Summary of medicine characteristics - DYSPORT 500 UNITS POWDER FOR SOLUTION FOR INJECTION
Dysport
500 units
Powder for solution for injection
2 QUALITATIVE AND QUANTITATIVE COMPOSITION
Clostridium botulinum type A toxin-haemagglutinin complex 500 units.
For a full list of excipients, see section 6.1.
3 PHARMACEUTICAL FORM
3 PHARMACEUTICAL FORMPowder for solution for injection
4 CLINICAL PARTICULARS
4.1 Therapeutic indications
Dysport is indicated for symptomatic treatment of focal spasticity of:
– Upper limbs in adults
– Lower limbs in adults affecting the ankle joint due to stroke or traumatic brain injury (TBI)
– Dynamic equinus foot deformity in ambulant paediatric cerebral palsy patients, two years of age or older
– Upper limbs in paediatric cerebral palsy patients, two years of age or older.
Dysport is indicated in adults for symptomatic treatment of:
– Spasmodic torticollis
– Blepharospasm
– Hemifacial spasm
– Severe primary hyperhidrosis of the axillae, which does not respond to topical treatment with antiperspirants or antihidrotics.
4.2 Posology and method of administration
The units of Dysport are specific to the preparation and are not interchangeable with other preparations of botulinum toxin.
Dysport should only be administered by an appropriately qualified healthcare practitioner with expertise in the treatment of the relevant indication and the use of the required equipment, in accordance with national guidelines.
For instructions on reconstitution of the powder for solution for injection, handling and disposal of vials please refer to section 6.6.
Focal spasticity in adults
Upper limb:
Posology
Dosing in initial and sequential treatment sessions should be tailored to the individual based on the size, number and location of muscles involved, severity of spasticity, the presence of local muscle weakness, the patient's response to previous treatment, and/or adverse event history with Dysport. In clinical trials, doses of 500 units and 1000 units were divided among selected muscles at a given treatment session as shown below.
No more than 1 ml should generally be administered at any single injection site. The total dose should not exceed 1000 units at a given treatment session.
Muscles Injected | Recommended Dose Dysport (U) |
Flexor carpi radialis (FCR) | 100–200U |
Flexor carpi ulnaris (FCU) | 100–200U |
Flexor digitorum profundus (FDP) | 100–200U |
Flexor digitorum superficialis (FDS) | 100–200U |
Flexor pollicis longus | 100–200U |
Adductor pollicis | 25–50U |
Brachialis | 200–400U |
Brachioradialis | 100–200U |
Biceps brachii (BB) | 200–400U |
Pronator teres | 100–200U |
Triceps brachii (long head) | 150–300U |
Pectoralis major | 150–300U |
Subscapularis | 150–300U |
Latissimus dorsi | 150–300U |
Although actual location of the injection sites can be determined by palpation, the use of injection guiding technique, e.g. electromyography, electrical stimulation or ultrasound is recommended to target the injection sites.
Clinical improvement may be expected one week after injection and may last up to 20 weeks. Injections may be repeated every 12 – 16 weeks or as required to maintain response, but not more frequently than every 12 weeks. The degree and pattern of muscle spasticity at the time of re-injection may necessitate alterations in the dose of Dysport and muscles to be injected.
Lower limb spasticity affecting the ankle joint:
Posology
In clinical trials, doses of 1000U and 1500U were divided among selected muscles. The exact dosage in initial and sequential treatment sessions should be tailored to the individual based on the size and number of muscles involved, the severity of the spasticity, also taking into account the presence of local muscle weakness and the patient’s response to previous treatment. However, the total dose should not exceed 1500U.
No more than 1 ml should generally be administered at any single injection site.
Muscle | Recommended Dose Dysport (U) | Number of injection sites per muscle |
Primary target muscle | ||
Soleus muscle | 300 –550U | 2 – 4 |
Gastrocnemius: Medial head Lateral head | ||
100 – 450U | 1 – 3 | |
100 – 450U | 1 – 3 | |
Distal muscles | ||
Tibialis posterior | 100 – 250U | 1 – 3 |
Flexor digitorum longus | 50 –200U | 1 – 2 |
Flexor digitorum brevis | 50 –200U | 1 – 2 |
Flexor hallucis longus | 50 –200U | 1 – 2 |
Flexor hallucis brevis | 50 – 100U | 1 – 2 |
The degree and pattern of muscle spasticity at the time of re-injection may necessitate alterations in the dose of Dysport and muscles to be injected.
Although actual location of the injection sites can be determined by palpation, the use of injection guiding techniques, e.g. electromyography, electrical stimulation or ultrasound are recommended to help accurately target the injection sites.
Repeat Dysport treatment should be administered every 12 to 16 weeks, or longer as necessary, based on return of clinical symptoms but no sooner than 12 weeks after the previous injection.
Upper and Lower limbs:
If treatment is required in the upper and lower limbs during the same treatment session, the dose of Dysport to be injected in each limb should be tailored to the individual’s need according to the relevant posology and without exceeding a total dose of 1500U.
Elderly patients (> 65 years): Clinical experience has not identified differences in response between the elderly and younger adult patients. In general, elderly patients should be observed to evaluate their tolerability of Dysport, due to the greater frequency of concomitant disease and other drug therapy.
Method of administration
When treating focal spasticity affecting the upper and lower limbs in adults, Dysport is reconstituted with sodium chloride injection B.P. (0.9 % w/v) to yield a solution containing either 100 units per ml, 200 units per ml or 500 units per ml of Dysport (see section 6.6).
Dysport is administered by intramuscular injection into the muscles as described above.
Focal spasticity in paediatric cerebral palsy patients, two years of age or older
Limb | Maximum total dose of Dysport to be administered per treatment session | Minimum time before retreatment should be considered |
Single lower limb Both lower limbs | 15 units/kg or 1000 units* 30 units/kg or 1000 units* | No sooner than 12 weeks |
Single upper limb Both upper limbs | 16 units/kg or 640 units* 21 units/kg or 840 units | No sooner than 16 weeks |
Upper and lower limbs | 30 units/kg or 1000 units | No sooner than 12–16 weeks |
whichever is lower
Please see below for full posology and method of administration by treatment indication.
Dynamic equinus foot deformity due to focal spasticity in ambulant paediatric cerebral palsy patients, two years of age or older:
Posology
Dosing in initial and sequential treatment sessions should be tailored to the individual based on the size, number and location of muscles involved, severity of spasticity, the presence of local muscle weakness, the patient’s response to previous treatment, and/or adverse event history with botulinum toxins. For treatment initiation, consideration should be given to start with a lower dose.
The maximum total dose of Dysport administered per treatment session must not exceed 15 units/kg for unilateral lower limb injections or 30 units/kg for bilateral injections. In addition, the total Dysport dose per treatment session must not exceed 1000 units or 30 units/kg, whichever is lower. The total dose administered should be divided between the affected spastic muscles of the lower limb(s). When possible, the dose should be distributed across more than 1 injection site in any single muscle.
