Med Rehabil. 2013;92:357-369.CrossRefGoogle ScholarPubMed
51. Fung, S, Phadke, CP, Kam, A, Ismail, F, Boulias, C. Effect of topical anesthetics on needle insertion pain during botulinum toxin type A injections for limb spasticity. Arch Phys Med Rehabil. 2012;93:1643-1647.Google Scholar
52. Chin, TY, Nattrass, GR, Selber, P, Graham, HK. Accuracy of intramuscular injection of botulinum toxin A in juvenile cerebral palsy: a comparison between manual needle placement and placement guided by electrical stimulation. J Pediatr Orthop. 2005;25:286-291.Google Scholar
53. Wendel, I, Cole, J. Treatment of extensor digitorum brevis manus myalgia with botulinum toxin. PMR. 2014;6:284-286.Google Scholar
54. Garner, CG, Straube, A, Witt, TN, Gasser, T, Oertel, WH. Time course of distant effects of local injections of botulinum toxin. Mov Disord. 1993;8:33-37.Google Scholar
55. Schnider, P, Brichta, A, Schmied, M, Auff, E. Gallbladder dysfunction induced by botulinum A toxin. Lancet. 1993;342:811-812.Google Scholar
56. Girlanda, P, Vita, G, Nicolosi, C, Milone, S, Messina, C. Botulinum toxin therapy: distant effects on neuromuscular transmission and autonomic nervous system. J Neurol Neurosurg Psychiatry. 1992;55:844-845.Google Scholar
57. MacKenzie, I, Burnstock, G, Dolly, JO. The effects of purified botulinum neurotoxin type A on cholinergic, adrenergic and non-adrenergic, atropine-resistant autonomic neuromuscular transmission. Neuroscience. 1982;7:997-1006.Google Scholar
58. Nigam, PK, Nigam, A. Botulinum toxin. Indian J Dermatol. 2010;55:8-14.Google Scholar
59. Schnider, P, Berger, T, Schmied, M, Fertl, L, Auff, E. Increased residual urine volume after local injection of botulinum A toxin. Nervenarzt. 1995;66:465-467.Google Scholar
60. Shaw, L, Rodgers, H. Botulinum toxin type A for upper limb spasticity after stroke. Expert Rev Neurother. 2009;9:1713-1725.Google Scholar
61. Wiegand, H, Erdmann, G, Wellhöner, HH. 125I-labelled botulinum A neurotoxin: pharmacokinetics in cats after intramuscular injection. Naunyn Schmiedebergs Arch Pharmacol. 1976;292:161-165.Google Scholar
62. Matak, I, Bach-Rojecky, L, Filipović, B, Lacković, Z. Behavioral and immunohistochemical evidence for central antinociceptive activity of botulinum toxin A. Neuroscience. 2011;186:201-207.Google Scholar
63. Matak, I, Riederer, P, Lacković, Z. Botulinum toxin’s axonal transport from periphery to the spinal cord. Neurochem Int. 2012;61:236-239.Google Scholar
64. Restani, L, Giribaldi, F, Manich, M, et al. Botulinum neurotoxins A and E undergo retrograde axonal transport in primary motor neurons. PLoS Pathog. 2012;8:e1003087.Google Scholar
65. Koman, LA, Mooney, JF, Smith, BP, Walker, F, Leon, JM. Botulinum toxin type A neuromuscular blockade in the treatment of lower extremity spasticity in cerebral palsy: a randomized, double-blind, placebo-controlled trial. BOTOX Study Group. J Pediatr Orthop. 2000;20:108-115.Google Scholar
66. Phadke, CP, Ismail, F, Boulias, C. Assessing the neurophysiological effects of botulinum toxin treatment for adults with focal limb spasticity: a systematic review. Disabil Rehab. 2011.Google Scholar
67. Marchand-Pauvert, V, Aymard, C, Giboin, LS, Dominici, F, Rossi, A, Mazzocchio, R. Beyond muscular effects: depression of spinal recurrent inhibition after botulinum neurotoxin A. J Physiol. 2013;591:1017-1029.CrossRefGoogle ScholarPubMed
68. Phadke, C, On, A, Kirazli, Y, Ismail, F, Boulias, C. Intrafusal effects of botulinum toxin injections for spasticity: revisiting a previous paper. Neurosci Letters. 2013;Accepted manuscript in press.Google Scholar
69. Borodic, GE, Ferrante, R, Pearce, LB, Smith, K. Histologic assessment of dose-related diffusion and muscle fiber response after therapeutic botulinum A toxin injections. Mov Disord. 1994;9:31-39.Google Scholar
70. Brodsky, MA, Swope, DM, Grimes, D. Diffusion of botulinum toxins. Tremor Other Hyperkinet Mov (N Y). 2012;2.Google Scholar
71. Benecke, R. Clinical relevance of botulinum toxin immunogenicity. BioDrugs. 2012;26:e1-e9.CrossRefGoogle ScholarPubMed
72. Walker, HW, Lee, MY, Bahroo, LB, Hedera, P, Charles, D. Botulinum Toxin Injection Techniques for the Management of Adult Spasticity. PM & R: the journal of injury, function, and rehabilitation. Apr 2015;7(4):417-427.Google Scholar
73. Truong, D, Brodsky, M, Lew, M, et al. Long-term efficacy and safety of botulinum toxin type A (Dysport) in cervical dystonia. Parkinsonism Relat Disord. 2010;16:316-323.Google Scholar
74. Anderson, TJ, Rivest, J, Stell, R, et al. Botulinum toxin treatment of spasmodic torticollis. J R Soc Med. 1992;85:524-529.Google Scholar
75. Zuber, M, Sebald, M, Bathien, N, de Recondo, J, Rondot, P. Botulinum antibodies in dystonic patients treated with type A botulinum toxin: frequency and significance. Neurology. 1993;43:1715-1718.Google Scholar
76. Canada DMRF. Botulinum Toxin Injections. http://www.dystoniacanada.org/about-dystonia/treatments/botulinum-injections. Accessed 30th March, 2015.Google Scholar
77. Canada DMRF. New XEOMIN® – Available in Canada. http://www.dystoniacanada.org/news/research/new-xeomin%C2%AE-%E2%80%93-available-canada. Accessed 30th March, 2015.Google Scholar
Figure 0

Figure 1 MeSH terms and key words combined with MeSH terms botulinum toxins, type A and muscle spasticity.

Figure 1

Figure 2 Categories of adverse events as a percentage of total adverse events with onabotulinumtoxinA reported to Health Canada. (Note: Data from incobotulinumtoxinA is not reported here because of insufficient AE data to allow comparison with onabotulinumtoxinA.)

Figure 2

Figure 3 PRISMA 2009 Flow Diagram From: Moher D, Liberati A, Tetzlaff J, Altman DG, The PRISMA Group (2009). Preferred Reporting Items for Systematic Reviews: The PRISMA Statement. PLoS Med 6(6): e1000097. doi:10.1371/journal.pmed1000097 For more information, visit www.prisma-statement.org

Figure 3

Table 1 Adverse events in studies reporting use of onabotulinumtoxinA

Figure 4

Table 2 Adverse events in studies reporting use of abobotulinumtoxinA

Figure 5

Table 3 Adverse events in studies reporting use of incobotulinumtoxinA