Clinical Trials Logo

Clinical Trial Summary

Despite the wide-spread use of botulinum toxin (BT) to treat spasticity (increased muscle tone) in central neurological disease, evidence-based guidance on dosing, dilution, and injection technique is limited. The wide-spread use of BT in spasticity management, expense of these agents, and detrimental impact from movement into non-injected muscles mandates a better understanding of BT movement within muscles. A proof-of-concept paper written by investigators at Weill Cornell Medicine introduced a non-invasive MRI approach with "voxel thresholds" that was able to detect intramuscular effects of BT at 2 and 3 months post-injection of BT. The purpose of the current set of studies is to refine this MRI technique to better visualize the movement of botulinum toxin through muscle. In addition, the investigators plan to explore, using the imaging technique, how spastic muscle and differing dilutions affect BT movement in an effort to support the development of better research techniques to study toxin movement in human muscle.


Clinical Trial Description

The research questions for the present study series are as followed: 1. How does the movement and morphology of BT muscle effect (BTME) differ between standardized, research injections into spastic and non-spastic lateral gastrocnemius muscle (LGM)? 2. How does the movement and morphology of BTME differ between a standardized, research injection into spastic LGM versus an injection using the same dose in a 100% greater dilution? 3. Is there a predictable BTME within a given muscle following lower extremity BT clinical injections based on clinical need? The two hypotheses are as followed: First, it is predicted that BT muscle effect (BTME) will be greater in normal muscle than in spastic muscle. Second, it is predicted that BTME will increase with increasing dilution. The standard BT injection will be an injection of 25 units of onobotulinumtoxinA (Botox®) diluted in 0.25cc of saline. The experimental BT injection will be an injection of 25 units of onobutilinumtoxinA (Botox®) diluted in 0.50cc of saline. The clinical BT injection will be an injection of up to 200 units of onobutilinumtoxinA (Botox®) to any clinically indicated muscle or combinations of muscle in the spastic leg. Dose, dilution, and site of injection will be determined by the PI and all parameters of each injection tracked for future reference. At baseline, subjects will receive research injections that are decided based on the research protocol. Given the very small dosage of the research BT injections, the investigators do not anticipate seeing any symptomatic effects in subjects. At 3 months following research injections, subjects will receive clinical injections that are decided based on their clinical need and are anticipated to result in clinical benefit for subjects. All subjects will have an MRI at baseline (MRIB), at 2M (months) following research injections (MRI2), and at 2M following clinical injections (MRI3). Experiment #1 - Pilot: The pilot experiment will be done to inform the study design for the subsequent experiments. For the pilot experiment, after a baseline MRI, 6 subjects will be randomized into three groups (N=2 in each group): standard injection in LGM, experimental injection in LGM, or experimental injection in medial gastrocnemius muscle (MGM). All 6 subjects will receive a standard injection to the non-spastic LGM. Subjects will undergo a second MRI 2 months after the research injections, which will be used to confirm the design of the subsequent experiments. If, for the data from the investigator's pilot study of N=6 subjects, the investigators find on MRI2 a similar appearance and volume of BTME (BTME volume +/- 20%) for both the LGM and MGM receiving the experimental injection and that the BTME is contained within each muscle, the investigators will have the option of proceeding with the within-subject design where each subject serves as his or her own control, receiving either the research or experimental injection in the spastic LGM and the alternative injection in the spastic MGM. If the within-subject design is used, 15 subjects will be recruited. If the BTME volumes for the LGM and MGM receiving the experimental injection are not within +/- 20% of each other, or the investigators see on the MRI that the BTME is not contained within each injected muscle, then a between subject design will be used where subjects will be randomized to receive either the experimental or standard injection to the spastic LGM and 25 subjects will be recruited. Subjects will receive clinical injections 3 months following the research injections and undergo a final MRI 2 months following clinical injections. Recruitment for the subsequent experiments will begin after data analysis from the second MRI in experiment #1 is complete. Experiment #2 (Effect of dilution, answer Research Question #1): If using a within-subject design, subjects will be randomized to receive a standard injection to either the LGM or MGM. The experimental injection will be delivered to the muscle not receiving the standard injection. If using a between-subjects design, subjects will be randomized to receive either a standardized injection in the LGM or an experimental injection in the LGM. On the same day of, but before the injection, the MRIB will be acquired. Using the localization schema proposed in the investigator's proof-of-concept study, the baseline scan will be used to determine the coordinates and depth of the injection into a given muscle. Two months (+/- 1 week) after the injection, subject will report for MRI2 and will be considered finished with Experiment #2. He/she will be scheduled for the "clinical" injection 5 weeks (+/- 1 week) from that time, which will be evaluated in Experiment #4. Experiment #3 (spastic vs. non spastic muscle, answer Research Question #2): Experiment #3 will take place simultaneously and within the same subject population as Experiment #2. Regardless of whether a within- or between subject design is adopted in Experiment #2, all subjects will also receive a standard injection to the non-spastic LGM. The same technique using MRIB for muscle localization and the same protocol for obtaining MRI2 employed in Experiment #2 will be used for Experiment #3, at the same time points. Subjects will be scheduled for the "clinical" injection 5 weeks (+/- 1 week) from the time of MRI2, as mentioned under the description for Experiment #2. Experiment #4: As described previously, all subjects that participated in Experiments #2 and #3 will undergo a cycle of clinically-based BT injections to the spastic lower extremity no sooner than 3 months after the research injections and about 1 month after MRI2. Potentially, any lower extremity muscle or combination of muscles may be injected based on clinical evaluation and need. The investigators reserve the right to limit the total dose of toxin injected to no more than 200 units of onobotulinumtoxinA. This would be a reasonable dose in clinical practice for the first cycle of lower extremity injections in a toxin-naive patient. All subjects will receive a third and final leg MRI3 2 months following the clinical injection, marking the end of this study approximately 5 months after the initial randomization in Experiment #2. ;