No more than 0.5 ml of Dysport should be administered in any single injection site. See below table for recommended dosing:
Muscle | Recommended Dose Range per muscle per leg (U/kg Body Weight) | Number of injection sites per muscle |
Gastrocnemius | 5 to 15 U/kg | Up to 4 |
Soleus | 4 to 6 U/kg | Up to 2 |
Tibialis posterior | 3 to 5 U/kg | Up to 2 |
Total dose | Up to 15 U/kg in a single lower limb or 30 U/kg if both lower limbs injected and not exceeding 1000 U Note: For concomitant treatment of upper and lower limbs, the total dose should not exceed 30 U/kg or 1000 U |
whichever is lower
Although actual location of the injection sites can be determined by palpation, the use of injection guiding technique, e.g. electromyography, electrical stimulation or ultrasound is recommended to target the injection sites.
Repeat Dysport treatment should be administered when the effect of a previous injection has diminished, but no sooner than 12 weeks after the previous injection. A majority of patients in clinical studies were re-treated between 16 – 22 weeks;
however, some patients had a longer duration of response, i.e. 28 weeks. The degree and pattern of muscle spasticity at the time of re-injection may necessitate alterations in the dose of Dysport and muscles to be injected.
Clinical improvement may be expected within two weeks after injection.
Method of administration
When treating lower limb spasticity associated with cerebral palsy in children, Dysport is reconstituted with sodium chloride injection B.P. (0.9 % w/v) (see also section 6.6) and is administered by intramuscular injection as detailed above.
Focal spasticity of upper limbs in paediatric cerebral palsy patients, two years of age or older:
Dosing in initial and sequential treatment sessions should be tailored to the individual based on the size, number and location of muscles involved, severity of spasticity, the presence of local muscle weakness, the patient's response to previous treatment, and/or adverse event history with botulinum toxins. For treatment initiation, consideration should be given to start with a lower dose.
The maximum dose of Dysport administered per treatment session for unilateral upper limb injections must not exceed 16 U/kg or 640 U whichever is lower. When injecting bilaterally, the maximum Dysport dose per treatment session must not exceed 21 U/kg or 840 U, whichever is lower.
The total dose administered should be divided between the affected spastic muscles of the upper limb(s). No more than 0.5 ml of Dysport should be administered in any single injection site. See table below for recommended dosing:
Dysport Dosing by Muscle for Paediatric Upper Limb Spasticity
Muscle | Recommended Dose Range per muscle per upper limb (U/kg Body Weight) | Number of injection sites per muscle |
Brachialis | 3 to 6 U/kg | Up to 2 |
Brachioradialis | 1.5 to 3 U/kg | 1 |
Biceps brachii | 3 to 6 U/kg | Up to 2 |
Pronator teres | 1 to 2 U/kg | 1 |
Pronator quadratus | 0.5 to 1 U/kg | 1 |
Flexor carpi radialis | 2 to 4 U/kg | Up to 2 |
Flexor carpi ulnaris | 1.5 to 3 U/kg | 1 |
Flexor digitorum profundus | 1 to 2 U/kg | 1 |
Flexor digitorum superficialis | 1.5 to 3 U/kg | Up to 4 |
Flexor pollicis longus | 1 to 2 U/kg | 1 |
Flexor pollicis brevis/ opponens pollicis | 0.5 to 1 U/kg | 1 |
Adductor pollicis | 0.5 to 1 U/kg | 1 |
Pectoralis major | 2.5 to 5 U/kg | Up to 2 |
Total dose | Up to 16 U/kg or 640 U* in a single upper limb (and not exceeding 21 U/kg or 840 U* if both upper limbs injected) Note: For concomitant treatment of upper and lower limbs the total dose should not exceed 30 U/kg or 1000 U |
whichever is lower
Although actual location of the injection sites can be determined by palpation the use of injection guiding technique, e.g. electromyography, electrical stimulation or ultrasound is recommended to target the injection sites.
Repeat Dysport treatment should be administered when the effect of a previous injection has diminished, but no sooner than 16 weeks after the previous injection. A majority of patients in the clinical study were retreated between 16–28 weeks;
however, some patients had a longer duration of response, i.e. 34 weeks or more. The degree and pattern of muscle spasticity at the time of re-injection may necessitate alterations in the dose of Dysport and muscles to be injected.
Method of administration
When treating upper limb spasticity associated with cerebral palsy in children, Dysport is reconstituted with sodium chloride injection (0.9% w/v) (see section 6.6) and is administered by intramuscular injection as detailed above.
Focal spasticity of upper and lower limbs in paediatric cerebral palsy patients, two years of age or older:
Posology
When treating combined upper and lower spasticity in children aged 2 years or older refer to the posology section for the individual indications above. The dose of Dysport to be injected for concomitant treatment should not exceed a total dose per treatment session of 30 U/kg or 1000 U, whichever is lower.
Retreatment of the upper and lower limbs combined should be considered no sooner than a 12 to 16-week window after the previous treatment session. The optimal time to retreatment should be selected based on individuals progress and response to treatment.
Method of administration
When treating combined upper and lower spasticity associated with cerebral palsy in children refer to the method of administration section for the individual indications above.
Posology
The doses recommended for torticollis are applicable to adults of all ages, provided the adults are of normal weight with no evidence of reduced neck muscle mass. A lower dose may be appropriate if the patient is markedly underweight or in the elderly, where reduced muscle mass may exist.
The initial recommended dose for the treatment of spasmodic torticollis is 500 units per patient given as a divided dose and administered into the two or three most active neck muscles.
For rotational torticollis distribute the 500 units by administering 350 units into the splenius capitis muscle, ipsilateral to the direction of the chin/head rotation and 150 units into the sternomastoid muscle, contralateral to the rotation.
For laterocollis, distribute the 500 units by administering 350 units into the ipsilateral splenius capitis muscle and 150 units into the ipsilateral sternomastoid muscle. In cases associated with shoulder elevation the ipsilateral trapezoid or levator scapulae muscles may also require treatment, according to visible hypertrophy of the muscle or electromyographic (EMG) findings. Where injections of three muscles are required, distribute the 500 units as follows, 300 units splenius capitis, 100 units sternomastoid and 100 units to the third muscle.
For retrocollis distribute the 500 units by administering 250 units into each of the splenius capitis muscles. Bilateral splenii injections may increase the risk of neck muscle weakness.
All other forms of torticollis are highly dependent on specialist knowledge and EMG to identify and treat the most active muscles. EMG should be used diagnostically for all complex forms of torticollis, for reassessment after unsuccessful injections in non-complex cases, and for guiding injections into deep muscles or in overweight patients with poorly palpable neck muscles.
On subsequent administration, the doses may be adjusted according to the clinical response and side effects observed. Doses within the range of 250 – 1000 units are recommended, although the higher doses may be accompanied by an increase in side effects, particularly dysphagia. The maximum dose administered must not exceed 1000 units.
The relief of symptoms of torticollis may be expected within a week after the injection.
Injections may be repeated approximately every 16 weeks or as required to maintain a response, but not more frequently than every 12 weeks.
Children: The safety and effectiveness of Dysport in the treatment of spasmodic torticollis in children have not been demonstrated.
Method of administration
When treating spasmodic torticollis, Dysport is reconstituted with sodium chloride injection B.P. (0.9 % w/v) to yield a solution containing 500 units per ml of Dysport (see section 6.6).
Dysport is administered by intramuscular injection as described above.
