Does Reducing Spasticity Permit an Increase in Strength?

Condition(s) targeted: Spastic Diplegic Cerebral Palsy

Intervention: baclofen (Drug)

Phase: Phase 2

Status: Completed

Sponsored by: Stanford University

Official(s) and/or principal investigator(s):
Terence Sanger, md,phd, Principal Investigator, Affiliation: Stanford University

Reduction of spasticity has been a major focus of the treatment of childhood cerebral palsy, resulting in numerous treatment strategies that target various parts of the motor system. However, in many children weakness may be a greater contributor to disability than spasticity. Recent results suggest a correlation between spasticity and weakness, but it is not known if reduction of spasticity can improve strength.

We suggest a simplified model in which spinal mechanisms (including reflex contributions to spasticity) and supraspinal mechanisms (including voluntary contributions to strength) combine to activate muscle. The model implies that the supraspinal contribution cannot increase unless the spinal contribution decreases. We therefore hypothesize that reduction of spasticity improves the ability to increase voluntary strength.

We propose a double-masked placebo-controlled clinical trial combining treatment using the oral anti-spasticity medication baclofen with a 6-week program of strength training. We will enroll 20 ambulatory children with spastic diplegic cerebral palsy. Prior to and following the intervention, we will obtain quantitative measures of spasticity, strength, and gait. We predict that the children taking baclofen will have a greater increase in strength than the children taking placebo. We predict that the increase in strength will be reflected in improved performance on gait analysis, and it will correlate with a reduction in quantitative measures of spasticity and spinal reflex excitability.

If the hypothesis is correct, it will provide important new information on the relationship between spasticity and strength in children with cerebral palsy. It will provide the first measurements of the effect of baclofen on voluntary muscle activation in children. It will support the short-term use of combined anti-spasticity medication and strengthening as a new clinical treatment for ankle weakness in children with spastic diplegia. A successful result will have immediate and significant implications for treatment of children with cerebral palsy.

Official title: Does Reducing Spasticity Permit an Increase in Strength?

Study design: Treatment, Non-Randomized, Open Label, Uncontrolled, Single Group Assignment, Efficacy Study

Primary outcome: Maximal Voluntary Contraction

Secondary outcome: H reflex

Minimum age: 5 Years. Maximum age: 18 Years. Gender(s): Both.

Criteria:

Inclusion Criteria:

- 1. Diagnosis of Cerebral Palsy 2. Spasticity at extensor muscle groups of one or both

ankles according to the definition of the Task Force on Childhood Motor Disorders, and as evidenced by the presence of a spastic catch or velocity-dependent hypertonia on rapid passive muscle lengthening while the subject attempts to maintain a relaxed state 3. Ambulatory without assistive devices 4. Sufficient ability to follow instructions to be able to comply with the strengthening program and strength testing

Exclusion Criteria:

- 1. Contracture at the ankle, or a limitation of the passive range of motion such that

neutral position is not achievable with the knee extended.

2. Hypersensitivity or allergy to Baclofen or related medications, or any medical condition that would be expected to increase the risks of this study 3. Respiratory difficulty due to weakness, restrictive lung disease, obstructive lung disease, tracheomalacia, or laryngeal weakness 4. Renal failure or chronic kidney disease 5. Pregnancy or planned pregnancy (sexually active girls will be asked to take a urine pregnancy test prior to study entry) 6. Difficulty maintaining head position while standing or seated 7. Current use of other anti-spasticity agents, including valium, tizanidine, clonidine, dantrolene, or similar agents 8. Use of oral baclofen within 3 months prior to study entry 9. Injection of botulinum toxin into the calf muscles within 3 months prior to study entry 10. Prior implantation of a baclofen pump or deep-brain stimulator 11. Seizure within previous two years 12. Lower extremity dystonia 13. Bradykinesia or evidence of parkinsonism 14. Spinal cord injury 15. Neurodegenerative disease 16. Ankle, foot, lower leg, or Achilles tendon surgery within the previous year 17. Dorsal rhizotomy or neurotomy

Stanford University, Stanford, California 94305-5235, United States

Starting date: January 2005
Ending date: April 2006
Last updated: March 1, 2007