Study Design


Related Conditions & MeSH terms


NCT number NCT03367429
Study type Interventional
Source Weill Medical College of Cornell University
Contact
Status Terminated
Phase Phase 4
Start date June 15, 2018
Completion date September 18, 2019

See also
  Status Clinical Trial Phase
Recruiting NCT04043052 - Mobile Technologies and Post-stroke Depression N/A
Recruiting NCT03869138 - Alternative Therapies for Improving Physical Function in Individuals With Stroke N/A
Completed NCT04034069 - Effects of Priming Intermittent Theta Burst Stimulation on Upper Limb Motor Recovery After Stroke: A Randomized Controlled Trial N/A
Completed NCT04101695 - Hemodynamic Response of Anodal Transcranial Direct Current Stimulation Over the Cerebellar Hemisphere in Healthy Subjects N/A
Terminated NCT03052712 - Validation and Standardization of a Battery Evaluation of the Socio-emotional Functions in Various Neurological Pathologies N/A
Completed NCT00391378 - Cerebral Lesions and Outcome After Cardiac Surgery (CLOCS) N/A
Recruiting NCT06204744 - Home-based Arm and Hand Exercise Program for Stroke: A Multisite Trial N/A
Active, not recruiting NCT06043167 - Clinimetric Application of FOUR Scale as in Treatment and Rehabilitation of Patients With Acute Cerebral Injury
Active, not recruiting NCT04535479 - Dry Needling for Spasticity in Stroke N/A
Completed NCT03985761 - Utilizing Gaming Mechanics to Optimize Telerehabilitation Adherence in Persons With Stroke N/A
Recruiting NCT00859885 - International PFO Consortium N/A
Recruiting NCT06034119 - Effects of Voluntary Adjustments During Walking in Participants Post-stroke N/A
Completed NCT03622411 - Tablet-based Aphasia Therapy in the Chronic Phase N/A
Completed NCT01662960 - Visual Feedback Therapy for Treating Individuals With Hemiparesis Following Stroke N/A
Recruiting NCT05854485 - Robot-Aided Assessment and Rehabilitation of Upper Extremity Function After Stroke N/A
Active, not recruiting NCT05520528 - Impact of Group Participation on Adults With Aphasia N/A
Completed NCT03366129 - Blood-Brain Barrier Disruption in People With White Matter Hyperintensities Who Have Had a Stroke
Completed NCT05805748 - Serious Game Therapy in Neglect Patients N/A
Completed NCT03281590 - Stroke and Cerebrovascular Diseases Registry
Recruiting NCT05621980 - Finger Movement Training After Stroke N/A