Posology
In a dose ranging clinical trial on the use of Dysport for the treatment of benign essential blepharospasm, a dose of 40 units per eye was significantly effective. Doses of 80 units and 120 units per eye resulted in a longer duration of effect. However, the incidence of local adverse events, specifically ptosis, was dose related. In the treatment of blepharospasm and hemifacial spasm, the maximum dose used must not exceed a total dose of 120 units per eye.
An injection of 10 units (0.05 ml) medially and 10 units (0.05 ml) laterally should be made into the junction between the preseptal and orbital parts of both the upper (3 and 4) and lower orbicularis oculi muscles (5 and 6) of each eye. In order to reduce the risk of ptosis, injections near the levator palpebrae superioris should be avoided.
For injections into the upper lid the needle should be directed away from its centre to avoid the levator muscle. A diagram to aid placement of these injections is provided above. The relief of symptoms may be expected to begin within two to four days with maximal effect within two weeks.
Injections should be repeated approximately every twelve weeks or as required to prevent recurrence of symptoms but not more frequently than every twelve weeks.
On such subsequent administrations, if the response from the initial treatment is considered insufficient, the dose per eye may need to be increased to:
– 60 units: 10 units (0.05 ml) medially and 20 units (0.1 ml) laterally;
– 80 units: 20 units (0.1 ml) medially and 20 units (0.1 ml) laterally; or
– up to 120 units: 20 units (0.1 ml) medially and 40 units (0.2 ml) laterally, above and below each eye in the manner previously described. Additional sites in the frontalis muscle above the brow (1 and 2) may also be injected if spasms here interfere with vision.
In cases of unilateral blepharospasm the injections should be confined to the affected eye. Patients with hemifacial spasm should be treated as for unilateral blepharospasm. The doses recommended are applicable to adults of all ages including the elderly.
Children: The safety and effectiveness of Dysport in the treatment of blepharospasm and hemifacial spasm in children have not been demonstrated.
Method of administration
When treating blepharospasm and hemifacial spasm, Dysport is reconstituted with sodium chloride injection B.P. (0.9 % w/v) to yield a solution containing 200 units per ml of Dysport (see section 6.6).
Dysport is administered by subcutaneous injection medially and laterally into the junction between the preseptal and orbital parts of both the upper and lower orbicularis oculi muscles of the eyes as described above.
Axillary hyperhidrosis
The recommended initial dosage is 100 units per axilla. If the desired effect is not attained, up to 200 units per axilla can be administered for subsequent injections. The maximum dose administered should not exceed 200 units per axilla.
The area to be injected may be determined beforehand using the iodine-starch test. Both axillae should be cleaned and disinfected. Intradermal injections at ten sites, each site receiving 10 units, i.e., to deliver 100 units per axilla, are then administered. The maximum effect should be seen by week two after injection. In many cases, the recommended dose will provide adequate suppression of sweat secretion for approximately 48 weeks. The time point for further applications should be determined on an individual basis according to clinical need. Injections should not be repeated more frequently than every 12 weeks. There is some evidence for a cumulative effect of repeated doses so the time of each treatment for a given patient should be assessed individually.
Children: The safety and effectiveness of Dysport in the treatment of axillary hyperhidrosis in children has not been demonstrated.
Method of administration:
When treating axillary hyperhidrosis, Dysport is reconstituted with sodium chloride solution B.P. (0.9 % w/v) to yield a solution containing 200 units per ml of Dysport (see section 6.6).
Dysport is administered by intradermal injection as described above.
4.3 Contraindications
Known hypersensitivity to the active substance or to any of the excipients listed in section 6.1.
4.4 Special warnings and precautions for use
Side effects related to spread of toxin distant from the site of administration have been reported (see section 4.8) which, in some cases, was associated with dysphagia, pneumonia and/or significant debility resulting, very rarely, in death. Patients treated with therapeutic doses may present with excessive muscle weakness. The risk of occurrence of such undesirable effects may be reduced by using the lowest effective possible dose and by not exceeding the maximum recommended dose.
Dysport should only be used with caution and under close medical supervision in patients with subclinical or clinical evidence of marked defective neuromuscular transmission (e.g. myasthenia gravis). Such patients may have an increased sensitivity to agents such as Dysport, which may result in excessive muscle weakness with therapeutic doses. Patients with underlying neurological disorders are at increased risk of this side effect.
Caution should be exercised when treating adult patients especially the elderly, with focal spasticity affecting the lower limbs, who may be at increased risk of fall. In placebo-controlled clinical studies, where patients were treated for lower limb spasticity, 6.3% and 3.7% of patients experienced a fall in the Dysport and placebo groups, respectively.
Dry eye has been reported with the use of Dysport in the treatment of blepharospasm and hemifacial spasm (see section 4.8). Reduced tear production, reduced blinking, and corneal disorders, may occur with the use of botulinum toxins, including Dysport.
Very rare cases of death, occasionally in the context of dysphagia, pneumopathy (including but not limited to dyspnoea, respiratory failure, respiratory arrest) and/or in patients with significant asthenia have been reported following treatment with botulinum toxin A or B. Patients with disorders resulting in defective neuromuscular transmission, difficulty in swallowing or breathing are more at risk of experiencing these effects. In these patients, treatment must be administered under the control of a specialist and only if the benefit of treatment outweighs the risk.
Dysport should be administered with caution to patients with pre-existing swallowing or breathing problems as these can worsen following the distribution of the effect of toxin into the relevant muscles. Aspiration has occurred in rare cases and is a risk when treating patients who have a chronic respiratory disorder.
The recommended posology and frequency of administration for Dysport must not be exceeded (see section 4.2).
Patients and their care-givers must be warned of the necessity to seek immediate medical treatment in case of swallowing, speech or respiratory problems.
Dysport should not be used to treat spasticity in patients who have developed a fixed contracture.
As with any intramuscular injection, Dysport should only be used where strictly necessary in patients with prolonged bleeding times, infection or inflammation at the proposed site(s) of injection.
Caution should be taken when Dysport is used where the targeted muscle shows excessive weakness or atrophy.
Dysport should only be used to treat a single patient, during a single session. Specific precautions must be taken during the preparation and administration of the product (see section 4.2) and for the inactivation and disposal of any unused reconstituted solution (see section 6.6).
Antibody formation to botulinum toxin has been noted rarely in patients receiving Dysport. Clinically, neutralising antibodies might be suspected by a substantial deterioration in response to therapy and/or the need for consistent use of increased doses.
Careful consideration should be given before the injection of patients who have experienced a previous allergic reaction to a product containing botulinum toxin type A. The risk of a further allergic reaction must be considered in relation to the benefit of treatment.
Paediatric use
For the treatment of spasticity associated with cerebral palsy in children, Dysport should only be used in children of 2 years of age or over. Post-marketing reports of possible distant spread of toxin have been very rarely reported in paediatric patients with comorbidities, predominantly with cerebral palsy. In general, the dose used in these cases was in excess of that recommended (see section 4.8).
There have been rare spontaneous reports of death sometimes associated with aspiration pneumonia in children with severe cerebral palsy after treatment with botulinum toxin, including following off-label use (e.g. neck area). Extreme caution should be exercised when treating paediatric patients who have significant neurologic debility, dysphagia, or have a recent history of aspiration pneumonia or lung disease.
Treatment in patients with poor underlying health status should be administered only if the potential benefit to the individual patient is considered to outweigh the risks.
Traceability
In order to improve the traceability of biological medicinal products, the name and the batch number of the administered product should be clearly recorded.
4.5. Interaction with other medicinal products and other forms of interaction
The effects of botulinum toxin may be potentiated by drugs interfering either directly or indirectly with neuromuscular function (e.g. aminoglycosides, curare-like nondepolarising blockers, muscle relaxants) and such drugs should be used with caution in patients treated with botulinum toxin due to the potential for undesirable effects.
4.6 Fertility, pregnancy and lactationPregnancy:
There are limited data from the use of Clostridium botulinum type A toxinhaemagglutinin complex in pregnant women. Studies in animals have shown reproductive toxicity at high doses causing maternal toxicity (see section 5.3).
Dysport should be used during pregnancy only if the benefit justifies any potential risk to the foetus. Caution should be exercised when prescribing to pregnant women.
It is not known whether Clostridium botulinum type A toxin-haemagglutinin complex is excreted in human milk. The excretion of Clostridium botulinum type A toxinhaemagglutinin complex in milk has not been studied in animals. The use of Clostridium botulinum type A toxin-haemagglutinin complex during lactation cannot be recommended.
Studies in male and female rats have shown effects on fertility (see section 5.3).
4.7 Effects on ability to drive and use machines
There is a potential risk of muscle weakness or visual disturbances which, if experienced, may temporarily impair the ability to drive or operate machinery.
4.8 Undesirable effectsGeneral
Side effects related to spread of toxin distant from the site of administration have been reported, such as dry mouth, exaggerated muscle weakness, dysphagia, aspiration/aspiration pneumonia, with fatal outcome in some very rare cases (see section 4.4). Hypersensitivity reactions have also been reported post-marketing.
The frequency of adverse reactions reported in placebo-controlled trials after a single administration is defined as follows:
Very common (>1/10); common (>1/100 to <1/10); uncommon (>1/1,000 to <1/100); rare (>1/10,000 to < 1/1,000); very rare (<1/10,000); not known (cannot be estimated from the available data).
The following adverse reactions were seen in patients treated across a variety of indications including blepharospasm, hemifacial spasm, torticollis, spasticity associated with either cerebral palsy or stroke/TBI and axillary hyperhidrosis:
System Organ Class | Frequency | Adverse Drug Reaction |
Nervous system disorders | Rare | Neuralgic amyotrophy |
Skin and subcutaneous tissue disorders | Uncommon | Pruritus |
Rare | Rash | |
General disorders and administration site conditions | Common | Asthenia, fatigue, influenza like illness and injection site reactions (e.g. pain, bruising, pruritus, oedema) |
In addition, the following adverse reactions specific to individual indications were reported:
Focal spasticity affecting the upper limbs in adults
System Organ Class | Frequency | Adverse Drug Reaction |
Gastrointestinal disorders | Uncommon | Dysphagia* |
Musculoskeletal and connective tissue disorders | Common | Muscular weakness, musculoskeletal pain, pain in the extremity |
*The frequency for Dysphagia was derived from pooled data from open-label studies. Dysphagia was not observed in the double-blind studies in the Adult Upper Limb (AUL) indication.
Focal spasticity affecting the lower limbs in adults
System Organ Class | Frequency | Adverse Drug Reaction |
Gastrointestinal disorders | Common | Dysphagia |
Musculoskeletal and connective tissue disorders | Common | Muscular weakness, myalgia |
General disorders and administration site conditions | Common | Asthenia, fatigue, influenza-like illness, injection site reactions (pain, bruising, rash, pruritus) |
Injury, poisoning and procedural complications | Common | Fall |
Dynamic equinus foot deformity due to focal spasticity in ambulant paediatric cerebral palsy patients, two years of age or older
System Organ Class | Frequency | Adverse Drug Reaction |
Musculoskeletal and connective tissue disorders | Common | Myalgia, muscular weakness |
Renal and urinary disorders | Common | Urinary incontinence |
General disorders and administration site conditions | Common | Influenza-like illness, injection site reaction (e.g. pain, erythema, bruising etc.), gait disturbance, fatigue |
Uncommon | Asthenia | |
Injury, poisoning and procedural complications | Common | Fall |
Focal spasticity of upper limbs in paediatric cerebral palsy patients, two years of age or older
System Organ Class | Frequency | Adverse Drug Reaction |
Musculoskeletal and connective tissue disorders | Common | Muscular weakness, Pain in extremity |
Uncommon | Myalgia | |
General disorders and administration site conditions | Common | Influenza-like illness, Asthenia, Fatigue, Injection site bruising |
Uncommon | Injection site eczema, Injection site pain, Injection site rash, Injection site swelling | |
Skin and subcutaneous tissue disorders | Common | Rash |
Focal spasticity of upper and lower limbs in paediatric cerebral palsy patients, two years of age or older
When treating upper and lower limbs concomitantly with Dysport at a total dose of up to 30 U/kg or 1000 U whichever is lower, there are no safety findings in addition to those expected from treating either upper limb or lower limb muscles alone.
Spasmodic torticollis
System Organ Class | Frequency | Adverse Drug Reaction |
Nervous system disorders | Common | Headache, dizziness, facial paresis |
Eye disorders | Common | Vision blurred, visual acuity reduced |
Uncommon | Diplopia, ptosis | |
Respiratory, thoracic and mediastinal disorders | Common | Dysphonia, dyspnoea |
Rare | Aspiration | |
Gastrointestinal disorders | Very common | Dysphagia, dry mouth |
Uncommon | Nausea | |
Musculoskeletal and connective tissue disorders | Very common | Muscle weakness |
Common | Neck pain, musculoskeletal pain, myalgia, pain in extremity, musculoskeletal stiffness | |
Uncommon | Muscle atrophy, jaw disorder |
Dysphagia appeared to be dose related and occurred most frequently following injection into the sternomastoid muscle. A soft diet may be required until symptoms resolve. These side effects may be expected to resolve within two to four weeks.
Blepharospasm and hemifacial spasm
System Organ Class | Frequency | Adverse Drug Reaction |
Nervous system disorders | Common | Facial paresis |
Uncommon | VIIth nerve paralysis | |
Eye disorders | Very common | Ptosis |
Common | Diplopia, dry eye, lacrimation increased | |
Rare | Ophthalmoplegia | |
Skin and subcutaneous tissue disorders | Common | Eyelid oedema |
Rare | Entropion |
Side effects may occur due to deep or misplaced injections of Dysport temporarily paralysing other nearby muscle groups.
Axillary hyperhidrosis
System Organ Class | Frequency | Adverse Drug Reaction |
Skin and subcutaneous tissue disorders | Common | Compensatory sweating |
Post-marketing experience
System Organ Class | Frequency | Adverse Drug Reaction |
Immune system disorders | Not known | Hypersensitivity |
Nervous system disorders | Not known | Hypoaesthesia |
Musculoskeletal and connective tissue disorders | Not known | Muscle atrophy |
Reporting of suspected adverse reactions
Reporting suspected adverse reactions after authorisation of the medicinal product is important. It allows continued monitoring of the benefit/risk balance of the medicinal product. Healthcare professionals are asked to report any suspected adverse reactions via the Yellow Card Scheme. Website: www.mhra.gov.uk/yellowcard or search for MHRA Yellow Card in the Google Play or Apple App Store.
4.9 Overdose
Excessive doses may produce distant and profound neuromuscular paralysis. Overdose could lead to an increased risk of the neurotoxin entering the bloodstream and may cause complications associated with the effects of oral botulinum poisoning (e.g. dysphagia and dysphonia). Respiratory support may be required where excessive doses cause paralysis of respiratory muscles. General supportive care is advised. In the event of overdose, the patient should be medically monitored for signs and/or symptoms of excessive muscle weakness or muscle paralysis. Symptomatic treatment should be instigated if necessary.
Symptoms of overdose may not present immediately following injection. Should accidental injection or oral ingestion occur, the patient should be medically supervised for several weeks for signs and/or symptoms of excessive muscle weakness or muscle paralysis.
5 PHARMACOLOGICAL PROPERTIES
5 PHARMACOLOGICAL PROPERTIES5.1 Pharmacodynamic properties
Pharmacotherapeutic group: Other muscle relaxants, peripherally acting agents.
ATC code: M03AX01
Clostridium botulinum type A toxin-haemagglutinin complex blocks peripheral cholinergic transmission at the neuromuscular junction by a presynaptic action at a site proximal to the release of acetylcholine. The toxin acts within the nerve ending to antagonise those events that are triggered by Ca2+ which culminate in transmitter release. It does not affect postganglionic cholinergic transmission or postganglionic sympathetic transmission.
The action of toxin involves an initial binding step whereby the toxin attaches rapidly and avidly to the presynaptic nerve membrane. Secondly, there is an internalisation step in which toxin crosses the presynaptic membrane, without causing onset of paralysis. Finally, the toxin inhibits the release of acetylcholine by disrupting the Ca2+ mediated acetylcholine release mechanism, thereby diminishing the endplate potential and causing paralysis.
Recovery of impulse transmission occurs gradually as new nerve terminals sprout and contact is made with the postsynaptic motor endplate, a process which takes 6 – 8 weeks in the experimental animal.
Focal spasticity in adults
Upper limb:
The efficacy and safety of Dysport for the treatment of upper limb spasticity was evaluated in a randomised, multi-centre, double-blind, placebo-controlled study that included 238 patients (159 Dysport and 79 placebo) with upper limb spasticity who were at least 6 months post-stroke (90%) or post-traumatic brain injury (10%). The primary targeted muscle group (PTMG) was the extrinsic finger flexors (56%), followed by the elbow (28%) and wrist flexors (16%).
The primary efficacy variable was the PTMG muscle tone at week 4, as measured by the Modified Ashworth Scale (MAS), a 5 point scale ranging from 0 (no increase in muscle tone) to 4 (affected in part[s] rigid in flexion or extension) and the first secondary endpoint was the Physician Global Assessment (PGA) of response to treatment (a 9 point scale ranging from –4 [markedly worse], through 0 [no change], to +4 [markedly improved]). The main results achieved at Week 4 and Week 12 are shown below:
Week 4 | Week 12 | |||||
Placebo (N=79) | Dysport (500U) (N=80) | Dysport (1000U) (N=79) | Placebo (N=79) | Dysport (500U) (N=80) | Dysport (1000U) (N=79) | |
LS Mean Change from Baseline in PTMG Muscle Tone on the MAS | –0.3 | –1.2 | –1.4 | –0.1 n=75 | –0.7** n=76 | –0.8** n=76 |
LS Mean PGA of Response to Treatment | 0.7 | 1.4* | 1.8 | 0.4 n=75 | 0.5 n=76 | 1.0* n=76 |
LS Mean Change from Baseline in Wrist Flexor Muscle Tone on the MAS | –0.3 n=54 | –1.4 n=57 | –1.6** n=58 | –0.3 n=52 | –0.7* n=54 | –0.9* n=56 |
LS Mean Change from Baseline in Finger Flexor Muscle Tone on the MAS | –0.3 n=70 | –0.9* n=66 | –1.2** n=73 | –0.1 n=67 | –0.4* n=62 | –0.6* n=70 |
LS Mean Change from Baseline in Elbow Flexor Muscle Tone on the MAS | –0.3 n=56 | –1.0* n=61 | –1.2** n=48 | –0.3 n=53 | –0.7* n=58 | –0.8* n=46 |
Mean Change from Baseline in Shoulder Extensors Muscle Tone on the MAS (1) | –0.4 n=12 | –0.6 n=7 | –0.7 n=6 | 0.0 n=12 | –0.9 n=7 | 0.0 n=6 |
p < 0.05; p < 0.0001; LS = Least Square (1) No statistical tests performed due to low frequency by treatment and placebo groups as there are limited data in patients treated in the shoulder muscles. |
The Principal Target of Treatment (PTT) of the Disability Assessment Scale (DAS) was used to investigate the effect of treatment on functional impairment (passive function). Although some improvement in the mean change from baseline at Week 4 in the Dysport groups was observed, it did not reach statistical significance compared to placebo, the proportion of DAS score responders (subjects achieving at least a one grade improvement) for the PTT was significantly higher at the 1000U dose as shown below:
Treatment Group | Week 4 % Responders | Week 12 % Responders |
Dysport 500U | 50.0 n=80 p = 0.13 | 41.3 n=76 p = 0.11 |
Dysport 1000U | 62.0 n=78 p = 0.0018 | 55.7 n=76 p = 0.0004 |
Placebo | 39.2 n=79 | 32.9 n=75 |
Domains included in DAS are hygiene, limb position, dressing and pain.
In addition, statistically significant improvements in spasticity (grade and angle) assessed by the Tardieu scale, in the active range of motion of the fingers, wrist or elbow, and in ease of applying a splint by the subject were observed, especially at the 1000U dose. However, there was no effect of treatment shown on the active function, as assessed by the Modified Frenchay Score, and on quality of life EQ5D or SF-36 questionnaires.
Lower limb affecting the ankle joint:
The efficacy and safety of Dysport for the treatment of lower limb spasticity was evaluated in a pivotal randomised, multi-centre, double-blind, placebo-controlled study that included 385 post-stroke and brain injury patients (255 Dysport and 130 placebo-treated subjects) with lower limb spasticity primarily affecting the ankle joint. Two doses of Dysport were evaluated for efficacy; Dysport 1000U (N = 125), Dysport 1500U (N = 128) against Placebo (N =128). The primary target muscle group was the gastrocnemius – soleus complex (GSC). The primary end point was Modified Ashworth Scale (MAS) score assessed at the ankle joint (with the knee extended) at week 4.
Dysport was divided between the GSC and at least one other distal or proximal lower limb muscle according to clinical presentation.
When assessing the primary endpoint, MAS at the ankle with the knee extended (involving all plantar flexors), statistically significant improvement was observed for 1500U. When assessing MAS at the ankle with the knee flexed (involving all plantar flexors except the gastrocnemius), statistically significant improvement was observed for both 1000U and 1500U.
Week 4 | Week 12 | |||||
Placebo (N= 128) | Dysport (1000U) (N=125) | Dysport (1500U) (N=128) | Placebo (N=128) | Dysport (1000U) (N=125) | Dysport (1500U) (N=128) | |
LS Mean Change from Baseline on the MAS (knee extended) | –0.5 | –0.6 | –0.8 | –0.4 | –0.4 | –0.6* |
LS Mean Change from Baseline on the MAS (knee flexed) | –0.4 | –0.7* | –0.8 | –0.3 | –0.5* | –0.6 |
p < 0.05; **p < 0.001; LS = Least Square
Spasticity assessment using the Tardieu Scale (TS) showed that there were statistically significant improvements in spasticity grade at Weeks 4 to 20 in the Dysport 1500U group and at Weeks 4 to 12 in the Dysport 1000U group. In addition it showed statistically significant differences in Angle of Catch at Week 1 and 16, favouring the higher dose of Dysport. Based on post hoc analysis due to nonnormality of PGA data, Dysport treatment was also associated with statistically significant clinical improvement at both doses as measured by the Physician Global Assessment (PGA) Score.
Numerical improvement in ankle dorsiflexion for the higher Dysport dose was seen with the change peaking at 4 weeks post administration. Additional endpoints such as reduction in pain, using walking aids and quality of life measures did not show statistically significant improvement.
On completion of this study, 345 patients entered an open-label extension study in which re-treatment with Dysport 1000U or 1500U was determined by clinical need. This long term follow up study confirmed a prolonged treatment effect on spasticity related outcome measures following repeated injections. Improvements in efficacy parameters (MAS, PGA and TS) seen after 4 weeks of double blind treatment with Dysport in the lower limb were maintained over repeated treatment.
Improvements in 10-m walking speed (comfortable and maximal, with or without shoes) were observed, which increased with successive treatment cycles. No significant improvements in lower limb pain using the SPIN scale, use of walking aids or quality of life measures were observed.
Three Dysport doses were investigated over 1 treatment cycle in a clinical study.
Efficacy was measured by the medians of differences in the Percentage of Normal Activity (PNA) values (derived from the Blepharospasm Disability Scale) between each treatment group and placebo. A dose-dependent improvement in blepharospasm was evident with increasing Dysport dose, with all treatment groups being superior to placebo.
Difference between the median of the changes in PNA values from baseline in the active group and the median of the changes in PNA values from baseline in the placebo group Visit | Dysport 40U (N=30) | Dysport 80U (N=31) | Dysport 120U (N=31) |
Week 4: | 31.2 % | 41.3 % | 48.5 % |
Week 8: | 36.0 % | 48.3 % | 55.0 % |
Week 12: | 36.0 % | 36.3 % | 50.0 % |
Week 16: | 10.5 %[a] | 24.2 % | 31.3 % |
[a] p value > 0.001
For the 40 units, 80 units and 120 units Dysport treatment groups, the medians of the changes from baseline in PNA values were statistically significantly higher compared to those in placebo group at weeks 4, 8, and 12.
A statistically significant difference compared to placebo group was also observed for the 80 units and 120 units Dysport treatment groups at week 16, indicating a greater duration of response at the 80 units and 120 units doses.
The incidence of related Treatment Emergent Adverse Events (TEAEs), specifically ptosis, was higher in the Dysport treatment groups than in the placebo treatment group and was dose-dependent with greater incidence seen at higher Dysport doses. See table below:
Statistic | Placebo (N=26) | Dysport 40U (N=31) | Dysport 80U (N=31) | Dysport 120U (N=31) | |
Patients with related TEAEs | n (%) | 3 (12) | 19 (61) | 23(74) | 26 (84) |
Patients with related eye TEAEs | n (%) | 3 (12) | 16 (52) | 23 (74) | 26 (84) |
Focal spasticity in paediatric cerebral palsy patients, two years of age or older
Dynamic equinus foot deformity due to focal spasticity in ambulant paediatric cerebral palsy patients, two years of age or older
A double-blind, placebo-controlled multicentre study (Study Y-55–52120–141) was conducted in children with dynamic equinus foot deformity due to spasticity in children with cerebral palsy. A total of 235 botulinum toxin naïve or non-naïve patients with a Modified Ashworth Score (MAS) of grade 2 or greater were enrolled to receive Dysport 10 units/kg/leg, Dysport 15 units/kg/leg or placebo. Forty one percent of patients were treated bilaterally resulting in a total Dysport dose of either 20 units/kg or 30 units/kg. The primary efficacy variable was the mean change from baseline in MAS in ankle plantar flexors at Week 4. Secondary efficacy variables were the mean Physicians Global Assessment (PGA) score and Mean Goal Attainment Scaling (GAS) score at Week 4. Patients were followed up for at least 12 weeks post-treatment and up to a maximum of 28 weeks. On completion of this study, patients were offered entry into an open-label extension study (Study Y-55–52120–147).
MAS Change from Baseline at Week 4 and Week 12, PGA and GAS at Week 4 and Week 12 (ITT Population)
Parameter | Placebo (N=77) | Dysport | |
10 U/kg/leg (N=79) | 15 U/kg/leg (N=79) | ||
LS mean change from baseline in ankle plantar MAS score Week 4 | –0.5 | –0.9 | –1.0 |
Week 12 | –0.5 | –0.8 | –1.0 |
LS mean score for PGA response to treatment Week 4 | 0.7 | 1.5 | 1.5 *** |
Week 12 | 0.4 | 0.8 | 1.0 |
LS mean GAS score [a] Week 4 Week 12 | 46.2 45.9 | 51.5 *** 52.5 *** | 50.9 50.5 |
p < 0.05; **p < 0.003; ***p < 0.0006 compared to placebo; LS = least square [a] GAS score measures progress towards goals that were selected at baseline from a list of twelve categories. The five most commonly selected goals were improved walking pattern (70.2%), improved balance (32.3%), decreased frequency of falling (31.1%), decreased frequency of tripping (19.6%) and improved endurance (17.0%) |
Improvement in the spasticity of the ankle plantar flexors was observed, as assessed by the Tardieu scale. The spasticity grade (Y) was statistically significantly improved compared to placebo for both the 10 units/kg/leg and 15 units/kg/leg Dysport treatment groups at Week 4 and Week 12, and the angle of catch (Xv3) was significant for the 10 units/kg/leg Dysport group at Week 12 and at both Week 4 and Week 12 for the 15 units/kg/leg Dysport group.
Both Dysport treatment groups, 10 units/kg/leg and 15 units/kg/leg, demonstrated a significant improvement from baseline in the Observational Gait Scale (OGS) overall score at Week 4 when compared to placebo and a statistically significantly higher proportion of patients were treatment responders for initial foot contact on the OGS at Week 4 and Week 12.
Parents completed the condition-specific Module for cerebral palsy for the Paediatric Quality of Life Inventory. There was a statistically significant improvement from baseline in fatigue at Week 12 in the Dysport 10 units/kg/leg and 15 units/kg/leg Dysport treatment groups compared to placebo. No other statistically significant improvements were observed in the other subscales.
On completion of this study, 216 patients entered an open-label extension study (Y-55–52120–147) where they could receive re-treatment based on clinical need. Both distal (gastrocnemius, soleus and tibialis posterior) and proximal (hamstrings and hip adductors) muscles were permitted to be injected, including multilevel injections.
Efficacy was observed over repeated treatment sessions for up to 1 year as assessed by MAS, PGA and GAS.
Focal spasticity of upper limbs in paediatric cerebral palsy patients, two years of age or older
The efficacy and safety of Dysport for the treatment of upper limb spasticity in children was evaluated in a randomised, multi-centre, double-blind, controlled, study in which doses of 8 U/kg and 16 U/kg in the selected study upper limb were compared with a low dose control group of 2 U/kg. A total of 210 botulinum toxin naïve or non-naïve patients with upper limb spasticity due to cerebral palsy (Modified Ashworth Scale (MAS) score >2 in the primary targeted muscle group (PTMG)) were randomised and treatedin the study.
The total dose of Dysport was injected intramuscularly into the affected upper limb muscles which
included the PTMG of either elbow flexors or wrist flexors as well as other upper limb muscles
according to the disease presentation. No more than 0.5 ml was allowed to be administered per
injection site. However more than one injection site per muscle was permitted.
An Electrical stimulation (ES) and/or ultrasound was used to assist muscle localisation for injection.
After the initial treatment, up to 3 further treatments of Dysport could be administered at planned doses of either 8 U/kg or 16 U/kg, although the investigator could elect to increase or decrease the dose (but not exceeding 16 U/kg). The minimum retreatment interval was 16 weeks. For treatment
cycles 2, 3 and 4, injection into the lower limbs and the non-study upper limb was also allowed at
the same time as the study upper limb was injected. Subjects were followed-up for a minimum of 1 year to a maximum of 1 year 9 months after entry into the study.
The primary efficacy variable was the mean change from baseline in MAS in PTMG at Week 6. Secondary efficacy variables were the mean Physicians Global
Assessment (PGA) score and mean Goal Attainment Scale (GAS) score at Week 6.
MAS Change from Baseline at Week 6 and Week 16,
PGA and GAS at Week 6 and Week 16 – Treatment Cycle 1 (mITT)
Dysport 2 U/kg (N=69) | Dysport 8 U/kg (N=69) | Dysport 16 U/kg (N=70) | |
Week 6 LS Mean Change from Baseline in PTMG MAS score Difference in LS Means (95% CI) compared to 2 U/kg | –1.5 | –1.9 –0.4 (-0.8, –0.1) | –2.2 –0.7 (-1.0, –0.4) |
Week 16 LS Mean Change from Baseline in PTMG MAS score Difference in LS Means (95% CI) compared to 2 U/kg | –1.0 | –1.3 –0.3 (-0.7, 0.0) | –1.6 –0.6 (-1.0, –0.3) |
Week 6 |
LS Mean Change from Baseline in Wrist Flexors MAS score Difference in LS Means (95% CI) compared to 2 U/kg | –1.3 | –1.5 –0.2 (-0.6, 0.2) | –1.7 –0.3 (-0.7, 0.0) |
Week 16 LS Mean Change from Baseline in Wrist Flexors MAS score Difference in LS Means (95% CI) compared to 2 U/kg | –0.9 | –1.0 –0.0 (-0.4, 0.4) | –1.2 –0.2 (-0.6, 0.1) |
Week 6 LS Mean Change from Baseline in Elbow Flexors MAS score Difference in LS Means (95% CI) compared to 2 U/kg | –1.1 | –1.7 –0.7 (-1.0, –0,3) | –1.9 –0.8 (-1.2, –0,5) |
Week 16 LS Mean Change from Baseline in Elbow Flexors MAS score Difference in LS Means (95% CI) compared to 2 U/kg | –0.6 | –1.1 –0.5 (-0.9, –0.1) | –1.3 –0.7 (-1.1, –0.4) |
Week 6 LS Mean Change from Baseline in Finger Flexors MAS score Difference in LS Means (95% CI) compared to 2 U/kg | –0.6 | –1.5 –0.9 (-1.4, –0.4) | –1.4 –0.7 (-1.3, –0.2) |
Week 16 LS Mean Change from Baseline in Finger Flexors MAS score Difference in LS Means (95% CI) compared to 2 U/kg | –0.7 | –1.1 –0.4 (-1.0, 0.2) | –1.4 –0.7 (-1.4, –0.1) |
Week 6 LS Mean PGA score Difference in LS Means (95% CI) compared to 2 U/kg | 1.8 | 2.0 0.3 (-0.0, 0.6) | 2.0 0.2 (-0.1, 0.5) |
Week 16 LS Mean PGA score Difference in LS Means (95% CI) compared to 2 U/kg | 1.7 | 1.6 –0.1 (-0.4, 0.3) | 1.8 0.1 (-0.2, 0.5) |
Week 6 LS Mean Total GAS score [a] Difference in LS Means (95% CI) compared to 2 U/kg | 52.1 | 52.6 0.5 (-2.7, 3.7) | 52.6 0.5 (-2.6, 3.7) |
Week 16 LS Mean Total GAS score [a] Difference in LS Means (95% CI) compared to 2 U/kg | 55.1 | 54.2 –0.9 (-4.4, 2.7) | 55.7 0.6 (-2.9, 4.1) |
LS=least square PTMG: elbow flexors or wrist flexors * p< 0.05; **p< 0.001; *** p< 0.0001; compared to 2 U/kg dose group [a] The four most commonly selected primary goals were Reaching, Grasp and release, Use of limb as a helping hand to stabilise and Involving affected arm more in daily activities. |
Improvement in the spasticity of the PTMG was observed, as assessed by the Tardieu scale. In the PTMG elbow flexors, the angle of catch (Xv3) was statistically significantly improved compared with Dysport 2 U/kg at Week 6 for both the 8 and 16 U/kg treatment groups and also at Week 16 for the Dysport 16 U/kg group. In addition, a statistically significant decrease from Baseline in spasticity grade (Y) at Week 6 and 16 was observed for the Dysport 16 U/kg group compared with Dysport 2 U/kg. In the PTMG wrist flexors, statistically significant improvements from Baseline in Xv3 and Y were observed in the Dysport 16 U/kg group compared with the Dysport 2 U/kg group at Week 6 but not for the 8 U/kg group.
Parents completed the condition-specific Module for Cerebral Palsy for the Paediatric Quality of Life Inventory. At Week 16, there was a statistically significant improvement from Baseline in fatigue (p=0.0251) in the Dysport 8 U/kg group and, in movement and balance (p=0.0253) in the 16 U/kg group compared with the Dysport 2 U/kg group. No other statistically significant improvements were observed in the other subscales.
The majority of subjects treated with Dysport were retreated by Week 28 (62.3% in the Dysport 8 U/kg group and 61.4% in the Dysport 16 U/kg group), though more than 24% of subjects in both treatment groups had not yet required retreatment by Week 34.
Following repeated treatment, efficacy was generally maintained across treatment cycles for both
Dysport 8 U/kg and 16 U/kg groups.
Axillary hyperhidrosis
The efficacy and safety of Dysport for the treatment of Axillary Hyperhidrosis was evaluated in a multi-centre, randomised, double-blind clinical study that included 152 adult patients with Axillary Hyperhidrosis who had symptoms for greater than one year and had failed standard therapy. Patients were injected with 200U in one axilla and placebo into the other. Two weeks later patients were injected with 100U Dysport in the axilla previously injected with placebo.
At the primary end point i.e. two weeks after treatment with Dysport, efficacy was measured as PCF (Proportional Change Function of sweat production on gravimetric analysis mg/min) relative to baseline. The results are shown below:
PCF in Sweat Production 2 Weeks Post injection | Dysport 200U (N=152) | Dysport 100U (N=151) | Placebo (N=152) |
Mean reduction (SD) | –0.814 (0.239) *# | –0.769 (0.257) | –0.051 (0.546) |
% reduction | 81.4 | 76.9 | 5.1 |
Median reduction [range] | –0.900 [-1.000; 0.545] | –0.845 [-1.000; 0.835] | –0.110 [-0.917; 3.079] |
PCF = proportional change function; SD = standard | deviation; U = units; vs =versus |
*Paired t-test Dysport 200U vs placebo: p<0.0001
#Paired t-test Dysport 200U vs Dysport 100U: p=0.0416
In the same study absolute sweat production was a secondary endpoint: 200U Dysport treatment resulted in an average absolute sweat production decrease from 165 ± 112 mg/min to 24 ± 27 mg/min 2 weeks after injection, and 86.2 % of patients achieved an absolute sweat rate of less than 50 mg/min. The 100U treatment resulted in an average absolute sweat production decrease from 143 ± 111mg/min to 31 ± 48 mg/min 2 weeks after injection, and 83.4% of patients achieved an absolute sweat rate of less than 50 mg/min. The placebo treatment resulted in an average absolute sweat production decrease from 173 ± 131mg/min to 143 ± 111 mg/min 2 weeks after injection, and 3.9 % of patients achieved an absolute sweat rate of less than 50 mg/min.
Efficacy was observed for up to 48 weeks. Subsequent injections under a follow up open label study showed a similar decrease in sweating though there was some evidence that duration of effect may persist for longer in subsequent treatment cycles.
5.2 Pharmacokinetic properties
Pharmacokinetic studies with botulinum toxin pose problems in animals because of the high potency, the minute doses involved, the large molecular weight of the compound and the difficulty of labelling toxin to produce sufficiently high specific activity. Studies using I125 labelled toxin have shown that the receptor binding is specific and saturable, and the high density of toxin receptors is a contributory factor to the high potency. Dose and time responses in monkeys showed that at low doses there was a delay of 2–3 days with peak effect seen 5–6 days after injection. The duration of action, measured by changes of ocular alignment and muscle paralysis varied between 2 weeks and 8 months. This pattern is also seen in man, and is attributed to the process of binding, internalisation and changes at the neuromuscular junction.
5.3 Preclinical safety data
In a chronic toxicity study performed in rats, up to 12 units/animal, there was no indication of systemic toxicity. Reproductive toxicity studies in pregnant rats and rabbits given Clostridium botulinum type A toxin-haemagglutinin complex by daily intramuscular injection, at doses of 6.6 units/kg (79 units/kg total cumulative dose) and 3.0 units/kg (42 units/kg total cumulative dose) in rats and rabbits respectively, did not result in embryo/fetal toxicity. Implantation losses at maternally toxic doses were observed at higher doses in both species. Clostridium botulinum type A toxinhaemagglutinin complex demonstrated no teratogenic activity in either rats or rabbits and no effects were observed in the pre- and postnatal study on the F1 generation in rats. Fertility of male and female rats was decreased due to reduced mating, secondary to muscle paralysis, at doses of 29.4 units/kg weekly in males and increased implantation loss at 20 units/kg weekly in females (see section 4.6).
In a pivotal single dose study, juveniles showed a slight delay in sexual maturation (not observed in the repeat dose study), an effect associated with decreased body weight, but subsequent mating performance and fertility were unaffected. In a pivotal repeated dose juvenile study, rats treated weekly from the age of weaning on Postnatal Day 21 up to 13 weeks of age comparable to children of 2 years old, to young adulthood (11 administrations over 10 weeks, up to total dose of approximately 33 units/kg) do not show adverse effects on postnatal growth (including skeletal evaluation), reproductive, neurological and neurobehavioral development.
The effects in reproduction, juvenile and chronic toxicity non-clinical studies were limited to changes in injected muscles related to the mechanism of action of Clostridium botulinum type A toxin-haemagglutinin complex.
There was no ocular irritation following administration of Clostridium botulinum type A toxin-haemagglutinin complex into the eyes of rabbits.
6 PHARMACEUTICAL PARTICULARS
6.1 List of excipients
Human albumin Lactose.
6.2 Incompatibilities
In the absence of compatibility studies, this medicinal product must not be mixed with other medicinal products.
6.3 Shelf lifeUnopened vial:
2 years
Chemical and physical in-use stability has been demonstrated for 24 hours at 2°C –8°C.
From a microbiological point of view, unless the method of reconstitution precludes the risk of microbial contamination, the product should be used immediately. If not used immediately, in-use storage times and conditions prior to use are the responsibility of the user.
6.4 Special precautions for storageUnopened vial:
Store in a refrigerator (2°C-8°C).
Do not freeze.
For storage conditions after reconstitution of the medicinal product, see section 6.3.
6.5 Nature and contents of container
3 ml vial (type 1 glass) with a stopper (bromobutyl rubber), with an overseal (aluminium), containing 500 units of botulinum toxin type A powder for solution for injection.
Pack sizes of 1 or 2 vials.
Not all pack sizes may be marketed.
6.6 Special precautions for disposal and other handling
When preparing and handling Dysport solutions, the use of gloves is recommended. If Dysport dry powder or reconstituted solution should come into contact with the skin or mucous membranes, they should be washed thoroughly with water.
The exposed central portion of the rubber stopper should be cleaned with alcohol immediately prior to piercing the septum. A sterile 23 or 25 gauge needle should be used.
Each vial is for single use only.
Reconstitution instructions are specific for each of the 300 unit vial and the 500 unit vial. These volumes yield concentrations specific for the use for each indication.
Resulting Dose Unit per ml | Diluent* per 500U vial | Diluent* per 300U vial |
500U | 1 ml | 0.6 ml |
200U | 2.5 ml | 1.5 ml |
100U | 5 ml | 3 ml |
*Preservative-free 0.9 % sodium chloride injection
For paediatric cerebral palsy spasticity, which is dosed using unit per body weight, further dilution may be required to achieve the final volume for injection.
Appearance of product after reconstitution:
A clear, colourless solution, free from particulate matter.
Immediately after treatment of the patient, any residual Dysport which may be present in either vial or syringe should be inactivated with dilute hypochlorite solution (1 % available chlorine).
Spillage of Dysport should be wiped up with an absorbent cloth soaked in dilute hypochlorite solution.
Any unused product or waste material should be disposed of in accordance with local requirements.
7 MARKETING AUTHORISATION HOLDER
Ipsen Limited
190 Bath Road
Slough
Berkshire
SL1 3XE
United Kingdom
8 MARKETING AUTHORISATION NUMBER(S)
8 MARKETING AUTHORISATION NUMBER(S)PL 34926/0001